JP7509090B2 - Dehumidifier - Google Patents

Description

This disclosure relates to a dehumidifier.

The conventional dehumidifier disclosed in the following Patent Document 1 is configured to be able to perform at least two levels of warning operation in response to at least two levels of water level in the water storage section.

JP 2020-12592 A

In conventional dehumidifiers, if more than two water levels were to be notified to the user in order to provide more precise water level notification, it would be necessary to increase the number of water level detection means, which would result in additional costs for installing the water level detection means and would tend to make the configuration more complicated.

This disclosure has been made to solve the problems described above, and aims to provide a dehumidifier that is advantageous in terms of lower cost and improved usability.

The dehumidifier according to the present disclosure comprises a housing having an intake port and an exhaust port, a blowing means for generating an airflow so that air flowing into the housing from the intake port flows out of the housing from the exhaust port, a dehumidifying means provided inside the housing for removing moisture from the air, a water storage means for storing the moisture removed by the dehumidifying means as liquid water, a water level detection means for detecting the water level in the water storage means, a water level notification means for performing an alarm operation related to the water level in the water storage means, and a water level notification control means for controlling the water level notification means based on a signal from the water level detection means, and at least two water level detection means are provided, and at least two water levels can be detected by ON signals output from the at least two water level detection means, and at least three water levels can be detected by detecting the water level between the at least two water level detection means by OFF signals output from the water level detection means, and the water level notification means can perform an alarm operation at at least three water levels.

This disclosure makes it possible to provide a dehumidifier that is advantageous in terms of lower cost and improved ease of use.

1 is a perspective view of a dehumidifier according to a first embodiment. FIG. 1 is a front view of a dehumidifier according to a first embodiment. FIG. 2 is a side view of the dehumidifier according to the first embodiment. 1 is a vertical cross-sectional view of a dehumidifier according to a first embodiment. FIG. 2 is a schematic side view showing the configuration of a water storage section, a first water level sensor, a full water level sensor, and a float in embodiment 1. FIG. FIG. 2 is a functional block diagram of the dehumidifier according to the first embodiment. 4 is a flowchart showing a control operation in the dehumidifier of the first embodiment. 11A and 11B are diagrams showing the state of the water storage section before and after a first water level is detected. 13A and 13B are diagrams showing the state of the water storage section before and after the second water level is detected. 13A and 13B are diagrams showing the state of the water storage section before and after the full water level is detected. A schematic side view showing the configuration of a water storage section, a first water level sensor, a full water level sensor, a third water level sensor, and a float in embodiment 2. FIG. 11 is a functional block diagram of a dehumidifier according to a second embodiment. 10 is a flowchart showing a control operation in the dehumidifier of the second embodiment. A schematic diagram showing the lighting state of the first water level LED, the second water level LED, the third water level LED, the fourth water level LED, and the full water LED in embodiment 2. FIG. 11 is a functional block diagram of a dehumidifier according to a third embodiment. 13 is a schematic diagram showing the display state of a water level LED by a water level notification unit. FIG. 13 is a flowchart showing a control operation in the dehumidifier of the third embodiment.

The following describes the embodiments with reference to the drawings. Elements that are common or correspond to each other in each drawing are given the same reference numerals, and the description is simplified or omitted.

Embodiment 1.
Fig. 1 is a perspective view of a dehumidifier 100 according to the first embodiment. Fig. 2 is a front view of the dehumidifier 100 according to the first embodiment. Fig. 3 is a side view of the dehumidifier 100 according to the first embodiment. Figs. 1, 2 and 3 are views showing the external appearance of the dehumidifier 100.

Here, the up-down direction on the paper in FIG. 2 is the up-down direction of the dehumidifier 100. The front direction of the paper in FIG. 2 is the front direction of the dehumidifier 100. The back direction of the paper in FIG. 2 is the rear direction of the dehumidifier 100. In FIG. 2, the left direction on the paper is the right direction of the dehumidifier 100, and the right direction on the paper is the left direction of the dehumidifier 100.

The left-right direction on the paper in FIG. 3 corresponds to the front-rear direction of the dehumidifier 100. The up-down direction on the paper in FIG. 3 corresponds to the up-down direction of the dehumidifier 100. In FIG. 3, the front side of the paper corresponds to the left side of the dehumidifier 100, and the back side of the paper corresponds to the right side of the dehumidifier 100.

Figure 4 is a vertical cross-sectional view of the dehumidifier 100 of the first embodiment. Figure 4 shows a cross-section of the dehumidifier 100 at the position A-A in Figure 2. Figure 4 shows a schematic diagram of the internal structure of the dehumidifier 100. The up, down, left, and right directions on the paper in Figure 4 correspond to the up, down, left, and right directions on the paper in Figure 3.

The dehumidifier 100 includes a housing 1. The housing 1 is a member that forms the outer shell of the dehumidifier 100. The housing 1 is formed, for example, in the shape of a vertically long box that can stand on its own. The dehumidifier 100 may include wheels 2. The wheels 2 are provided, for example, on the bottom of the housing 1. The wheels 2 allow a user to easily move the dehumidifier 100.

The housing 1 has an intake port 3 and an exhaust port 4. The intake port 3 is an opening for taking in air into the housing 1. The intake port 3 is formed, for example, on the rear surface of the housing 1. The exhaust port 4 is an opening for blowing air from the inside of the housing 1 to the outside. The exhaust port 4 is formed, for example, on the upper part of the front surface of the housing 1. The exhaust port 4 is shaped, for example, like a rectangle extending in the left-right direction of the housing 1.

An air passage 5 is formed inside the housing 1. The air passage 5 is a space that serves as a passage for air from the intake 3 to the exhaust 4. The dehumidifier 100 includes a blower fan 6a and a fan motor 6 as an example of a blowing means. The blower fan 6a generates an air current in the air passage 5 that flows from the intake 3 to the exhaust 4. The blower fan 6a is connected to the fan motor 6. The fan motor 6 is a device that rotates the blower fan 6a.

The blower fan 6a and the fan motor 6 are provided inside the housing 1. The blower fan 6a is disposed in the air passage 5. When the blower fan 6a rotates, an airflow is generated such that air that has flowed into the housing 1 from the intake port 3 passes through the air passage 5 and flows out of the housing 1 from the exhaust port 4. Here, in the air passage 5, the side where the intake port 3 is located is the upstream side, and the side where the exhaust port 4 is located is the downstream side. That is, in this embodiment, when the blower fan 6a rotates, air flows from the upstream side to the downstream side in the air passage 5.

The dehumidifier 100 includes a dehumidifier 7 as an example of a dehumidification means for removing moisture from the air. The dehumidifier 7 is a device that condenses moisture in the air and discharges it. As an example, the dehumidifier 7 drips the condensed moisture downward as liquid water. The dehumidifier 7 removes moisture from the air, i.e., dehumidifies the air. The air dehumidified by the dehumidifier 7 becomes dry air.

The dehumidifier 7 is, for example, a device that uses a heat pump circuit. The dehumidifier 7 that uses a heat pump circuit condenses moisture in the air using an evaporator. The dehumidifier 7 may be, for example, a desiccant type device. The desiccant type dehumidifier 7 has an adsorbent that adsorbs moisture in the air, a heater, and a heat exchanger. The moisture adsorbed by the adsorbent of the desiccant type dehumidifier 7 is heated by the heater. The moisture heated by the heater is cooled by the heat exchanger and condensed.

The dehumidifier 7 is provided inside the housing 1. The dehumidifier 7 is disposed in the air passage 5. As an example, the dehumidifier 7 is disposed between the air inlet 3 and the blower fan 6a. In this embodiment, the dehumidifier 7 is disposed upstream of the blower fan 6a. In this embodiment, the air inlet 3, the dehumidifier 7, the blower fan 6a, and the air outlet 4 are disposed in this order from the upstream side to the downstream side.

The dehumidifier 100 of this embodiment includes a water storage section 8 that stores the moisture removed by the dehumidification section 7 as liquid water. That is, the water storage section 8 has a function of storing water discharged from the dehumidification section 7. The water storage section 8 has, for example, a container-shaped member with an open top. The water storage section 8 is provided inside the housing 1, below the dehumidification section 7. The water storage section 8 receives and stores water dripped from the dehumidification section 7 through the opening at the top. This water storage section 8 is provided detachably with respect to the housing 1. The water storage section 8 of this embodiment is an example of a water storage means.

The dehumidifier 100 may also include a filter 9. The filter 9 is provided inside the housing 1. The filter 9 is provided so as to cover the intake port 3 from inside the housing 1. The filter 9 prevents dust and dirt from entering the inside of the housing 1.

Figure 5 is a schematic side view showing the configuration of the water storage section 8, the first water level sensor 10a, the full water level sensor 10b, and the float 20 in embodiment 1. Figure 6 is a functional block diagram of the dehumidifier 100 in embodiment 1. The dehumidifier 100 in this embodiment is equipped with a sensor unit 10. The sensor unit 10 detects the water level in the water storage section 8. As shown in Figure 5, as an example, the sensor unit 10 has a first water level sensor 10a and a full water level sensor 10b attached in close proximity to the water storage section 8. In this embodiment, each of the first water level sensor 10a and the full water level sensor 10b is an example of a water level detection means. Thus, in this embodiment, two water level detection means are arranged at positions at different heights from each other. The first water level sensor 10a and the full water level sensor 10b in this embodiment use float-type switches. A float switch is a device in which a float 20 moves up and down depending on the water level, and detects the water level by turning a reed switch on and off using a magnet 20a attached to the float 20. Note that the water level detection means in this disclosure is not limited to using a float switch, and may use any detection principle as long as it can detect the water level.

As shown in FIG. 5, as an example, the first water level sensor 10a can detect whether the water level in the water storage section 8 has reached the height of the first water level L1 by the magnet 20a of the float 20 reaching the ON area A1 of the first water level sensor 10a as the water level rises. In other words, when the magnet 20a reaches the ON area A1 as the water level rises, the first water level sensor 10a outputs an ON signal, thereby detecting that the first water level L1 has been reached. Note that in this disclosure, the water level detection means issuing an ON signal may be referred to as "ON detection" or "turning ON". Also, in this disclosure, the water level detection means issuing an OFF signal may be referred to as "OFF detection" or "OFF".

Similarly, the full water level sensor 10b can detect whether the water level in the water storage section 8 has reached the full water level by the magnet 20a of the float 20 reaching the ON area A3 of the full water level sensor 10b as the water level rises. In other words, when the magnet 20a reaches the ON area A3 as the water level rises, the full water level sensor 10b outputs an ON signal, thereby detecting that the full water level has been reached.

The first water level sensor 10a and the full water level sensor 10b are arranged so that the OFF area A2, which is not the ON area of either the first water level sensor 10a or the full water level sensor 10b, is located at a height between the ON area A1 and the ON area A3. As a result, after the first water level sensor 10a turns ON and detects the first water level L1, dehumidification progresses and the float 20 rises along with the water level, and by detecting the OFF signal of the first water level sensor 10a, it is possible to detect whether the water level in the water storage section 8 has reached the height of the second water level L2. The first water level L1 and the second water level L2 are water levels lower than the full water level. The second water level L2 corresponds to the water level between the first water level sensor 10a and the full water level sensor 10b. The first water level L1 may be, for example, a water level with a water storage volume of about 1/2 of the full water level, and the second water level L2 may be a water level with a water storage volume of about 3/4 of the full water level. Additionally, the locations of the first water level sensor 10a and the full water level sensor 10b may be changed depending on the water level to be detected.

The dehumidifier 100 is equipped with a water level notification unit 11 that performs a notification operation regarding the water level in the water storage unit 8. As shown in FIG. 1, as an example, the water level notification unit 11 has a first water level LED 11a, a second water level LED 11b, a full water LED 11c, a voice alarm 11d, and a liquid crystal display 11e. As shown in FIG. 1, the water level notification unit 11 is disposed, for example, on the rear side of the top surface of the housing 1. The water level notification unit 11 in this embodiment is an example of a water level notification means. The dehumidifier 100 can notify the user of information regarding the water level in the water storage unit 8 by having the water level notification unit 11 perform a notification operation based on the water level detected by the first water level sensor 10a and the full water level sensor 10b.

In this embodiment, the first water level LED 11a, the second water level LED 11b, and the full water LED 11c of the water level notification unit 11 use LEDs (light-emitting diodes) as light-emitting elements that perform the notification operation by emitting light, but it goes without saying that light-emitting elements other than LEDs, such as incandescent bulbs, halogen bulbs, neon tubes, fluorescent lights, and organic electroluminescence, may be used instead.

The dehumidifier 100 has a control device 12 that controls the water level notification unit 11 based on a signal from the sensor unit 10. As shown in FIG. 4, the control device 12 is provided, for example, inside the housing 1. The control device 12 is connected to each device provided in the dehumidifier 100. The control device 12 controls each device provided in the dehumidifier 100. As shown in FIG. 6, as an example, the control device 12 has an operation control unit 12a and a memory unit 12b. The control device 12 is electrically connected to each of the fan motor 6, the dehumidification unit 7, the sensor unit 10, and the water level notification unit 11.

The first water level sensor 10a and the full water level sensor 10b of the sensor unit 10 convert the detected water level information into an electrical signal such as a voltage. The first water level sensor 10a and the full water level sensor 10b transmit the converted electrical signal to the control device 12. The control device 12 controls the first water level LED 11a, the second water level LED 11b, the full water LED 11c, the audio alarm 11d, and the LCD display 11e based on the signals from the first water level sensor 10a and the full water level sensor 10b.

The memory unit 12b is an example of a storage means. A plurality of notification methods by the water level notification unit 11 are set in advance in the memory unit 12b. In the present embodiment, a first mode, a second mode, and a third mode are set as examples.

The operation control unit 12a in this embodiment functions as a water level notification control means that controls the water level notification unit 11 based on the signal from the sensor unit 10. The operation control unit 12a executes the first mode, second mode, and third mode processing based on the signals from, for example, the first water level sensor 10a and the full water level sensor 10b.

The operation control unit 12a executes one process from among multiple notification methods set in the memory unit 12b based on signals from the first water level sensor 10a and the full water level sensor 10b. For example, the operation control unit 12a controls the first water level LED 11a, the second water level LED 11b, the full water LED 11c, the audio alarm 11d, and the liquid crystal display 11e based on signals from the first water level sensor 10a and the full water level sensor 10b.

The sensor unit 10 only needs to be able to detect at least three different water levels. As described above, the sensor unit 10 of this embodiment can detect the first water level L1, the second water level L2, and the full water level as three different water levels.

The dehumidifier 100 of this embodiment includes an operation unit 13. The operation unit 13 is used by a user to operate the dehumidifier 100. As shown in FIG. 1, the operation unit 13 is disposed, for example, on the rear side of the top surface of the housing 1. As an example, the operation unit 13 has an operation button 13a.

The operation button 13a is operated by the user to start and stop the operation of the dehumidifier 100. The control device 12 and the operation unit 13 are electrically connected. The operation unit 13 transmits a signal corresponding to the operation by the user to the control device 12. The control device 12 controls the operation of the fan motor 6 and the dehumidification unit 7 based on the signal from the operation unit 13. As a modified example, the operation unit 13 may be provided with a stop button (not shown) in addition to the operation button 13a, and the user may press the stop button when stopping the operation of the dehumidifier 100. The alarm water level setting button 13b in FIG. 4 will be described later in embodiment 3.

The water level notification unit 11 may perform different notification operations at least at three water levels. The "different notification operations" are notification operations that the user can distinguish by senses such as vision or hearing. The water level notification unit 11 of this embodiment can perform a first mode notification operation, a second mode notification operation, and a third mode notification operation as three different notification operations. The operation control unit 12a controls the three-stage notification operation by the water level notification unit 11 according to the three-stage water level detected by the sensor unit 10. This provides the following effects. Since the water level notification unit 11 performs three-stage notification operations corresponding to the three different water levels in the water storage unit 8, the user is advantageous in accurately knowing the water level in the water storage unit 8. For example, the user is advantageous in knowing whether the water level in the water storage unit 8 is close to the full water level. As a result, the usability of the dehumidifier 100 is improved. For example, this is useful in preventing a situation in which a user starts the dehumidification operation of the dehumidifier 100 without knowing that the water level in the water storage section 8 is close to the full water level, and the water level in the water storage section 8 reaches the full water level within a short time after the operation starts, causing the dehumidifier 100 to automatically stop the dehumidification operation against the user's will.

When the control device 12 detects that the first water level sensor 10a is ON, it causes the water level notification unit 11 to perform a first mode notification operation. The first mode notification operation is as follows. As a first process, the audio alarm 11d is made to sound for a fixed period of time. As an example, a buzzer sound is made to sound for one second. After the audio alarm 11d sounds, the first water level LED 11a is turned on. This first mode notification operation can notify the user that the water level in the water storage unit 8 has reached the height of the first water level L1. The state in which the first water level LED 11a is turned on is referred to as the "first water level notification state."

When the dehumidifier 100 is in the first water level notification state and the first water level sensor 10a detects the OFF state, the control device 12 causes the water level notification unit 11 to perform the second mode notification operation. The second mode notification operation is as follows. As a first process, the audio alarm 11d is made to sound for a certain period of time. As an example, a buzzer sound is made to sound for one second. After the audio alarm 11d is made to sound, the second water level LED 11b is turned on. The color of the light emitted by the second water level LED 11b may be a color different from the color of the light emitted by the first water level LED 11a. This second mode notification operation can notify the user that the water level in the water storage unit 8 has reached the height of the second water level L2. The state in which the first water level LED 11a and the second water level LED 11b are turned on is referred to as the "second water level notification state."

When the dehumidifier 100 is in the second water level notification state and the full water level sensor 10b detects the ON state, the control device 12 causes the water level notification unit 11 to perform the third mode notification operation. The third mode notification operation is as follows. As the first process, the voice alarm 11d is made to sound for a certain period of time. As an example, a buzzer sound is made to sound for one second. After the voice alarm 11d sounds, the full water LED 11c is turned on. The light color of the full water LED 11c may be a color different from the light color of the first water level LED 11a and the second water level LED 11b. Furthermore, a predetermined full water display may be displayed on the liquid crystal display 11e. The full water display may include, for example, the characters "full water". According to such a third mode notification operation, the user can be notified that the water level in the water storage unit 8 has reached the height of the full water level. The state in which the first water level LED 11a, the second water level LED 11b, and the full water LED 11c are lit and the LCD display 11e shows the full water indication is called the "full water notification state."

The sound generated by the audio alarm 11d may not be a simple buzzer sound, but may be audio guidance, and multiple types of alert sounds to be uttered may be set in advance in the storage unit 12b. For example, the following alert sound 1, alert sound 2, and alert sound 3 may be set in the storage unit 12b as multiple types of alert sounds.

When the sensor unit 10 detects that the water level in the water storage unit 8 has reached the first water level L1, the audio alarm 11d emits an alert voice 1. The alert voice 1 may be, for example, "The water level in the tank has reached the intermediate water level."

When the sensor unit 10 detects that the water level in the water storage unit 8 has reached the second water level L2, the audio alarm 11d emits the notification sound 2. The notification sound 2 may be, for example, "The water level in the tank is almost full."

When the sensor unit 10 detects that the water level in the water storage unit 8 has reached the full water level, the audio alarm 11d emits the notification sound 3. The notification sound 3 may be, for example, "The water level in the tank is full."

In this embodiment, in the first water level notification state, only the first water level LED 11a is lit, and in the second water level notification state, the first water level LED 11a and the second water level LED 11b are lit. In the full water notification state, the first water level LED 11a, the second water level LED 11b, and the full water LED 11c are lit. This allows the user to reliably identify whether the dehumidifier 100 is in the first water level notification state, the second water level notification state, or the full water notification state based on the number of lit LEDs, even if the user views the dehumidifier 100 from a distance.

Water cannot be stored in the water storage section 8 beyond the full water level. Therefore, when the full water warning state occurs, the control device 12 automatically stops the dehumidification operation of the dehumidifier 100.

As described above, in this embodiment, the control device 12 causes the water level notification unit 11 to perform the first mode notification operation when the water level in the water storage unit 8 reaches the first water level L1, causes the water level notification unit 11 to perform the second mode notification operation when the water level in the water storage unit 8 reaches the second water level L2, and causes the water level notification unit 11 to perform the third mode notification operation when the water level in the water storage unit 8 reaches the full water level. This makes it possible to reliably notify the user of information regarding the water level in the water storage unit 8 at each of the timings when the water level in the water storage unit 8 reaches the first water level L1, when the water level in the water storage unit 8 reaches the second water level L2, and when the water level in the water storage unit 8 reaches the full water level. As a result, the usability of the dehumidifier 100 becomes even better.

Next, referring to FIG. 7, the operation of the dehumidifier 100 of the present embodiment will be further described. FIG. 7 is a flowchart showing the control operation of the dehumidifier 100 of the first embodiment. The dehumidifier 100 is used indoors, such as in a living room. In step S101, when a user presses the operation button 13a, the operation button 13a transmits a signal to the operation control unit 12a. When the operation control unit 12a receives a signal from the operation button 13a, it drives the fan motor 6 and the dehumidification unit 7. When the fan motor 6 is driven, the blower fan 6a rotates. The blower fan 6a generates an air flow. As shown in FIG. 4, the blower fan 6a takes in the indoor air P from the intake port 3 into the housing 1. The indoor air P is dehumidified by the dehumidification unit 7 to become dry air Q. The dry air Q is sent out from the air outlet 4 to the room by the blower fan 6a. In this manner, the dehumidifier 100 starts the dehumidification operation (step S102).

The moisture removed by the dehumidifier 7 is stored in the water storage unit 8 as liquid water. In step S103, the operation control unit 12a determines whether the first water level sensor 10a has detected that the water level in the water storage unit 8 has reached the first water level L1. If the water level in the water storage unit 8 has not yet reached the first water level L1, the process of step S103 is repeated, and the dehumidifier 100 continues the dehumidification operation.

Figure 8 shows the state of the water storage section 8 before and after the first water level L1 is detected. Figure 8 (a) shows the "NO" state in step S103, where the magnet 20a attached to the float 20 is located in the OFF area A0 of the first water level sensor 10a due to the water level. As the dehumidification progresses and the water level rises to the state shown in Figure 8 (b), the magnet 20a attached to the float 20 enters the ON area A1 of the first water level sensor 10a. This causes the first water level sensor 10a to perform an ON detection, detecting that the water level in the water storage section 8 has reached the first water level L1 (step S103 "YES" state).

If the answer is "YES" in step S103, the process proceeds to step S104, and the dehumidifier 100 executes the first mode notification operation. As the first process of the first mode notification operation, the operation control unit 12a causes the audio alarm 11d to sound in step S105. By causing the audio alarm 11d to sound, the user will pay attention to the dehumidifier 100 even if the user is far away from the dehumidifier 100. Next, in step S106, the operation control unit 12a turns on the first water level LED 11a. When the above-described first mode notification operation is executed, the dehumidifier 100 enters the first water level notification state (step S107).

When the dehumidifier 100 enters the first water level notification state, the process proceeds to step S108, where the operation control unit 12a determines whether the first water level sensor 10a detects that the water level in the water storage unit 8 has reached the second water level L2 by detecting whether the first water level sensor 10a is OFF. If the water level in the water storage unit 8 has not yet reached the second water level L2, the process returns to step S106, where the dehumidifier 100 continues dehumidification operation in the first water level notification state.

Figure 9 shows the state of the water storage section 8 before and after the second water level L2 is detected. Figure 9(a) shows the "NO" state in step S108, where the magnet 20a attached to the float 20 is located in the ON area A1 of the first water level sensor 10a due to the water level. As the dehumidification progresses and the water level rises to the state shown in Figure 9(b), the magnet 20a attached to the float 20 enters the OFF area A2 of the first water level sensor 10a. This causes the first water level sensor 10a to perform an OFF detection, detecting that the water level in the water storage section 8 has reached the second water level L2 (step S108 "YES" state).

If step S108 is "YES", the process proceeds to step S109, and the dehumidifier 100 executes the second mode notification operation. As the first process of the second mode notification operation, the operation control unit 12a causes the audio alarm 11d to sound in step S110. Next, the second water level LED 11b is turned on (step S111). When the second mode notification operation described above is executed, the dehumidifier 100 enters the second water level notification state (step S112).

When the dehumidifier 100 enters the second water level notification state, the process proceeds to step S113, where the operation control unit 12a determines whether the full water level sensor 10b has detected that the water level in the water storage unit 8 has reached the full water level by turning ON. If the water level in the water storage unit 8 has not yet reached the full water level, the process returns to step S111, and the dehumidifier 100 continues dehumidification operation in the second water level notification state.

Figure 10 shows the state of the water storage section 8 before and after the full water level is detected. Figure 10 (a) shows the "NO" state in step S113, where the magnet 20a on the float 20 is located in the OFF area A2 of the first water level sensor 10a and the full water level sensor 10b due to the water level. As the dehumidification progresses and the water level rises to the state shown in Figure 10 (b), the magnet 20a on the float 20 enters the ON area A3 of the full water level sensor 10b. This causes the full water level sensor 10b to perform an ON detection, detecting that the water level in the water storage section 8 has reached the full water level (step S113 "YES" state).

When step S113 is "YES", the process proceeds to step S114, and the dehumidifier 100 executes the third mode notification operation. As the first process of the second mode notification operation, the operation control unit 12a causes the audio alarm 11d to sound in step S115. Next, the full water LED 11c is turned on (step S116). Next, the operation control unit 12a causes the liquid crystal display 11e to display a full water display (step S117). When the third mode notification operation is executed as described above, the dehumidifier 100 enters a full water notification state (step S118). When the full water notification state is reached, the operation control unit 12a stops the dehumidification operation of the dehumidifier 100 (step S119).

The process proceeds from step S119 to step S120, where the operation control unit 12a determines whether the full water level sensor 10b continues to detect the full water level. If the full water level sensor 10b continues to detect the full water level, the operation control unit 12a repeats the process from step S116 onwards. As a result, the dehumidifier 100 maintains the full water notification state and continues to stop dehumidification operation.

In this embodiment, the water level notification unit 11 can reliably notify the user that the water level in the water storage unit 8 is high, i.e., that the water accumulated in the water storage unit 8 should be discarded, by the notification action of the water level notification unit 11. When the user receives such a notification action and performs the operation to discard the water accumulated in the water storage unit 8, the water level in the water storage unit 8 drops, and in step S120, the full water level sensor 10b no longer detects the full water level. When the full water level sensor 10b no longer detects the full water level, the process proceeds from step S120 to step S121.

In step S121, the operation control unit 12a turns off the first water level LED 11a, the second water level LED 11b, and the full water LED 11c, and disables the full water display on the LCD display 11e. The operation control unit 12a then repeats the process from step S102 onwards. As a result, the dehumidifier 100 resumes dehumidification operation.

In this embodiment, when the dehumidifier 100 enters the first water level notification state, when it goes from the first water level notification state to the second water level notification state, or when it goes from the second water level notification state to the full water notification state, the first water level LED 11a, the second water level LED 11b, the full water LED 11c, the voice alarm 11d, and the liquid crystal display 11e of the water level notification unit 11 can be combined to perform a step-by-step notification operation. Therefore, the user can accurately recognize the water level in the water storage unit 8 without having to frequently check the water level in the water storage unit 8, and can easily predict how much longer the dehumidification operation can be continued. According to this embodiment, the water level can be detected in three stages, making it possible to obtain a dehumidifier that is easy for the user to use.

In this embodiment, at least two water level detection means can be used to perform at least three levels of warning operation in response to at least three levels of water level in the water storage section 8, making it possible to provide a dehumidifier 100 that is advantageous in terms of lower cost and improved usability.

Embodiment 2.
Next, a second embodiment will be described with reference to Figures 11 to 14. The differences from the above-described embodiment will be mainly described, and descriptions of the same or corresponding parts will be simplified or omitted. The basic configuration of a dehumidifier 100 of the second embodiment is shown in Figures 1 to 4, similarly to the first embodiment. Descriptions of the same configuration and operation as the first embodiment will be omitted.

The dehumidifier 100 of this embodiment is equipped with three or more water level detection means for detecting the water level in the water storage section 8, and can detect water levels other than the first water level L1, the second water level L2, and the full water level. As an example, the sensor unit 10 of this embodiment has a third water level sensor 10c in addition to the first water level sensor 10a and the full water level sensor 10b. That is, in this embodiment, the three water level detection means are arranged at positions at different heights. Figure 11 is a schematic side view showing the configuration of the water storage section 8, the first water level sensor 10a, the full water level sensor 10b, the third water level sensor 10c, and the float 20 in embodiment 2. As shown in Figure 11, the third water level sensor 10c is arranged at a position where it can detect whether the water level in the water storage section 8 has reached the position L3. In this embodiment, the first water level sensor 10a, the full water level sensor 10b, and the third water level sensor 10c use float switches as in the first embodiment, but they are not limited to this and can use any detection principle as long as they can detect the water level.

As shown in FIG. 11, in this embodiment, the first water level sensor 10a has an ON area A1, the third water level sensor 10c has an ON area A3, and the full water level sensor 10b has an ON area A5. When the magnet 20a of the float 20 reaches the ON area of each water level sensor due to a change in the water level, it is possible to detect whether the water level in the water storage section 8 has reached the height of the first water level L1, the third water level L3, or the full water level, respectively. In addition, the first water level sensor 10a, the third water level sensor 10c, and the full water level sensor 10b are arranged so that the OFF area A2, which is not the ON area of either the first water level sensor 10a or the third water level sensor 10c, is located at a height between the ON area A1 and the ON area A3, and the OFF area A4, which is not the ON area of either the third water level sensor 10c or the full water level sensor 10b, is located at a height between the ON area A3 and the ON area A5. As a result, after the first water level sensor 10a turns ON and detects the first water level L1, dehumidification progresses and the float 20 rises along with the water level, and by detecting the OFF of the first water level sensor 10a, it is possible to detect whether the water level in the water storage section 8 has reached the height of the second water level L2. Also, after the third water level sensor 10c turns ON and detects the third water level L3, dehumidification progresses and the float 20 rises along with the water level, and by detecting the OFF of the third water level sensor 10c, it is possible to detect whether the water level in the water storage section 8 has reached the height of the fourth water level L4.

In this embodiment, the operation control unit 12a, as an example, executes the processing of the fourth and fifth modes set in the memory unit 12b based on a signal from the third water level sensor 10c.

The operation control unit 12a executes one process from among multiple notification methods set in the memory unit 12b based on signals from the first water level sensor 10a, the full water level sensor 10b, and the third water level sensor 10c. The operation control unit 12a controls the third water level LED 11f, the fourth water level LED 11g, and the audio alarm 11d based on a signal from the third water level sensor 10c.

When the control device 12 receives an ON signal from the third water level sensor 10c, which detects that the water level in the water storage section 8 has reached the third water level L3, it causes the water level notification section 11 to perform a fourth mode notification operation. In the fourth mode notification operation, the third water level LED 11f is turned on. By visually checking that the third water level LED 11f is turned on, the user can know that the water level in the water storage section 8 has reached the third water level L3.

When the control device 12 receives an OFF signal from the third water level sensor 10c, which detects that the water level in the water storage section 8 has reached the fourth water level L4, it causes the water level notification section 11 to perform a fifth mode notification operation. In the fifth mode notification operation, the fourth water level LED 11g is turned on. By visually checking that the fourth water level LED 11g is turned on, the user can know that the water level in the water storage section 8 has reached the fourth water level L4.

The sensor unit 10 in this embodiment can detect five different water levels, starting from the lowest, which are the first water level L1, the second water level L2, the third water level L3, the fourth water level L4, and the full water level. The sensor unit 10 in this embodiment can also perform the first, second, fourth, fifth, and third modes, starting from the lowest water level, as the five different water levels. The operation control unit 12a controls the five-level notification operation by the water level notification unit 11 according to the five water levels detected by the sensor unit 10. This provides the following effects. The water level notification unit 11 performs five levels of notification corresponding to the five different water levels in the water storage unit 8, so the user can know the water level in the water storage unit 8 more precisely and accurately than in the first embodiment. As a result, the usability of the dehumidifier 100 is further improved.

In this embodiment, three water level detection means can be used to perform five different alarm operations in response to the five different water levels in the water storage section 8, making it possible to provide a dehumidifier 100 that is advantageous in detecting multiple water levels at a lower cost and with improved usability.

Figure 12 is a functional block diagram of the dehumidifier 100 of the second embodiment. The first water level sensor 10a, the full water level sensor 10b, and the third water level sensor 10c of the sensor unit 10 convert the detected water level information into an electrical signal such as a voltage, and transmit the electrical signal to the control device 12.

Next, the operation of the dehumidifier 100 of this embodiment will be further described with reference to FIG. 13. FIG. 13 is a flowchart showing the control operation of the dehumidifier 100 of embodiment 2. The processes of steps S201 to S212 and S223 to S231 in the flowchart of FIG. 13 are similar to the processes of steps S101 to S112 and S113 to S121 in the flowchart of FIG. 7 showing the operation of embodiment 1. For this reason, the description of the processes of steps S201 to S212 and S223 to S231 will be omitted. Also, the schematic diagrams showing the state of the water storage section 8 before and after each water level detection shown in FIG. 8 to FIG. 10 in embodiment 1 will not be described because the operation due to the rise in water level is similar in this embodiment.

The processing of steps S213 to S222 in FIG. 13 will be described. In step S213, the operation control unit 12a determines whether the water level in the water storage unit 8 has reached the third water level L3 based on whether the third water level sensor 10c has detected an ON state. If the water level in the water storage unit 8 has not yet reached the third water level L3, the processing of step S213 is repeated, and the dehumidifier 100 continues dehumidification operation.

In contrast, if the third water level sensor 10c detects by ON detection that the water level in the water storage section 8 has reached the third water level L3, the process proceeds to step S214, and the dehumidifier 100 executes the fourth mode notification operation. In this embodiment, the operation control section 12a causes the audio alarm 11d to sound in step S215 as the first process of the fourth mode notification operation. By sounding the audio alarm 11d, the user will pay attention to the dehumidifier 100 even if the user is far away from the dehumidifier 100. Next, the third water level LED 11f is turned on as the fourth mode notification operation (step S216). When the fourth mode notification operation as described above is executed, the dehumidifier 100 enters the third water level notification state (step S217).

When the dehumidifier 100 enters the third water level notification state, the process proceeds to step S218, where the operation control unit 12a determines whether the water level in the water storage unit 8 has reached the fourth water level L4 based on whether the third water level sensor 10c has detected an OFF state. If the water level in the water storage unit 8 has not yet reached the fourth water level L4, the process returns to step S216, and the dehumidifier 100 continues dehumidification operation in the third water level notification state.

When the third water level sensor 10c detects that the water level in the water storage section 8 has reached the fourth water level L4 by OFF detection, the process proceeds to step S219, and the dehumidifier 100 executes the fifth mode notification operation. In this embodiment, the operation control section 12a causes the audio alarm 11d to sound in step S220 as the first process of the fifth mode notification operation. By sounding the audio alarm 11d, the user will pay attention to the dehumidifier 100 even if the user is far away from the dehumidifier 100. Next, the fourth water level LED 11g is turned on as the fifth mode notification operation (step S221). When the fifth mode notification operation is executed as described above, the dehumidifier 100 enters the fourth water level notification state (step S222). Then, the process proceeds to step 223.

Figure 14 is a schematic diagram showing the lighting state of the first water level LED 11a, the second water level LED 11b, the third water level LED 11f, the fourth water level LED 11g, and the full water LED 11c in the second embodiment. (a) shows the state where the first water level L1 is reached, (b) shows the state where the second water level L2 is reached, (c) shows the state where the third water level L3 is reached, (d) shows the state where the fourth water level L4 is reached, and (e) shows the full water state, respectively, and shows how the first water level LED 11a, the second water level LED 11b, the third water level LED 11f, the fourth water level LED 11g, and the full water LED 11c are lit up in stages. This allows the user to reliably identify which water level notification state the dehumidifier 100 is in by the number of lit LEDs, even when the user looks at the dehumidifier 100 from a distance. In addition, the light color of each LED may be changed to make it easier to identify.

As described above, in this second embodiment, three or more water level sensors are used to detect the water level, thereby increasing the number of detectable water levels. In addition, by switching the notification method based on the detected water level, the water level can be notified to the user in more detail. According to the second embodiment, five or more water levels can be detected without increasing the number of installed water level sensors, making it possible to obtain a dehumidifier that is even more user-friendly for the user at a lower cost.

Embodiment 3.
Next, a third embodiment will be described with reference to Figures 15 to 17. The differences from the above-described embodiments will be mainly described, and descriptions of the same or corresponding parts will be simplified or omitted. The basic configuration of a dehumidifier 100 of the third embodiment is shown in Figures 1 to 14, similarly to the first and second embodiments. Descriptions of the same configurations and operations as those of the first and second embodiments will be omitted.

Figure 15 is a functional block diagram of the dehumidifier 100 of the third embodiment. The fan motor 6, the dehumidification unit 7, the sensor unit 10, and the water level notification unit 11 are the same as those of the second embodiment. As shown in Figure 15, in this embodiment, the operation unit 13 is provided with a notification water level setting button 13b. The dehumidifier 100 in this embodiment is provided with a notification water level setting button 13b that allows the user to select the water level at which the notification operation is performed from among the multiple water levels that can be detected by the sensor unit 10. That is, in this embodiment, the user can operate the notification water level setting button 13b to arbitrarily set the water level at which the user wishes to be notified from the multiple notification water levels set by the sensor unit 10. The notification water level setting button 13b in this embodiment is an example of a notification water level setting means.

By operating the water level notification setting button 13b, a signal is sent to the control device 12. Each time the water level notification setting button 13b is operated, the control device 12 changes the LED display state of the water level notification unit 11 to notify the user of the water level notification to be set. Figure 16 is a schematic diagram showing the display state of the water level LED by the water level notification unit 11. As an example, each time the user operates the water level notification setting button 13b, the first water level LED 11a → second water level LED 11b → third water level LED 11f → fourth water level LED 11g → full water LED 11c flashes. Figure 16(a) shows the third water level LED 11f flashing.

Meanwhile, the control device 12 is equipped with an internal timer 12c. The internal timer 12c measures the waiting time after the alarm water level setting button 13b is operated. After the user operates the alarm water level setting button 13b and selects the water level LED that indicates the desired alarm water level, it measures whether a certain waiting time (e.g., 5 seconds) has elapsed. If the waiting time has elapsed, the operation control unit 12a determines that the user has selected the alarm water level, and makes a short alarm sound (e.g., 0.5 seconds) from the audio alarm 11d and changes the display of the water level display LED from flashing to off.

The water level to be notified may also be selected not only when the standby time has elapsed, but also by pressing and holding the water level setting button 13b for a long time. In this case, the user operates the water level setting button 13b to select the water level LED that indicates the desired water level to be notified, and the internal timer 12c measures how long the water level setting button 13b is pressed (for example, for 3 seconds). In this case, too, if the long press time has elapsed, the operation control unit 12a determines that the user has selected the water level to be notified, and issues a short (for example, 0.5 second) alarm sound from the audio alarm 11d, and changes the water level display LED from flashing to off.

When the user selects the water level to be notified, the operation control unit 12a simultaneously selects the detection content of the sensor unit 10 according to the selected water level to be notified and stores it in the memory unit 12b. As an example, if the user sets the water level to be notified to the third water level, "third water level sensor: ON" is selected as the detection content and stored in the memory unit. This allows the dehumidifier 100 to notify the user when the water level in the water storage unit 8 reaches the third water level L3 during dehumidification operation and the third water level sensor 10c detects ON.

Next, the operation of the dehumidifier 100 of this embodiment will be further described with reference to FIG. 17. FIG. 17 is a flowchart showing the control operation of the dehumidifier 100 of embodiment 3. The processing of steps S301 and S302 in the flowchart of FIG. 17 is similar to the processing of steps S101 and S102, respectively, in the flowchart of FIG. 7 showing the operation of embodiment 1. Therefore, the description of the processing of steps S301 and S302 will be omitted.

The process from step S303 onward in FIG. 17 will now be described. In step S303, the operation control unit 12a determines whether the user has operated the notification water level setting button 13b. If it is determined that the notification water level setting button 13b has not been operated, the process proceeds to step S304, and then to step S103 in embodiment 1 or step S203 in embodiment 2, where the dehumidification operation continues.

If the operation control unit 12a determines in step S303 that the water level notification setting button 13b has been operated, the process proceeds to a desired water level notification selection state in step S305. In step S306, the LED display state of the water level notification unit 11 is changed to notify the user of the water level notification to be set. As an example, each time the user operates the water level notification setting button 13b, the LED changes from first water level LED 11a to second water level LED 11b to third water level LED 11f to fourth water level LED 11g to full water LED 11c, flashing.

In step S307, the operation control unit 12a determines whether the user's selection of the desired water level to be notified is valid. To make this determination, the internal timer 12c measures whether a certain waiting time (e.g., 5 seconds) has elapsed after the user selects the water level LED that indicates the desired water level to be notified. If the waiting time has elapsed, the operation control unit 12a determines that the user has selected the water level to be notified, sets the desired water level to be notified, makes the audio alarm 11d emit a short alarm sound (e.g., 0.5 seconds), and changes the water level display LED from blinking to off. At the same time, it selects the detection content of the sensor unit 10 according to the selected water level to be notified, and stores it in the memory unit 12b. As an example, if the user sets the water level to be notified to the third water level, "third water level sensor: ON" is selected as the detection content and stored in the memory unit (step S308).

The moisture removed by the dehumidifier 7 is stored in the water storage unit 8 as liquid water. In step S309, the operation control unit 12a determines whether the water level in the water storage unit 8 has reached the desired water level set by the user based on the detection content stored in the memory unit 12b. If the water level in the water storage unit 8 has not yet reached the desired water level set by the user, the process of step S309 is repeated, and the dehumidifier 100 continues dehumidification operation.

When it is determined in step S309 that the water level desired by the user has been reached, the process proceeds to step S310, and the dehumidifier 100 executes the sixth mode of notification operation. As the first process of the sixth mode of notification operation, the operation control unit 12a causes the audio alarm 11d to sound in step S311. Next, the water level LED corresponding to the desired water level is turned on (step S312). As an example, FIG. 16(b) shows a state in which the third water level LED 11f is turned on. When the sixth mode of notification operation is executed as described above, the dehumidifier 100 enters a state of notifying the desired water level (step S313). When the state of notifying the desired water level is entered, the operation control unit 12a stops the dehumidification operation of the dehumidifier 100 (step S314).

The process proceeds from step S314 to step S315, where the operation control unit 12a determines whether or not the sensor unit 10 continues to detect the water level desired by the user to be notified. If the sensor unit 10 continues to detect the water level desired to be notified, the operation control unit 12a repeats the process from step S312 onwards. As a result, the dehumidifier 100 maintains the state of the water level desired to be notified and continues to stop dehumidification operation.

In this embodiment, the water level notification unit 11 can reliably notify the user that the water level in the water storage unit 8 has reached the water level that the user wishes to be notified of, i.e., that the water stored in the water storage unit 8 should be discarded, by the notification action of the water level notification unit 11. When the user receives such a notification action and performs an operation to discard the water stored in the water storage unit 8, the water level in the water storage unit 8 drops, and in step S315, the sensor unit 10 no longer detects the water level that the user wishes to be notified of. When the sensor unit 10 no longer detects the water level that the user wishes to be notified of, the process proceeds from step S315 to step S316.

In step S316, the operation control unit 12a turns off the LED corresponding to the desired water level to be notified. The operation control unit 12a then repeats the processes from step S302 onwards. As a result, the dehumidifier 100 resumes dehumidification operation.

This embodiment allows the user to set the water level at which they would like to be notified, making it possible to provide a dehumidifier that is advantageous in terms of improving usability.

In the example of FIG. 17, the dehumidification operation is stopped when the desired water level for notification is reached, but the dehumidification operation may be continued even after the desired water level for notification is reached until the tank is full. In addition, the notification water level setting means of the dehumidifier 100 in this embodiment may allow the user to select multiple water levels at which the notification operation will be performed from the five water levels that can be detected by the sensor unit 10. In other words, the user may be able to select multiple desired water levels for notification.

In the present disclosure, three or more water level detection means may be disposed, and three or more water levels may be detected by ON signals output from the three or more water level detection means, and the water levels between the three or more water level detection means may be detected by OFF signals output from the water level detection means, making it possible to detect a total of five or more water levels, and the water level notification means may be able to perform a notification operation at five or more water levels. For example, four water level detection means may be disposed, and four water levels may be detected by ON signals output from the four water level detection means, and the three water levels between the four water level detection means may be detected by OFF signals output from the water level detection means, making it possible to detect a total of seven water levels, and the water level notification means may be able to perform a notification operation at seven water levels. In addition, in the present disclosure, an example has been shown in which the notification water level setting means allows the user to select the water level at which the notification operation is performed from five water levels: first water level, second water level, third water level, fourth water level, and full water; however, the user may be able to select the water level at which the notification operation is performed from at least three water levels, such as the first water level, second water level, and full water in embodiment 1.

1 Housing, 2 Wheels, 3 Intake port, 4 Outlet port, 5 Air passage, 6 Fan motor, 6a Blower fan, 7 Dehumidifier, 8 Water storage, 9 Filter, 10 Sensor, 10a First water level sensor, 10b Full water level sensor, 10c Third water level sensor, 11 Water level notification, 11a First water level LED, 11b Second water level LED, 11c Full water LED, 11d Voice notification, 11e Liquid crystal display, 11f Third water level LED, 11g Fourth water level LED, 12 Control device, 12a Operation control unit, 12b Memory unit, 12c Internal timer, 13 Operation unit, 13a Operation button, 13b Notification water level setting button, 20 Float, 20a Magnet, 100 dehumidifier

Claims (3)

A housing having an inlet and an outlet;
a blowing means for generating an air current so that the air flowing into the housing from the air inlet flows out to the outside of the housing from the air outlet;
A dehumidifying means provided inside the housing for removing moisture from the air;
a water storage means for storing the moisture removed by the dehumidifying means as liquid water;
a water level detection means for detecting a water level in the water storage means;
a water level notification means for performing a notification operation regarding the water level in the water storage means;
a water level notification control means for controlling the water level notification means based on a signal from the water level detection means;
Equipped with
At least two water level detection means are provided,
At least two water levels can be detected by the ON signals output from the at least two water level detection means,
The water level between the at least two water level detection means is detected by an OFF signal output from the water level detection means, so that at least three water levels can be detected in total.
The water level notification means is capable of performing the notification operation at the at least three stages of water level. The water level detection means is arranged in three or more units,
Three or more stages of water level can be detected by ON signals outputted from the three or more water level detection means,
The water level between the three or more water level detection means is detected by an OFF signal output from the water level detection means, so that five or more water levels can be detected in total.
The dehumidifier according to claim 1 , wherein the water level notification means is capable of performing the notification operation at the five or more water levels. The dehumidifier according to claim 1 or 2, further comprising a notification water level setting means that allows the user to select the water level at which the notification operation is to be performed from among the at least three water levels.

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