JP2010094168A - Dehumidifier - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a dehumidifier which can properly dry clothes within a specified period of time even when conditions such as the size of a room, the humidity of the room, and the amount of clothes are different. <P>SOLUTION: A drying speed Tt of clothes is calculated by the temperature Tr and the relative humidity Hr of the ambient air which are sensed by a specified interval. The drying speeds Tt are added and accumulated (S13 to S17), and the added-accumulated value ∫Tt is compared with a determination value Dn after a specified period of time, after a specified period of time has passed after the start of the operation (S21). If ∫Tt<Dn is satisfied, the dehumidifying capability is raised (S22), and if ∫Tt<Dn is not satisfied, the dehumidifying capability is lowered (S23), and thus, the dehumidifying capability is adjusted. Also, Dn is set according to the temperature and the relative humidity of the ambient air right after the start of the operation (S12). <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a dehumidifier having a function of drying clothes hung indoors.

Conventionally, a dehumidifier equipped with this type of clothes drying function ends the clothes drying operation when the user sets the time limit of a timer provided in the dehumidifier when drying clothes hung indoors. It was common (see, for example, Patent Document 1).
JP 2001-141284 A

  In the conventional method, there is a problem that clothes are undried (freshly dried) or overdried (too dry) depending on the size of the room, the amount of clothes, and the temperature and humidity conditions in the room.

  The present invention solves such a conventional problem, and includes means for determining the dryness of clothes during the clothes drying operation, and the dehumidifying capacity of the dehumidifier is determined if necessary by the determination of this means. An object of the present invention is to provide a dehumidifier that can be adjusted by raising or lowering it and drying clothes appropriately in a predetermined time.

  In order to achieve the above object, the dehumidifier of the present invention includes a dehumidifying means for dehumidifying the air provided in the main body, a blowing means for blowing air, a heater control means for heating the air to be dehumidified, the dehumidifying means, A control unit that controls the operation of the blower unit and the heater control unit, a humidity sensor that detects the humidity of the ambient air, and a temperature sensor that detects the temperature of the ambient air, and the control unit starts the clothing drying operation Sometimes, an algorithm for setting a determination value for completion of drying from the temperature and relative humidity of the ambient air, an algorithm for calculating the drying speed of clothing based on the ambient temperature and relative humidity detected at regular intervals, and the drying speed An algorithm for adding and accumulating at regular intervals, an algorithm for determining that the drying of clothes has been completed when the accumulated value has reached the determination value for completion of drying, and a drying operation An algorithm for setting a determination value after a predetermined time obtained by multiplying the determination value for completion of drying by a predetermined coefficient at the start, and addition accumulation of the determination value after the predetermined time and the drying speed after a predetermined time after the start of the drying operation It is configured to have an algorithm for comparing values and an algorithm for adjusting the dehumidifying capacity according to the comparison result.

  By this means, it is possible to obtain a dehumidifier capable of reducing the influence of the amount of clothing and the size of the room and drying the clothing for a predetermined time.

  In another aspect, the control unit includes an algorithm that adjusts the dehumidifying capacity by changing an air blowing amount of the air blowing means.

  By this means, when the dehumidifying capacity is increased, by increasing the rotational speed of the blower fan, a strong wind can be applied to the clothing, so that the clothing can be dried more easily and the dryness can be prevented. Further, when the dehumidifying capacity is lowered, by reducing the rotational speed of the blower fan, a dehumidifier capable of reducing wasteful power consumption and obtaining an energy saving effect can be obtained.

  In another aspect, the control unit has an algorithm for adjusting the dehumidification capability by changing the heating amount of the heater control unit.

  By this means, when the dehumidifying capacity is increased, the amount of heating is increased and high-temperature air is applied to the clothing, so that the clothing can be dried more easily and the dehumidifier can be prevented from being dry. Further, when the dehumidifying capacity is lowered, by reducing the heating amount, a dehumidifier capable of reducing wasteful power consumption and obtaining an energy saving effect can be obtained.

  Another means is that the control unit has an algorithm for determining whether or not to display the dehumidifying ability.

  By this means, the user can visually recognize the adjustment status of the dehumidifying ability, and thus a dehumidifier capable of taking actions to adjust how to dry clothes and improving usability can be obtained. .

  Another means includes a switch for turning ON / OFF the display of the dehumidifying capacity.

  By this means, a dehumidifier can be obtained that can be turned off when the user is concerned about the light of the display while sleeping, etc., can be improved in use, and can save energy by turning off the display.

  In addition, the other means has a configuration in which the control unit selects and sets whether or not to adjust the dehumidifying capacity.

  By this means, when the user is sleeping or in the vicinity of the dehumidifier, it is possible to obtain a dehumidifier capable of preventing an increase in noise generated when the dehumidifying capacity is enhanced and an increase in the room temperature.

  Further, the other means is characterized in that the control unit determines whether or not to adjust the dehumidifying capacity according to the detection result of the human sensor that detects the presence of a person around the main body. is there.

  By this means, a dehumidifier can be obtained that can automatically increase noise and prevent room temperature rise without increasing the user's operation when the dehumidifying capacity is increased, and can improve usability and comfort. .

  In another aspect, the control unit has an algorithm for determining whether or not to adjust the dehumidifying capacity in accordance with a detection result of an illuminance sensor that detects illuminance around the main body.

  By this means, a dehumidifier can be obtained that can automatically increase noise and prevent room temperature rise without increasing the user's operation when the dehumidifying capacity is increased, and can improve convenience and comfort. .

  In another aspect, the control unit has an algorithm for automatically stopping operation.

  By this means, it is possible to obtain a dehumidifier that can omit the work of manually stopping the operation while the user confirms the degree of dryness of the clothes, and can be used and improved.

  ADVANTAGE OF THE INVENTION According to this invention, even if conditions, such as the area of a room, the humidity of a room, and the quantity of clothing, differ, the dehumidifier which has the effect of being able to dry clothing appropriately in predetermined time can be provided.

  The invention according to claim 1 of the present invention includes a dehumidifying means for dehumidifying the air provided in the main body, a blowing means for blowing air and a heater control means for heating the air to be dehumidified, the dehumidifying means, the blowing means, A control unit for controlling the operation of the heater control means, a humidity sensor for detecting the humidity of the ambient air, and a temperature sensor for detecting the temperature of the ambient air; An algorithm for setting a determination value for completion of drying from the temperature and relative humidity of the air, an algorithm for calculating the drying speed of the clothing based on the ambient temperature and relative humidity detected every certain period, and the drying speed for a certain period An algorithm that adds and accumulates every time, an algorithm that determines that the drying of the clothes has been completed when the accumulated value reaches the drying completion determination value, An algorithm for setting a determination value after a predetermined time obtained by multiplying a determination value for completion of drying by a predetermined coefficient, and a determination value after the predetermined time and an accumulated cumulative value of the drying speed after a predetermined time after the start of the drying operation. Comparing an algorithm to be compared and an algorithm to adjust the dehumidifying capacity according to the comparison result, and comparing a cumulative value of the drying speed with a judgment value after a predetermined time after a predetermined time after the start of the drying operation Thus, it has the effect of adjusting the dehumidifying ability and drying the clothes.

  In the invention according to claim 2, the control unit has an algorithm for adjusting the dehumidifying capacity by changing the amount of air blown by the air blowing means. By raising the wind, it is possible to apply a strong wind to the clothing, making it easier for the clothing to dry and preventing it from drying out. When the dehumidifying capacity is reduced, the rotational speed of the blower fan is reduced to reduce unnecessary power consumption and save energy. It has the effect of being able to.

  In the invention according to claim 3, the controller has an algorithm for adjusting the dehumidifying capacity by changing the heating amount of the heater control means. By raising the temperature, applying high-temperature air to clothing will make the clothing easier to dry and prevent dry-drying. When the dehumidifying capacity is lowered, reducing the amount of heating can reduce wasted power consumption and save energy. It has the effect of being able to.

  In the invention according to claim 4, the control unit has an algorithm for determining whether or not to display the dehumidification capability, and the user can visually recognize the adjustment status of the dehumidification capability. Thus, it is possible to take an action of adjusting how to dry the clothes and to improve usability.

  Further, the invention described in claim 5 is provided with a switch for turning on / off the display of the dehumidifying ability, and can be turned off when the user is concerned about the light of the display while sleeping, etc. It has the effect of saving energy by turning off the display.

  Further, the invention according to claim 6 has a configuration in which the control unit selects and sets whether or not to adjust the dehumidifying capacity, and when the user is sleeping or in the vicinity of the dehumidifier In addition, it has the effect of increasing the noise generated when the dehumidifying capacity is increased and preventing the room temperature from rising.

  Furthermore, the invention according to claim 7 has an algorithm for determining whether or not to adjust the dehumidifying capacity according to the detection result of the human sensor that detects the presence of a person around the main body. Therefore, an increase in noise generated when the dehumidification capability is increased and prevention of a rise in room temperature can be automatically performed without any user operation, and the usability can be improved and the comfort can be improved.

  The invention according to claim 8 has an algorithm for determining whether or not the dehumidifying capacity is adjusted according to a detection result of the illuminance sensor that detects the illuminance around the main body. In addition, the increase in noise generated when the dehumidification capability is increased and the prevention of the increase in the room temperature can be automatically performed without any user operation, thereby improving the usability and comfort.

  Further, the invention according to claim 9 is characterized in that the control unit automatically stops the operation, and the operation of manually stopping the operation while the user confirms the degree of dryness of the clothes is omitted. It has the effect of being easy to use and improving.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
Embodiment 1 of the present invention will be described with reference to FIGS. First, the structure of the dehumidifier will be described with reference to FIG. 1, and the electrical configuration will be described with reference to FIG. As shown in FIG. 1, the dehumidifier includes a dehumidifier 2 provided in the main body 1, a blower 3, a regenerative heater 4, a temperature sensor 6 that is connected to a control unit 5 and detects the temperature around the main body, and the main body. It comprises a humidity sensor 7 for detecting the surrounding humidity, a human sensor 8 for detecting the presence of a person around the main body, and an operation display unit 9.

  The dehumidifying device 2 includes a dehumidifying rotor 10 as rotating dehumidifying means, a regeneration fan 11 that blows air heated by the regeneration heater 4 to the dehumidifying rotor 10, a heat exchanger 12, and a water tank 13. .

  The air sucked from the room by driving the blower 3 cools the heat exchanger 12 and is then absorbed by the dehumidifying rotor 10 as a dehumidifying means, and the dehumidified air is discharged again into the room to dehumidify the room air. Is done.

  The moisture absorbed by the dehumidifying rotor 10 is evaporated by the warm air heated by the regeneration heater 4 that heats and regenerates the dehumidifying rotor 10 on the other side of the dehumidifying rotor 10, cooled by the heat exchanger 12, and condensed as moisture. The water is stored in the water tank 13.

  Therefore, the dehumidifying capacity of the dehumidifier to be described later is adjusted by changing the blowing power (fan rotation speed) of the regeneration fan 11, the energizing power of the regeneration heater 4, and the blowing power (fan rotation speed) of the blower 3. be able to.

  Although not shown, the operation display unit 9 has a setting switch for the user to select and set whether or not to adjust the dehumidifying capacity of the dehumidifier, an LED for displaying the dehumidifying capacity, and the dehumidifying capacity. A switch capable of turning on / off the display is housed (details will be described later).

  As shown in FIG. 2, the control unit 5 is configured with a microcomputer 21 as a core.

  The microcomputer 21 is connected to the dehumidifying device 2, the blower 3, and the regenerative heater 4 through the respective dehumidifying control means 22, the air blowing control means 23, and the heater, and detects the indoor temperature (the temperature of the ambient air of the clothing). Temperature sensor 6, humidity sensor 7 for detecting indoor relative humidity (humidity of surrounding air of clothing), infrared sensor 8 for detecting a person near the dehumidifier, and start of clothing drying operation Switch for operating the switch, setting switch for selecting whether or not to adjust the dehumidifying capacity, which will be described later, and the switch for switching ON / OFF the LED for displaying the dehumidifying capacity and the LED for displaying the dehumidifying capacity are operated It is connected to the display unit 9.

  Here, the dehumidification control means 22 is, for example, a relay for switching a winding tap (not shown) of a motor for driving the regeneration fan 11, and the air blowing control means 23 is for driving the blower 3, for example. This is a relay for switching a winding tap (not shown) of the motor. The heater control means 24 is a relay for switching a tap (not shown) of the regenerative heater 4, for example.

  Further, the inside of the microcomputer 21 includes an air diagram 25, a drying completion degree of dryness Dx table (a constant number table based on an experimental result related to the room temperature and relative humidity in the initial stage of operation) 26, a drying condition calculation means 27, It includes a drying speed calculation means 28, a dryness calculation means 29, a dryness determination means 30, and an operation stop timer 31.

  Further, as shown in FIG. 4, at the start of the clothes drying operation, the control unit 5 receives the signals from the temperature sensor 6 and the humidity sensor 7 and determines the drying completion determination value Dx from the ambient temperature Tr and the relative humidity Hr. An algorithm 5A for setting, an algorithm 5B for calculating the drying rate Tt of the clothes based on the temperature Tr and the relative humidity Hr detected at regular intervals, and an algorithm 5C for adding and accumulating the dry rate Tt at regular intervals, An algorithm 5D that determines that the drying of the clothes has been completed when the cumulative cumulative value ∫Tt reaches the drying completion determination value Dx, and a predetermined coefficient that is multiplied by the drying completion determination value Dx at the start of the drying operation. An algorithm 5E for setting a determination value Dn after a predetermined time, and an addition cumulative value 判定 of the determination value Dn after the predetermined time and the drying speed Tt after a predetermined time after the start of the drying operation. And algorithms 5F comparing the t, depending on the comparison result, and a algorithm 5G adjusting the dehumidification capacity.

  Further, the control unit 5 selects and sets whether or not to adjust the dehumidifying capacity, and determines whether or not to adjust the dehumidifying capacity according to the detection result of the human sensor 8. It has algorithm 5H.

  Further, a setting switch (not shown) for selecting whether or not to display the dehumidifying capacity of the operation display unit 9 is provided on the operation display unit 9, and the control unit 5 determines whether or not this switch is set to valid. An algorithm 5J for checking whether or not

  The microcomputer 21 has the above-described main parts functioning based on the information of the temperature sensor 6, the humidity sensor 7, the human sensor 8, and the operation display unit 9, and the dehumidifying device 2, the blower 3 and a configuration for controlling the regenerative heater 4.

  In the above configuration, the operation of the dehumidifier according to the present embodiment will be described below.

  First, a description will be given of the difference in the degree of dryness of clothes when the blowing force and the energizing power of the regenerative heater 4 are adjusted as a method of adjusting the dehumidifying capacity of the present embodiment.

  FIG. 3 is a diagram showing the relationship between the clothes drying operation time and the degree of drying of clothes. FIG. 3A shows a state in which the blowing power of the blower 3 is increased during the drying operation. As shown by the characteristic D, the blowing power is increased 4 hours after the start of the operation, and the timer time is 10 hours. (Characteristic C is a characteristic indicating the progress of drying without increasing the blowing power).

  FIG. 3B shows a state where the blowing power of the blower 3 is increased during the drying operation and the energizing power of the regenerative heater 4 is increased. Four hours later, the blowing power of the blower 3 was increased, and the energizing power of the regenerative heater 4 was increased, and the drying within the timer time limit of 10 hours was completed (characteristic F indicates that the blowing power is not increased) And a characteristic indicating the progress of drying while maintaining the energizing power of the regenerative heater 4).

  FIG. 3 (c) shows a state where the blower power of the blower 3 is reduced during the drying operation and the energizing power of the regenerative heater 4 is lowered. 4 hours later, the blowing power of the blower 3 was reduced, the energizing power of the regenerative heater 4 was lowered, and the drying within the timer time limit of 10 hours was completed (characteristic G indicates that the blowing power is not increased) And a characteristic indicating the progress of drying while maintaining the energizing power of the regenerative heater 4).

  As described above, adjusting the blowing power and the energizing power of the regenerative heater 4 is extremely effective as a method for adjusting the dehumidifying capacity.

  The clothes drying operation by the dehumidifier of the present embodiment is automatically performed 10 hours after the user presses the clothes drying operation start switch (not shown) of the operation display unit 9. The operation of the dehumidifier is advanced by the algorithm shown in the flowchart of FIG.

  In S11 of FIG. 4, the temperature sensor 6 and the humidity sensor 7 detect the temperature Tr and the relative humidity Hr of the air around the dehumidifier. Next, in S12, the microcomputer 21 extracts and sets the drying completion determination value Dx corresponding to the temperature Tr and humidity Hr detected from the table 26 of the drying completion determination value Dx. Also, a determination value Dn after a predetermined time is set by multiplying the determination value Dx value of completion of drying by a coefficient (a coefficient less than 1.0, for example, about 0.4). In the present embodiment, for example, when the drying operation is completed in 10 hours, the predetermined time is set to 4 hours, and when the drying state is set to 20 ° C. and 70% RH, the reference value for the completion of drying is set. If Dx is 7500, the reference value Dn after a predetermined time is 3000 (the coefficient 0.4 is multiplied by 0.4. As a result, the coefficient 0.4 is set to a predetermined time 4 hours after the start of operation with respect to 10 hours of operation. Therefore, 4 ÷ 10 = 0.4).

  Next, in S13, the temperature Tr and the humidity Hr of the air around the dehumidifier are detected for a certain time (for example, 1 minute).

  In S14, the microcomputer 21 performs the following processing based on the temperature Tr and humidity Hr data. That is, the total heat amount Ir and the absolute humidity Hr of the ambient air are obtained from the temperature Tr and the humidity Hr of the ambient air.

  Further, in S15, the drying condition calculation means 27 estimates the absolute humidity Xc of the clothing vicinity air from the total amount of heat Ir and the absolute humidity Xr of the ambient air (in this case, the relative humidity of the clothing vicinity air is estimated as 100%).

  In S16, the drying speed calculation means 28 calculates a drying speed Tt (= α (Xc−Xr)) obtained by multiplying the difference between the absolute humidity Xc of the air near the clothing and the absolute humidity Xr of the ambient air by the coefficient α. .

  This drying speed Tt is added and accumulated in the dryness calculating means 29 in S17, and is stored in the memory in the microcomputer 21 as an added accumulated value ∫Tt.

  In S18, the process jumps to S24, which will be described later, until 4 hours as a predetermined time have elapsed from the start of the clothes drying operation, but when 4 hours have elapsed from the start of the clothes drying operation, in S19, the operation display unit It is checked whether or not the dehumidifying capacity 9 is set by a setting switch for selecting whether or not to perform adjustment, that is, whether or not the setting is valid. If “NO (No)”, the process jumps to S24, but if “YES (validly set)”, it is checked in next S20 whether the human sensor 8 detects a person. If no person is detected, the process jumps to S24, but if a person is detected, the next process of S21 is performed.

  When a person is detected, in S21, the dryness determination means 30 compares the cumulative value Tt of Tt in S17 with the determination value Dn after a predetermined time set in S12. “YES” with respect to “∫Tt <Dn”, that is, the dry state after 4 hours indicated by the added cumulative value ∫Tt is from the target dry state after a predetermined time (after 4 hours) indicated by the determination value Dn after the predetermined time. If not, the dehumidifying capacity is increased in S22, and if “NO”, the dehumidifying capacity is decreased in S23.

  Here, the process for increasing the dehumidifying capacity in S22 and the process for decreasing the dehumidifying capacity in S23 will be further described with reference to FIG.

  That is, as shown in FIG. 3 (a), when the dry state after 4 hours is confirmed, if the accumulated cumulative value ∫Tt is smaller by ΔD1 than the determination value Dn after the predetermined time, it is within the predetermined value k set in advance. The blowing power of the blower 3 will be increased. Here, the predetermined value k is, for example, a value of 900, that is, about 30% with respect to 3000 of the determination value Dn after the predetermined time.

  Further, as shown in FIG. 3B, when the dry state after 4 hours is confirmed, the addition cumulative value ∫Tt is smaller than the determination value Dn after the predetermined time, and the determination value Dn after the predetermined time and the addition cumulative value If the difference ΔD2 from the kite Tt is larger than the predetermined value k, the operation is performed in a state where the blowing power of the blower 3 is increased and the energizing power of the regenerative heater 4 is increased. The drying of the clothes is completed in about 9 hours.

  Further, as shown in FIG. 3C, when the dry state after 4 hours is confirmed, the cumulative accumulated value ∫Tt is larger than the reference dryness Dn after the predetermined time, and the cumulative value ∫Tt and the determination value after the predetermined time Since the difference ΔD3 from Dn is larger than the predetermined value k, the operation is performed in a state where the blowing power of the blower 3 is lowered and the energizing power of the regenerative heater 4 is lowered. The drying of the clothes is completed in about 9 hours.

  Thus, in the middle of the clothes drying operation, the determination value Dn after the predetermined time indicating the target dry state after the lapse of the predetermined time is compared with the added cumulative value ∫Tt indicating the actual dry state after the predetermined time, Depending on the magnitude and the deviation value, the power of the blower 3 and the regenerative heater 4 is combined to increase or decrease the capacity of the dehumidifier and adjust within a predetermined time (in this case, 10 hours). Appropriate drying of clothing. As described above, the method of adjusting the capacity of the dehumidifier may be to adjust the blowing power (fan rotation speed) of the regeneration fan 11 of the dehumidifying device 2, and a combination of these may be performed. It doesn't matter.

  Now, in this way, the capacity of the dehumidifier is adjusted to operate, but the user can visually recognize the adjustment status of the dehumidification capacity and adjust how to dry the clothes to dry the clothes more effectively. In order to do so, it is necessary to show the capability of the dehumidifying operation which is an operation state. Therefore, as shown in S24 of FIG. 4, it is checked whether or not the setting switch for selecting whether or not to display the dehumidifying capacity of the operation display unit 9 is set to be effective. If "NO (No)", the process jumps to S26, but if "YES (enabled)", the dehumidifying capacity adjustment result is displayed in the next S25. That is, the LED corresponding to the dehumidifying capacity up and the dehumidifying capacity down is turned on (LED and specific display are not shown).

  In S26, the completion of drying is checked by comparing the added cumulative value 乾燥 Tt with the drying completion determination value Dx, and if it is determined “NO” in this step, that is, the added cumulative value ∫Tt is the completion of drying. If it is less than the determination value Dx, the process returns to S13 again, and Tr and Hr are detected every minute, and based on this, the above calculation operation is performed to calculate the accumulated value ∫Tt that is the dry state of the clothes. Will continue driving. When the accumulated cumulative value ∫Tt, which is the dryness of the clothes, reaches again the drying completion determination value Dx set again in S12 in S26, the clothes drying operation ends.

  As described above, the dehumidifier of the present invention sets a determination value for completion of drying and a determination value after a predetermined time based on this predetermined value from the ambient air temperature and relative humidity at the initial stage of clothes drying operation. After a predetermined time after the start of operation, a determination value after a predetermined time calculated based on a dry completion determination value, which is an accumulated cumulative value of drying speeds calculated based on ambient air temperature and relative humidity detected at regular intervals In comparison with the results, the dehumidifying capacity of the dehumidifier is adjusted by adjusting the rotational speed of the blower and the energizing power of the regenerative heater.

  Thereby, even when conditions such as the size of the room, the humidity of the room, and the amount of clothes are different, the clothes can be properly dried within a predetermined time.

(Embodiment 2)
Embodiment 1 of the present invention will be described with reference to FIGS. First, the structure of the dehumidifier will be described with reference to FIG. 5, and the electrical configuration will be described with reference to FIG.

  5 and 6, the configuration different from that of the first embodiment is replaced with the human sensor 8 as one of the sensors connected to the control unit 5 and the algorithm 5H that determines whether or not to adjust the dehumidifying capacity. An illuminance sensor 51 for detecting the illuminance around the dehumidifier and an algorithm 5K for determining whether or not to adjust the dehumidifying capacity according to the detection result of the illuminance sensor 51 are provided.

  In FIG. 5 and FIG. 6, the same reference numerals are used to simplify the description of the same configuration as that of the first embodiment in order to facilitate understanding.

  Hereinafter, the algorithm 5K will be described.

  FIG. 7 is a flowchart showing an operation from when the user presses a clothing drying operation start switch (not shown) of the operation display unit 9 until the clothing drying operation is automatically terminated.

  In FIG. 7, the difference from the first embodiment is that a determination is made as to whether or not to adjust the dehumidifying capacity in accordance with the detection result of the illuminance sensor 51 connected to the control unit 5. That is, in S40, if it is detected that the illuminance sensor 51 is dark, the process jumps to S44, but if it is detected that the light is bright, the process of adjusting the dehumidifying capacity in the next S41 and thereafter is performed.

  With the above configuration, the dehumidifying ability is adjusted when the periphery of the body of the dehumidifier is bright, and the dehumidifying ability is not adjusted when the periphery of the dehumidifier is dark.

  This makes it possible to maintain the noise generated from the dehumidifier by not automatically adjusting the dehumidifying capacity during sleeping at night. That is, unexpected noise is not generated by adjusting the dehumidifying capacity, and usability and comfort can be improved.

  The dehumidifier of the present invention can properly dry clothes within a predetermined time even when conditions such as the size of the room, the humidity of the room, and the amount of clothes are different. Since it can eliminate unnecessary noises when the air is in the vicinity of the dehumidifier, it can be applied to business use such as inns regardless of the dehumidifier for home use.

The figure which shows the structure of the dehumidifier of Embodiment 1 of this invention Diagram showing the electrical configuration The figure for demonstrating the driving | operation operation | movement ((a) The figure which shows the state at the time of raising the ventilation power of a fan in the middle of drying operation, (b) The blowing power of a fan is improved in the middle of drying operation, and The figure which shows the state at the time of raising the energizing power of a regeneration heater, (c) The figure which shows the state at the time of lowering the blowing power of an air blower in the middle of drying operation, and lowering the energizing power of a regeneration heater) Flow chart showing details of the operation The figure which shows the structure of the dehumidifier of Embodiment 2 of this invention Diagram showing the electrical configuration Flow chart showing details of the operation

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Main body 2 Dehumidifier 3 Blower 4 Regenerative heater 5 Control part 5A Algorithm 5B Algorithm 5C Algorithm 5D Algorithm 5E Algorithm 5F Algorithm 5G Algorithm 5H Algorithm 5J Algorithm 6 Temperature sensor 7 Humidity sensor 8 Human sensor 9 Operation display part 10 Dehumidification rotor 11 Reproduction Fan 12 Heat exchanger 13 Water tank 51 Illuminance sensor

Claims (9)

A dehumidifying means for dehumidifying the air provided in the body, a blowing means for blowing air and a heater control means for heating the air to be dehumidified, and a controller for controlling the operation of the dehumidifying means, the blowing means and the heater control means And a humidity sensor that detects the humidity of the surrounding air and a temperature sensor that detects the temperature of the surrounding air, and the controller completes drying from the temperature and relative humidity of the surrounding air at the start of the clothing drying operation. An algorithm for setting the determination value, an algorithm for calculating the drying speed of the clothing based on the ambient temperature and the relative humidity detected at regular intervals, an algorithm for adding and accumulating the dry speed at regular intervals, and the cumulative accumulation An algorithm for determining that the drying of the clothes has been completed when the value reaches the determination value for completion of drying, and a predetermined coefficient for the determination value for completion of drying at the start of drying operation An algorithm for setting a determination value after a predetermined time multiplied, an algorithm for comparing the determination value after the predetermined time with the cumulative accumulated value of the drying speed after a predetermined time after the start of the drying operation, and according to the comparison result And a dehumidifier having an algorithm for adjusting the dehumidifying capacity. The dehumidifier according to claim 1, wherein the control unit has an algorithm that adjusts the dehumidifying capacity by changing an air blowing amount of the air blowing means. The dehumidifier according to claim 1, wherein the control unit has an algorithm for adjusting the dehumidifying capacity by changing a heating amount of the heater control means. The dehumidifier according to claim 1, wherein the control unit has an algorithm for determining whether or not to display the dehumidifying capacity. The dehumidifier according to claim 4, further comprising a switch for turning ON / OFF the display of the dehumidifying capacity. The dehumidifier according to claim 1, wherein the control unit has a configuration that selects and sets whether or not to adjust the dehumidifying capacity. The dehumidifier according to claim 6, wherein the control unit has an algorithm for determining whether or not to adjust the dehumidifying capacity in accordance with a detection result of a human sensor that detects the presence of a person around the main body. The dehumidifier according to claim 6, wherein the control unit has an algorithm for determining whether or not to adjust the dehumidifying capacity in accordance with a detection result of an illuminance sensor that detects illuminance around the main body. The dehumidifier according to claim 1, wherein the control unit automatically stops the operation.

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