KR102234780B1 - Dehumidifier and method for controlling the same - Google Patents

Abstract

The present invention comprises: a refrigeration cycle unit comprising a compressor and a heat exchanger connected to the compressor and performing dehumidification through heat exchange with indoor air; A humidity detection unit that detects humidity of indoor air; A controller configured to control an operation rate of the compressor as a first operation rate when the detected indoor humidity is higher than the target humidity and control the operation rate of the compressor as a second operation rate when the indoor humidity is less than the target humidity; It includes an inverter unit for driving the compressor based on the operation rate transmitted from the control unit.
According to the present invention, when the indoor humidity reaches the target humidity, the operation rate of the compressor is controlled to the lowest operation rate and the number of rotations of the blowing fan is reduced, thereby preventing the moisture remaining in the reservoir and evaporator from affecting the increase of indoor humidity. have.
Accordingly, the humidity of the indoor space can be maintained at the target humidity for a long time.
In addition, when the indoor humidity reaches the target humidity, power consumption can be reduced by controlling the operation rate of the compressor to the lowest operation rate.

Description

Dehumidifier and method for controlling the same}

The present invention relates to a dehumidifier for reducing power consumption and a control method thereof.

In general, a dehumidifier removes moisture from the air using a cooling method of a refrigeration cycle. That is, the dehumidifier removes moisture from the air by using the transfer of heat generated during evaporation and condensation.

Such a dehumidifier includes a fan for inhaling external air, a refrigeration cycle unit for removing moisture contained in the suctioned air, and a water storage tank for storing water dehumidified in the refrigeration cycle unit.

When the indoor humidity reaches the target humidity, the dehumidifier stops the compressor of the refrigeration cycle unit, and when the indoor humidity is higher than the target humidity, the compressor is driven again to perform a dehumidification operation.

When the fan is operated when the dehumidifier is turned off, the moisture accumulated in the evaporator evaporates and moves to the indoor space, which causes a problem in that the relative humidity in the room is rapidly increased and the compressor is frequently driven. That is, when the fan is operated when the dehumidifier is turned off, the driving time of the compressor is shortened, resulting in an increase in power consumption.

On the other hand, when the fan is turned off when the dehumidifier is turned off, the indoor air is used as information to determine the next operation time of the compressor because it detects the humidity in the device and determines the next operation time of the compressor. In the detection of humidity, there is a problem that the accuracy of the detected humidity is low.

An aspect provides a dehumidifier for preventing an increase in indoor humidity by variably controlling the operation of a compressor when indoor humidity is a target humidity, and a control method therefor.

Another aspect provides a dehumidifier for preventing an increase in indoor humidity by variably controlling an operation of a suction fan when indoor humidity is a target humidity, and a control method therefor.

Another aspect provides a dehumidifier and a control method for controlling the operation of an auxiliary fan when indoor humidity is a target humidity so that indoor air for indoor humidity detection is sucked.

The dehumidifier according to an aspect includes: a refrigeration cycle unit comprising a compressor and a heat exchanger connected to the compressor and performing dehumidification through heat exchange with indoor air; A humidity detection unit that detects humidity of indoor air; A controller configured to control an operation rate of the compressor as a first operation rate when the detected indoor humidity is higher than the target humidity, and control the operation rate of the compressor as a second operation rate when the indoor humidity is less than the target humidity; It includes an inverter unit for driving the compressor based on the operation rate transmitted from the control unit.

The second driving rate is lower than the first driving rate.

The second driving rate is adjusted in multiple steps based on the difference between the indoor humidity and the target humidity.

The dehumidifier further includes a circulation unit that allows indoor air to be introduced and the dehumidified air to be discharged into the room.

The controller controls the fan speed of the circulation unit to the first rotational speed when the detected humidity of the room is higher than the target humidity, and controls the fan speed of the circulation unit to the second rotational speed when the humidity of the room is less than the target humidity.

The second rotational speed is slower than the first rotational speed.

The dehumidifier according to another aspect comprises: a refrigeration cycle unit comprising a compressor and a heat exchanger connected to the compressor and performing dehumidification through heat exchange with indoor air; A first fan to allow indoor air to be introduced and to allow dehumidified air to be discharged into the room; A humidity detection unit that detects humidity of indoor air; A second fan provided around the humidity detection unit; A controller configured to control an operation rate of the compressor to decrease when the detected indoor humidity is less than the target humidity, and to turn on the operation of the second fan when controlling the compressor at the second operation rate; It includes an inverter unit for driving the compressor based on the operation rate transmitted from the control unit.

If the detected indoor humidity is higher than the target humidity, the control unit controls the operation rate of the compressor to the first operation rate, and if the indoor humidity is less than the target humidity, the control unit controls the operation rate to a second operation rate lower than the first operation rate.

The controller controls the rotation speed of the first fan to decrease when the detected indoor humidity is less than the target humidity.

The control unit stops the operation of the first fan when the detected indoor humidity is less than the target humidity.

A method of controlling a dehumidifier according to another aspect is a control method of a dehumidifier having an inverter-type compressor and a heat exchanger connected to the compressor, in which a dehumidifying operation is performed by driving the compressor at a first operation rate, and humidity is detected. The detected humidity is compared with the target humidity to determine whether the detected humidity is higher than the target humidity, and if the detected humidity is less than the target humidity, the operation rate of the compressor is adjusted to a second operation rate lower than the first operation rate.

The control method of the dehumidifier further includes maintaining the operation rate of the compressor at the first operation rate when the detected humidity is higher than the target humidity.

The control method of the dehumidifier further includes reducing the rotation speed of the first fan provided around the heat exchanger when the detected humidity is less than the target humidity.

The control method of the dehumidifier further includes stopping the operation of the first fan provided around the heat exchanger when the detected humidity is less than the target humidity, and operating a second fan provided around the humidity detection unit to allow indoor air to flow in.

The control method of the dehumidifier is to control the operation rate of the compressor to the first operation rate when the humidity detected during operation of the second fan is higher than the target humidity, operate the first fan provided around the heat exchanger, and operate the second fan provided around the humidity detection unit. It further includes stopping the fan.

According to one aspect, when the indoor humidity reaches the target humidity, the operation rate of the compressor is controlled to the lowest operation rate, and the number of rotations of the blowing fan is reduced to prevent moisture remaining in the reservoir and evaporator from affecting the increase in indoor humidity. can do.

Accordingly, the humidity of the indoor space can be maintained at the target humidity for a long time.

In addition, when the indoor humidity reaches the target humidity, power consumption can be reduced by controlling the operation rate of the compressor to the lowest operation rate.

That is, since the total power consumption of the compressor operating at the lowest operation rate is lower than the total power consumption of the compressor that is turned on and off with frequent operation cycles, the total power consumption of the dehumidifier can be reduced.

In addition, even if the ventilation fan stops when the indoor humidity reaches the target humidity, indoor air can be introduced into the dehumidifier by rotating the fan installed around the humidity detector, and accordingly, the humidity of the indoor air to determine the timing of the change in the operation rate of the compressor can be determined. It can be detected accurately.

1 is an exemplary diagram of a dehumidifier according to an embodiment.
2 is a cross-sectional view of a dehumidifier according to an embodiment.
3 is a control configuration diagram of a dehumidifier according to an embodiment.
4 is a flowchart illustrating a control process of a dehumidifier according to an exemplary embodiment.
5 is a graph illustrating humidity, operation cycles, and accumulated power consumption of a dehumidifier and a conventional dehumidifier according to an exemplary embodiment.
6 is a control configuration diagram of a dehumidifier according to another embodiment.
7 is a control flowchart of a dehumidifier according to another embodiment.

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

1 is an exemplary view of a dehumidifier according to an embodiment, and FIG. 2 is a cross-sectional view of a dehumidifier according to the embodiment.

The dehumidifier 100 includes a main body 110 forming an exterior, a storage tank 120 detachably provided under the main body 110, and an opening/closing member 130 provided to be opened and closed on the upper part of the main body 110. do.

Here, the main body 110 includes a front panel 111, a rear panel 112 and a bottom panel 113, and the front panel 111 and the rear panel 112 are detachably coupled to each other. An accommodation space is formed, and openings that can be opened and closed are formed in the upper and lower portions.

Here, the rear panel 112 includes a plurality of suction holes 112a to allow air in the indoor space to be sucked into the body.

In addition, the bottom panel 113 of the main body covers an opening in the lower part of the main body formed by the front panel 111 and the rear panel 112.

The opening of the upper part of the main body formed by the front panel 111 and the rear panel 112 of the main body 110 can be opened and closed by the opening/closing member 130.

An opening and closing member 130 is installed in an opening formed in the upper portion of the main body 110 so as to be able to open and close.

Here, the opening formed in the upper portion of the main body 110 is a discharge port 114 through which dehumidified air is discharged.

That is, the air introduced into the body 110 through the suction hole 112a of the rear panel 112 is discharged to the outside through the discharge port 114 after moisture is removed.

In addition, a grill member for adjusting the discharge direction of the dehumidified air may be provided in the discharge port 114.

The grill member moves upward when the dehumidifier is operated, and moves downward when the dehumidifier stops to open and close the discharge port. Accordingly, malfunction of the dehumidifier 100 due to foreign substances penetrating into the body 110 can be prevented.

The dehumidifier further includes a filter unit 115 provided inside the main body 110 and adjacent to the rear panel 112 but provided to be detachable. That is, the filter unit 115 is replaceable.

The filter unit 115 purifies the air flowing into the main body 110 through the suction hole 112a of the rear panel 112. In this way, the filter unit 115 filters foreign substances in the indoor air so that the purified air flows into the body.

The filter unit 115 may be at least one of a pre-filter for removing relatively large dust contained in the air, a deodorizing filter for removing odors, a dust collecting filter for collecting dust through an electrical action, and a HEPA filter for removing fine dust.

The water storage tank 120 stores condensed water generated during the heat exchange process of air introduced into the main body.

That is, the main body includes an accommodation space capable of accommodating a storage water tank, and the storage water tank 120 is retractably inserted into the accommodation space of the main body. Through this, it is possible to remove the condensed water stored in the storage tank.

The water storage tank 120 may include a storage space for storing water and a handle to facilitate withdrawal and insertion.

The storage tank 120 further includes a flow path that is formed adjacent to the evaporator and the condenser and guides the condensed water formed in the evaporator to the storage tank 120, generated in the heat exchange process, and an inlet connected to the flow path, Save it.

The opening/closing member 130 is installed on the upper part of the body, and is installed to be movable vertically to open and close the upper opening of the body. The opening/closing member 130 maintains an open state during operation of the dehumidifier and maintains a closed state during operation of the dehumidifier.

In addition, it is possible to open and close only the grill member according to the operating state of the dehumidifier, and to maintain the open state of the opening and closing member.

In addition, the dehumidifier 100 is provided inside the main body 110 and is provided with a circulation unit 140 for inhaling and blowing air in the indoor space, and is provided inside the main body 110 and is provided around the circulation unit 140 and inhaled. It further includes a refrigeration cycle unit 150 for removing moisture in the indoor air.

The circulation unit 140 allows air from the indoor space to be sucked into the body and discharges the air from which moisture has been removed to the indoor space.

The circulation unit 140 includes a fan 141 made of a plurality of blades and allowing air to flow, and a fan motor 142 that rotates the fan 141.

The fan motor 142 provides rotational force to the fan 141, and the fan 141 may rotate around an axis connected to the fan motor 142.

Here, the rotation speed of the fan 141 rotated by the fan motor is variable based on indoor humidity.

Accordingly, the air introduced into the main body 110 through the inlet 112a by the rotation of the fan is discharged to the discharge port 114 through the evaporator and condenser, but the discharge amount of the dehumidified air can be varied based on the rotation speed. .

The refrigeration cycle unit 150 removes moisture in the introduced air by performing heat exchange of the air introduced into the body.

This refrigeration cycle unit 150 is provided in the lower portion of the main body, a compressor 151 provided on one side of the storage tank, a condenser 152 connected to the compressor through a refrigerant pipe, and an expansion valve 154 (see FIG. 3) at one side. And an evaporator 153 connected to the condenser through and the other side connected to the compressor.

The condenser 152 and the evaporator 153 are disposed inside the main body 110 and disposed between the blower 140 and the filter 115, and the condenser 152 and the evaporator 153 are installed adjacent to each other. do.

In addition, the condenser 152 and the evaporator 153 are heat exchangers that perform heat exchange of air, and the heat exchanger is a plurality of heat exchangers that allow more heat exchange between the air and the refrigerant introduced into the body 110 through the inlet 112a. It may include a pin or a tube.

The compressor 151 compresses the refrigerant and discharges the compressed high-temperature, high-pressure gaseous refrigerant to the condenser 152. The compressor 151 is an inverter type compressor capable of adjusting an operation rate.

Here, adjusting the driving rate includes adjusting the rotational speed of the motor in the compressor.

The condenser 152 is connected to the discharge port of the compressor 151 through a refrigerant pipe, and condenses the refrigerant introduced from the compressor 151 through heat dissipation of the refrigerant. At this time, the high-temperature, high-pressure gaseous refrigerant is phase-changed into a high-temperature, high-pressure liquid refrigerant.

The expansion valve 154 is disposed between the condenser 152 and the evaporator 153.

The expansion valve 154 lowers the pressure and temperature of the refrigerant introduced from the condenser 152 so that heat absorption by evaporation of the refrigerant easily occurs, and then transfers it to the evaporator 153.

That is, the refrigerant passing through the expansion valve changes from a liquid state of high temperature and high pressure to a liquid state of low temperature and low pressure. Here, the expansion valve may be implemented as a capillary tube.

The evaporator 153 is disposed in the indoor space and performs heat exchange with indoor air through heat absorption by evaporation of the refrigerant flowing from the expansion valve. At this time, the low-temperature and low-pressure liquid refrigerant phase changes to the low-temperature and low-pressure gaseous refrigerant.

A dehumidification process according to the operation of the refrigeration cycle unit will be described.

The refrigerant in the refrigeration cycle unit 150 circulates through the compressor 151, the condenser 151, the expansion valve 154, and the evaporator 153 in order.

In addition, the air in the indoor space is purified through the filter unit 115 and then introduced into the main body 110, and the air introduced into the main body 110 moves to the evaporator 153, and is evaporated by the evaporator 153. After the heat absorption process is performed, it moves to the condenser 152, and after the heat dissipation process is performed in the condenser 152, it moves to the discharge port 114 through the fan 141 and is discharged to the outside.

The air discharged to the outside is air from which moisture has been removed from the air introduced into the body. Here, the moisture removed from the inside of the body is water condensed in the evaporator, and the condensed water formed in the evaporator moves to the storage tank 120 along the flow path.

In this way, moisture contained in the indoor air is condensed in the evaporator 153 in the form of condensed water, and the condensed water moves to the storage space of the water storage tank 120 through the flow path.

The main body 110 further includes a user interface for receiving an operation command of the dehumidifier and displaying an operation state, and a driving module for controlling the operation of the dehumidifier.

Here, the user interface includes an input unit having a plurality of buttons and a display unit such as a light emitting diode (LED) or LCD.

3 is a control configuration diagram of a dehumidifier according to an embodiment, wherein the dehumidifier includes an input unit 161, a humidity detection unit 162, a control unit 163, a storage unit 164, a display unit 165, and a driving unit 166. .

The input unit 161 receives power on/off, an operation mode, a target humidity, and the like.

The humidity detection unit 162 detects humidity of indoor air provided inside the main body and introduced into the main body, and transmits information on the detected humidity to the control unit 163.

The humidity detection unit 162 may be provided around the evaporator 152.

The controller 163 controls the operation of the compressor and the fan when a power-on command is input.

The controller 163 compares the indoor humidity detected during the dehumidification operation with the target humidity, determines whether the indoor humidity is higher than the target humidity, and controls the operation rate of the compressor as the first operation rate if the detected indoor humidity is higher than the target humidity. If the indoor humidity is less than the target humidity, the operation rate of the compressor is controlled as the second operation rate.

Here, the second driving rate is a lower driving rate than the first driving rate.

In addition, when the indoor humidity is less than the target humidity, the control unit 163 may gradually adjust the operation rate of the compressor to a lower level as the difference between the indoor humidity and the target humidity increases.

The control unit 163 adjusts the rotational speed (RPM) of the motor inside the compressor, and transmits a pulse width modulation (PWM) control signal to the driving unit.

The controller 163 controls the fan speed of the circulation unit to the first rotational speed when the detected humidity in the room is higher than the target humidity, and controls the fan speed of the circulation unit to the second rotational speed when the humidity in the room is less than the target humidity.

Here, the second rotational speed is a rotational speed that is slower than the first rotational speed.

In addition, controlling the fan speed includes controlling the rotational speed of the fan motor.

In addition, when the indoor humidity is less than the target humidity, the control unit 163 may gradually adjust the rotation speed of the fan to be lower as the difference between the indoor humidity and the target humidity increases.

The controller 163 controls the operation rate of the compressor and the rotational speed of the fan to decrease when the indoor humidity is less than the target humidity, and controls the operation rate of the compressor and the rotational speed of the fan for a preset time.

In addition, when the indoor humidity is less than the target humidity, the control unit 163 compares the indoor humidity and the stationary humidity while controlling the operation rate of the compressor and the rotational speed of the fan to decrease, and when the indoor humidity is less than the stop humidity, the compressor and the fan operate. It is also possible to control the stop.

Here, the stop humidity is a humidity at which the indoor humidity does not rise above the target humidity due to condensed water formed in the evaporator and water stored in the storage tank even when the dehumidification operation is stopped, and is a humidity subtracted by a predetermined size from the target humidity or a preset humidity.

The control unit 163 continuously compares the indoor humidity and the target humidity in order to check whether the indoor humidity increases due to environmental changes while the operation rate of the compressor is decreased or adjusted or stopped, and when the indoor humidity is higher than the target humidity, the compressor The operation rate of is controlled upward again to the first operation rate, and the speed of the fan is controlled upward again to the first rotational speed.

In addition, when the dehumidification operation is stopped, the control unit 163 controls the operation of the fan at a preset cycle.

Here, controlling the operation of the fan at a preset period allows indoor air to flow into the body in order to check the indoor humidity for determining the next operation point of the compressor during dehumidification stop.

The storage unit 164 stores the target humidity, stores the first and second operation rates of the compressor, and stores the first and second rotational speeds of the fan.

In addition, when the indoor humidity is less than the target humidity, the storage unit 164 may store an operation rate corresponding to a difference value between the indoor humidity and the target humidity.

In addition, the storage unit 164 may store a preset time or stop humidity for stopping the compressor, and may store the operation cycle of the fan for detecting indoor humidity when the dehumidification is stopped.

The display unit 165 displays an operating state of the dehumidifier, a current indoor humidity, a target humidity, and the like.

Here, the operation state includes operation on/off, whether an error exists, and a driving mode.

The driving unit 166 drives various loads in the dehumidifier based on a command from the control unit, and the first driving unit 166a driving the compressor 151, the second driving unit 166b driving the expansion valve 154, and circulation It includes a third driving unit (166c) for driving the negative fan (141).

The first driving unit 166a is an inverter unit that includes a plurality of switching elements and drives the plurality of switching elements on and off based on the PWM control signal, and adjusts the operation rate of the compressor based on the PWM control signal of the control unit.

The second driving part 166b can also adjust the opening degree of the expansion valve.

The third driving unit 166c adjusts the rotational speed of the fan.

4 is a flowchart illustrating a control flow chart of a dehumidifier according to an exemplary embodiment, and will be described with reference to FIGS. 1 to 3.

When the power-on and operation command is input 201, the dehumidifier operates the compressor of the refrigeration cycle unit at the first operation rate and the fan of the circulation unit operates at the first rotational speed (202).

The dehumidifier can also store the target humidity when the target humidity is input. In addition, the target humidity may be a preset humidity.

The dehumidifier detects indoor humidity (203), compares the detected indoor humidity with the target humidity, determines whether the indoor humidity is higher than the target humidity (204), and operates the compressor first if the detected indoor humidity is higher than the target humidity. Rate and keep the fan speed at the first rotational speed.

On the other hand, when the detected indoor humidity is less than the target humidity, the dehumidifier lowers the operating rate of the compressor to the second operation rate and lowers the speed of the fan to the second rotational speed.

Accordingly, the compressor operates at a second operation rate, and the fan operates at a second rotational speed (205).

That is, the second driving rate is a driving rate lower than the first driving rate, and the second rotational speed is a rotational speed slower than the first rotational speed.

In addition, when the indoor humidity is less than the target humidity, the dehumidifier may stepwise adjust the operation rate of the compressor to a lower level as the difference between the indoor humidity and the target humidity increases.

For example, if the difference between indoor humidity and target humidity is 0.5%, the dehumidifier can adjust the operation rate to the first stage, and if the difference between indoor humidity and the target humidity is 1%, the operation rate can be adjusted to the second stage, lower than the first stage have.

The dehumidifier compares the detected indoor humidity with the target humidity even when the operation of the compressor and the fan is lowered, that is, when the indoor humidity is less than the target humidity, determines whether the indoor humidity is higher than the target humidity (206), and detects the indoor humidity. If is higher than the target humidity, the operation rate of the compressor is increased to the first operation rate and the speed of the fan is increased to the first rotational speed.

That is, in order to determine whether the indoor humidity has risen above the target humidity according to the environmental change, the indoor humidity is detected even when the compressor and the fan are adjusted downward and operated.

On the other hand, if the detected indoor humidity is maintained below the target humidity, the dehumidifier maintains the operation rate of the compressor at the second operation rate and maintains the speed of the fan at the second rotational speed (207).

In addition, the dehumidifier may compare the detected indoor humidity with the stationary humidity in a state in which the operation of the compressor and the fan is lowered, and control the operation of the compressor and the fan to stop when the indoor humidity is less than the stop humidity.

In addition, in a state in which the dehumidification operation is stopped, in order to check whether the indoor humidity is increased due to environmental changes, it is possible to periodically operate the fan to allow indoor air to flow into the body. Through this, it is possible to detect the humidity of the indoor space, not the humidity inside the main body.

The operation state of the dehumidifier can be displayed through the display unit 165.

The dehumidifier stops all loads when a power-off command is input by the user.

In this way, it is possible to prevent the humidity of the indoor space from increasing again by the condensate formed in the evaporator and the water stored in the fresh water tank by lowering the operating rate of the compressor and the rotational speed of the fan while the indoor humidity is lower than the target humidity. .

That is, the dehumidifier can maintain the humidity of the indoor space at the target humidity for a long time.

In addition, when the indoor humidity is lower than the target humidity, rather than turning off the compressor, it is possible to reduce the power consumption of the compressor by lowering the operation rate of the compressor. This will be described with reference to FIG. 5.

The graph a1 of FIG. 5 is a graph of indoor humidity when a constant-speed compressor is used, a graph a2 is a graph of indoor humidity when an inverter-type compressor is used, and the graph b1 of FIG. 5 is a graph of the on-off period of the constant-speed compressor, and b2 The graph is a graph of the operation rate change of the inverter type compressor.

It can be seen that when dehumidification is performed using a constant-speed compressor, the compressor is turned on and off according to a change in indoor humidity (%).

That is, in the case of a constant-speed compressor, when the indoor humidity reaches the target speed, the operation is stopped, and at this time, moisture from the evaporator and the storage tank is discharged to the indoor space, so that the indoor humidity rises rapidly. Accordingly, the constant speed compressor is turned on within a short period of time after being turned off.

However, it can be seen that when dehumidification is performed using an inverter type compressor, indoor humidity is also maintained as the operating rate of the compressor is maintained.

The c1 graph of FIG. 5 is a graph of accumulated power consumption (kW) when a constant speed compressor is used, and the c2 graph is a graph of accumulated power consumption when an inverter type compressor is used.

As shown, it can be seen that the total cumulative power consumption when using the inverter type compressor operating at the lowest operating rate is lower than the total cumulative power consumption when using the constant speed compressor that is turned on and off at frequent operating cycles. .

In addition, when the indoor humidity reaches the target humidity, the inverter-type compressor is not turned off and the operation frequency is lowered to operate at the lowest operation rate, thereby gradually reducing the amount of dehumidification, thereby preventing the moisture accumulated in the evaporator from evaporating and being discharged into the indoor space. .

6 is a control configuration diagram of a dehumidifier according to another embodiment. The dehumidifier includes an input unit 161, a humidity detection unit 162, a control unit 163, a storage unit 164, a display unit 165, and a driving unit 166. And a second fan as a load.

The input unit 161, the humidity detection unit 162, the storage unit 164, and the display unit 165 are the same as in the exemplary embodiment, and thus descriptions thereof will be omitted.

When a power-on command is input, the control unit 163 controls the operation of the compressor and the first fan 142 (same as the fan of the circulation unit in one embodiment).

The controller 163 compares the indoor humidity detected during the dehumidification operation with the target humidity, determines whether the indoor humidity is higher than the target humidity, and controls the operation rate of the compressor as the first operation rate if the detected indoor humidity is higher than the target humidity. If the indoor humidity is less than the target humidity, the operation rate of the compressor is controlled as the second operation rate.

Here, the second driving rate is a lower driving rate than the first driving rate.

In addition, when the indoor humidity is less than the target humidity, the control unit 163 may gradually adjust the operation rate of the compressor to a lower level as the difference between the indoor humidity and the target humidity increases.

The control unit 163 adjusts the rotational speed (RPM) of the motor inside the compressor, and transmits a pulse width modulation (PWM) control signal to the driving unit.

The controller 163 controls the speed of the first fan 141 of the circulation unit to the first rotational speed when the detected humidity in the room is higher than the target humidity, and when the humidity in the room is less than the target humidity, the first fan 141 of the circulation unit is The speed is controlled as the second rotational speed.

Here, the second rotational speed is a rotational speed that is slower than the first rotational speed.

In addition, when the indoor humidity is less than the target humidity, the control unit 163 may gradually adjust the rotational speed of the first fan 141 to a lower level according to the difference between the indoor humidity and the target humidity.

In addition, the controller 163 may turn off the operation of the first fan 141 when the indoor humidity is less than the target humidity.

When the indoor humidity is less than the target humidity, the control unit 163 downwardly controls the operation rate of the compressor and the rotation speed of the fan for a preset time.

In addition, when the indoor humidity is less than the target humidity, the control unit 163 compares the indoor humidity and the stationary humidity while controlling the operation rate of the compressor and the rotational speed of the fan to decrease, and when the indoor humidity is less than the stop humidity, the compressor and the fan operate. It is also possible to stop control, and at this time, the operation of the second fan 143 is turned on.

The operation of the second fan is turned on and controlled so that indoor air is introduced into the body in order to check the indoor humidity for determining the next operation point of the compressor while the dehumidification operation is stopped.

Here, the stop humidity is a humidity at which the indoor humidity does not rise above the target humidity due to condensed water formed in the evaporator and water stored in the storage tank even when the dehumidification operation is stopped, and is a humidity subtracted by a predetermined size from the target humidity or a preset humidity.

The control unit 163 continuously compares the indoor humidity and the target humidity to check whether the indoor humidity increases due to environmental changes even while the dehumidification operation is stopped, and when the indoor humidity and the target humidity are above the target humidity, the operation rate of the compressor is adjusted to a first operation rate. And the fan speed is controlled to rise again at the first rotational speed.

The driving unit 166 drives various loads in the dehumidifier based on a command from the control unit, and the first driving unit 166a driving the compressor 151, the second driving unit 166b driving the expansion valve 154, and circulation A third driving unit 166c driving the negative first fan 141 and a fourth driving unit 166d driving the second fan 143 are included.

The first driving unit 166a is an inverter unit that includes a plurality of switching elements and drives the plurality of switching elements on and off based on the PWM control signal, and adjusts the operation rate of the compressor based on the PWM control signal of the control unit.

The second driving part 166b can also adjust the opening degree of the expansion valve.

The third driving unit 166c adjusts the rotational speed of the fan.

The fourth driving unit 166d rotates the second fan 143 while the dehumidification operation is stopped, and stops the operation during the dehumidification operation.

Here, the second fan 143 is a small fan that is smaller in size than the first fan, and is provided around the humidity detection unit 162 so that indoor air flows toward the humidity detection unit 162 while the dehumidification operation is stopped.

7 is a control flow chart of a dehumidifier according to another exemplary embodiment, and will be described with reference to FIG. 6.

When a power-on and operation command is input 211, the dehumidifier operates the compressor 151 of the refrigeration cycle unit at a first operation rate, operates the first fan 141 of the circulation unit, and does not operate the second fan (212).

The dehumidifier can also store the target humidity when the target humidity is input. In addition, the target humidity may be a preset humidity.

The dehumidifier detects indoor humidity (213), compares the detected indoor humidity with the target humidity, determines whether the indoor humidity is higher than the target humidity (214), and determines the operating rate of the compressor if the detected indoor humidity is higher than the target humidity. The operating rate is maintained, the operation of the first fan 141 is maintained, and the second fan 143 is maintained in a stopped state.

On the other hand, when the detected indoor humidity is less than the target humidity, the dehumidifier lowers the operation rate of the compressor to the second operation rate, stops the first fan 141, and operates the second fan 143 (215).

Here, the second driving rate is a lower driving rate than the first driving rate.

In addition, it is possible to adjust the rotation speed of the first fan 141 downward.

The dehumidifier lowers the operation of the compressor 151, stops the first fan 141, and rotates the second fan 143, that is, the detected indoor humidity and the target humidity are reduced even when the indoor humidity is less than the target humidity. It compares and determines whether the indoor humidity is higher than the target humidity (216). If the detected indoor humidity is higher than the target humidity, the operation rate of the compressor is increased to the first operation rate, the first fan 141 is operated again, and the second The fan 143 is stopped.

That is, in order to determine whether the indoor humidity has risen above the target humidity according to environmental changes, the indoor humidity is detected even in a state in which the operating rate of the compressor is lowered and operated.

On the other hand, the dehumidifier maintains the state of the compressor, the first fan, and the second fan when the detected indoor humidity is maintained below the target humidity. That is, the dehumidifier maintains the operation rate of the compressor at the second operation rate, maintains the first fan in a stopped state, and the second fan continuously operates (217).

In addition, the dehumidifier may compare the detected indoor humidity with the stationary humidity in a state in which the operation rate of the compressor is lowered, and control the operation of the compressor to stop when the indoor humidity is less than the stationary humidity.

The operation state of the dehumidifier can be displayed through the display unit 165.

The dehumidifier stops all loads when a power-off command is input by the user.

As described above, when the indoor humidity is lower than the target humidity, the rotational speed of the compressor is lowered to operate, thereby preventing the humidity of the indoor space from increasing again due to the condensate formed in the evaporator and the water stored in the fresh water tank.

That is, the dehumidifier can maintain the humidity of the indoor space at the target humidity for a long time.

In addition, it is possible to reduce the power consumption of the compressor by lowering the operating rate of the compressor, rather than turning off the compressor when the indoor humidity is lower than the target humidity.

100: dehumidifier 110: main body
120: reservoir 130: opening and closing member
140: circulation unit 150: refrigeration cycle unit

Claims (15)

A refrigeration cycle unit comprising a compressor provided in the main body and a heat exchanger connected to the compressor and performing dehumidification through heat exchange with indoor air;
A humidity detector for detecting the humidity of the indoor air;
A circulation unit to allow the indoor air to be introduced and to allow the dehumidified air to be discharged into the room;
If the detected indoor humidity is higher than the target humidity, the operation rate of the compressor is controlled as a first operation rate, and if the indoor humidity is less than the target humidity, the operation rate of the compressor is controlled as a second operation rate, and the detected When the indoor humidity is less than a preset stop humidity, the compressor and the circulation unit are stopped to stop the dehumidification operation, and when the dehumidification operation is stopped, the circulation unit is periodically operated so that indoor air is introduced into the body, A control unit for controlling the re-operation of the dehumidification operation based on the indoor humidity detected by the humidity detection unit during the operation of the circulation unit;
Dehumidifier comprising an inverter unit for driving the compressor based on the operation rate transmitted from the control unit. The method of claim 1,
The second operation rate is lower than the first operation rate of the dehumidifier. The method of claim 1,
The second driving rate is adjusted in multiple stages based on a difference between the indoor humidity and the target humidity. delete The method of claim 1, wherein the control unit,
If the detected indoor humidity is higher than the target humidity, the speed of the fan provided in the circulation unit is controlled to a first rotational speed, and if the indoor humidity is less than the target humidity, the speed of the fan is controlled to a second rotational speed. Dehumidifier. The method of claim 5,
The second rotational speed is slower than the first rotational speed. A refrigeration cycle unit comprising a compressor and a heat exchanger connected to the compressor and performing dehumidification through heat exchange with indoor air;
A first fan allowing the indoor air to flow in and the dehumidified air to be discharged into the room;
A humidity detector for detecting the humidity of the indoor air;
A second fan provided around the humidity detection unit;
When performing dehumidification, the operation of the compressor and the first fan is controlled, but if the detected indoor humidity is higher than the target humidity, the operation rate of the compressor is controlled as the first operation rate, and the detected indoor humidity is the target humidity. A control unit controlling the operation rate of the compressor at the second operation rate and turning on the operation of the second fan when the compressor is controlled at the second operation rate;
And an inverter unit for driving the compressor based on the operation rate transmitted from the control unit,
The control unit is a dehumidifier configured to control an operation rate of the compressor to the first operation rate and stop the operation of the second fan when the humidity detected by the humidity detection unit is higher than the target humidity during operation of the second fan. . delete The method of claim 7, wherein the control unit,
When the detected indoor humidity is less than the target humidity, the dehumidifier is controlled to decrease the rotational speed of the first fan. The method of claim 7, wherein the control unit,
When the detected indoor humidity is less than the target humidity, the dehumidifier stops and controls the operation of the first fan. In the control method of a dehumidifier having an inverter type compressor provided in a main body and a heat exchanger connected to the compressor,
Detect humidity,
If the detected indoor humidity is higher than the target humidity, the operating rate of the compressor is controlled to the first operating rate, and a first fan provided around the heat exchanger is rotated,
If the detected indoor humidity is less than the target humidity, the second operation rate of the compressor is controlled as the second operation rate, the rotation speed of the first fan is adjusted, and a second fan provided around the humidity detection unit is operated to operate the second fan. Indoor air is allowed to flow into the interior of the main body by a fan,
If the humidity detected by the humidity detection unit during the operation of the second fan is higher than the target humidity, the operation rate of the compressor is controlled to the first operation rate, the first fan is operated, and the second fan is stopped. How to control the dehumidifier to let. The method of claim 11,
The control method of a dehumidifier further comprising maintaining an operation rate of the compressor at the first operation rate when the detected humidity is higher than the target humidity during operation of the second fan. The method of claim 11, wherein adjusting the rotation speed of the first fan,
And reducing the rotational speed of the first fan. The method of claim 11, wherein adjusting the rotation speed of the first fan,
And controlling the rotation speed of the first fan to zero so that the operation of the first fan is stopped. delete

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