KR101191211B1 - Controlling method of a drying device - Google Patents

Abstract

The present invention relates to a control method of a dryer for automatically cleaning the lint laminated to the filter, the sensing step of continuously detecting the humidity value in the air discharged from the drum or the drum by the humidity sensor; A determination step of determining whether the humidity value detected in the sensing step is equal to or greater than a preset reference humidity value; And an automatic cleaning step of starting the automatic cleaning of the filter for filtering the lint in the air discharged from the drum when the humidity value is greater than or equal to the reference humidity value in the determining step.

Description

Controlling method of a drying device

The present invention relates to a control method of a dryer, and more particularly, to a control method of a dryer for controlling so as to automatically clean the lint laminated to the filter.

The laundry treatment apparatus typically includes a washing machine for washing laundry and a dryer for drying the laundry.

A dryer is a household appliance in which laundry is normally washed, that is, clothes are mainly dried using high temperature air. In general, a dryer has a laundry container for receiving laundry. The laundry is dried by supplying dry air to the laundry accommodating part and evacuating the wet air in the laundry accommodating part.

The dryer may be divided into a top loading method and a front loading method according to a method of putting laundry into the dryer. In the top loading method, laundry is input from the upper side of the dryer, and in the front loading method, the laundry is input from the front of the dryer.

Such dryers may also be divided depending on the type of laundry container in which the laundry is accommodated. Examples are cabinet type dryers and drum type dryers.

In the cabinet-type dryer, the laundry is hung inside the laundry accommodating part through a hanger or the like, and is lying through the shelf.

The drum type dryer includes a drum accommodating laundry, a driving source for driving the drum, heating means for heating air introduced into the drum, and a fan for sucking or discharging air in the drum.

Another way to distinguish a dryer is to classify it as a condensation dryer and an exhaust dryer.

In the condensing dryer, the air that has been heated and exchanged with the laundry in the drum is circulated without being discharged to the outside of the dryer, and the condensate is made by exchanging heat with the outside air in a separate condenser and discharged to the outside.

In the exhaust dryer, the air that has been heat-exchanged with the laundry in the drum and becomes humid is discharged directly to the outside of the dryer.

However, lint is included in the air used to dry the object to be dried in such a dryer. This lint is filtered by a lint filter installed on the flow path of air discharged from the drum.

However, in the related art, after the drying stroke is completed, the user has to take out the lint filter every time to remove the lint. If the lint filter is not cleaned for a long time, the air volume decreases, and thus the drying efficiency is lowered.

Therefore, in order to solve this problem, there is a need for a filter assembly capable of automatically cleaning the filter and a control method thereof.

An object of the present invention is to provide a control method of a dryer for controlling so that the lint laminated to the filter can be automatically cleaned.

In order to achieve the above object, the present invention includes a sensing step of continuously detecting the relative humidity value in the air discharged from or inside the drum by the humidity sensor; A determination step of determining whether the relative humidity value detected in the sensing step is equal to or greater than a preset reference relative humidity value; And an automatic cleaning step of starting the automatic cleaning of the filter for filtering the lint in the air discharged from the drum when the relative humidity value is greater than or equal to the reference relative humidity value in the determination step.

The reference relative humidity value is characterized in that it is set within the range of 80 to 90% relative humidity value.

The method may further include an automatic cleaning repeating step of controlling the number of times of automatic cleaning according to a drying time after the start of the automatic cleaning step.

The automatic cleaning step may be started at a time after at least 50% or more of the total drying time has elapsed.

The reference relative humidity value is characterized in that when the moisture content of the drying object is 30 to 40%.

As described above, the control method of the dryer according to an embodiment of the present invention has the effect of improving the user's convenience by controlling the automatic cleaning timing and the number of times of the filter, and maintaining the air volume and preventing excessive internal temperature rise.

1 is a cross-sectional view showing a dryer according to an embodiment of the present invention.
2 is a plan view of the dryer according to FIG. 1;
3 is a perspective view of a filter assembly according to the present invention;
Figure 4 is a flow chart illustrating a control sequence of the dryer according to an embodiment of the present invention.
5 is a graph showing a control time point of the dryer according to FIG. 4.

The control method of the dryer according to an embodiment of the present invention can be used in both an exhaust type dryer, a condensation type dryer and a combined washing machine.

Here, the exhaust type dryer is a dryer configured to heat external air to be supplied into the drum, and the wet air is discharged to the outside after being used to dry the object to be dried in the drum.

The condensation type dryer is a dryer configured to dehumidify the humid air dried by drying the object in the drum through a condenser or a heat pump module, and then heat and supply the same to the drum.

Hereinafter, a control method of a dryer according to one embodiment of the present invention will be described in detail with reference to the accompanying drawings.

First, a general configuration of a dryer according to an embodiment of the present invention will be described.

As shown in Figure 1 and 2, the drying dryer according to an embodiment of the present invention has a large appearance, the cabinet 10 is provided with a main controller (not shown) for controlling the dryer, the cabinet The drum 20 which is rotatably coupled to the inside of the 10 to receive the drying object, the front supporter which rotatably supports the open front of the drum 20, and the rear of the drum 20 to be rotatable And a journal bearing member 24 for supporting and a motor 60 for rotating the drum 20.

In addition, the dryer has a discharge duct 50 connected to the front supporter 30, a supply duct 40 connected to the rear of the cabinet 10 to communicate with the drum 20, and a drum installed in the discharge duct 50. (20) A blowing fan 52 for exhausting the air inside and a heater 42 provided on the supply duct 40 to heat outside air are provided.

The air to be dried and dried is dehumidified through the condenser 70, and the condensate generated in the condenser 70 is drained out of the cabinet 10 by the drain pump assembly 80. One side of the condenser 70 is provided with a cooling fan 72 and a driving motor 60 for cooling the condenser 70.

An opening corresponding to the opening 21a formed in front of the drum 20 is formed in front of the cabinet 10, and the opened portion is opened and closed by the door 15.

The front supporter 30 and the journal bearing member 24 rotatably support the front and rear of the drum 20, respectively, and the front upper or lower portion of the drum 20 can be rotatably supported by the roller 90 or the like. Can be. Even if the drum 20 rotates, the front supporter 30 is fixed inside the cabinet 10 without rotating.

In addition, the journal bearing member 24 is also fixed to the inside of the cabinet 10 does not rotate, the drum 20 is rotated relative to the bearing installed on the inside of the journal bearing member 24.

A discharge duct 50 is connected to the lower side of the front supporter 30, and a blowing fan 52 is installed in the discharge duct 50 to circulate air in the drum 20 after drying is completed. One end of the discharge duct 50 is connected to the front supporter 30 and the other end is in communication with the supply duct 40. The connection assembly between the front supporter 30 and the discharge duct 50 may be further provided with a filter assembly 100 for filtering the air exhausted from the drum 20 after drying. The filter assembly 100 will be described later.

The blowing fan 52 is directly connected to the motor 60 to forcibly blow air inside the drum 20.

A plurality of through holes 10a are formed at the rear of the cabinet 10, and a supply duct 40 for supplying air circulated through the discharge duct 50 to the drum 20 is connected. A cover 22 is provided between the rear inner surface of the cabinet 10 and the rear outer surface of the drum 20 so that the air supplied from the supply duct 40 can be supplied into the drum 20 without flowing out. Is mounted.

A plurality of vent holes 20b are formed at the rear of the drum 20 for air communication, and the through holes 10a formed in the cabinet 10 and the vent holes 20b formed in the drum 20 are covered with a cover 22. It is preferably located inside of.

The through-hole 10a and the vent hole 20b should be positioned inside the cover 22 so that air introduced through the supply duct 40 may directly flow into the drum 20. On the supply duct 40, a heater 42 for heating air is provided.

The heater 42 heats the introduced dry air when the humid air circulated by the blowing fan 52 after the completion of drying is introduced into the supply duct 40 after being dehumidified through the condenser 70 to be described later. The dried air is heated by the heater 42 and resupplied to the drum 20 through the supply duct 40.

That is, when the drum 20 rotates and the air inside the drum 20 is exhausted through the discharge duct 50 by the blowing fan 52, the air heated through the supply duct 40 is inside the drum 20. Will be sucked into. At this time, the heater 42 is installed in the inlet end or the supply duct 40 into which the air is introduced into the supply duct 40 so that the heated air can be supplied into the drum 20 through the supply duct 40. It is preferable.

The motor 60 has two rotation shafts, and one rotation shaft is connected to the blowing fan 52 to drive the blowing fan 52. The other axis of rotation of the motor 60 is coupled to the pulley 62 to rotate the pulley 62. Since the pulley 62 is connected to the drum 20 by the belt 64, the drum 20 is rotated by the rotation of the belt 64.

On the other hand, as shown in Figure 1 and 2, the condenser 70 is installed between the discharge duct 50 and the supply duct 40 to dehumidify the humid air exhausted through the discharge duct 50 to supply the duct Allow 40 to be supplied.

Condenser 70 may be used in both air-cooled or water-cooled condenser.

In the case of using an air-cooled condenser, moisture is condensed through heat exchange by supplying outside air, which is relatively colder than air, to the condenser after drying. In the case of using a water-cooled condenser, moisture is condensed through heat exchange by supplying a refrigerant or cooling water to the condenser.

Condensate generated when using the air-cooled or water-cooled condenser is drained out of the cabinet 10 through the drain pump assembly 80. In the present invention, the air-cooled condenser has been described as an example for convenience.

 When the air-cooled condenser 70 is used, cold air must be supplied from the outside of the cabinet 10 to condense moisture in the air moistened after drying by heat exchange. Therefore, it is preferable that the outside air supply duct 40 is provided to supply the outside air, and one side thereof is connected to one side of the condenser 70, and the motor 60 and the blowing fan 52 are formed at the other side. To this end, the outside air supply duct 40 is formed on one side of the cabinet 10 to communicate with the outside, one end is preferably connected to one side of the condenser 70.

However, if the drying stroke continues, foreign matters such as lint are stacked on the filter assembly 100. If the lint filter is not cleaned for a long time, the air volume decreases, and thus the drying efficiency is lowered. Therefore, after the use of the dryer is complete, the user has to take out the lint filter every time to remove the lint.

In order to solve this problem, the present invention provides a filter assembly 100 which can automatically clean the lint filter to improve the user's convenience and solve problems caused by airflow and temperature overheating.

As shown in FIG. 1, the filter assembly 100 is installed on the discharge duct 50 through which air discharged from the drum 20 passes.

As shown in FIGS. 2 and 3, the filter assembly 100 automatically cleans the filter body 110, the filter unit 120 formed on at least one surface of the filter body 110, and the filter unit 120. It consists of a filter cleaner (not shown).

The filter body 110 has an air inlet 111a formed at one side thereof, and is foldably coupled around the other side of the filter body 110 opposite to the air inlet 111a, and a lint collecting space is formed therein. That is, the front surface 112 and the rear surface 114, the relatively narrow side 116 and lower surface 118 compared to these are formed. The filter unit 120 is integrally formed on the front surface 112, and the front surface 112 is rotatably opened and closed about the lower ends of both side surfaces 116 (for convenience, the air exit surface is opposed to the front surface of the filter body and is opposed thereto). The back side, the air inlet side is defined as upper side, and the opposite side is defined as lower side).

The upper portion of the filter body 110 in which the air inlet 111a is formed is streamlined to prevent interference with the coupling portion. The air discharged from the drum 20 flows into the filter body 110 through the air inlet 111a and exits through the filter unit 120 formed on the front surface 112 of the filter body 110.

The filter unit 120 may be integrally formed with at least the front side 112 of the filter body 110 and may be integrally formed with the rear side 114 of the filter body 110. When the filter unit 120 is formed on both sides, it is advantageous to secure the air volume more than when the air escapes to only one side, thereby helping to improve the drying performance.

The filter unit 120 is a part in which lint contained in the air is filtered while the air introduced through the air inlet 111a is passed out. The filter unit 120 supports a thin and dense circular mesh 122 and a plurality of meshes 122. Rib 124. Since the mesh 122 is circular, the rib 124 is preferably formed in a combination of a circular and a straight line so as to support the circular mesh 122 evenly and reinforce the strength. When the air from which the lint is removed through the filter unit 120 is drawn out, the lint is gradually laminated in a state in which the lint is attached to the filter unit 120, and a filter cleaning unit is installed inside the filter body 110 to automatically clean the lint. do.

The filter cleaner may be controlled to operate periodically to automatically clean the filter. In an embodiment of the present invention, the filter cleaner automatically operates, and the relative humidity value, the drying time, and the moisture content of the drying object may be used as a reference, and a separate humidity sensor may be installed to calculate the relative humidity value. The humidity sensor may be installed inside the cabinet 10 but may be installed on the above-described circulation passage.

In the dryer according to the embodiment of the present invention having such a configuration, a control method of the dryer for automatically cleaning the lint in the filter assembly will be described.

4 is a flowchart illustrating a control sequence of the dryer according to an embodiment of the present invention, and FIG. 5 is a graph illustrating a control time point of the dryer according to FIG. 4.

In the microcomputer or the control unit of the dryer, when the dryer is used for a predetermined number or more and the lint is laminated on the filter, the filter assembly is controlled to automatically clean the filter assembly in order to prevent a decrease in drying efficiency.

The start time of the automatic cleaning may be determined by the number of times the drying stroke is executed or the quantity of the object to be dried, or may be determined by a factor such as a relative humidity value as in an exemplary embodiment of the present invention. Alternatively, the automatic cleaning timing may be determined based on the relative humidity value after the drying stroke is performed several times or more.

As shown in FIG. 4, the controller detects a relative humidity value in the air discharged from the drum 20 by a humidity sensor installed on the circulation flow path (detection step S100). At this time, the relative humidity value is preferably continuously detected.

The reason for detecting the relative humidity value in the air discharged from the drum 20 is that when a drying time of the drying object is started and a predetermined time elapses, moisture is dried from the drying object and the relative humidity value in the air discharged from the drum 20 becomes high. Because.

The controller determines whether the relative humidity value detected in the sensing step S100 is equal to or greater than a predetermined reference relative humidity value (determination step S200).

If it is determined that the relative humidity value detected in the determination step (S200) is greater than or equal to the reference relative humidity value, the automatic cleaning step (S300) is performed to automatically clean the filter for filtering lint in the air discharged from the drum 20. After the automatic cleaning step (S300) is carried out by performing the automatic cleaning repeating step (S400) by controlling the number of times the automatic cleaning according to the drying time.

As shown in Fig. 5, in the initial stage of drying (A section), since the drying target is wet, there is little lint generation and less evaporation occurs from the drying target. ).

Therefore, since the filter unit 120 does not need to be automatically cleaned during the time corresponding to this section, the automatic cleaning step S300 is not started.

When the drying is completed to some extent and the moisture content is about 30 to 40%, the amount of lint generation starts to increase, and the relative humidity value at this time becomes the reference relative humidity value.

Therefore, a time point (C time point) at which the automatic cleaning step S300 starts for the first time is a time point at which the relative humidity value of the air discharged from the drum 20 is equal to or greater than a predetermined reference relative humidity value. In this case, the reference relative humidity value may be set within the range of 80 to 90% of the relative humidity value.

After the automatic cleaning step (S300) is started, it is preferable to control the number of repeated cleaning of the filter unit 120 based on the drying time in order to secure the reliability of the motor and reduce unnecessary energy consumption (S400).

In addition, the time point (C time point) at which the relative humidity value of the air is equal to or higher than the reference relative humidity value corresponds to the time after at least 50% or more of the total drying time has elapsed (Section B). Therefore, if the remaining drying time is greater than or equal to a predetermined time, the automatic cleaning is repeated at least once, and if the remaining drying time is less than or equal to the predetermined time, the automatic cleaning is not repeated based on the drying time. Can be controlled.

The drying stroke consists of a drying step of performing drying by increasing the temperature of the air supplied to the drying object, and a cooling step of gradually lowering the temperature of the drying air after a predetermined time after drying, and later cooling the drying object. do.

Since the lint is a large amount is generated in the second half of the drying step to dry the object to some extent (about 30 to 40% moisture content) may be necessary to automatically clean the filter unit 120 at this time.

However, since the cooling step serves to cool the drying object, there is almost no amount of lint. Therefore, the automatic cleaning of the filter unit 120 does not have to be repeated. Therefore, it is preferable to determine whether the remaining drying time is based on the drying time and to determine whether to repeat the automatic cleaning of the filter unit 120 and the number of times of automatic cleaning.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. And such changes are within the scope of the appended claims.

10 cabinet 20 drum
50: discharge duct 70: condenser
100: filter assembly 110: filter body
120: filter unit

Claims (5)

A sensing step of continuously detecting a relative humidity value in air discharged from or inside the drum by a humidity sensor;
A determination step of determining whether the relative humidity value detected in the sensing step is equal to or greater than a preset reference relative humidity value; And
And an automatic cleaning step of automatically cleaning the filter for filtering lint in the air discharged from the drum when the relative humidity value is greater than or equal to the reference relative humidity value in the determining step. The method of claim 1,
The reference relative humidity value is a control method of the dryer, characterized in that the humidity value is set within the range of 80 to 90%. The method of claim 1,
And a repeating automatic cleaning step in which the number of automatic cleaning operations is controlled according to a drying time after the start of the automatic cleaning step. The method of claim 1,
The automatic cleaning step is a control method of the dryer, characterized in that started at a time after at least 50% of the total drying time has elapsed. The method of claim 1,
And said reference relative humidity value corresponds to when the moisture content of the object to be dried is 30 to 40%.

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