This application claims the benefit of Korean Patent Application No. 10-2010-0126854, filed on Dec. 13, 2010 in the Korean Intellectual Property Office, the disclosure of which is incorporated herein by reference.
1. Field
Embodiments of the present disclosure relate to a dryer to dry an object accommodated in a drum via circulation of air.
2. Description of the Related Art
In general, a dryer includes a drum in which an object to be dried is accommodated, the drum being rotated to rotate the object, and a heat source (e.g., a heater or a heat pump) to heat air. As a drying fan is rotated to move low-temperature and low-humidity air through the heat source, the low-temperature and low-humidity air is changed into high-temperature and low-humidity air by the heat source. The resulting high-temperature and low-humidity air is introduced into the drum to heat the object to be dried. Then, the high-temperature and low-humidity air is changed into high-temperature and high-humidity air by steam generated while the object is heated. Although an open type dryer directly discharges the high-temperature and high-humidity air to the outside, in the case of a closed type dryer, the high-temperature and high-humidity air is changed into low-temperature and low-humidity air by a condenser which condenses the air to remove moisture from the air. The low-temperature and low-humidity air is changed into high-temperature and low-humidity air while passing through the heat source via rotation of the drying fan and then, is introduced into the drum to heat the object to be dried. This circulation cycle is repeated until the object is completely dried. After the object is completely dried, only a motor is driven and the heat source is not operated, which serves to cool the object to allow a user to easily take the object out of the drum.
The above-described dryer may need to display and inform the user of a remaining drying time until the object is completely dried.
Conventional dryers have been designed to preset a drying time and a cooling time, to display a remaining drying time. A display unit displays the preset drying time which is decremented as time passes during drying and also, displays the preset cooling time which is decremented as time passes during cooling.
However, since these conventional dryers function to display the remaining drying time regardless of load of an object to be dried, i.e. the amount of moisture contained in the object to be dried, there is a great difference between an actual remaining drying time and a remaining drying time displayed on the display unit, resulting in deterioration in the reliability of the dryer.
It is one aspect of the present disclosure to provide a dryer and a control method thereof, in which load of an object to be dried is detected and an anticipated drying time based on the detected load is accurately determined and displayed.
It is another aspect of the present disclosure to provide a dryer and a control method thereof, in which load of an object is accurately detected using a sensor which has less risk of contamination, which ensures reliable anticipation of a drying time.
Additional aspects of the disclosure will be set forth in part in the description which follows and, in part, will be apparent from the description, or may be learned by practice of the disclosure.
In accordance with one aspect of the disclosure, a dryer includes a drum installed in a rotatable manner and configured to accommodate an object to be dried therein, a front support installed at an entrance of the drum to support the drum, a rear support installed at an opposite side of the entrance of the drum to support the drum, an exhaust hole formed in the front support, through which interior air of the drum is discharged, and a humidity sensor installed to the front support at a position adjacent to the exhaust hole and serving to detect humidity of the air to be introduced into the exhaust hole, wherein the installation position of the humidity sensor allows the air moving in a rotating direction of the drum within the drum to pass a surface of the humidity sensor prior to being discharged through the exhaust hole.
The humidity sensor may be installed to the front support such that a humidity detecting surface of the humidity sensor does not protrude from a surface of the front support.
The dryer may further include an electrode sensor installed to the front support to detect humidity by coming into contact with the object.
The humidity sensor may cooperate with the electrode sensor to enable compensation of a drying time of a drying operation.
The humidity sensor may enable compensation of the drying time by detecting humidity in a section in which humidity detection by the electrode sensor is not possible.
In accordance with another aspect of the disclosure, a dryer includes a drum installed in a rotatable manner and configured to accommodate an object to be dried therein, an exhaust hole formed at an entrance of the drum, through which interior air of the drum is discharged, and a humidity sensor installed at the entrance of the drum at a position adjacent to the exhaust hole, the humidity sensor being installed in front of the exhaust hole on the basis of a rotating direction of the drum to detect humidity of air to be introduced into the exhaust hole.
The dryer may further include a front support installed at the entrance of the drum to support the drum, and the exhaust hole and the humidity sensor may be provided at the front support.
The dryer may further include an electrode sensor to detect humidity by coming into contact with the object to be dried.
These and/or other aspects of the disclosure will become apparent and more readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:
Reference will now be made in detail to the exemplary embodiment of the present disclosure, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to like elements throughout.
The control panel 104 as an input unit, the humidity sensor 210, the temperature sensor 604 and the electrode sensor 212 may be connected to an input side of the control unit 602 to enable communication therebetween. The control panel 104 allows the user to input drying conditions (e.g., a desired drying level), and the temperature sensor 604 measures the interior temperature of the drum 202. Measuring the interior temperature of the drum 202 serves to supply air of an appropriate temperature during drying as necessary and to prevent overheating of the drum 202.
A heater drive unit 606, a fan drive unit 608, a display drive unit 610, and a motor drive unit 618 are connected to an output side of the control unit 602 to enable communication therebetween. The heater drive unit 606 heats air by driving a heater 614 that serves as one kind of heat source. Instead of the heater 614, a heat pump may serve as the heat source. The fan drive unit 608 drives a fan 208 to supply heated air into the drum 202. The display drive unit 610 drives the display 106 as a display unit to display information on the display 106. The motor drive unit 618 drives a motor 620 to rotate the drum 202. The display 106 displays drying conditions selected by the user or operational states of the dryer during drying (e.g., a current temperature and a remaining drying time), allowing the user to confirm them.
The control unit 602 drives the heater 614 and the fan 208 via the heater drive unit 606 and the fan drive unit 608 based on the drying conditions (e.g., a desired drying level) input via the control panel 104, thereby allowing hot wind to be supplied into the drum 202. The hot wind is used to dry the object within the drum 202. The control unit 602 controls driving rates of the heater 614 and the fan 208 during drying in consideration of humidity change in the drum 202 detected via the humidity sensor 210 and the electrode sensor 212 and temperature change in the drum 202 detected via the temperature sensor 604. In particular, the control unit 620 calculates an anticipated drying time until the object is dried to a target level based on the humidity change in the drum 202 detected via the humidity sensor 210 and the electrode sensor 212 and the temperature change in the drum 202 detected via the temperature sensor 604. The calculated anticipated drying time is displayed via the display 106. As such, the anticipated drying time displayed on the display 106 informs the user of a remaining drying time until completion of drying. If the humidity sensor 210 does not accurately detect (change of) the interior humidity of the drum 202 and the temperature sensor 604 does not accurately detect (change of) the interior temperature of the drum 202, it is difficult to accurately calculate the anticipated drying time until the object is dried to a target level. This means that the object may be insufficiently or excessively dried as compared to the target level. In addition, if the anticipated drying time is not accurate, the remaining drying time displayed on the display 106 is also inaccurate, losing the reliability of the user. Thus, accurately detecting (change of) the interior humidity of the drum 202 using the humidity sensor 210 and the electrode sensor 212 and (change of) the interior temperature of the drum 202 using the temperature sensor 604 is very important in operation of the dryer.
First, in the case of the first load determination (704 to 710 in
In the case of the second load determination (712 to 718 in
Here, according to the progress circumstances of the first load determination (704 to 710 in
Drying experiments may be previously performed with respect to various kinds and amounts of objects and with analysis of the resulting experimental data, data of humidity change and temperature change with respect to the kind and quantity of each test object may be obtained. The kind and amount of an object during actual drying may be determined by comparing humidity change and temperature change detected during the actual drying with the previously obtained data. In this case, more accurate determination may be possible when considering both the interior temperature of the dryer and an outside temperature around the dryer. In the embodiment of the present disclosure, the control unit 602 utilizes data of the reference table mentioned in the above description of
After completion of both the first load determination and the second load determination, drying time is compensated using results of the first load determination and the second load determination (720). Specifically, since an object begins to dry as moisture is evaporated from the surface of the object, no moisture remains on the surface of the object after drying has progressed to some extent even if the object still contains moisture therein. Thus, the electrode sensor 212, which is devised to detect humidity by coming into direct contact with moisture, may fail to detect humidity (or dryness) if the humidity of the object does not reach a predetermined value. To overcome such a limitation of the electrode sensor 212, although additional drying may be performed for an arbitrary time in a section in which humidity detection using the electrode sensor 212 is not possible, this may cause drying defects, such as insufficient or excessive drying, according to the amount or state of the object. In the embodiment of the present disclosure, instead of the additional drying, the humidity sensor 210 may be used along with the electrode sensor 212 to accurately detect humidity (dryness) even in the section in which humidity detection using the electrode sensor 212 is not possible. With regard to the compensation of drying time 720 in
The control unit 602 calculates an anticipated drying time based on the drying time compensation results and displays the calculated anticipated drying time on the display 106 (722). Thereby, the user can be informed of a remaining drying time until completion of drying. Dryness in the drum 202 may be continuously detected using the humidity sensor 210 even after calculation of the anticipated drying time is completed (724). This serves to confirm whether or not the dried state of the object reaches a target level. For example, the drying of the object and the detection of dryness are continued before the object is completely dried (No in 726). If the object is completely dried (Yes in 726), the heater 614 and the fan 208 are stopped to end drying (728). When it is desired to cool the object after completion of drying, an operation to circulate unheated air within the drum 202 by stopping only the heater 614 and continuously driving the fan 208 may be added.
As is apparent from the above description, one or more embodiments include a dryer and a control method thereof, in which load of an object to be dried is detected and an anticipated drying time based on the detected load is accurately determined and displayed.
Further, one or more embodiments include a dryer and a control method thereof, in which load of an object to be, dried is accurately determined using a sensor which has less risk of contamination.
Although the embodiment of the present disclosure has been shown and described, it would be appreciated by those skilled in the art that changes may be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the claims and their equivalents.
Number | Date | Country | Kind |
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10-2010-0126854 | Dec 2010 | KR | national |