This application claims the benefit of Korean Patent Application No. 2004-91830, filed Nov. 11, 2004, in the Korean Intellectual Property Office, the disclosure of which is incorporated herein by reference.
1. Field of the Invention
The present invention relates to a clothing drying machine and a method for sensing a dryness level using the same, and more particularly, to a clothing drying machine, which performs drying operation in various dryness levels and a method for sensing a dryness level using the clothing drying machine.
2. Description of the Related Art
Generally, a clothing drying machine includes a housing forming an external structure, a drum installed in the housing for containing laundry to be dried, a heating duct for generating hot air to be supplied to the drum, a hot air inlet channel for guiding the hot air generated form the heating duct to the drum, and a hot air outlet channel for guiding the hot air discharged from the drum to the outside.
The drum is rotatably installed in the housing, and an air blast fan for generating force for flowing the hot air is installed in the hot air outlet channel. The hot air circulates into the drum and the duct by the operation of a driving motor for simultaneously driving the drum and the air blast fan, thereby drying the laundry.
A conventional clothing drying machine, which is disclosed by Korean Laid-open Publication No. 2002-62446, senses a dryness level of clothing using an electrode sensor and a thermistor. The electrode sensor determines the dryness level of the clothing according to a sensed voltage using a principle, in which the voltage is increased when laundry having a high humidity contacts a metal plate, and the thermistor allows control of the drying of the clothing using a principle in which electric resistance varies according to a variation of temperature. That is, the thermistor determines a dryness level of the clothing by sensing the temperature of air discharged from the drum to the outside. As shown in
When the drying of the clothing is in progress (S10), the dried state value (V) of the clothing and the temperature (T) of the air vary based on the curves of V and T versus time (t) shown in
In the above-described conventional method for sensing a dryness level of clothing, when the temperature (T) of the air reaches the predetermined upper limit (T1) and the thermistor starts its control operation, the clothing has been comparatively highly dried. Accordingly, the above conventional method cannot cope with the situation in which a user wants a low dryness level of the clothing so that the clothing has a high remaining moisture content.
Further, if a dryness level of the clothing is determined using a voltage value inputted to the electrode sensor, the voltage value momentarily may fluctuate widely. Accordingly, in this case, it is difficult to sense a precise dryness level of the clothing.
Therefore, one aspect of the invention is to provide a clothing drying machine, which terminates drying operation when a dryness level of clothing reaches a target level desired by a user, and a method for sensing the dryness level using the same.
In accordance with one aspect, the present invention provides a clothing drying machine including: an electrode sensor, in which voltage varies according to moisture content of laundry; a counting unit for counting the frequency of a case, in which the voltage sensed by the electrode sensor is more than a predetermined reference voltage; and a control unit for terminating drying operation when the frequency counted by the counting unit for a predetermined reference time is in the range of one of predetermined dryness levels.
In accordance with another aspect, the present invention provides a method for sensing a dryness level using a clothing drying machine including: counting the frequency of a case, in which voltage sensed by an electrode sensor, in which the voltage varies according to moisture content of laundry, is more than a predetermined reference voltage; and terminating the drying operation when the frequency counted by the counting unit for a predetermined reference time is in the range of one of predetermined dryness levels.
In accordance with yet another aspect, the present invention provides a method for sensing a dryness level using a clothing drying machine including: allowing an electrode sensor, in which voltage varies according to moisture content of laundry, to sense the voltage; and determining the dryness level corresponding to the frequency of a case, in which the sensed voltage is in a predetermine range.
Aspects of the invention will become apparent and more readily appreciated from the following description of the exemplary embodiments, taken in conjunction with the accompanying drawings in which:
Reference will now be made in detail to the exemplary embodiment of the present invention, an example of which is illustrated in the accompanying drawings, wherein like reference numerals refer to like elements throughout. The exemplary embodiment is described below to explain the present invention by referring to the annexed drawings.
As shown in
An opening 11 for putting laundry into and taking laundry out of the drying machine is formed through the central portion of the front surface of the housing 10, and a door 12 for opening and closing the opening 11 is hinged to one side of the opening 11. A key input unit 66 (in
The drum 20 includes a front portion 21 provided with an opening formed through the central portion thereof towards the door 12, a rear portion 23 located in the rear portion of the inside of the housing 10 and provided with a hot air inlet 27 formed through the upper portion thereof, and a side portion 22 connecting the front portion 21 and the rear portion 23. The side portion 22 can be rotated.
Two bar-shaped electrodes 28 extend in a transverse direction with respect to the front portion 21 and are provided with side surfaces protruded towards the rear portion 23 of the drum 20. The two bar-shaped electrodes are installed on the lower part of the front portion 21 and form an electrode sensor 65 (in
Lifters 24 extended in a transverse direction of the side portion 22 are protruded from the inner cylindrical surface of the side portion 22 towards the center of the inside of the drum 20. The lifters 24 lift laundry and then drop the laundry according to the rotation of the side portion 22, thereby uniformly mixing the laundry. Both ends of the inside of the side portion 22 are supported by support portions 25 protruded from the front and rear portions 21 and 23 to the side portion 22. Sliding pads 26 are installed between the support portions 25 and both ends of the side portion 22 of the drum 20, thereby facilitating the sliding motion of the side portion 22 of the drum 20.
A heater 31 for heating air sucked from the inside of the housing 10 to the heating duct 30 is installed in the heating duct 30. An inlet 32 for sucking air in the housing 10 is formed through the front end of the heating duct 30, and an outlet 33 connected to the hot air inlet channel 40 so that the heated air is supplied to the drum 20 is formed through the rear end of the heating duct 30.
One end of the hot air inlet channel 40 is connected to the outlet 33 of the heating duct 30, and bent upwardly at the rear portion of the housing 10. The other end of the hot air inlet channel 40 is connected to the hot air inlet 27 of the rear portion 23 of the drum 20. The hot air outlet channels 50a and 50b are connected to the lower part of the front portion 21 of the drum 20, and communicate with the outside of the housing 10 along the bottom surface of the inside of the housing 10. An air blast fan 51 for supplying force for sucking and discharging the hot air and a discharged air temperature sensor 52 for sensing the temperature of the discharged air are installed in the hot air outlet channels 50a and 50b.
Accordingly, when the air blast fan 51 is rotated, hot air generated from the heating duct 30 is guided to the inside of the drum 20. The hot air, which is supplied to the inside of the drum 20, evaporates moisture contained in laundry, and is then discharged to the outside of the housing 10 through the hot air outlet channels 50a and 50b.
A driving motor 53 transmits rotary force to the air blast fan 51 and the side portion 22 of the drum 20. For this reason, driving shafts 54a and 54b of the driving motor 53 extend forwards and backwards. The air blast fan 51 is directly connected to the driving shaft 54a, which extends forwards, and a pulley 55 for driving the side portion 22 of the drum 20 is fixed to the other driving shaft 54b, which extends backwards. The pulley 55 is connected to the side portion 22 of the drum 20 by a motor-driven belt 56, thereby transmitting the rotary force of the driving motor 53 to the side portion 22 of the drum 20. Thus, the air blast fan 51 and the side portion 22 of the drum 20 are simultaneously rotated.
As shown in
The electrode sensor 65 includes the two bar-shaped electrodes 28 (in
The above current is received as a voltage by the microcomputer 64. The lower the moisture content of the laundry, the lower the voltage value inputted into the microcomputer 64. The microcomputer 64 sets a reference voltage (approximately 2˜2.5V). When the voltage inputted from the electrode sensor 65 to the microcomputer 64 is more than the reference voltage, the microcomputer 64 recognizes the inputted voltage as the number “1”, and when the voltage inputted from the electrode sensor 65 to the microcomputer 64 is not more than the reference voltage, the microcomputer 64 recognizes the inputted voltage as the number “0”. Then, the microcomputer 64 counts the frequency of the number “1”. The lower the moisture content of the laundry is, the smaller the frequency of counting the number “1” is.
Dryness of the clothing drying machine is divided into five levels according to the remaining moisture content of the laundry after drying. When the remaining moisture content of the laundry is 15˜25%, the dryness level is set to “damp dry”; when the remaining moisture content of the laundry is 5˜20%, the dryness level is set to “less dry”; when the remaining moisture content of the laundry is 3˜5%, the dryness level is set to “normal dry”; when the remaining moisture content of the laundry is 1˜3%, the dryness level is set to “more dry”; and when the remaining moisture content of the laundry is 1˜2%, the dryness level is set to “very dry”.
The above five dryness levels are distinguished from one another using the frequency of counting the number “1”.
In the case that the dryness level of clothing using the drying machine is performed higher than “normal dry”, the degree of drying cannot be sensed only by the frequency of counting the number “1” using the electrode sensor 65. Hereinafter, with reference to
When a user puts laundry to be dried into the drum 20, the user inputs a desired dryness level through the key input unit 66, and then presses a dry start button. The driving motor 53 and the heater 31 are operated and drying operation is started (S100).
When the drying operation is started, the electrode sensor 65 senses current according to the dried state of the laundry, and the current is inputted as voltage (V) to the microcomputer 64 (S110).
The microcomputer 64 compares the voltage (V), inputted from the electrode sensor 65, to a reference voltage (Vs: approximately 2˜2.5V). When the inputted voltage (V) is higher than the reference voltage (Vs), the microcomputer 64 recognizes the inputted voltage (V) as the number “1”, and when the inputted voltage (V) is not higher than the reference voltage (Vs), the microcomputer 64 recognizes the inputted voltage (V) as the number “0”. Then, the microcomputer 64 counts the frequency of the number “1” (S120).
Thereafter, the microcomputer 64 determines whether or not the dryness level inputted by the user through the key input unit 66, i.e., the current drying operation, corresponds to one of the levels consisting of “normal dry”, “less dry”, and “damp dry” (S130).
When it is determined that the inputted dryness level corresponds to one of the above levels, the microcomputer 64 counts the frequency of the case in which the inputted voltage (V) is higher than the reference voltage (Vs) for a predetermined time (approximately 1 minute), i.e., the frequency of the number of “1” (S140).
The microcomputer 64 determines whether or not the counted frequency is in a predetermined range according to individual dryness levels (S150). For example, in the case that the desired dryness level, set by the user, is “normal dry”, it is determined that the drying operation in a state, in which the remaining moisture content is 3˜5%, is completed only when the counted frequency for 1 minute is 0 as shown in
The drying operation is continuously performed until the counted frequency corresponding to the desired dryness level, set by the user, is sensed. In the case that the counted frequency is in the predetermined range corresponding to the dryness levels, the microcomputer 64 determines that the drying operation is completed and terminates the drying using hot air (S190), performs a cooling operation for a designated time (S200), and then completely terminates the drying operation (S210).
In the case that it is determined that the dryness level during the drying operation corresponds to one of the levels consisting of “more dry” and “very dry” at step S130, the laundry is first dried to the level of “normal dry”. That is, the microcomputers 64 performs the drying operation until the counted frequency of the number “1” for 1 minute is 0, and then senses time (Tn) taken to perform the above drying operation (S160).
When the drying operation is performed up to the level of “normal dry”, the microcomputer 64 calculates additional drying time by multiplying the time taken to perform the drying operation by a predetermined coefficient. Assuming that it takes 30 minutes to perform the drying operation until the level of “normal dry”, the additional drying times to reach the levels of “more dry” and “very dry” are respectively obtained by multiplying the above time by coefficients of 0.1˜0.2 and 0.2˜0.4 (S170). The obtained additional drying times to reach the levels of “more dry” and “very dry” are respectively 3˜6 minutes and 6˜12 minutes.
Thereafter, the drying operation is additionally performed during either one of the above additional drying times according to the dryness levels (“more dry” and “very dry”) (S180), and then the drying using hot air is terminated (S190). When the drying is completed, the cooling operation is performed for a designated time (S200), and then the drying operation is completely terminated (S210).
As described above, the clothing drying machine of the exemplary embodiment of the present invention performs drying operation according to various dryness levels.
As apparent from the above description, the exemplary embodiment of the present invention provides a clothing drying machine, which terminates drying operation when a dryness level of clothing reaches a target dryness level (target remaining moisture content) desired by a user.
The clothing drying machine of the exemplary embodiment of the present invention precisely senses a low dryness level of clothing having high remaining moisture content as well as a high dryness level of clothing having low remaining moisture content, thereby sensing the optimum dryness level of the clothing according to user's tastes and preventing damage to the clothing or loss of electric power due to excessive drying of the clothing.
Although an exemplary embodiment of the invention has been shown and described, it would be appreciated by those skilled in the art that changes may be made in this exemplary embodiment 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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10-2004-0091830 | Nov 2004 | KR | national |
Number | Name | Date | Kind |
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3762064 | Offutt | Oct 1973 | A |
4385452 | Deschaaf et al. | May 1983 | A |
4477982 | Cotton | Oct 1984 | A |
Number | Date | Country |
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2002-0062446 | Jul 2002 | KR |
Number | Date | Country | |
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20060096117 A1 | May 2006 | US |