KR850001136B1 - Drying apparatus - Google Patents

Abstract

A control device for a clothes dryer comprises an instantaneus value- detecting means with a pair of electrodes that are successively brought into contact with clothes stirred in the rotating drum of the drying apparatus. The electrodes produce an instantaneous detection voltage indicating the drying rate of the clothing. The device also has a setting part, a comparing part and a controlling part.

Description

dryer

1 is a connection diagram of a driving circuit showing an embodiment of the present invention.

2 is an explanatory diagram of an operation portion of a timer.

3 is a time chart of a timer.

4 and 5 are voltage waveform diagrams.

The present invention relates to a dryer of a type which makes it possible to detect a drying rate by detecting an electrical resistance of a garment.

BACKGROUND ART Conventionally, as a method of detecting the drying rate of clothes, an electric resistance of the clothes itself is detected between the electrodes. In this case, the clothing is stirred in the rotating drum, so the contact time between the electrodes is very short.

Therefore, since the voltage corresponding to the electrical resistance obtained between the electrodes is in the form of a beard-shaped pulse, conventionally, this is integrated by a capacitor to average the detection input. On the other hand, since dried clothes and other things coexist in the clothes, when the average value as described above is used as a detection input, even undried foods are likely to be dried. In order to prevent this, conventionally, among the voltage pulses generated between the electrodes, a voltage signal corresponding to the low drying rate is integrated and averaged by a capacitor, and it is determined how long the average value exceeds the set value. One way to do it (for example, commando 48-4666).

However, this conventional method also has the following drawbacks.

(A) Integrating and averaging the inter-electrode voltage results in a large difference in the mean value depending on the frequency of contact between the electrode and the cloth due to the long integration time constant, and the dryness detection result because the contact frequency is related to the amount of cloth. It changes according to the amount of cloth and becomes inaccurate.

(B) In the case of drying clothes and those that do not coexist, if you try to get the average value by reducing the integral time constant, there will be a big change in the average value. Will change.

(C) There is a state of use of the dryer, called "pushing out," which is to remove undried clothing such as cotton during drying operation and to take out the dried quickly such as a fiber, or to take it out of an undried body for ironing. In such a case as well, it is necessary to perform the drying rate detection in determining the "duck" timing. However, the conventional one has a drawback that it is not suitable for the determination of a subtle " duck out " time, because it is representatively different from the actual dry rate of the dry rate detection result as described in (a) and (b).

(D) When attempting complete drying, all parts of clothing or fabric must be completely dry, but as it nears the end of drying, the moistened fabric becomes narrower, and the wetted part has a very high frequency of contact with the electrodes. Less. Therefore, the detected average value is high and it is easy to be considered to be dry even though there is a part that is wet.

The present invention has been made in order to eliminate the above-mentioned defects, and its object is not to average the resistance detected between the electrodes, but to store the instantaneous value as an instantaneous resistance as a determining factor of the drying rate. By setting the resistance to be determined by comparing the resistance with the set value, an accurate drying rate is obtained which does not depend on the presence of a large amount of cloth or coexistence of clothes having different drying speeds, and in particular, the determination of "take out". Not only is this titration corrected, but it is further provided to provide a drier which can be expected to be completely dried with few wetted parts.

The present invention will be described below with reference to the drawings based on one embodiment.

In FIG. 1, (1) is an instantaneous value detection circuit, (2) is an instantaneous value memory circuit, (3) is a comparison circuit, (4) is a control part, and (5) is a state switching means. In these specific configurations, (6) is an AC power source, (7) is a transformer operated by the AC power source 6, and the direct current bus line 10 passes through the full-wave rectifying circuit 8 and the smoothing circuit 9. DC power is supplied between and 11). Denoted at 12 is a timer equipped with a timer motor 13 and cam switches 14 to 19. The operation part of this timer 12 is shown in FIG. 2, and the opening / closing timing of the cam switches 14-19 is shown as an oblique line in FIG. In FIG. 2, reference numeral 20 denotes an operation dial of the timer 12, and reference numeral 21 denotes a setting instruction unit for instructing setting of the operation dial 20. In FIG. A0, A1, and B0, A1 shown in FIG. 3 are symbols indicating replacement positions of the cams for opening and closing the cam switches 14 to 19, some of which are also shown in FIG. This timer 12 is an automatic setting area TA having a timing area between the positions AO and BO, and a manual setting area having a timing area between the point-turning positions OFF and the position BO, as understood in FIGS. 2 and 3. TB, etc. By the way, (22) is a drive motor for driving the rotating drum and fun, which is controlled by the cam switch 15, and (23) is a heater that is a heat source of hot air supplied to the rotating drum, Controlled by 14. The timer 12 is energized and controlled by the cam switches 16 and 17, and is also energized and controlled by the upper contact 25 of the relay 24 irrespective of this. In the instantaneous value detection circuit 1, (26, 27) is a pair of electrodes, one electrode 26 of which is connected to the DC bus line 10 via a resistor 28, and the other electrode. Reference numeral 27 is grounded via resistors 29 and 30. Here, the value of the resistor 30 is set to a value substantially equal to the resistance of the cloth between the electrodes 26 and 27 during the intermediate drying period of the drying rate of approximately 75% to 85%, that is, "during off". The detection terminal 31, which is the non-ground terminal of the resistor 30, is configured to provide an input resistance 32a, an operational amplifier 32, a diode 33, and a memory capacitor 34 in the instantaneous value memory circuit 2. Grounded via. The instantaneous value output terminal 35, which is the non-grounded terminal of the memory capacitor 35, is connected to one input terminal of the comparator 36 in the comparison circuit 3, and the other input terminal is connected to the DC bus 10 with the input terminal. In series with ground

This instant charging is possible because the gain of the operational amplifier 32 is very high. On the other hand, the comparator 36 outputs a high level voltage VD (see FIGS. 4 and 5) as a set value reaching signal when (VC> VR), and receives the transistor 41 received through the resistor 40. ) Is configured to energize the relay 24. In the state switching means 5, 42 is a switching switch having the contacts 42a to 42d, and the diode 43 and the resistance when the contact 42a and the contact 42d are operated "on". The circuit 45 constitutes 44a and 44b so as to operate the transistor 45 "on" and to supply the potential of the DC bus 10 to the common point with the resistors 37 and 38 via the diode 46. When the contact 42a and the contact 42b are turned on or the contact 42a and the contact 42c are respectively turned on, the potential of the DC bus line 10 The 47 is supplied to the 47 via a series circuit between the diode 48 and the cam switch 18 or via only the cam switch 19. Dividing resistors 49 and 50 are interposed in series with conductor 47, and transistor 41 is forcibly " on " when electric potential of DC bus 10 is given to conductor 47. FIG. On the other hand, the series circuit of the transistor 45 and the resistor 51 and the resistor 52 are connected to each other in parallel with the storage capacitor 34 in the instantaneous value memory circuit 2. The transistor 45 is for switching the storage time, that is, for switching the discharge time constant of the memory capacitor 34. When the transistor 45 is "off", the discharge time constant is TC and "on". The values of the resistors 51 and 52 are set to be Td (T _{? =} 10 Td). On the other hand, if it of the change-over switch 42, the contact (42a) and the contact (42b) to "on" VR to, and the "off" the VR ₁ at the time when the liver when in a VR ₂ (VR ₁ = 10VR ₂ ) The values of the resistors 37, 38, 39 are determined.

The operation of the above-described configuration will be described below in each state.

(A) Driving in the "Down" state

In this case, the contact 42a and the contact 42b of the switching switch 42 are set to "on". As a result, since the transistor 45 is turned "on", the discharge time constant of the memory capacitor 34 is set to a short value of Td, while VR is set to a high value of VR ₁ (see FIG. 4). do. In this state, the operation dial 20 of the timer 12 is set to the position A ₆ in the automatic setting area TA. The cam switches 14, 15, 16, 18, and 19 are then closed. As a result, the driving motor 22 and the heater 23 are energized to start the drying operation. At this time, the cam switch 18 is closed and the transistor 41 is forcibly " on " The upper contact 25 of "" is " on " to force the timer motor 13 to energize. Accordingly, the timer 12 continuously advances and stops to the position A ₄ at which the cam switch 18 opens regardless of the cam switches 16 and 17. On the other hand, after this, the clothing in the rotating drum is repeatedly contacted with the electrodes 26 and 27, and VS and VC change as shown in FIG. As shown in FIG. 4, in the initial stage of drying, such as the time zone t ₀ -t ₂ , the instantaneous values of VS appearing on the detection terminal 31 are all VR ₁ or more, but become VR ₁ or less as drying proceeds. The number of things is slowly increasing. However, the fourth is apparent VS is a predetermined time by the storage for capacitor 34 is that VR ₁ or more VS value of a charged immediately by, VS, even if being less than VR ₁ to VC as shown in (depending on the Td VC maintains VR ₁ or more for a certain time even if VS of VR ₁ or less occurs. This clearly means the first detection of low drying rate. By the way, if the state (VC> VR ₁ ) is formed even once even when the process proceeds to the drying intermediate time indicated by the time zone (t ₄ -t ₀ ), the comparator 36 outputs the high level voltage VD (the first time). 43, the timer 24 advances intermittently _{from the} stop position A _{4 to the} position A ₃ according to the timer motor 13 because the relay 24 is energized each time.

These positions A ₄ -A ₃ are set in a very short time, for example, 1 second. When the timer 12 reaches the position A ₃ , the cam switch 17 is closed, so the timer motor 13 is switched to continuous energization by the cam switches 16 and 17 and the timer 12 is continuous. Start the process. On the other hand, when the position A ₃ is reached, the heater 23 is disconnected by the cam switch (1 $) to perform cold wind operation, and the drive motor (22) by the cam switch (15) at the subsequent position A ₂ . Is cut off and the drying operation is stopped.

In other words, the instantaneous value resistance (VC) of the cloth at the lowest drying rate among the various parts of the cloth of various drying rates is stored and compared with the drying rate setting value (VR) to reach the set value. The set value arrival signal VD of the minimum drying rate obtained each time is integrated by the timer 1 @ as the time width and the number of occurrences (integration between positions A _{4 and} A ₃ ), and this is the set value of the set value (position A _3). Is reached, the drying operation is stopped.

According to this configuration, even if the contact frequency between the electrodes 26 and 27 and the clothes varies depending on the amount of cloth, the detection instantaneous value and the set acid value do not change. Becomes higher. This is also suitable for the so-called "taking out" because the drying rate of the garment which has not been dry and the garment which has not been coexisted is set at the set drying rate.

(B) Driving in "normally dry" condition

In this case, the contact 42a and the contact 42c of the switching switch 42 are set to "on". As a result, since the transistor 45 is turned "off" in contrast to the above, the discharge time constant of the storage capacitor 34 is set to a long value TC, while VR is VR ₂ as shown in FIG. It is set to a low value (high drying rate). This " normally dry " usually attempts to obtain approximately 100% of the drying rate with respect to the quality of the cloth as automatic control, and as described above, moves the operation dial 20 of the timer 12 to position A ₆ in the automatic setting area TA. By this setting, the timer 12 is forcibly advanced to the position A ₅ by the cam switch 19. During the period of increase in the drying rate, the "during out" time zone after t ₁₁ (enlarged in Fig. 5) corresponds to "normal drying" and most of the time after t ₁₁ , especially at the end of drying Even if the fabric part is above the set dry rate, only a fraction of the cuffs of the garment, etc., are below the set dry rate. Therefore, the period of (VC <VR ₂ ) becomes very long

In addition, in the timer 12, the set value relating to the drying rate is also "off" with the integration time cam switches 17 and 19 of the moon signal VD, so that the timer motor 13 contacts the upper contact 25. Since the time of intermittent energization by the bay is set long between positions (A ₅ -A ₃ ) (corresponding to a larger set acid value), even a part of the fabric which is difficult to dry can be completely dried.

(C) operation in the "drying of a thick cloth";

In this case, the contact 42a and the contact 42d of the switching switch 42 are set to "on". Then, the discharge time constant and VR of the memory capacitor 34 are set to Td and VR ₂ as in the case of " normal drying &quot;. Then, the timer 12 is set in position A _6, as before. As a result, the timer 1 @ remains stopped at the position A ₆ since the opening and closing of the cam switches 18 and 19 are invalidated. Therefore, the integration time of the set value arrival signal VD becomes longer between positions A ₆ -A ₃ . The reason why the set acid value is increased in this way is that in the case of thick fabrics, it takes a relatively long time for the internal moisture to seep out to the surface of the fabric, resulting in a delay in drying. According to the above, this drying delay time is compensated by increasing the set acid value, and the correspondence between the set drying rate and the actual drying rate is increased.

(D) "manual driving"

In this case, the operation dial 20 of the timer 1 @ is set to the blind position in the manual setting area TB to operate. In this state, since the cam switch 17 is closed for all the zones of the manual setting area TB, the drying time is only the set time of the timer 12.

The present invention is not limited to the above-described embodiments only, and a capacitor may be connected in parallel with the resistor 30 in order to prevent noise from a commercial power supply. In this case, it is of course necessary to set the value at which the instantaneous value detection action is not lost. For example, when the value of the resistor 30 is 2.2 M ?, the capacitor capacity is set to 0.1 µF. Of course, the instantaneous value memory element is not limited to the capacitor.

As described above, the present invention is not configured to average the resistance detected between the electrodes, but to store the instantaneous value resistance as a drying rate determination element, and to determine the drying rate by comparing the instantaneous value resistance with a set value. As a result, an accurate drying rate is obtained that does not depend on the amount of cloth or the coexistence state of the reasons of different drying speeds, so that the determination of “take out” is appropriate. Complete drying that is left over can also be provided with a dryer that can be expected.

Claims (1)

An instantaneous value detecting circuit 1 having electrodes 26 and 27 in contact with clothes in the rotating drum and detecting instantaneous value resistance between the electrodes 26 and 27, and an instant of detection output from the detecting circuit 1; A dryer provided with an instantaneous value memory circuit (2) for storing a value (VS), comprising: a comparison circuit (3) for comparing withdrawal from the memory circuit (2) and a drying rate set value (VR); In the control unit 4 and in the instantaneous value memory circuit 2, in which the set value arrival signal VD outputted from the comparison circuit 3 is integrated in time and stops the drying operation when it reaches the set value. And a state switching means for switching the storage time and the drying rate set value (VR) at the same time and for switching the set accumulation value.

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