KR840001547Y1 - Dryer - Google Patents

Abstract

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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 tile chart of the timer.

4 and 5 are voltage waveform diagrams.

The present invention relates to a dryer of a method for detecting the drying rate by detecting the electrical resistance of the garment.

Conventionally, as a method of detecting the drying rate of clothes, there is a method in which the electrical resistance of the clothes itself is detected between the electrodes. In this way, the garment 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, it was conventionally integrated and averaged by a capacitor to be a detection input. On the other hand, since clothes and dried things coexist in the clothes, when the average value as described above is used as the detection input, it is easy to treat the clothes as dried until undried. In order to prevent this, conventionally, a voltage signal corresponding to a low drying rate among the voltage pulses generated between the electrodes is averaged by integrating by a capacitor, and it is determined how much time exceeds the set value among the average values. There is one way to do it (eg Bulletin 48-4666). However, this conventional method also has the following drawbacks.

(A) Integrating and averaging the voltages between the electrodes has a long integral time constant, which causes a large difference in the average value depending on the contact frequency between the electrode and the cloth, and the contact frequency is related to the amount of cloth. The amount of cloth becomes inaccurate.

(B) In the case where the clothes which have been dried and others do not coexist, if the integral time constant is reduced to obtain an average value, there will be a large variation in the average value. Tuning changes drastically.

(C) The state of use of the dryer is called taking out during the drying operation, which leaves undried clothing such as cotton and removes the dried quickly, such as cotton, or undried for ironing. In such a case, it is necessary to detect the drying rate also in determining the timing of taking out the process. However, the conventional one has a drawback that it is not suitable for the determination of the time of taking out delicately because there is a big difference between the drying rate detection result and the actual drying rate as described in (a).

(D) When attempting complete drying, all parts of clothing or fabric must be completely dry, but as the end of drying closes, the moistened fabric becomes narrow and the contact frequency of the wet part with the electrode Very small. Therefore, the detected average value becomes high and it is considered to be dry even though there is a wet part.

The present invention has been made to eliminate the drawbacks as described above, and its purpose is to obtain a proper drying rate which is not influenced by the amount of cloth, the drying speed is different depending on the coexistence state of other clothes, etc. Further, it is to provide a dryer that can be expected to dry completely with little wetted parts.

Next, the present invention will be described with reference to the accompanying drawings.

In Fig. 1, reference numeral 1 denotes a resistance detector of the fabric, 2 denotes an instantaneous value detection circuit, 3 denotes a comparison circuit, 4 denotes a control section, and 5 denotes a drying rate setting means. In these specific configurations, reference numeral 6 denotes an AC power supply, and reference numeral 7 denotes a transformer biased by the AC power supply 6, and the DC bus 10 passes through the full-wave rectifying circuit 8 and the smoothing circuit 9. DC power is applied between and (11). Denoted at 12 is a timer equipped with a timer motor 13 and a cam switch 14-19. The operating portion of this timer 12 is shown in FIG. 2, and the opening / closing timing of the cam switches 14-19 is indicated by oblique lines 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 which instructs the setting of the operation dial 20. AO, A, ... shown in FIG. And BO, B1... Is a code | symbol which shows the solid position of the cam which opens and closes the cam switch 14-19, The part was shown also in FIG. 2 for convenience. As shown in FIGS. 2 and 3, the timer 12 includes an automatic setting area TA having a timing area between the positions AO and BO and a manual setting area TB having a timing area between the switching position off and the position BO. Has By the way, (22) is a drive motor for driving the rotating drum and the fan, 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, 14). The aforementioned timer 12 is energized and controlled by the cam switches 16 and 17, and is energized and controlled by the normally open contact 25 of the relay 24 irrespective of this. In the resistance detection unit 1 of the above-mentioned cloth, (26) and (27) are a pair of electrodes, the one electrode 26 is connected to the DC bus line 10 via the resistor 28, and the other Electrode 27 is grounded via resistors 29 and 30. The detection terminal 31, which is the non-ground terminal of the resistor 30, is connected to the (−) input terminal of the operational amplifier 33 via the input resistor 32 in the instantaneous value detection circuit 2, and the operation thereof is performed. The output terminal of the amplifier 33 is grounded through the diode 35 and the capacitor 36 which are set to the polarity shown in the charging circuit 34, and the output terminal 37 which is the non-ground terminal of the capacitor 36 is compared with the comparison circuit ( 3) is connected to the (+) input terminal of the comparator 38, and the resistance (39) and (40) provided in series between the DC bus 10 and the ground point at the (-) input terminal. The terminal voltage VD of 40 is given as a predetermined reference value. On the other hand, the resistors 41 and 42 are interposed between the DC bus 10 and the ground point in series, and the operational amplifier 33 sets the voltage V _R of the terminal 43, which is a common connection point thereof, as the set level. To the (+) input terminal. Reference numeral 44 denotes a feedback resistance of the comparator 38. The detection terminal 31 of the instantaneous value detection circuit 2 described in the foregoing description has a voltage as shown in FIG. 4 inversely proportional to the instantaneous value resistance of the cloth between the electrodes 26 and 27, namely, Instantaneous value detection signal V _S appears, and when V _S > V _R , the output of the operational amplifier 33, that is, the drying rate signal, becomes low level and discharges the capacitor 36 through the diode 35 (reset). The charging path of the capacitor 36 includes a resistor 45 provided between the output terminal 37 and the DC bus 10, and a resistor 46 and a transistor connected in parallel thereto. And the discharge time constant of the capacitor 36 becomes T ₁ when the transistor 47 is off, and T ₂ (10 of T ₁ ) when the transistor 47 is on. It is possible to switch to be double. As a result, a series circuit composed of the resistor 48 and the transistor 49 is connected in parallel with the electric resistor 41, whereby the electric voltage V _R is turned off as high as V _R2 when the transistor 49 is on. Is configured to be switched to be low to V _R1 (V _R2 = 10 V _R1 ). On the other hand, the comparator 38 outputs a high level signal as the set value reaching signal V _E when the terminal voltage V _C of the capacitor 36 is set to V _C > V _D and passes the resistor 50 through the resistor 50. 51), so that the relay 24 is energized. In the drying rate setting means 5 described above, reference numeral 52 denotes a switching switch having contacts 52a-52d, and the diode 53 and the resistor 54 when operated on between the contacts 52a-52b. Transistor 56 is turned on by means of a network of 55, and both transistors 47 and 49 are turned on by applying a ground potential to their base via resistors 57 and 58, respectively. It is supposed to work. When the contact 52a-52b is turned ON and the contact 52a-52c is turned ON, the potential of the DC bus 10 is set in series with the diode 60 and the cam switch position 18. It is supplied to the conductive wire 59 via a circuit and only via the cam switch 19, respectively. Dividing resistances 61 and 62 are interposed in series in the conducting wire 59, and the transistor 51 is forcibly turned on when the potential of the DC bus 10 is given to the conducting wire 59.

Next, the operation of the above-described configuration will be described as follows.

(A) Operation in the ejected state in such a case, the switching switch 52 is set to on between the contacts 52a to 52b. As a result, since the transistor 56 is turned on, the other transistors 47 and 49 are turned on together, and the charging time constant of the capacitor 36 is set to a short value such as T ₁ while V _R is set to V _R2 . It is set to a high value (see Figure 4). In this state, the operation dial 20 of the timer 12 is set to the position A ₆ in the automatic setting area TA. Then, the cam switches 14, 15, 16, 18, and 19 become closed. As a result, the driving motor 22 and the heater 23 are energized to start the drying operation. At this time, since the cam switch 18 is closed and the transistor 51 is forcibly turned on, the relay 24 is normally turned on. The open contact 25 turns on and forcibly energizes the timer motor 13. Therefore, the timer 12 continuously advances to the position A ₄ at which the cam switch 18 is opened regardless of the cam switches 16 and 17, and stops here. On the other hand, after that time, the clothing in the rotating drum is repeatedly contacted with the electrodes 26 and 27, and V _S changes 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 sequence values of V _S appearing on the detection terminal 31 are all higher than V _R2 , but become lower than V _R as the drying proceeds. The number of things is gradually increased. In the meantime, the output of the operational amplifier 33 discharges the capacitor 36 at a low level when V _S > V _{R2, and} becomes a high level when V _S > V _R2 , thereby charging the capacitor 36. The terminal voltage of V _C changes as shown in FIG. In such a change in voltage V _C , as shown between the times t _4- t ₁₀ during the fourth period, the relationship of V _C > V _D becomes equal to the fourth in the comparator 38 whenever such a relationship is established. The set value reaching signal V _E as shown in the figure is outputted, and the transistor 51 is turned on with respect to the signal V _E to energize the relay 24, so that the timer 12 along the timer footer 13 is stopped. Interruption proceeds from ₄ to position A ₅ . These positions A ₄ -A ₃ are set for a very short time, for example 2 minutes. Since the cam switch 17 closes when the timer 12 reaches position A ₃ , the timer motor 13 is switched to continuous energization by the cam switches 16 and 17 and the timer 12 is continuous. Initiate an ongoing process. On the other hand, when the electric heater 23 is disconnected by the cam switch 14 at the time when the position A ₃ reached, the refrigeration operation is performed, and the driving motor 22 is operated by the cam switch 15 at the subsequent position A ₂ . ) Is cut off and the drying operation is stopped.

In other words, the so-called instantaneous value detection method of taking out the instantaneous value of drying as a signal by the comparison between V _S and V _R at a predetermined level or more, and the magnitude of the signal itself is defined by the electrodes 26, ( 27) is not related to the contact frequency of clothing, and even if the contact frequency varies depending on the amount of cloth, the error between the set drying rate and the actual drying rate is much smaller than the conventional one. Such high agreement between the set drying rate and the actual drying rate is suitable for the draw-out operation in which a small change in the drying rate is a problem, and it is possible to easily obtain a garment of moisture very close to the set value. . In particular, a, V _R, as described above for the "during ejection" As set to V _R2 can charging time constant of capacitor 36 cycles to monitor the coordinate signal is shortened, as T ₁ s as the comparator 38, that is This means shortening the sampling time. In this way, in the case of " during takeout ", despite the high frequency of contact with the wetted electrode 26 and 27, the time for V _{C to} become V _D or more is shortened, so that V _C becomes V _Since it takes a long time to become _D or more, it is possible to prevent the inconvenience that the drying becomes more than the set value in the meantime and becomes unsuitable for "take out". Moreover, even if the thing which progressed and the thing which did not coexist exists in the state which stops operation by the drying rate signal of the thing which advanced, since there is no excess drying, it is suitable for "take out".

(B) Operation in the "normally dry" state In this case, the switching switch 52 is set to ON between the contacts 52a to 52c. As a result, since the transistors 56, 47 and 49 are turned off in contrast to the above, the charging time constant of the capacitor 36 is set to a value as long as T ₂ , while V _R is also shown in FIG. Likewise, it is set to a low value (high drying rate), such as V _R. The "normal dry", is the closest to about 100% of the normal cheonjil Articles intended to obtain by automatically controlling the tuning, the automatic drying dial 20 of the timer 12, as electric setting area location of T _A A Set to ₆ . By this setting, the timer 12 is forcibly advanced to the position A ₅ by the cam switch 19. The time period t ₁₁ (shown enlarged in FIG. 5) beyond the "during" time zone during the increase of the drying rate corresponds to "normal drying", and most of the time after the time period t ₁₁ , in particular, at the end of drying Even if the fabric portion is above the set drying rate, only a fraction of the sleeves of the garment and the like fall below the set drying rate. Therefore, the period of V _S <V _R1 becomes very long. However, since the charging time constant of the capacitor 36 is set to T ₂ longer than T ₁ by the switching switch 52, the sampling time described above is long. The priority of detecting the drying rate of the cloth, which is difficult to dry, is increased. In addition, in the timer 12, the integration time of the set value reaching signal V _E related to the drying rate (the cam switches 17 and 19 are turned off together so that the timer mutter 13 is normally opened only at the contact point 25). Time of intermittent energization] is set long (approximately 10 minutes) between positions A ₅ and A ₃ (corresponding to a larger set-up value), so that even dry fabrics can be completely dried. have.

(C) Operation in the "drying of thick cloth" state In this case, set the switching switch 52 to on between the contacts 52a-52d. Then, the number of discharge time constant, and V _R of the capacitor 36, as in the case of "normal dry", is set to T ₂ and V _R1. And timer 12 is set in position A _6, as jeonbyeon. As a result, the timer 12 remains stopped at the position A ₆ since the opening and closing of the cam switches 18 and 19 is invalidated. Therefore, the integration time of the setpoint arrival signal V _E becomes longer between the positions A ₆ -A ₃ . The reason why the set integration value is increased in this case is that in the case of thick cloth, it takes a relatively long time for the inside portion to seep out to the surface of the cloth, resulting in a drying delay. According to the above, this drying delay time is compensated by increasing the set integration value, thereby increasing the correspondence between the set drying rate and the actual drying rate.

(D) Manual operation In this case, the operation dial 20 of the timer 12 is set to a desired position in the manual setting area T _B and operated. In this state, since the cam switch 17 is closed for all the zones of the manual setting area T _B , the drying time is only the setting time of the timer 12.

Incidentally, the present invention is not limited only to the above-described embodiment, 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 goes without saying that it is necessary to set the value at which the instantaneous value detecting action is not lost. For example, when the value of the resistor 30 is 2.2 kW, the capacitor capacity is preferably 0.1 kW.

As described above, an instantaneous value detection circuit having an electrode in contact with clothes in a rotating drum and outputting a drying rate signal by comparing the instantaneous resistance between the electrodes with respect to a set level, A charging circuit reset by the output, a comparison circuit for comparing the output of the charging circuit with a predetermined reference value, and outputting a set value reaching signal; A control unit for stopping the drying operation and a drying rate setting means for simultaneously switching the charging time constant and the setting level of the aforementioned charging circuit are provided so that the amount of cloth is somewhat influenced by the coexistence state of clothes having different drying speeds. Accurate drying rate is obtained, in particular, the determination of (taken out) is appropriate, and further, there is almost no wetted part. It is possible to provide a drier that can be expected to be completely dry.

Claims (1)

Rotation has an electrode (26, 27) in contact with the garments in the drum, by comparing against the instantaneous value detection signal (V _S) to a setting level (V _R) based on the instantaneous value resistance between the electrode gun outputs a tuning signal The instantaneous value detecting circuit 2 includes a charging circuit 34 that is reset in accordance with an output change of the instantaneous value detecting circuit, an output V _C of the charging circuit, and a predetermined reference value V _D. ) Is compared with the comparison circuit (3) for outputting the setpoint reaching signal (V _E ) and the control point (4) for stopping the drying operation by stopping the drying operation by reaching the setpoint reaching value. And a drying rate setting means (5) for simultaneously switching the charging time constant and the setting level of the charging circuit.