KR200361091Y1 - Dryness measurement device for dryer - Google Patents

Abstract

The present invention relates to a dryness measuring apparatus of a dryer, and more particularly to a dryness measuring apparatus of a dryer for measuring the dryness of the laundry in the drying operation. The present invention uses an electrode sensor to detect the dryness of the laundry, it characterized in that the current dryness is measured as a change in the voltage charged to the capacitor by the resistance value change of the electrode sensor. In addition, the present invention minimizes external influence by discharging the charging voltage of the capacitor every predetermined period.

Description

Drying measurement device for dryer

The present invention relates to a dryness measuring apparatus of a dryer, and more particularly to a dryness measuring apparatus of a dryer for measuring the dryness of the laundry in the drying operation.

1 and 2 is a configuration diagram of a typical dryer. As shown, the outer case 53 forms the exterior of the dryer. And the front plate 41 is connected to the front end of the outer case 53 to form the front of the dryer. In the interior of the outer case 53, laundry is introduced into the drum 44, which is dried and rotatably installed. The drum 44 is rotated by a drum drive belt 54 surrounding its outer surface.

An exhaust port 43 is formed to correspond to an inner surface of the front plate 41 and to be opened toward the inside of the drum 44. The exhaust port 43 serves to exhaust the air in the drum 44 to the outside of the drum 44, and a lint filter 36 is installed at the inlet to remove foreign substances mixed in the air.

On one side of the exhaust port 43, an electrode sensor 38 for measuring the dryness of the laundry inside the drum 44 during the drying operation is mounted. When the laundry is touched, the electrode sensor 38 detects the degree of drying by the difference in voltage applied to both ends of the electrode. The detected signal is output as a voltage signal.

An exhaust passage 45 is formed inside the front plate 3 to be connected to the exhaust port 43. And blower assembly 30 is installed in communication with the exhaust passage (45). The exhaust passage 45 is equipped with a temperature sensor 2 (32) for sensing the temperature of the exhaust air.

The blower assembly 30 is connected to an exhaust duct 34 for discharging air from the exhaust passage 45 to the outside of the dryer. The blower assembly 30 is a blower for circulating and inhaling air in the drum 44 to introduce the heat of the heater 42, which will be described later, into the drum 44 and to discharge the moisture of the clothes to the exhaust port 43 ( 31) is included. The blower 31 uses a variable speed.

Meanwhile, a supply duct 46 for supplying air into the drum 44 is installed at a portion of the inside of the outer case 53 corresponding to the lower portion of the drum 44. The supply duct 46 supplies air to the inside of the drum 44 through the rear of the drum 44. The heater 42 is provided on one side of such a supply duct 46. One side of the supply duct 46 is provided with a temperature sensor 48 for sensing the temperature of the air sucked into the drum 44.

And a main board 52 for electrically controlling the operation of the dryer on one side of the outer case 53 of the dryer.

Next, a configuration for controlling the dryer included in the main board 52 will be described. 3 is a control block diagram of the dryer according to the above configuration.

As shown, the drying operation is performed under the control of the microcomputer 100. Therefore, the driving unit configured to receive electrical control inside the dryer and each sensor detecting the electrical signal output a signal to the microcomputer 100 or receive a signal from the microcomputer 100. .

First, a power input signal according to a user selection, a drying operation signal, a signal for inputting drying conditions, and the like are input, and a key input unit 103 for transmitting to the microcomputer 100 and a current degree of drying of the laundry are detected. The detection signal of the electrode sensor 38 is also transmitted to the microcomputer 100 through the electrode sensor signal conversion unit 106.

In addition, the detection signal of the temperature sensor 1 48 for detecting the temperature of the hot air supplied into the drum 44 is converted into a signal by the temperature sensor 1 signal conversion unit 109 and transmitted to the microcomputer 100. And the temperature of the hot air discharged from the drum is detected by the temperature sensor 2 (32), the signal is converted in the signal conversion unit 112 and transmitted to the microcomputer (100). In addition, the detection signal of the door detection unit 115 and the like for preventing the door opening during the drying operation is configured to be transmitted to the microcomputer.

And a drum motor driver 118 for driving the drum motor for generating a driving force for the rotation of the drum 44 and a blower motor driver 121 for driving a blower motor for generating a driving force for the rotation of the blower 31. ) Is operated and stopped under the control of the microcomputer 100 to control the rotation of the drum and the rotation of the blower 31. In addition, a heater driver 124 for driving a heater for supplying a heat source is driven under the control of the microcomputer 100.

The following describes the operation of the dryer according to the prior art having such a configuration.

First, laundry for drying is put into the drum 44. When the user closes the door and selects a drying operation signal from the key input unit 103, the signal is input to the microcomputer 100 in the main board 52. The microcomputer 100 outputs a drum drive signal to the drum motor driving unit 118, and then, the drum belt 54 is rotated while the drum motor is driven, and thus the drum 44 is rotated.

The microcomputer 100 outputs a driving signal to the blower driver 121. Therefore, when the blower assembly 30 is operated and the blower 31 is driven, air in the drum 44 is discharged to the exhaust duct 34 through the lint filter 36.

In addition, before and after the air in the drum 44 is discharged, the microcomputer 100 outputs a driving signal to the heater driver 124. In this operation, the heater 42 is driven to generate heat energy for supplying hot air.

Therefore, when the air in the drum 44 is discharged, the outside air is sucked into the drum 44 through the supply duct 46, the heater 42 at the inlet of the supply duct 46 The air is heated by the exothermic heat to reach a predetermined temperature and is supplied into the drum 44. In this case, the air sucked by the suction force driven by the blower 31 is heated by the heater 42 to be supplied into the drum 44.

In this way, the air supplied into the drum 44 absorbs the moisture in the laundry and flows to the exhaust passage 45 through the exhaust port 43 by driving the blower assembly 30. The exhaust passage 45 is discharged to the outside through the blower assembly 30 through the exhaust duct 34. At this time, the air is discharged from the drum 44 through the exhaust port 43 is made by the suction force of the blower (31).

At this time, the air passing through the exhaust port 43 is purified by the lint filter 36 so that foreign substances (for example, seams or lint of laundry) mixed in the air are not transmitted to the blower assembly 30. It plays a role.

On the other hand, the microcomputer 100 in the main board 52 presets the detection value of the electrode sensor 38 in accordance with the type of dry matter and the degree of drying. Therefore, when a drying operation is started, the detection value according to the kind of dry material is recognized based on the preset value. Then, the operation of the heater 42 is controlled to generate heat. After the heater 42 generates heat, external inflow air sucked into the drum 44 through the supply duct 46 is generated by the heat generated by the heater 42 at the inlet of the supply duct 46. Is heated to a predetermined temperature and is supplied into the drum 44.

In this operation, the electrode sensor 38 detects the degree of drying of the dry matter in the air circulating inside the drum 44, and transmits the detected signal to the microcomputer as a voltage signal. In this case, the electrode sensor 38 detects the degree of drying by using the difference in the voltage value applied to both ends of the electrode when the building is touched by the sensor. The sensed temperature is then output as a voltage signal.

The detected value of the electrode sensor 38 is continuously input to the microcomputer 100 through the signal converter 106, and the microcomputer is currently dried by the change of the voltage value detected by the electrode sensor 38. You will judge the degree.

In addition, the microcomputer 100 is a drum and the temperature of the hot air supplied into the drum 44 by the signal detected from the temperature sensor 1 signal converter 109 and the temperature sensor 2 signal converter 112. The temperature of the hot air discharged from the 44 is sensed, and the drying degree of the laundry is determined together with the dryness detected by the electrode sensor 38. When the determined value reaches a predetermined value, the driving of the heater is interrupted while the signals supplied to the heater driving units 124 and 127 are interrupted.

In cooperation with the operation, a signal applied from the microcomputer 100 to the blower motor driver 121 is blocked, and thus the blower motor 31 is also controlled to be in a stopped state.

In the conventional dryer operating as described above, the dryness measurement is based on the detection value of the electrode sensor 38 described above.

4 is a diagram illustrating a configuration of converting a detection value of a conventional electrode sensor 38 into an electrical signal and transmitting the same to the microcomputer 100.

That is, as shown, when the laundry circulating inside the drum 44 touches the electrode sensor 38, the resistance value of the electrode sensor 38 changes according to the degree of drying. As such, the resistance value of the electrode sensor 38 and the voltage distributed by the resistor R11 are applied to the microcomputer 100 according to the current drying degree, and the drying degree of the laundry inside the drum 44 is measured. .

However, in the conventional dryer, the dryness measurement had insufficient detection accuracy. Moreover, the structure for measuring the dryness of the prior art was inevitably affected by external influences. This is because the detection value input to the microcomputer 100 is not only a value detected at a specific time point for measuring dryness, but also a value detected continuously. In other words, the dryness measuring device composed of the electrode sensor 38 and the resistor R11 continuously outputs a detection value regardless of the dryness measurement time point, and the output value is input to the microcomputer 100. It is becoming. Accordingly, the microcomputer 100 has no choice but to determine the degree of drying at the present time while the signal is continuously input before and after the present time. That is, the dryness detection value of the present time point is inevitably affected before and after the detection time point.

In the conventional dryness measuring device, when the electrode sensor 38 has a resistance value that changes from external influence as a result, it has to be applied to the detection value as it is. Therefore, the conventional dryness measuring device is inevitably subjected to a lot of external influences, so that the detection accuracy was not accurate in determining the drying degree at the present time.

Therefore, an object of the present invention is to provide an apparatus for measuring the dryness of a dryer with reduced external influence.

1 is a side cross-sectional view of a common dryer,

2 is a plan view of a typical dryer,

3 is a control block diagram of a general dryer,

4 is a configuration diagram for measuring the dryness in a conventional dryer,

Figure 5 is a block diagram for measuring the dryness in the dryer according to the present invention.

Explanation of symbols on the main parts of the drawings

30 blower assembly 31 blower motor

32,48: Temperature sensor 34: Exhaust duct

36: lint filter 38: electrode sensor

42: heater 44: drum

46: supply duct 52: main board

54 belt 100 microcomputer

103: key input unit 106,109,112: signal conversion unit

115: door detection unit 118: drum motor driving unit

121: blower motor driving unit 124: heater driving unit

R1 ~ R11: Resistor C1: Capacitor

Q1: transistor

Drying measuring device of the dryer according to the present invention for achieving the above object is a dryer configured to heat the laundry by supplying the heated air into the rotary drum, and to discharge the air in the rotary drum to the outside, the rotary drum An electrode sensor installed to be able to contact laundry inside; A capacitor for charging a voltage according to a change in resistance generated when laundry is in contact with the electrode sensor; A discharge circuit for discharging the charging voltage of the capacitor; And controlling means for discharging the charging voltage of the capacitor by operating the discharge circuit at a predetermined period and measuring the current dryness by the change of the voltage charged in the capacitor.

The discharge circuit includes a resistor connected to a connection point between the electrode sensor and the capacitor, and a switching element connected in series between the resistor and the ground, wherein the switching element has a turn-on period under the control of the control means. It is characterized by being controlled.

The switching element is characterized by using a transistor.

The control means is characterized by using a microcomputer.

Hereinafter, a dryer according to the present invention will be described in detail with reference to the accompanying drawings.

5 is a block diagram of an apparatus for measuring dryness of a dryer according to the present invention. And the structure of the dryer required in description is demonstrated with reference to FIGS.

As shown, the dryness measurement value of the dryer according to the present invention, by connecting the electrode sensor 38 and the capacitor (C1) in series with the resistor (R1), according to the resistance value of the electrode sensor 38 changes The charging voltage of the capacitor C1 is configured to change differently.

A discharge circuit is formed at the connection point between the electrode sensor 38 and the capacitor C1. The discharge circuit includes a resistor R2 and a transistor Q1 which is a switching element, and is configured to discharge the voltage charged in the capacitor C1 when the transistor Q1 is turned on. The turn-on period of the transistor Q1 is configured to be controlled by a microcomputer.

The charging voltage of the capacitor C1 is configured to be supplied to the microcomputer through the resistor R3.

Drying degree measurement process of the dryer according to the present invention made in this configuration is made as follows.

The laundry for drying is put into the drum 44. When the user closes the door and selects a drying operation signal from the key input unit 103, the signal is input to the microcomputer 100 in the main board 52. The microcomputer 100 outputs a drum drive signal to the drum motor driving unit 118, and then, the drum belt 54 is rotated while the drum motor is driven, and thus the drum 44 is rotated.

The microcomputer 100 outputs a driving signal to the blower driver 121. Therefore, when the blower assembly 30 is operated and the blower 31 is driven, air in the drum 44 is discharged to the exhaust duct 34 through the lint filter 36.

In addition, before and after the air in the drum 44 is discharged, the microcomputer 100 outputs a driving signal to the heater driver 124. When the heater driving unit 124 operates normally in this way, the heater is driven to generate heat energy required for the drying operation.

Therefore, when the air in the drum 44 is discharged, the outside air is sucked into the drum 44 through the supply duct 46, the heater 42 at the inlet of the supply duct 46 The air is heated by the heat of heating to a predetermined temperature and is supplied into the drum 44. In this case, the air sucked by the suction force driven by the blower 31 is heated by the heater 42 to be supplied into the drum 44.

In this way, the air supplied into the drum 44 absorbs the moisture in the laundry and flows to the exhaust passage 45 through the exhaust port 43 by driving the blower assembly 30. The exhaust passage 45 is discharged to the outside through the blower assembly 30 through the exhaust duct 34. At this time, the air is discharged from the drum 44 through the exhaust port 43 is made by the suction force of the blower (31).

At this time, the air passing through the exhaust port 43 is purified by the lint filter 36, so that foreign matter (for example, seams or lint of laundry) mixed in the air is not transmitted to the blower assembly 30. It plays a role.

On the other hand, the microcomputer 100 in the main board 52 presets the detection value of the electrode sensor 38 in accordance with the type of dry matter and the degree of drying. Therefore, in the state in which air is circulated inside the drum 44, the electrode sensor 38 has a resistance value that is changed when the building is touched by the sensor, and outputs a detection value that is changed from the resistance value.

In this operation, the microcomputer 100 turns on the transistor Q1 in the discharge circuit shown in FIG. 5 before a predetermined time from the time point for measuring the dryness. At this time, the charging voltage of the capacitor C1 is discharged. When the discharge of the capacitor C1 is completed, the microcomputer 100 controls the transistor Q1 to be turned off again. That is, afterwards, the charging voltage of the capacitor C1 according to the dryness level for detecting is not to be discharged.

When the external influence for the current dryness measurement is minimized by this operation, the microcomputer divides the voltage from the changed resistance value of the electrode sensor 38 and charges the charge voltage charged in the capacitor C1 to the resistor R3. Through detection. The value thus detected is determined by the current dryness.

As described above, in order to measure the dryness, it is possible to measure the dryness in which the external influence is minimized by repeatedly discharging and charging the dryness measuring circuit at a predetermined cycle.

In this way, the detection value through the electrode sensor 38 is discharged and charged at a predetermined period into the microcomputer 100 through the signal converter 106, and the microcomputer is detected by the electrode sensor 38. The change in voltage value determines the current drying degree.

In addition, the microcomputer 100 is a drum and the temperature of the hot air supplied into the drum 44 by the signal detected from the temperature sensor 1 signal converter 109 and the temperature sensor 2 signal converter 112. By detecting the temperature of the hot air discharged from the 44, it is used as the basic information for determining the drying degree of the laundry with the value detected by the electrode sensor 38. When the determined value reaches a predetermined value, the driving of the heater 42 is interrupted while the signal supplied to the heater driver 124 is interrupted.

When the signal applied to the blower motor driver 121 is cut off from the microcomputer 100 in conjunction with the operation, the power supplied to the blower motor 31 is cut off, and thus the blower motor 31 is also controlled to be stopped. The drying operation is completed.

As described above, in the dryer of the present invention, the dryness is detected by detecting a change in the charging voltage of the capacitor by a change in resistance when the laundry touches the electrode sensor. In addition, the charging voltage of the capacitor is discharged every predetermined period to minimize external influence.

Therefore, the present invention uses an electrode sensor to detect the dryness of the laundry, it is a basic technical idea to measure the current dryness as a change in the voltage charged to the capacitor by the resistance value of the electrode sensor. And within the scope of the technical idea of the present invention, a variety of modifications will be possible to those skilled in the art.

As described above, the present invention improves the detection accuracy as the dryness measured during the automatic drying operation in the dryer is not affected by the external influence. Therefore, the dryer of the present invention can prevent the heating shortage or overheating by improving the detection accuracy, and can improve the dry state of the laundry as well as prevent damage to the laundry. In addition, the improvement of the drying yields an advantage of improving reliability and product power of the product.

Claims (4)

A dryer configured to supply heated air into a rotating drum to heat dry laundry and to discharge air in the rotating drum to the outside, An electrode sensor installed inside the rotating drum to be in contact with laundry; A capacitor for charging a voltage according to a change in resistance generated when laundry is in contact with the electrode sensor; A discharge circuit for discharging the charging voltage of the capacitor; And a control means for operating the discharge circuit at a predetermined cycle to discharge the charging voltage of the capacitor and measuring the current dryness by the change of the voltage charged in the capacitor. The method of claim 1, The discharge circuit includes a resistor connected to a connection point between the electrode sensor and the capacitor, and a switching element connected in series between the resistor and the ground, wherein the switching element has a turn-on period under the control of the control means. Drying degree measuring device of the dryer, characterized in that controlled. The method of claim 2, The switching element is a dryness measuring device of the dryer, characterized in that using a transistor. The method according to any one of claims 1 to 3, And said control means uses a microcomputer.