KR20010004429A - Washing and Dryer in one the Boiling Washing machine - Google Patents

Abstract

PURPOSE: Boiling washer is provided which applies electronic induction heating principle to wash and dry simultaneous so that it raises heating efficiency at a washing bath. CONSTITUTION: The boiling washer for washing and drying comprises the parts of: a washing bath(102) which is included in a tank(101) to wash and dry; an inverter tool which generates continuous resonance current in washing and drying; an induction heating tool which induces eddy current to the washing bath to be heated as resonance current of the inverter tool; and a temperature detector which detects air humidity and water temperature circulated by heat exchange with garments to determine whether drying and washing are finished or not.

Description

Washing and Dryer in one the Boiling Washing machine}

The present invention relates to a washing machine capable of washing and boiling laundry and drying, and more particularly, to washing, rinsing and dehydrating in the same operation as a general washing machine during a washing operation stroke, and using an electromagnetic induction heating principle during washing and drying. It relates to a laundry-drying integral boil- ing washing machine which allows boil- ing washing and drying to be done more quickly.

For example, a dry integral washing machine generally detects a quantity of clothes and the like put into a washing tank, and when the quantity is determined, sets the water flow, the detergent, and the total washing time according to the quantity.

Then, the washing operation is performed to separate the stained time of the garment by friction with the garment to be washed by vortexing water through the reverse rotation of the pulsator with the entire washing time.

After the washing administration is completed, the turbid water is discharged and the washing tank is supplied with fresh water to rinse for a predetermined number of times.

When the rinsing is completed, the washing operation is controlled by the process of dehydration which discharges the water in the washing tank and rotates the induction motor at a predetermined speed to remove the water of the clothes by centrifugal separation.

Then, after the washing stroke, the rinsing stroke, and the dehydration stroke, the drying stroke is performed by evaporating the moisture of the clothes with high temperature heat and drying.

In such a dry integrated washing machine, a hot air circulation drying method has been mainly used, in which external air is sucked in a drying stroke, heated by a heater, and the heated air is blown to clothes to dry.

1 and 2 show such a conventional dry integral washing machine for drying clothes using such a hot air circulation drying method.

As shown in FIGS. 1 and 2, the drying integrated washing machine includes a tank 51 installed in the case 50 with the upper portion opened and the bottom closed, and the tank 51 installed inside the tank 51. 51 and a tubular perforated laundry-and-dehydration tank (hereinafter referred to as a "washing tank") which are accommodated in a coaxial relationship to wash and dehydrate, and are provided at an outer upper portion of the tank 51 to form an external cold. A fan motor 52 that sucks air by heat exchange with clothes in the air and the washing tank 51a, a drying duct 54 for guiding cold air sucked by the fan motor to the washing tank 51a, and drying Humidity by heat exchange with the heater 53 installed in the duct 54 and heating the cold air sucked by the fan motor 52 and blowing to the washing tank 51a with high temperature dry air, and clothes in the washing tank 51a. Condensation of one air and the water droplets from the condensation through the condensate drain hose (57) Condensation duct 56 for circulating air and circulating air toward the fan motor 52, a condensate valve 55 installed at an upper portion of the tank 51, and supplying condensed water to the condensation duct 56, and the tank 51. Water supply pipe 61 for supplying water to the washing tank (51a) interposed in the water supply line installed at the top of the) and installed on the bottom of the tank 51, the turbid water in the washing tank (51a) through the drain hose (59) It is composed of a drain pump (58) for discharging to the outside of the dry integral washing machine, and a detergent container (60) installed at the upper portion of the tank (51) to supply detergent to the washing tank (51a) during the washing stroke.

Dry integrated washing machine according to the prior art configured as described above will be further embodied through the following.

In addition, since the washing stroke, the rinsing stroke and the dehydrating stroke are the same as the general operating principle of the washing machine, the description thereof will be simplified, and the operation of the drying stroke will be described in detail with reference to FIGS. 1 and 2.

First, when the washing stroke, the rinsing stroke, and the dehydration stroke are set through an operation panel not shown in the drawing, the washing machine control unit of the normal washing machine controls the water supply valve and together with the detergent of the detergent container 61 in the washing tank 51a through the water supply pipe 61. After the water is properly supplied, the washing motor is rotated reversely (when washing and rinsing) or at high speed (when dewatering), and the turbid water in the washing tank 51a is drained through the drain hose 59 through the drain pump 58. The process of discharging is controlled in a predetermined sequence to perform the washing operation of the washing administration, the rinsing administration and the dehydration administration.

In this way, when washing, rinsing, and dehydration are all completed in the washing operation stroke, and the user performs a drying operation by operating the drying key of the operation panel to dry the clothes washed in the washing tank 51a, the fan motor is initially performed. As the 52 is rotated, the external cold air is sucked and blown to the washing tank 51a.

At this time, in order to heat the air blown into the washing tank 51a, power is applied to the heater 53 installed in the drying duct 54 to generate heat. As a result, the external cold air is heated by the hot dry air while passing through the heater 53, and the heated hot dry air is guided through the drying duct 54, thereby providing moisture by heat exchange with the clothes in the washing tank 51a. Evaporates to remove moisture from the garment.

The humid air generated by the heat exchange with the clothes is again condensed in the condensation duct 56 by the fan motor 52, reheated by the heater 53, and circulated to the washing tank 51a in a hot and dry state. The process is repeated to dry the clothes.

At this time, the process of removing the moisture in the circulation of the air is when the humid air including the moisture generated by the heat exchange with the clothing passes through the condensation duct 56, water vapor enters through the condensate valve 55 The water is changed by the condensate into water droplets and is discharged out of the case 50 of the dry integrated washing machine through the condensate drain hose 57 together with the condensate to remove moisture. The air from which the moisture is removed is dried again, reheated by the heater 53, and circulated through the drying duct 54 to the washing tank 51a in the tank 51 to dry the clothes. This process is repeated to complete the drying administration of the clothing when all the moisture evaporates.

In the drying integrated washing machine described above, it can be seen that the drying motor repeats the process of circulating cold air into the washing tank through the circulation path and repeatedly heats the circulated cold air in the heater to dry the clothes of the washing tank. have.

However, the conventional dry integral washing machine using such a hot air circulation drying method heats cold air while circulating through the circulation path, so that the heat exchange efficiency in each circulation path is very low, resulting in a large amount of heat loss. As well as delay, power consumption is increased, and there is a problem in safety due to the use of a heater.

In addition, since it does not have a separate washing function compared to the power consumption, there is a problem that the use of the dry integral washing machine is impossible when the washing is required other than normal washing and drying.

In addition, it is also conceivable to give a washing function by heating the water in the washing tank, but it requires the difficulty of installation, difficulty in manufacturing, and greater power consumption, which require the installation of a heater for separate water heating. .

Accordingly, it is desirable to provide a laundry / drying integrally boiled washing machine having a lower power consumption and various functions in terms of power consumption and function, and a more efficient and stable laundry / drying integral boiled washing machine in terms of reliability. desirable.

Accordingly, it is an object of the present invention to provide a laundry drying integral boil- ing washing machine which performs clothes drying and boil- ing laundry through the same heating structure, and this washing machine is provided in a washing tank to be heated when performing drying and boil- ing laundry without using a heater. Induced by the eddy current through the heating structure is characterized in that for heating to a desired heating temperature.

Another object of the present invention is to provide a laundry-drying integral boil- ing washing machine that allows washing and drying to be boiled quickly and safely by using an electromagnetic induction effect, and the washing machine has a temperature response of a heating structure during drying of clothes and washing of boiled laundry. Characterized by differently controlled, characterized in that the washing and drying to safely boil without damaging the clothing.

1 and 2 is a configuration diagram provided in the description of a dry washing machine according to the prior art,

1 is a perspective view of the dry integrated washing machine,

Figure 2 is a block diagram for explaining the hot air drying operation of the dry integral washing machine,

3 to 5 is a block diagram showing an embodiment provided for the description of the laundry drying integral boil-type washing machine according to the present invention,

Figure 3 is an internal view of the laundry drying integral washing machine viewed from the side,

Figure 4 is a cross-sectional view showing in more detail the induction heating unit of Figure 3,

5 is a view showing an inverter circuit for heating the washing tank through the induction heating unit of FIG.

<Description of the code | symbol about the principal part of drawing>

100: case 101: tank

102: washing tank 103: walking coil

104: fan motor 105: condensate valve

106: condensation duct 107: washing motor

108: drying duct 109: drain valve

110: water supply valve 111: converter unit

112: smoothing portion 113: inverter portion

In the laundry drying integrated washing machine according to an aspect of the present invention for achieving the above object, in the washing machine for drying the clothes in the washing tank by circulating and heating the dry air through a circulation path:

(1) a washing tank made of a magnetic metal material accommodated in a coaxial relationship with the tank to wash and dehydrate;

(2) inverter means for generating a large continuous resonant current with an input direct voltage during the washing of laundry and drying clothes;

(3) induction heating means installed at a lower portion of the tank to induce an eddy current in the washing tank to be heated according to a resonance current of the inverter means for heating; And

(4) temperature detecting means for detecting the temperature of the air and the temperature of the water in the washing tank by heat exchange with the clothes.

Preferably, the inverter means is characterized in that it comprises a resonant capacitor, a damping diode, a switching element and a switching control means for controlling the switching element forming a series of resonant circuits with the induction heating means.

Optionally, the induction heating means is characterized by consisting of a working coil for generating a magnetic field by the resonant current obtained from the inverter means and by inducing vortex in the washing tank and heating by the electromagnetic induction effect caused by the magnetic field.

Preferably, the inverter means is characterized in that the control by sharing the washing motor with the induction heating means.

In this way, it can be seen that, during the washing operation control, in particular, during the washing operation and the drying stroke, the washing tank can be heated and heated by heating the washing tank by the electromagnetic induction heating principle without a separate heater.

As a result, the heating efficiency of the washing tank is very high, and there is no time delay when washing the laundry and drying the clothes, and it is possible to control the temperature of the washing tank according to the response characteristics of the temperature, thereby drying the washing and clothes boiled safely and quickly. There is an advantage to that.

And, there may be a plurality of embodiments of the present invention, the following will be described in detail for the most preferred embodiment.

Through this preferred embodiment, the objects, other objects, features and advantages of the present invention will become more apparent from the following description with an embodiment according to the present invention in connection with the accompanying drawings shown for illustrative purposes.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the laundry drying integrated boil-type washing machine according to the present invention.

In addition, in each figure used for description, the same component may be attached | subjected, and may show the same number, and the overlapping description may be abbreviate | omitted.

Figure 3 is an internal configuration of the laundry drying integral washing machine of the present invention viewed from the side, Figure 4 is a cross-sectional view showing the induction heating unit of Figure 3 in more detail, Figure 5 is to heat the washing tank through the induction heating unit of Figure 3 Is a diagram showing an inverter circuit.

The laundry-drying integral washing machine according to the present embodiment includes a tank 101 installed in the case 100 with an upper portion opened and a bottom closed, and installed inside the tank 101 and the tank 101. Washing tub 102 formed of a magnetic metal material accommodated in a coaxial relationship to wash, dehydrate, and dry clothes, a washing motor 107 installed in the outer lower portion of the tank 101 and alternately reversely rotated, and a washing tank Water supply for supplying water to the washing tank 102 is rotatably installed on the inner bottom of the 102 is interposed in the pulsator (107a) for vortexing the water in the washing tank 102 and the water supply line provided in the upper portion of the tank 101 A fan motor 104 installed on the valve 110 and the outer upper portion of the tank 101 to suck and circulate the outside cold air and the heat-exchanged air from the washing tub 102 to the clothes, and sucked by the fan motor Guided cold air to the upper side of the washing tub (102) It is provided on the side wall of the case 100 and the condensation duct 106 for condensing and circulating the humid air by heat exchange between the drying duct 108 and the clothes in the washing tank 102 to the fan motor 104. A condensate valve 105 for supplying condensate to the condensation duct 106, and a drainage water installed at the bottom of the tank 101 to discharge turbid water of the washing tub 102 and water droplets due to condensation through the discharge duct 109a. It is installed on the valve 109, the operation panel 119 for inputting washing, rinsing, dehydration, drying functions, etc., attached to the upper part of the case 100, and the inner wall of the condensation duct 106 and the tank 101. The fan driving unit 114 according to the first and second sensors 117 and 117a which measure the temperature during the drying stroke and the washing stroke, and the key measured by the sensor and the key operated by the operation panel 119. ), The fan motor 104 and the washing motor 107 are controlled through the motor driver 115, and the condensate valve 105 is controlled through the valve driver 116. , A microprocessor 118 for controlling the entire operation of a series of washing-drying integrated washing machines, such as controlling the drain valve 109 and the water supply valve 110, and a converter for rectifying commercial AC power to a pulsating DC voltage. Electromagnetic induction effect due to the magnetic field generated by the resonant voltage is installed in the lower portion of the tank 111, the smoothing unit 112 for smoothing the rectified pulsating DC voltage to a constant level The working coil 103 which induces vortex in the metal washing tank 102 to be heated by heating to heat the laundry in the washing tank 102, and a pulse inputted from the microprocessor 118 by forming a series of resonant circuits with the working coil. A resonant capacitor C1, a damping diode D1, a switching element Q1, and a switching control unit which resonate the DC voltage input from the smoothing unit 112 according to the width modulation signal to provide a large resonance voltage to the working coil 103. To (113a) Luer binary and an inverter 113, adding the inverter can also be controlled by sharing the working coil 103 and the washing motor 107.

In the laundry drying integrated washing machine according to an embodiment of the present invention made as described above, the washing and drying of the washing and drying by heating by one working coil is not performed during the washing operation control, in particular, during the washing operation and the drying operation. Perform.

When the user sets the washing stroke to operate by operating the operation panel 119 and starts operation, as shown in FIG. 5, the commercial AC power source AC is converted into a pulsating DC voltage in the converter unit 111 and the pulsating DC The voltage is again smoothed to a constant level through the smoothing unit 112 and supplied to the working coil 103 and the inverter unit 113 to be described later.

In such a state, the microprocessor 118 first opens the water supply valve 110 through the valve driving unit 116 to perform the boiled washing until the proper level is reached in the washing tub 102 formed of the magnetic metal material. Perform watering.

When a certain amount of water is filled in the washing tub 102, the pulse width modulation signal is provided to the switching control unit 113a of the inverter unit 113 to heat the washing tub 102 by an induction heating means such as the working coil 103.

The switching control unit 113a drives the switching element Q1 of the inverter unit 113 in response to the pulse width modulated signal input from the microprocessor 118, so that the working coil 103, the resonant capacitor C1, and the damping diode D1 is brought into a continuous resonance state by the pulsating DC voltage input from the smoothing unit 112.

Accordingly, a large resonance current flows through the working coil 103, and as a result, vortices are induced in the washing tub 102 formed of the magnetic metal material to be heated due to the electromagnetic induction effect due to the magnetic field generated from the working coil 103. The washing tub 102 is heated rapidly.

That is, when the cone resonant current flows through the working coil 103 of the induction heating means, a varying magnetic field is formed around the working coil 103 due to the resonance current. This changing magnetic field passes through the inside of the washing tank 102, thereby eddy current is induced inside the washing tank 102. At this time, eddy currents (Eddy Current) a I, leaving the equivalent resistance of the washing tub 102 to the R _L washing tub 102 line effects (Joule Effect) corresponding to I ² R _L, i.e., is the occurrence of heat loss, the heat The loss causes the washing tub 102 to be directly heated, which has a high thermal efficiency of approximately 85% or more.

Subsequently, and the rapidly heated washing tub 102 is heated by heat transfer to the water therein, wherein the microprocessor 118 is the temperature of the water from the second sensor 117a provided on the side wall of the tank 101. Continue to measure and maintain the desired heating temperature.

As such, in the state where the temperature of the water in the washing tank 10 is sufficiently heated, the microprocessor 118 alternately energizes the washing motor 107 through the motor driving unit 115 to alternately adjust the pulsator 107a. Rotate in reverse.

The alternating forward and reverse rotations of the pulsator 107a cause the heated water in the washing tub 102 to vortex, and with this, a washing stroke which causes friction with the clothes and is boiled is performed.

Subsequently, when the boiled laundry administration is completed, the drain valve 109 is opened through the valve driving unit 116 to discharge turbid water in the washing tank 102 through the discharge duct 109a.

When the boiled laundry administration is completed, the washing tank 102 is rinsed and finished by supplying and draining water to the washing tank 102 in the same manner as described above.

After performing the washing and rinsing of the boil, the microprocessor 118 rotates the washing motor 107 at a predetermined speed for the dehydrating stroke and completes the dehydrating stroke.

On the other hand, if the user starts the operation after setting the drying stroke by operating the operation panel 119 to dry the laundry is completed, the large resonant current is applied to the induction heating means such as the walking coil 103 in the same manner as the washing stroke boiled It is applied to heat the clothes in the washing tank 102 to a constant temperature, and also blows the air into the washing tank 102 by driving the man motor 104 through the fan drive 114. As a result, heat is exchanged with the clothes in the washing tub 102, and the water is evaporated from the clothes, and the evaporated moisture is transferred back into the washing tub 102 through the condensation duct 106 by the fan motor 104. The humid air generated by heat exchange with the clothes is condensed into water droplets by the cold water supplied from the condensate valve 105 in the condensation duct 106 and discharged through the drain valve 109 and the discharge duct 109a. .

And, the cold air condensed in the condensation duct 106 is repeated by the fan motor 104 through the drying duct 108 to the washing tank 102 to dry the clothes.

On the other hand, the first sensor 117 provided in the condensation duct 106 detects the moisture of the air circulated to the condensation duct 106 and provides it to the microprocessor 118.

The microprocessor 118 determines the degree of drying progress with the signal input from the first sensor 117, and stops driving the inverter unit 113 and the fan motor 104 when moisture is no longer generated. Will complete.

On the other hand, as a comparative example, unlike the prior art, that is, to dry clothes in the hot air circulation method using a heater and a fan motor during the drying operation, the present invention is the clothes using the electromagnetic induction heating principle without a separate heater Drying as well as boiled laundry can be seen that.

In this result, it is found that according to the present invention, the heating efficiency of the washing tank is very high, so that no time delay and danger occur when washing the laundry and drying the clothes, and that a separate heater and the mechanical and electrical elements for the washing wash are excluded. have.

As described above, in the present embodiment, by performing both the washing and drying boiled by the electromagnetic induction effect through a single heating structure, the drying delay according to the conventional hot air circulation method, and also for washing the boiled laundry other than the drying function Structural difficulties to install a heater and thereby does not cause an increase in energy.

According to this application example, a separate heater is not required in the washing operation of the washing machine, and the washing and drying time of the washing machine is significantly reduced, thereby minimizing power consumption and product stability.

In addition, although specific embodiments of the present invention have been described and illustrated above, it is obvious that the present invention may be variously modified and implemented by those skilled in the art.

Such modified embodiments should not be individually understood from the technical spirit or the prospect of the present invention, and such modified embodiments should fall within the appended claims of the present invention.

It is clear from the above description that the washing and drying integrated washing machine according to the present invention uses the electromagnetic induction heating principle rather than the hot air circulation method, so that the heating efficiency of the washing tank is very high and the temperature of the washing tank according to the temperature response characteristics is increased. Precise control is available for safe, fast-life washing and drying.

In addition, the power consumption is minimized by performing both the washing and drying functions boiled in the same heating structure without the addition of a separate heater, and the inverter circuit can also be shared with the inverter circuit driving the washing motor.

Claims (5)

In a washing machine for drying clothes in a washing tank by circulating and heating dry air through a fan motor and a condensation duct: (1) a washing tank accommodated in a coaxial relationship with the tank to wash and dehydrate; (2) inverter means for generating a continuous resonant current when boiling laundry and drying clothes; (3) induction heating means installed in place of the tank to induce an eddy current in the washing tank to be heated according to the resonance current of the inverter means for heating; And (4) a washing machine integrated washing machine comprising temperature detecting means for detecting the humidity of the air purified by heat exchange with the clothes and the temperature of water in the washing tank to determine whether to finish drying and boiling. The method of claim 1, And said inverter means comprises a resonant capacitor, a damping diode, a switching element forming a series of resonant circuits with said induction heating means, and a switching control means for controlling said switching element. The method of claim 2, The induction heating means generates a magnetic field by the resonant current obtained from the inverter means, and the washing and drying integrally boiled washing machine comprising a working coil for heating the washing tank by inducing vortex in the washing tank by the electromagnetic induction effect caused by the magnetic field. . The method according to claim 1 or 3, The washing dryer is a laundry drying integral boil washing machine, characterized in that made of a magnetic metal material. The method of claim 1, The temperature detecting means includes a first sensor detecting a humidity of the circulated air and a second sensor detecting a temperature of water in the washing tank; And said first sensor is attached to said condensation duct and said second sensor is attached to a wall of said tank.