KR20080094564A - Washing and drying machine - Google Patents

Abstract

A washing/drying machine is provided to reduce a manufacturing cost and prevent a fan motor from being affected by regenerative voltage of a washing machine motor by sharing a second DC circuit as a common DC circuit for a compressor motor drive circuit and a fan motor drive circuit. A washing/drying machine comprises a washing machine motor(14), a compressor motor(35), a fan motor(29), first and second DC circuits(50,57), a washing machine motor drive circuit(44), a compressor motor drive circuit(46), a fan motor drive circuit(45), and control units(68,69). The first and second DC circuits convert AC power into DC power by using a rectifying circuit and a smoothing capacitor. The washing machine motor drive circuit drives the washing machine motor by using DC power applied from the first DC circuit. The compressor motor and the fan motor drive circuits drive the compressor motor and the fan motor respectively by using DC power of the second DC circuit as the common DC circuit.

Description

Laundry dryer {WASHING AND DRYING MACHINE}

The present invention relates to a laundry dryer in which a condenser of a heat pump is used as a heat source for carrying out drying.

As a drum type laundry drying machine which is a laundry dryer, a horizontal rotating drum (drum) is provided in a water tank, and the rotating tank is driven to rotate by a washing machine motor for washing and drying operations such as washing and drying, and the refrigerant is compressed by a compressor. And a heat pump which circulates to condense in the condenser and evaporate in the evaporator, and transfers the heat of the condenser to the rotary tank by a fan to perform drying.

In this case, from the ease of control, it is conceivable to use an inverter as a drive circuit for driving a washing machine motor, a compressor motor for driving a compressor, and a fan motor for driving a fan, respectively. However, when the inverter is used as a driving circuit, the power supply of the inverter is a DC power supply. Therefore, for each driving circuit, a DC power supply circuit for rectifying the AC power from the AC power supply through the rectifying circuit and the smoothing capacitor to obtain smooth and direct current power is required. There is a problem that the cost rises.

For this reason, conventionally, it is proposed to make common use (shared) of the direct current power supply circuit of the drive circuit for washing machine motors, and the drive circuit for fan motors. For example, Japanese Laid-Open Patent Publication No. 2006-187394.

In the conventional configuration, since the washing machine motor is often regeneratively braked during washing and drying operation, the voltage of the smoothing capacitor of the DC power supply circuit is greatly changed by the regenerative voltage, and the fan motor receiving the DC power as a vibration power (bit note) There is a problem that occurs.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object thereof is to provide a laundry dryer capable of preventing the occurrence of vibration noise of a fan motor while reducing the cost even if the condenser of a heat pump is used as a heat source for drying. have.

The laundry dryer of the present invention includes a washing machine motor for performing laundry drying operations such as washing and drying, and a compressor motor for driving the compressor in a heat pump that circulates the refrigerant to be compressed into a compressor, condensed in the condenser, and evaporated in the evaporator. And a fan motor for driving the fan for generating the above-mentioned drying warm air by using the heat of the condenser in the aforementioned heat pump, and for exchanging AC power from an AC power source with DC power through a rectifying circuit and a smoothing capacitor. DC power supply circuit common with the 1st and 2nd DC power supply circuit, the drive circuit for washing machine motors which drive the above-mentioned washing machine motor based on the DC power from the above-mentioned 1st DC power supply circuit, and the 2nd DC power supply circuit mentioned above. A compressor circuit for driving the compressor motor and the fan motor described above on the basis of the DC power; And a control means for controlling the driving circuit for the motor, the driving circuit for the washing machine motor, the driving circuit for the compressor motor, and the driving circuit for the fan motor to execute the above-described washing and drying operations such as washing and drying. .

According to such a structure, since a 2nd DC power supply circuit is common to the drive circuit for compressor motors, and the drive circuit for fan motors, when a dedicated DC power supply circuit is provided in the drive circuit for compressor motors and the drive circuit for fan motors, respectively, In comparison, the cost can be reduced. And since the DC power supply circuit of a compressor motor drive circuit and a fan motor drive circuit is shared, it can prevent a fan motor from generating the vibration sound, without being influenced by the regenerative voltage of a washing machine motor.

Even if the laundry dryer of the present invention is configured to use a condenser of a heat pump as a heat source for drying, by using a DC power supply circuit of a compressor motor drive circuit and a fan motor drive circuit in common, it is possible to reduce costs and to reduce vibration noise of the fan motor. It has an excellent effect of preventing the occurrence.

Hereinafter, with reference to FIG. 1 thru | or 3 based on the 1st Example of this invention.

FIG. 2 shows the overall configuration of the laundry dryer, and in particular, the drum-type (horizontal) laundry dryer, wherein a water tank 2 is installed inside the outer box 1 and a rotating tank (drum) inside the water tank 2. (3) is installed.

Both the water tank 2 and the rotating tank 3 have a cylindrical shape, and each has openings 4 and 5 at the cross section of the front side (left side in the drawing). Among these, the opening part 5 of the rotating tank 3 is for laundry (clothing) entrance and exit, and this is surrounded by the opening part 4 of the water tank 2. In addition, the opening 4 of the water tank 2 is connected to the laundry opening opening 6 formed in the front portion of the outer box 1 by a bellows 7, and the opening 6 of the outer box 1 is connected to the opening 6 of the outer box 1. The door 8 is provided so that opening and closing is possible.

In the water tank 2, the hot air outlet 9 is formed in the upper part (part above the opening part 4 mentioned above) of the front side cross section, and the warm air inlet 10 is formed in the upper part of the cross section of the rear side. . A drain port 11 is formed at the rearmost part of the bottom of the water tank 2, and a drain valve 12 is connected to the drain port 11 outside the water tank 2, and a drain hose ( 13 is connected so that the water in the water tank 2 is discharged out of the washing machine.

The washing machine motor 14 is attached to the back part of the water tank 2, The said washing machine motor 14 is comprised by the three-phase brushless motor of the outer motor type. The rotating tub 15 of the washing machine motor 14 protrudes in the water tank 2, and its front end is attached to the center part of the rear end surface part of the rotating tank 3 mentioned above, and the rotating tank 3 is a water tank ( 2) is rotatably supported coaxially. Moreover, the water tank 2 is elastically supported by the outer box 1 mentioned above by the some suspension 16, The support form is the horizontal axis shape in which the axial direction of the water tank 2 becomes front and back, and is forward. The rotating tank 3 inclined so that it may go up and thus supported by the said water tank 2 is also the same form.

The base plate 17 is arrange | positioned under the water tank 2 (on the bottom face of the outer box 1), and the ventilation duct 18 is arrange | positioned on this base plate 17. As shown in FIG. The ventilation duct 18 is provided with an air intake 19 at the upper end of the front end portion, the hot air outlet 9 of the water tank 2 described above in the air intake 19 is a ventilation duct 20 and the connection hose ( 21). In addition, the ventilation duct 20 is piped so that the left side of the opening part 4 of the water tank 2 mentioned above may be bypassed.

On the other hand, the casing 23 of the fan 22 is extended to the rear end of the ventilation duct 18, and the outlet part 24 of the casing 23 is connected through the connection hose 25 and the air blowing duct 26. It is connected to the warm air inlet 10 of the water tank 2 mentioned above. In addition, the blowing air duct 26 is piped so that the left side of the washing machine motor 14 mentioned above may be bypassed. And the above-mentioned hot air outlet 9 of the water tank 2 is made by the above ventilation duct 20, the connection hose 21, the ventilation duct 18, the casing 23, the connection hose 25, and the air blowing duct 26. ) And a ventilation path 27 connecting the warm air inlet 10.

In addition, the fan 22 mentioned above is a centrifugal fan in this case, and is provided with the centrifugal vane wheel 28 inside the casing 23, The fan motor 29 which rotates the centrifugal vane wheel 28 is a casing. It is attached to the outer wall of (23). In addition, the fan motor 29 is constituted by an inner rotor type three-phase brushless motor.

However, the evaporator 30 is arrange | positioned at the front part inside the ventilation duct 18, and the condenser 31 is arrange | positioned at the rear part. Although these evaporator 30 and the condenser 31 are not shown in detail at all, it is a tube type with a fin installed in many pitches in the heat exchange fin in a refrigerant | coolant distribution pipe, and it is excellent in heat exchangeability, and between each of these heat transfer fins is excellent. The air flows through the above-described ventilation duct 18 as described below. The evaporator 30 and the condenser 31 constitute a heat pump 33 together with a compressor 32 installed on the bottom of the outer box 1, in which the heat pump 33 is connected by a connecting pipe 34. The compressor 32, the condenser 31, and the evaporator 30 are cycle-connected in this order (freezing cycle), and the compressor 32 is driven by the compressor motor 35 (see FIG. 1) to circulate the refrigerant. It is made to let. In addition, the compressor motor 35 is comprised with the inner rotor type three-phase brushless motor.

Moreover, the warm air inlet 36 is formed in the end surface part 3a of the rear side of the rotating tank 3 mentioned above, and the said warm air inlet 36 is the center of the cross section of the rear side of the rotating tank 3. There exists a plurality in concentric annular arrangement, and each one is made to face the hot air inlet 10 of the above-mentioned water tank 2 by rotation of the rotating tank 3.

Further, on the inner circumferential surface of the body portion 3b of the rotating tub 3, a plurality of laundry baffles 37 are provided at substantially equal intervals (for example, about three) and the front of the rotating tub 3 is provided. The rotary balancer 38 is provided in the inner periphery of the end surface part 3c of the side (peripheral part of the opening part 5 mentioned above). In this case, the rotary balancer 38 is a liquid encapsulation type, and the interior of the rotary balancer 38 is partitioned into a plurality of liquid receiving compartments. And the body part 3b of the said rotating tank 3 is provided with the hole 39 for dehydration and ventilation.

In addition, a water supply valve 41 is installed in the upper portion of the outer box 1 on the wiring board 40 on which the electric and electronic components (various circuits) necessary for the control of the laundry dryer are mounted, and the water is supplied to the water tank 2. ), A water supply case 42 and a water supply hose 43 are provided.

Next, the electrical configuration of this embodiment will be described with reference to FIG.

The washing machine motor 14, the fan motor 29, and the compressor motor 35, each consisting of a three-phase brushless motor, respectively include a driving circuit 44 for a washing machine motor, a driving circuit 45 for a fan motor, and a driving circuit for a compressor motor ( 46). Although the driving circuit 44 for the washing machine motor, the driving circuit 45 for the fan motor, and the driving circuit 46 for the compressor motor are not shown, each of six switching elements, for example, an Insulated Gate Bipolar Transistor (IGBT), is a three-phase bridge. The three-phase alternating current output terminal is connected to each input terminal of the washing machine motor 14, the fan motor 29, and the compressor motor 35, respectively.

In the noise filter 47, its input terminal is connected to a 100 V single-phase AC power supply (commercial power supply) 48, and its output terminal is connected to the power supply lines 49a and 49b. The first DC power supply circuit 50 includes a full-wave rectifier circuit 51 and two smoothing capacitors 52 and 53 formed by connecting four diodes (not shown) by single-phase bridge connection. The AC input terminal of the full wave rectifier circuit 51 is connected to the power supply lines 49a and 49b, and the series circuit of the smoothing capacitors 52 and 53 is connected between the direct current output terminals of the full wave rectifier circuit 51, The common connection point of the capacitors 52 and 53 is connected to the power supply line 49b. In the series circuit of the smoothing capacitors 52 and 53, one terminal 54 and the other terminal 55 are driven circuit 44 for a washing machine motor via a current fuse 56 on one terminal 54 side. Is connected to the DC input terminal.

The second DC power supply circuit 57 includes a full-wave rectifier circuit 58 and two smoothing capacitors 59 and 60 formed by connecting four diodes (not shown) by single-phase bridge connection. The AC input terminal of the full wave rectifier circuit 58 is connected to the power supply lines 49a and 49b, and the series circuit of the smoothing capacitors 59 and 60 is connected between the DC output terminals of the full wave rectifier circuit 58, The common connection point of the utilization capacitors 59 and 60 is connected to the power supply line 49b. In the series circuit of the smoothing capacitors 59 and 60, one terminal 61 and the other terminal 62 are driven by the compressor motor 46 through the current fuse 63 on the one terminal 61 side. Is connected to the DC input terminal.

In addition, in the series circuit of the smoothing capacitors 59 and 60, one terminal 61 and the other terminal 62 are fan circuit drive circuits 45 through the current fuse 64 on one terminal 61 side. Is connected to the DC input terminal. That is, the second DC power supply circuit 57 is configured to be commonly used as the DC power supply circuit of the drive circuit 46 for the compressor motor and the drive circuit 45 for the fan motor.

The voltage detecting circuit 65 has an input terminal connected to the DC input terminal of the driving circuit 44 for the washing machine motor, and the DC voltage input to the driving circuit 44 for the washing machine motor, that is, the direct current of the rear end of the current fuse 56. It is made to detect the voltage. The voltage detecting circuit 66 has an input terminal connected to the DC input terminal of the fan motor driving circuit 45, and the DC voltage input to the fan motor driving circuit 45, i.e., the direct current of the rear end of the current fuse 64. It is made to detect the voltage. The voltage detection circuit 67 is configured such that an input terminal detects a direct current voltage input to the compressor motor drive circuit 46, that is, a direct current voltage at the rear end of the current fuse 63.

The main microcomputer 68 and the sub microcomputer 69 as control means have ROM (Read Only Memory) and RAM (Random Access Memory) (both not shown). The ROM of the main microcomputer 68 stores an operation program, a control program and necessary data for executing a laundry drying operation such as washing, rinsing, dehydration and drying. The ROM of the sub-microcomputer 69 also performs laundry drying. An operating program, a control program and necessary data for specifically performing drying of the operation are stored.

In the main microcomputer 68, the input / output port is connected to the control input / output terminal of the drive circuit 44 for the washing machine motor, and the input port is connected to the output terminal of the voltage detection circuits 65 and 66. Thereby, the main microcomputer 68 detects the rotation position of the rotor of the washing machine motor 14 by the signal from the drive circuit 44 for washing machine motors, and washes the washing machine based on the detection voltage of the voltage detecting circuit 65. PWM control of the motor drive circuit 44 is carried out, and the washing machine motor 14 is controlled to a set speed.

In the main microcomputer 68, the input / output port is connected to the control input / output terminal of the fan motor drive circuit 45 and the input port is connected to the output terminal of the voltage detection circuit 66. As a result, the main microcomputer 68 detects the rotational position of the rotor of the fan motor 29 by the signal from the fan motor drive circuit 45 and gives a gate signal to the fan motor drive circuit 45. The fan motor 29 is operated at a constant speed, and the melt of the current fuse 64 is detected by the presence or absence of the detection voltage of the voltage detection circuit 66.

The sub microcomputer 69 has an input / output port connected to the control input / output terminal of the drive circuit 46 for the compressor motor, an input port connected to the output terminal of the voltage detection circuit 67, and another input / output port connected to the main microcomputer. It is connected to the input / output port of (68). Thereby, when the drying start instruction is given from the main microcomputer 68, the sub microcomputer 69 detects the rotation position of the rotor of the compressor motor 35 by the signal from the drive circuit 46 for compressor motors. The pulse width modulation (PWM) control of the drive circuit 46 for a compressor motor is performed based on the detection voltage of the voltage detection circuit 66, and the compressor motor 35 is controlled at a set speed.

FIG. 3 is a plan view of the wiring board 40 on which the component parts (electrical and electronic parts) having the electrical configuration shown in FIG. 1 are mounted. In other words, the first DC power supply circuit 50, the washing machine motor driving circuit 44, and the main microcomputer 68 are arranged in a series at the right side of the wiring board PCB 40, which is one side thereof. On the left side of the other side, the second DC power supply circuit 57, the compressor motor drive circuit 46, and the sub microcomputer 49 are arranged in series, and therefore, the first DC power supply circuit in the series state ( 50) in parallel with the drive circuit 44 for the washing machine motor and the second DC power supply circuit 57 in series with the main microcomputer 68, the drive circuit 46 for the compressor motor, and the sub microcomputer 49; It is arranged.

In addition, the noise filter 47 and the fan motor drive circuit 45 are arranged in the center portion of the wiring board 40 in the center thereof, and thus the noise filter 47 and the fan motor drive circuit 45 in the series state. ) Is the first DC power supply circuit 50 in series, the drive circuit for washing machine motor 44, and the second DC power supply circuit 57 in series with the main microcomputer 68, and the drive circuit 46 for the compressor motor. And the submicrocomputer 49.

The power supply terminal part 70 is attached to the upper part of the center part of the wiring board 40, the power supply side terminal is connected to the single-phase AC power supply 48, and the load side terminal is connected to the input terminal of the noise filter 47. Moreover, of course, the current fuses 56, 63, and 64 and the voltage detection circuits 65, 66, 67 are also arrange | positioned in the wiring board 40 as shown in FIG. In this case, as shown in FIG. 3, the DC power lines (wiring patterns) P and N connected to the DC input terminals of the fan motor driving circuit 45 are the terminals 61, 62 of the smoothing capacitors 59, 60. Directly withdrawn from

Next, the operation of the laundry dryer having the above configuration will be described.

When the AC power supply voltage from the single-phase AC power supply 48 is applied to the first DC power supply circuit 50 through the noise filter 47, the AC power supply voltage is full-wave rectified by the full-wave rectifying circuit 51 and smoothed out. It is smoothed by the capacitors 52 and 53 and is formed between the both terminals 54 and 55 of the series circuit of the smoothing capacitors 52 and 53 as a DC power supply voltage of double voltage. The DC power supply voltage of the double voltage is applied to the driving circuit 44 for the washing machine motor through the current fuse 56.

In addition, when the AC power supply voltage from the single-phase AC power supply 48 is applied to the second DC power supply circuit 57 through the noise filter 47, the AC power supply voltage is full-wave rectified by the full-wave rectification circuit 58, and It is smoothed by the smoothing capacitors 59 and 60, and it generate | occur | produces between the both terminals 61 and 62 of the series circuit of the smoothing capacitors 59 and 60 as a DC power supply voltage of a double voltage. The DC power supply voltage of the above double voltage is applied to the drive circuit 46 for the compressor motor through the current fuse 63, and is further applied to the drive circuit 45 for the fan motor through the current fuse 64. The main microcomputer 68 is supplied with a DC control voltage obtained by stepping down the DC power supply voltage generated between both terminals 54 and 55 of the series circuit of the smoothing capacitors 52 and 53 to start operation. In addition, the sub-microcomputer 69 is supplied with a DC control voltage obtained by stepping down the DC power supply voltage generated between both terminals 61 and 62 of the series circuit of the smoothing capacitors 59 and 60 to start operation. Based on the control of the main microcomputer 68 and the submicrocomputer 69, the following laundry drying operation is executed.

Initially, washing and rinsing operations by the control of the main microcomputer 68 are started. In the above operation, water is supplied from the water supply valve 41 to the water tank 2 via the water supply case 42 and the water supply hose 43, and the washing machine motor 14 is operated to operate the rotary bath 3. Rotates alternately in both forward and backward directions at low speed.

When the rinsing operation is finished, the drying operation is executed by the control of the sub-microcomputer 69 which has been instructed by the main microcomputer 68 next. In the above operation, the fan motor 29 of the fan 22 is operated while rotating the rotary tub 3 at high speed and rotating in the forward and reverse directions at low speed. Then, as the centrifugal vane wheel 28 blows, air in the water tank 2 flows from the hot air outlet 9 to the ventilation duct 20 and the connection hose as shown by the arrow in FIG. It flows into the ventilation duct 18 via the 21.

At this time, the compressor 32 of the heat pump 33 is driven by the compressor motor 35. As a result, the refrigerant encapsulated in the heat pump 33 is compressed to become a high temperature and high pressure refrigerant, and the high temperature and high pressure refrigerant flows through the condenser 31, and the condenser 31 generates heat to generate air and the air in the ventilation duct 18. Heat exchange. As a result, the air in the ventilation duct 18 is heated, on the contrary, the refrigerant is lowered in temperature to liquefy. The liquefied refrigerant is then introduced into the evaporator 30 and vaporized. Thereby, the evaporator 30 cools the air in the ventilation duct 18. The refrigerant passing through the evaporator 30 is returned to the compressor 32.

Thereby, the air which flowed into the ventilation duct 18 from the inside of the above-mentioned water tank 2 is cooled and dehumidified by the evaporator 30, and is heated in the condenser 31, and is warmed up after that. And the warm air is supplied into the water tank 2 from the warm air inlet 10 via the connection hose 25 and the hot air duct 25, and is supplied into the rotating tank 3 from the hot air inlet 36. As shown in FIG. The hot air supplied into the rotary tub 3 deprives the laundry of water, and then exits the hole 39 or the opening 5 of the rotary tub 3 from the vent duct 20 and the connection hose from the above-described hot air outlet 9. It flows into the ventilation duct 18 via the 21. In this way, air circulates between the ventilation duct 18 which has the evaporator 30 and the condenser 31, and the rotating tank 3, and the laundry in the rotating tank 3 is dried.

However, during the above laundry drying operation, the voltage detection circuit 44 detects the input DC voltage of the drive circuit 44 for the washing machine motor, that is, the DC voltage at the rear end of the current fuse 56, and outputs the detected voltage signal to the main microcomputer. (68). Therefore, since the detected voltage signal disappears when the current fuse 56 is blown due to an overload or a short circuit of the washing machine motor 14, for example, the main microcomputer 68 blows the current fuse 56. On the other hand, the drive circuit 44 for the washing machine motor and the drive circuit 45 for the fan motor are stopped, and the sub-microcomputer 69 is notified to stop the drive circuit 46 for the compressor motor. The main microcomputer 68 performs the same operation as described above even when the current fuse 64 on the fan motor drive circuit 45 side is blown off.

The sub microcomputer 69 is configured to notify the main microcomputer 69 that the current fuse 63 of the compressor motor drive circuit 46 is blown out during the laundry drying operation. ) Stops the washing machine motor drive circuit 44 and the fan motor drive circuit 45 when the notification is received.

The main microcomputer 69 monitors the submicrocomputer 69 during the laundry drying operation. When the submicrocomputer 69 has runaway, the main microcomputer 69 drives the drive circuit 44 for the washing machine motor and the drive circuit 45 for the fan motor. Stop it.

According to this embodiment, the first DC power supply circuit 50 is a dedicated DC power supply circuit of the washing machine motor driving circuit 44, and the second DC power supply circuit 57 is a compressor motor driving circuit 46 and a fan motor. It was set as the common DC power supply circuit of the driving drive circuit 45 for them. Therefore, when the washing machine motor performs regenerative control during the washing and drying operation, even if the regenerative voltage is added to the series circuit of the smoothing capacitors 52 and 53 and the detected voltage between both terminals 54 and 55 is greatly changed, this is a fan. It is not applied to the motor drive circuit 45, and unlike the prior art, the fan motor 29 does not generate a vibration sound. Of course, the detection voltage between both terminals 54 and 55 of the series circuit of the smoothing capacitors 52 and 53 is not applied to the drive circuit 46 for compressor motors.

In addition, since the direct current power supplied to the fan motor driving circuit 45 is drawn out from the terminals 61 and 62 of the smoothing capacitors 59 and 60, as shown in FIG. Even when voltage fluctuation occurs in the wiring pattern connected to the compressor motor drive circuit 46 in the wiring board 40 by the current, the voltage fluctuation affects the DC power supplied to the fan motor drive circuit 45. There is no giving.

In addition, the noise filter 47, the first and second DC power supply circuits 50 and 57, the drive circuit 44 for the washing machine motor, the drive circuit 46 for the compressor motor, the drive circuit 45 for the fan motor, and the main The microcomputer 68 and the submicrocomputer 69 are mounted on the same wiring board 40, and the above-mentioned 1st DC power supply circuit 50, the drive circuit 44 for washing machine motors, and the main microcomputer 68 are mentioned. Are arranged in series, and the above-described second DC power circuit 57, the compressor motor drive circuit 46 and the sub-microcomputer 69 are arranged in series, and the above-described first DC power circuit 50 , The drive circuit 44 for the washing machine motor and the main microcomputer 68 are arranged in parallel, and the noise filter 47 and the drive circuit 45 for the fan motor described above are arranged in series and have a first direct current. Power supply circuit 50, drive circuit for washing machine motor 44 and main microcomputer 68 Claim is disposed between the second direct-current power supply circuit 57, driving circuit 46 and the sub-microcomputer (69) for the compressor motor. Therefore, the electrical and electronic components constituting each circuit can be arranged reasonably, the wiring is simplified, and there is no need to provide a DC power supply circuit dedicated to the drive circuit 45 for the fan motor, and the wiring board 40 can be miniaturized. can do.

4 to 6 show the second embodiment of the present invention, the same parts as those of the first embodiment described above are denoted by the same reference numerals, and other parts will be described below.

In the second embodiment, as shown in Fig. 6, the noise filter 47 in the first embodiment is combined with the first noise filter 47A for the first DC power supply circuit 50 (washing machine motor 14). It is divided into the 2nd noise filter 47B for the 2nd DC power supply circuit 57 (compressor motor 35), and the input terminal of the 1st and 2nd noise filters 47A and 47B is an AC power supply line ( It is connected to the single phase AC power supply 48 via 48a, 48b. And the output terminal of the 1st noise filter 47A is connected to the AC input terminal of the full wave rectification circuit 51 in the 1st DC power supply circuit 50, and the output terminal of the 2nd noise filter 47B is 2nd. It is connected to the AC input terminal of the full wave rectifier circuit 58 in the DC power supply circuit 57.

Further, in the second embodiment, the control input / output terminal of the fan motor drive circuit 45 is connected to the input / output port of the sub microcomputer 69 instead of the main microcomputer 68, and the output terminal of the voltage detection circuit 66 is connected. Also, it is connected to the input port of the sub microcomputer 69. Therefore, the drive circuit 45 for the fan motor is controlled in the same manner as the first embodiment by the sub-microcomputer 69 based on the command of the main microcomputer 68.

In the second embodiment, as shown in FIG. 5, the wiring board 40 in the first embodiment is divided into a first wiring board 40A and a second wiring board 40B. The first wiring board 40A includes a first DC power supply circuit 50, a driving circuit 44 for a washing machine motor, a current fuse 56, a voltage detection circuit 65, and a main microcomputer 68 in the first embodiment. It is mounted in the same arrangement as. The second wiring board 40B includes a second DC power circuit 57, a fan motor driving circuit 45, a compressor motor driving circuit 46, current fuses 63 and 64, and a voltage detecting circuit 66. 67 and the sub microcomputer 69 are mounted in the same arrangement as in the first embodiment.

The power supply terminal portion 70 in the first embodiment is divided into a first power supply terminal portion 70A and a second power supply terminal portion 70B. In the first wiring board 40A, the first power supply terminal portion 70A is disposed above the central portion thereof, and the first noise filter 47A is disposed below the first wiring substrate 40A. In the second wiring board 40B, the second power supply terminal portion 70B is disposed above the central portion thereof, and the second noise filter 47B is disposed above the fan motor driving circuit 45. However, as shown in FIG. 4, the 1st wiring board 40A is arrange | positioned at the upper part in the outer box 1, and the 2nd wiring board 40B is comprised so that it may be arrange | positioned in the vicinity of the fan 22. As shown in FIG.

By this second embodiment also, the same effects as those of the first embodiment can be obtained. In particular, according to the second embodiment, the first wiring board 40A equipped with the main microcomputer 49 for controlling the overall washing and drying operation of the wiring board 40 and the sub-microcomputer controlling the operation of drying ( 69 is divided into a second wiring board 40B mounted thereon, the first wiring board 40A is disposed above the outer box 1, and the second wiring board 40B is placed near the fan 22. Since the wiring boards 40A and 40B are located in the vicinity of the washing machine motor 14, the fan motor 29, and the compressor motor 35 to be controlled, respectively, the wiring becomes easy. In addition, since the wiring boards 40A and 40B are spaced apart from each other, the switching noise of the drive circuit 44 for the washing machine motor in the first wiring board 40A is also loaded on the wiring pattern of the second wiring board 40B. You can prevent it.

In addition, this invention is not limited only to the Example mentioned above and shown in the figure, It can change and implement as follows.

In the above embodiment, the control means is composed of two of the main microcomputer 68 and the sub microcomputer 69, but may be constituted of one microcomputer.

The washing machine motor 14 and the compressor motor 35 may be constituted by an induction motor, or the fan motor 29 may be constituted by a DC motor. In any case, the drive circuit is supplied with DC power from the DC power supply circuit.

The present invention is not limited to a laundry dryer having a horizontal rotating drum (drum), but can also be applied to a laundry dryer having a vertical rotating drum.

1 is a block diagram showing the electrical configuration of a drum type laundry dryer according to a first embodiment of the present invention;

2 is a longitudinal sectional view of the drum type laundry dryer,

3 is a plan view of a wiring board showing an arrangement state of components;

4 is a view corresponding to FIG. 2 showing a second embodiment of the present invention;

5 is equivalent to FIG. 3, and

6 is a diagram corresponding to FIG. 1.

* Explanation of symbols for the main parts of the drawings

3: rotating tub 14: washing machine motor

22: fan 29: fan motor

30: evaporator 31: condenser

32: compressor 33: heat pump

35: compressor motor 40: wiring board

40A: first wiring board 40B: second wiring board

44: drive circuit for washing machine motor 45: drive circuit for fan motor

46: drive circuit for compressor motor 50: first DC power supply circuit

51: full-wave rectifying circuit 52, 53: smoothing capacitor

56: current fuse 57: second DC power supply circuit

59: full-wave rectifier circuit 59, 60: smoothing capacitor

63, 64: current fuse 65, 67: voltage detection circuit

68: main microcomputer (control means)

69: sub microcomputer (control means)

Claims (5)

Washing machine motor to perform washing drying operation such as washing-drying, A compressor motor for driving the compressor in a heat pump that compresses the refrigerant in the compressor and circulates to condense in the condenser and evaporate in the evaporator, A fan motor that drives a fan that generates the drying warm air by using heat of a condenser in the heat pump, First and second DC power supply circuits for converting AC power from an AC power source into DC power through a rectifying circuit and a smoothing capacitor, A driving circuit for a washing machine motor for driving the washing machine motor based on the DC power from the first DC power circuit; A drive circuit for a compressor motor and a drive circuit for a fan motor, each of which uses the second DC power circuit as a common DC power circuit and drives the compressor motor and the fan motor based on the DC power; And a control means for controlling the drive circuit for the washing machine motor, the drive circuit for the compressor motor, and the drive circuit for the fan motor to execute the laundry drying operation such as washing and drying. The method of claim 1, The DC power supplied to the drive circuit for fan motors is taken out from the smoothing capacitor of a 2nd DC power supply circuit. The method according to claim 1 or 2, The first and second DC power supply circuits, the driving circuit for the washing machine motor, the driving circuit for the compressor motor, and the driving circuit for the fan motor are mounted on the same wiring board, and the first DC power supply circuit and the driving circuit for the washing machine motor are in series. And the second DC power circuit and the drive circuit for the compressor motor are arranged in series and in parallel with the first DC power circuit and the drive circuit for the washing machine motor. And a first DC power supply circuit and a washing machine motor driving circuit in series, and a second DC power supply circuit and compressor motor driving circuit in series. The method according to any one of claims 1 to 3, The control means comprises a main microcomputer for controlling the drive circuit for the washing machine motor, and a submicrocomputer for controlling the drive circuit for the compressor motor, and the drive circuit for the fan motor is configured to be controlled by the main microcomputer. Laundry dryer. The method of claim 1, The control means comprises a main microcomputer for controlling the drive circuit for the washing machine motor, and a submicrocomputer for controlling the drive circuit for the compressor motor and the drive circuit for the fan motor, The first DC power supply circuit, the drive circuit for the washing machine motor and the main microcomputer are mounted on the first wiring board, and the second DC power supply circuit, the drive circuit for the compressor motor, the drive circuit for the fan motor and the submicrocomputer are the second wiring board. A laundry dryer, characterized in that mounted on.

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