Electric washer-dryer

FIELD OF THE INVENTION

The present invention relates to a washer-dryer that treats a washing, which has been thrown into an inner tub disposed rotatably inside an outer tub of the washer-dryer, whole through the process beginning from washing to drying.

BACKGROUND OF THE INVENTION

A conventional washer-dryer having the above-described functions has been structured as illustrated in FIG.

20

. The structure is described below.

Referring to

FIG. 20

, an inner tub

1

of approximately cylindrical shape, functioning as a tub for both washing and spin-drying operations, is provided rotatably within the inside of an outer tub

2

. At the upper part of inner tub

1

is a fluid balancer

3

, in the inner bottom is a pulsator

4

provided freely rotatable. The outer tub

2

is housed in a cabinet

6

, being suspended by a suspension gear

5

for anti-vibration. A motor

7

is provided at the bottom part of the outer tub

2

. The motor

7

has a built-in clutch and gear for conveying the revolving force of the motor to a wash/spin-dry shaft

8

, which has an empty dual-shaft structure and switches the transmission to the pulsator

4

or to the inner tub

1

in accordance with a process, washing or spin-drying. The outer tub

2

is connected at the bottom to a drain channel

9

via a drain cock

10

. Hot air blowing means

11

comprises an air-blower and a heater (neither is shown); which is attached on the outer tub

2

for supplying hot air inside the inner tub

1

for drying the washing.

The operation of a washer-dryer of the above structure is described below. In a washing process, a washing

12

is thrown into the inner tub

1

together with detergent, and water or hot water is supplied therein. The clutch built in the motor

7

is switched to conveying the driving force of the motor

7

to the pulsator

4

via a wash shaft. The washing

12

is stirred by rotation of the pulsator

4

.

In a spin-drying process, which follows after the washing process is over, water in the inner tub

1

is discharged by opening the discharge cock

10

, and the clutch built in the motor

7

is switched to conveying the driving force of the motor

7

to the inner tub

1

via a spin-dry shaft. The inner tub is rotated, and the washing

12

is provided with a centrifugal force and is spin-dried.

In a drying process, hot air is supplied to inside the inner tub

1

by the hot air blowing means

11

while the pulsator

4

is driven in a normal mode. The washing

12

is dried by the hot air.

However, in the drying process under the conventional structure as described above, the hot air supplied from the hot air blowing means

11

into the inner tub

1

does not reach to the whole space of inner tub

1

; the bottom space, among others, is not provided with a sufficient amount of hot air. Therefore, it is difficult to provide a washing

12

with a sufficient amount of the heat and the velocity of hot air in an efficient manner. Which means that it takes a long time for drying, and that a washing may not be dried evenly. Furthermore, as the hot air blowing means

11

has been attached on the outer tub

2

, the gross weight of the vibrating body formed of the outer tub

2

and the hot air blowing means

11

, which have been suspended by the suspension gear

5

from the cabinet

6

, reaches to a substantial amount; which results in a significant vibration during operation, especially during the spin-drying process.

SUMMARY OF THE INVENTION

The present invention addresses the above-described problems, and intends to raise the efficiency of drying performance by reducing the drying time and improving the unevenness of drying. Also intended in the present invention is to alleviate the vibration during operations, especially during spin-drying process.

An invented washer-dryer comprises an inner tub of approximately cylindrical shape rotating around a substantially vertical axis for receiving a washing, which inner tub being housed in an outer tub, agitation means disposed rotatably in the inner tub for agitating a washing, a motor for rotating the inner tub or the agitation means, heating means for heating the air to be supplied through a hot air supply channel into the inner tub, a drying air blower for delivering hot air into the inner tub, and control means for controlling each of the washing, rinsing, spin-drying and drying processes by controlling the operations of the motor, heating means, drying air blower, etc. During the drying process, a washing is agitated by the agitation means and the air heated by the heating means is blown by the drying air blower against the washing staying within the inner tub. By so doing, the washing may be dehydrated and dried within a short period of time, without leaving significant unevenness of drying. Thus, the efficiency of drying is improved; also the vibration is substantially alleviated during operation, especially during the spin-drying process.

More desirably, the coupling of a hot air supply channel and an outer tub should be made by using a flexible and expandable tube. Under such structure, even if the inner tub rotating at a high speed generates an oscillating vibration during the spin-drying process, the outer tub may not be jerked in one specific horizontal direction by the hot air supply channel, so it can continue making a natural vibration. Vibration of outer tub caused by the high-speed rotation of inner tub is conveyed evenly to a cabinet; therefore the vibration as a whole is suppressed.

Desirably also, the upper part of outer tub should be covered with a separation board for preventing the air from escaping; and a water supply cock for supplying water into the inner tub is connected to an intake of water provided in the separation board by using a water supply duct in order to facilitate the water supply into the inner tub. Under such structure, the hot air is prevented from escaping during the drying process. Thus the drying performance is improved. At the same time, the increase of humidity in the room air due to escaping hot air is avoided.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1

is a vertical cross sectional view of a washer-dryer in accordance with a first exemplary embodiment of the present invention.

FIG. 2

is a vertical cross sectional view of a washer-dryer in accordance with a second exemplary embodiment of the present invention.

FIG. 3

is a vertical cross sectional view of a washer-dryer in accordance with a third exemplary embodiment of the present invention.

FIG. 4

is a horizontal cross sectional view of the above washer-dryer.

FIG. 5

is a horizontal cross sectional view of a washer-dryer of other example.

FIG. 6

is a partially cut-off vertical cross sectional view of a washer-dryer in accordance with a fourth exemplary embodiment of the present invention.

FIG. 7

is a vertical cross sectional view of a washer-dryer in accordance with a fifth exemplary embodiment of the present invention.

FIG. 8

is a vertical cross sectional view of a washer-dryer in accordance with a sixth exemplary embodiment of the present invention.

FIG. 9

is a vertical cross sectional view of a washer-dryer in accordance with a seventh exemplary embodiment of the present invention.

FIG. 10

is a vertical cross sectional view of a washer-dryer in accordance with an eighth exemplary embodiment of the present invention.

FIG. 11

is a vertical cross sectional view of a washer-dryer in accordance with a ninth exemplary embodiment of the present invention.

FIG. 12

is a vertical cross sectional view of a washer-dryer in accordance with a tenth exemplary embodiment of the present invention.

FIG. 13

is a vertical cross sectional view of a washer-dryer in accordance with an eleventh exemplary embodiment of the present invention.

FIG. 14

is a vertical cross sectional view of a washer-dryer in accordance with a twelfth exemplary embodiment of the present invention.

FIG. 15

is a partially cut-off plan view of the above washer-dryer.

FIG. 16

is a vertical cross sectional view of a washer-dryer in accordance with a thirteenth exemplary embodiment of the present invention.

FIG. 17

is a vertical cross sectional view of a washer-dryer in accordance with a fourteenth exemplary embodiment of the present invention.

FIG. 18

is a partially cut-off plan view of the above washer-dryer.

FIG. 19

is a cross sectional view showing a key portion of the above washer-dryer.

FIG. 20

is a vertical cross sectional view of a conventional washer-dryer.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

A first exemplary embodiment of the present invention is described with reference to FIG.

1

.

An inner tub

13

forms a tub for both washing and spin-drying operations. It has an approximately cylindrical shape with a number of small holes (not shown) in the sidewall, rotates around an approximately vertical axis, being housed inside an outer tub

14

. At the upper part of inner tub

13

is a fluid balancer

15

, and a bowl shape pulsator (agitation means)

16

is provided freely rotatable at the inner bottom. The pulsator

16

has a slope region

17

in the outer portion, and is provided with a plurality of ribs

18

extending in radial directions across the slope region

17

as far as almost outer edge. An outer tub

14

is housed in a cabinet

20

being suspended by a suspension gear

19

, for preventing vibration. A motor

21

is provided at the bottom of the outer tub

14

. The motor

21

has a built-in clutch and gear for switching the transmission of rotating force of the motor

21

to a wash shaft or to a spin-dry shaft in order to rotate the pulsator

16

or the inner tub

13

depending on the process, washing or spin-drying. The outer tub

14

is connected at the bottom to a water discharge channel

22

via a water discharge valve

23

.

A hot air supply channel

24

, which is to supply hot air to the inside of inner tub

13

during drying process, comprises a heater (heating means)

25

for heating the air and a drying air blower

26

for delivering hot air into the inner tub

13

. The hot air supply channel

24

is fixed to the cabinet

20

, and connected to a separation board

28

provided on the upper part of outer tub

14

by means of a flexible and expandable tube

27

of bellows shape. The outer tub

14

is provided at the bottom with a connection duct

29

for returning the hot air. The connection duct

29

is coupled with a heat exchanger

31

via a water discharge-switching valve

30

, and is coupled further with the hot air supply channel

24

containing the heater

25

and the drying air blower

26

, finally with the outer tub

14

via the flexible and expandable tube

27

. The separation board

28

is provided with a freely openable lid

32

. The separation board

28

is fixed on the outer tub

14

covering the upper end in order to prevent the hot air from escaping upward. The freely openable lid

32

is for throwing in and out a washing. A closed circulation channel is thus formed by the connection duct

29

, the heat exchanger

31

, the hot air supply channel

24

, etc. The flexible and expandable tube

27

and the connection duct

29

connect the cabinet

20

(fixed end) and the outer tub

14

(vibrating end) in a flexible manner. The heat exchanger

31

is disposed outside of the cabinet

20

so as to ensure the heat exchange by means of the air-cooling. A drain hole

33

is provided at the bottom of the heat exchanger

31

.

Control means

34

controls each of the washing, rinsing and spin-drying processes through the control on the operation of the motor

21

, the water discharge valve

23

, a water supply tap (not shown), etc. The control means

34

controls also the drying process through the control on the operation of the motor

21

, the heater

25

, the drying air blower

26

, etc. During the drying process, a washing

35

is agitated by the pulsator

16

and is blown by the hot air heated by the heater

25

delivered by the drying air blower

26

into the inner tub

13

. The heat exchanger

31

dehydrates the air for drying. The control means

34

also controls the rotation speed of pulsator

16

so as it rotates at a higher speed during the washing process than during the drying process.

The operation under the above structure is described below. In the washing process through the spin-drying process, a washing

35

is put into the inner tub

13

through the freely openable lid

32

together with detergent; starting the operation, water is supplied from a water tap into the inner tub

13

upto a certain level, and then the pulsator

16

is rotated to initiate a washing process. After the washing process is finished, the same procedures are repeated for rinsing. By closing the water discharge-switching valve

30

, the water in the outer tub

14

is prevented from escaping through the drain hole

33

. A spin-drying process begins with opening of the water discharge valve

23

, and the inner tub

13

is rotated at a high speed. The washing is spin-dried through an ordinary procedure, and then it proceeds to a drying process.

In the drying process, the water discharge valve

23

is closed, whereas the water discharge-switching valve

30

is opened. Hot air created by the heat generation of heater

25

is delivered into the inner tub

13

by the operation of the drying air blower

26

through the flexible and expandable tube

27

. The washing

35

sticking to the inner wall of inner tub

13

at the end of the spindrying process is peeled off the inner wall by a rotating action of the pulsator

16

, and is rotated along the slope region

17

of pulsator

16

to be hauled up by the rib

18

extending in radial direction. The washing

35

agitated and hauled upward are exposed to the hot air. The hot air evaporates the humidity contained in washing

35

to dry up the washing

35

, the hot air itself becomes a humid air and proceeds through the holes of the side wall of inner tub

13

, the space between fluid balancer

15

and separation board

28

, and the space between outer wall of inner tub

13

and inner wall of outer tub

14

, eventually reaching the connection duct

29

provided at the bottom of outer tub

14

. Then, it proceeds following the arrow marks, passing through the heat exchanger

31

, the heater

25

, reaching again to the drying air blower

26

. During the travelling, the hot air of high humidity makes contact with the inner wall of outer tub

14

, the inner wall of heat exchanger

31

, etc. constituting part of the circulation channel. The heat is exchanged and dehydrated at these surfaces. By the time when it reaches the heater

25

it becomes a cooled dry air. The dry air is heated again by the heater

25

and passes through the washing

35

. The drying process proceeds by repetition of a cycle of the above-described procedures.

The hot air circulates in a circulation channel formed by the connection duct

29

, the heat exchanger

31

, hot air supply channel

24

, etc. As the circulating air is heading for the water discharge-switching valve

30

located in the lower end, it passes evenly through the washing

35

within the inner tub

13

. Therefore, the washing dries up evenly. As the heat exchanger

31

, which being a part of the circulation channel, is disposed outside the cabinet

20

, the surface is always cooled contributing to the efficient dehydration at the heat exchanger

31

. Therefore, the washing dries up quickly and dehydration water generated as a result of heat exchange conducted in the heat exchanger

31

is discharged through the drain hole

33

.

As describe in the above, a washing

35

is agitated during the drying process by pulsator

16

, and is blown with the hot air heated by the heater

25

and delivered by the drying air blower

26

within the inner tub

13

, and the hot air is heat-exchanged at the heat exchanger

31

for dehydration in order to dry up the washing with the dehydrated air. Besides the heat exchange conducted at the heat exchanger

31

, the hot air is heat-exchanged also at the inside of outer tub

14

and such other places; therefore, the drying time is shortened and the unevenness in the drying of washing

35

is improved to an increased drying efficiency. Furthermore, because the hot air supply channel

24

containing the heater

25

and the drying air blower

26

, the heat exchanger

31

, etc. are not attached on the outer tub

14

, the vibration to be caused during operation, especially during spin-drying process, is lessened.

As the hot air supply channel

24

forms a circulation channel taking the air from the inner tub

13

, heating it by the heater

25

and delivering into the inner tub

13

, and the heat exchange is conducted at either within inside of the outer tub

14

or at the heat exchanger

31

provided in the circulation channel, the heat exchange performance has been raised. Such structure contributes to presenting a washer-dryer, which is compact in size yet having a high drying efficiency. Furthermore, as the heat exchanger

31

is disposed outside the cabinet

20

so as heat exchange takes place through the air-cooling principle, the heat exchange proceeds while the hot air is circulating in the circulation channel including the heat exchanger

31

. This factor makes a further contribution in presenting a compact washer-dryer of high drying efficiency.

The pulsator

16

is disposed freely rotatable in the inner bottom of inner tub

13

. It has a slope region

17

in the outer circumference and is provided with a plurality of ribs

18

extending in radial directions across the slope region

17

reaching almost edge. Therefore, a washing

35

is hauled upward and agitated by the ribs

18

of radial directions as a result of rotation of the pulsator

16

. The hauled up washing

35

is exposed to the hot air to an improved efficiency of drying. Thus the drying time is shortened, the drying efficiency is raised and the unevenness of drying is improved. Furthermore, as the control means

34

controls so as the number of rotations of pulsator

16

during washing process is different from that in the drying process, the pulsator

16

may be driven at an own optimum rotation speed for the washing process and the drying process, respectively. Thus the efficiency of washing and the efficiency of drying may be improved altogether.

Although in the present embodiment a closed circulation channel has been formed by connecting the heat exchanger

31

coupled with the outer tub

14

via the connection duct

29

to the hot air supply channel

24

, the same function and effect are obtainable even if such a closed circulation channel is not formed, without connecting the heat exchanger

31

to the hot air supply channel

24

.

The heat exchanger

31

in the present embodiment has been designed to the air-cooling principle. However, it may be structured instead based on the water-cooling principle.

A second exemplary embodiment of the present invention is described with reference to FIG.

2

.

As shown in

FIG. 2

, a cooling air blower

36

is provided in a side face of cabinet

37

in order to introduce the outside air for cooling an outer tub

14

. Other structures remain the same as those of the embodiment 1 above; therefore, using the same symbols represents such portions and the descriptions are not repeated here.

The operation under the above-described structure is described below. The operations during the washing process until the spin-drying process remain the same as in the embodiment 1, so no description is given on these operations.

When the drying process is initiated, after the spin-drying process is over, the cooling air blower

36

starts its operation to take cooling air (outside air) in from outside of the cabinet

37

. The cooling air is blown to the outer tub

14

. Inside of the outer tub

14

is cooled down and the humid hot air flowing inside the outer tub

14

is efficiently heat-exchanged and dehydrated. Thus the heat exchange performance is improved and a washing is dried up quickly.

Although the heat exchanger

31

, the heater

25

and the drying air blower

26

are disposed outside the cabinet

37

in the present embodiment, these items may be disposed instead within inside of the cabinet

37

. Then, the heat exchanger

31

is cooled by the cooling air introduced from outside of the cabinet

37

by the cooling air blower

36

. In this way, the humid hot air flowing in the heat exchanger

31

may be heat-exchanged and dehydrated efficiently and a washing may be dried up more quickly.

A third exemplary embodiment of the present invention is described below referring to FIG.

3

and FIG.

4

.

As shown in FIG.

3

and

FIG. 4

, a heat exchanger

38

is connected to the outer tub

14

via a connection duct

29

, it is also connected to a hot air supply channel

24

which has a built-in heater

25

and a drying air blower

26

. A circulation channel for circulating the hot air heated by the heater

25

is thus formed to air-cool the humid hot air for conducting the heat exchange and the dehydration. The heat exchanger

38

is disposed inside the cabinet

37

at a corner. Other structures remain the same as in the embodiment 2; therefore, using the same symbols represents these portions and the description is not repeated here.

The operation under the above-described structure is described. The operations from the washing process until the spin-drying process remain the same as in the embodiment 2; therefore description on these operations is omitted here.

When a drying process is initiated, after the spin-drying process is over, the humid hot air makes contact with the inner wall of outer tub

14

and the inner wall of heat exchanger

38

forming part of the circulation channel. At these surfaces the hot air is heat-exchanged and dehydrated to become cool dry air at the time when it arrives at the heater

25

. The dry air is heated again by the heater

25

to be delivered to washing

35

. The drying process proceeds by repeating a cycle of the above procedures. As the heat exchanger

38

is disposed at a corner of the cabinet

37

, a washer-dryer may be fabricated in a compact profile.

The heat radiating capacity may be increased by providing a plurality of heat radiation fin

39

on the outer wall surface of heat exchanger

38

constituting the circulation channel, as illustrated in FIG.

5

. As the heat radiation fin

39

remarkably increases the heat radiating performance, the heat exchanging capacity of heat exchanger

38

is significantly raised. This helps implement a washer-dryer that is compact yet having a highly efficient drying capability.

Although the heat radiation fin

39

is provided on the outer wall surface of heat exchanger

38

in

FIG. 5

, the heat radiation fin may be provided instead on the inner wall surface for obtaining the same effects.

A fourth exemplary embodiment of the present invention is described below referring to FIG.

6

.

As shown in

FIG. 6

, an outer tub

40

is provided on its outer surface with a protruding guide wall

41

of a fin shape, which guide wall

41

being disposed starting from a place facing to a cooling air blower

36

so as to guide the air taken in from outside and to discharge the heat of outer tub. Other structures remain the same as in the embodiment 2; therefore, using the same symbols represents these portions and the description is not repeated here.

The operation under the above-described structure is described. The operations form the washing process until the spin-drying process remain the same as in the embodiment 1; therefore description on these operations is omitted here.

When a drying process is initiated, after the spin-drying process is over, the humid hot air makes contact with the inner wall of outer tub

40

and the inner wall of heat exchanger

31

forming part of the circulation channel. At these surfaces the hot air is heat-exchanged and dehydrated to become cool dry air at the time when it arrived at the heater

25

. The dry air is heated again by the heater

25

to be delivered to washing

35

. The drying process proceeds by repeating a cycle of the above procedures. The outside air taken in by the cooling air blower

36

is guided by the guide wall

41

provided on the side wall of outer tub

40

to travel around the entire surface of outer tub

40

along the guide wall

41

. As the guide wall

41

functions also as a cooling fin and the blown air travels along the guide wall

41

around the entire surface of outer tub

40

, the heat radiation characteristics at the surface of outer tub

40

are improved. This results in significantly improved heat exchange characteristics and much improved drying efficiency.

A fifth exemplary embodiment of the present invention is described with reference to FIG.

7

.

As shown in

FIG. 7

, the heat exchanger

42

is provided with a water supply section

43

. The heat exchange is conducted in the water-cooling principle for dehydration. A hot air supply channel

24

containing a built-in heater

25

and a drying air blower

26

is connected via a flexible and expandable tube

44

of bellows shape to a separation board

28

provided at the top of outer tub

14

. An almost closed circulation channel is formed by the connection duct

29

, the heat exchanger

42

, the hot air supply channel

24

, etc. The flexible and expandable tube

44

of bellows shape is disposed in an approximately vertical direction. Other structures remain the same as those in the embodiment 1; using the same symbols represents these portions and the description is not repeated here.

The operation under the above-described structure is described in the following. The operations from the washing process until the spin-drying process remain the same as in the embodiment 1; therefore description on these operations is omitted here.

In the drying process, the water discharge-switching valve

30

is opened. Hot air created by the heat generation of heater

25

is delivered into the inner tub

13

by the operation of the drying air blower

26

through the flexible and expandable tube

44

. A spin-dried washing

35

is peeled off the inner wall by a rotating action of the pulsator

16

, and is hauled up by the rib

18

extending in radial directions on the pulsator

16

. The washing

35

agitated and hauled upward is exposed to the hot air. The hot air deprives the humidity contained in washing

35

to make itself a humid hot air, which proceeds along the side wall of inner tub

13

, passes through the space between outer surface of inner tub

13

and inner surface of outer tub

14

, reaching the connection duct

29

provided at the bottom of outer tub

14

. Then, the humid hot air proceeds following the arrow marks, passing through the heat exchanger

42

, the heater

25

, reaching again to the drying air blower

26

. During the travelling in the heat exchanger

42

, the hot air of high humidity is cooled by the water supplied from the water supply section

43

and dehydrated. By the time when it reaches the heater

25

it becomes a cooled dry air. The dry air is heated again by the heater

25

and goes through the washing

35

. The drying process proceeds by repetition of a cycle of the above-described procedures.

While a washer-dryer is in operation during the above processes, the pulsator

16

or the inner tub

13

is rotating. As a result, the outer tub

14

and other members suspended by a suspension gear

19

make vibrations in up-down directions and/or oscillatory directions. The vibrations, in so far as they are the free vibrations, are absorbed by a plurality of suspension gears

14

supporting the outer tub

14

, and a cabinet

20

is not quite affected by the vibrations. Considering the nature of vibrations in the present embodiment; although the cabinet

20

and the separation board

28

on the outer tub

14

are connected with the flexible and expandable tube

44

the vibrations of the vibrating member are not restricted, neither in up-down nor oscillatory directions, because the flexible and expandable tube has been disposed in a substantially vertical direction and has a shape of bellows. Therefore, the nature of free vibration is maintained.

The vibration of a cabinet

20

due to vibrations of the outer tub

14

and other vibrating members supported by a suspension gear

19

is thus reduced. So, a washer-dryer of less vibration is presented in accordance with the present invention.

Although the heat exchanger

42

is provided with a water supply section

43

for conducting the heat-exchange in the water-cooling principle in the present embodiment, it may of course be conducted in the air-cooling principle, in the same way as in the embodiment 1.

A sixth exemplary embodiment of the present invention is described in the following with reference to FIG.

8

.

As shown in

FIG. 8

, an empty path

45

is provided on the surface of separation board

47

facing the inner tub

13

, coupling through with the flexible and expandable tube

46

. The empty path

45

extends to as far as substantially the center of the separation board

47

. At the exit of empty path

45

is a guide

48

provided for guiding the air coming from the empty path

45

towards substantially the center of the inner tub

13

. Other structures remain the same as those in the above embodiment 5; using the same symbols represents these portions and the description of which is not repeated here.

The operation under the above-described structure is described in the following. The operations from the washing process until the spin-drying process remain the same as in the embodiment 5; therefore description on these operations is omitted here.

In the drying process, the water discharge-switching valve

30

is opened. Hot air created by the heat generation of heater

25

is delivered into the inner tub

13

by the operation of the drying air blower

26

through the flexible and expandable tube

46

and the separation board

47

. In the present embodiment, an empty path

45

is provided extending as far as approximately the center of the separation board

47

; therefore, the hot air proceeds along the empty path

45

to substantially the center of the separation board

47

. The hot air is directed downward into the inner tub

13

guided by a guide

48

provided at the exit of empty path. Thus the hot air is delivered efficiently to the washing

35

locating in the inner tub

13

. The efficiency of drying is improved and the drying time is shortened; eventually the total time needed through the processes from washing to drying is reduced.

A seventh exemplary embodiment of the present invention is described in the following with reference to FIG.

9

.

As shown in

FIG. 9

, the flexible and expandable tube

49

is provided with a non-return valve

50

within the inside. The non-return valve

50

opens when the hot air goes from the hot air supply channel

24

to the inner tub

13

, whereas it closes at a reverse flow. Other structures remain the same as those in the above embodiment 5; using the same symbols represents these portions and the description of which is not repeated here.

The operation under the above-described structure is described in the following. The operations from the washing process until the spin-drying process remain the same as in the embodiment 5; therefore description on these operations is omitted here.

In the drying process, the water discharge-switching valve

30

is opened. Hot air created by the heat generation of heater

25

is delivered into the inner tub

13

by the operation of the drying air blower

26

through the flexible and expandable tube

49

and the separation board

28

. If during a washing process, for example, water or foam of detergent is intruding into the hot air supply channel

24

from the flexible and expandable tube

49

, namely if something is coming towards the drying air blower

26

or the heater

25

, the intrusion is halted by the non-return valve

50

. Thus an intrusion of unwanted items with reverse flow is avoided for assuring a higher safety.

An eighth exemplary embodiment of the present invention is described below referring to FIG.

10

.

As shown in

FIG. 10

, an outer tub

51

which houses in it an inner tub

13

rotating around a substantially vertical axis and functioning as a tub for washing and spin-drying is suspended in a cabinet

52

with a suspension gear

19

for the sake of anti-vibration. A hot air supply channel

53

is provided for supplying hot air into the inner tub

13

during drying process. The hot air supply channel

53

comprises a heater

25

for heating the air and a drying air blower

26

for delivering the hot air into the inner tub

13

, and connected to the cabinet

52

. A flexible and expandable tube

54

is provided to enclosing the outer circumference of an opening

55

for throwing a washing into the inner tub

13

, connecting the outer tub (vibrating end)

51

with the cabinet (stationary end)

52

. Other structures remain the same as those of the embodiment 1 above; using the same symbols represents these portions and description of which is not repeated here.

The operation under the above-described structure is described in the following. The operation in the washing process remains the same as in the embodiment 1; therefore description on which is omitted here.

A spin-drying process begins, after the washing process is over, with opening of the water discharge valve

23

for discharging the water in the inner tub

13

, and a clutch built in a motor

21

is switched to the spin-dry side to convey the rotating force of the motor

21

to the inner tub

13

via a spin-dry shaft. The inner tub

13

is rotated at a high speed and a washing is spin-dried by a centrifugal force. The outer tub

51

supported by the suspension gear

19

is vibrated by the rotating inner tub

13

. The vibration is conveyed to the cabinet

52

, which is vibrated during the spin-drying process.

As the outer tub (vibrating end)

51

and the cabinet (stationary end)

52

are connected by the flexible and expandable tube

54

, conduction of the vibration of outer tub (vibrating end)

51

to the cabinet (stationary end)

52

is absorbed by the flexible and expandable tube

54

. So, the vibration at cabinet

52

is suppressed. Furthermore, the flexible and expandable tube

54

has been disposed enclosing the entire circumference of the opening

55

provided for throwing a washing in. The flexible and expandable tube

54

disposed in a well-balanced arrangement causes no jerking force in one specific direction. Thus the vibration is suppressed to a minimum.

In the drying process, the water discharge-switching valve

30

is opened and hot air created by the heat generation of heater

25

is delivered into the inner tub

13

by the operation of the drying air blower

26

through the flexible and expandable tube

54

. The washing

35

sticking to the inner wall of inner tub

13

after the spin-drying process is peeled off the inner wall by a rotating action of the pulsator

16

, and is rotated along the slope region

17

of pulsator

16

to be hauled up by the rib

18

extending in radial direction. The washing

35

agitated and hauled upward are exposed to the hot air. The hot air evaporates the humidity contained in the washing

35

to dry it up. The hot air itself becomes a humid air and proceeds along the side wall of inner tub

13

and the space between outer wall of inner tub

13

and inner wall of outer tub

51

, reaching the connection duct

29

provided at the bottom of outer tub

51

. And then, it proceeds following the arrow marks, passing through the heat exchanger

31

, the heater

25

, reaching again to the drying air blower

26

. During the travelling, the hot air of high humidity makes contact with the inner wall of outer tub

51

, the inner wall of heat exchanger

31

, etc. constituting part of the circulation channel. The heat is exchanged and the air is dehydrated at the surfaces. By the time when it reaches the heater

25

it becomes a cooled dry air. The dry air is heated again by the heater

25

and goes through the washing

35

. The drying process proceeds by repetition of a cycle of the above-described procedures.

The flexible and expandable tube

54

has been connecting the outer tub (vibrating end)

51

and the cabinet (stationary end)

52

in a well-balanced manner by enclosing the entire circumference of the opening provided for throwing a washing in. This structure contributes to suppress the vibration to be caused by rotation of the pulsator

16

or inner tub

13

during the washing, rinsing, spin-drying and drying processs.

A ninth exemplary embodiment of the present invention is described in the following with reference to FIG.

11

.

As shown in

FIG. 11

, a separation board

57

having a hot air entrance hole

56

is provided on the top of an outer tub

51

. Other structures remain the same as those of the embodiment 8; using the same symbols represents these portions and the description is omitted here.

The operation under the above-described structure is described in the following. The operations from the washing process through the spin-drying process remain the same as in the embodiment 8 above; therefore description on which is not repeated here.

In the drying process, the water discharge-switching valve

30

is opened and hot air created by the heat generation of heater

25

is delivered into the inner tub

13

by the operation of the drying air blower

26

through the hot air supply channel

53

, the flexible and expandable tube

54

and the separation board

57

. The hot air raises the temperature within the inner tub

13

. By rotation of the pulsator

16

, the washing

35

is made to have contact with the hot air to be dried up. The hot air is guided by the hot air entrance hole

56

so that it is directed vertically downward at a place close to the washing

35

. In this way, the hot air makes contact with the washing

35

while the temperature is high; which contributes to expedite the drying of washing

35

.

The separation board

57

having a hot air entrance hole

56

directs the flow of hot air vertically downward at a place close to the washing

35

. A washing

35

may have contact with the hot air of high temperature, which contributes to shorten the time needed to dry up a washing.

A tenth exemplary embodiment of the present invention is described in the following with reference to FIG.

12

.

As shown in

FIG. 12

, a separation board

59

having a hot air entrance hole

58

is provided on the top of outer tub

51

, the hot air entrance hole

58

having a contracting shape. Other structures remain the same as those of the embodiment 9, using the same symbols represents these portions and description of which is omitted here.

The operation under the above-described structure is described in the following. The operations from the washing process through the spin-drying process remain the same as in the embodiment 9 above; therefore description on which is not repeated here.

In the drying process, the water discharge-switching valve

30

is opened and hot air created by the heat generation of heater

25

is delivered into the inner tub

13

by the operation of the drying air blower

26

through a hot air supply channel

53

, a flexible and expandable tube

54

and the separation board

59

. The temperature within the inner tub

13

is raised. By the rotation of pulsator

16

, the washing

35

is made to have contact with the hot air to be dried up. Because of the contracting shape of the hot air entrance hole

58

the hot air is blown vertically downward at a high flow velocity. Therefore, the hot air of high temperature actively makes contact with the washing

35

; which contributes to expedite the drying of washing

35

.

By shaping the hot air entrance hole

58

in a contracting shape, velocity of the vertical downward flow of hot air during drying process is increased. Thus the hot air of a high temperature reaches actively even to the washing

35

staying at the bottom part of the inner tub

13

. The time needed to dry up a washing

35

can be reduced.

An eleventh exemplary embodiment of the present invention is described in the following with reference to FIG.

13

.

As shown in

FIG. 13

, a gushing mouth

60

is provided to gush out the hot air delivered via the flexible and expandable tube

62

from the hot air supply channel

61

into the inner tub

13

. A freely openable lid

64

is provided in the separation board

63

attached on the top of outer tub

14

. The gushing mouth

60

is fixed to the lid

64

. The cross sectional area of the gushing mouth

60

gradually decreases towards the exit so as to deliver the hot air at an increased flow velocity into the inner tub

13

. Other structures remain the same as those of the embodiment 1, using the same symbols represents these portions and the description is omitted here.

The operation under the above-described structure is described in the following. The operations from the washing process through the spin-drying process remain the same as in the embodiment 1; therefore description on which is not repeated here.

In the drying process, the water discharge-switching valve

30

is opened and hot air created by the heat generation of heater

25

is delivered into the inner tub

13

by the operation of the drying air blower

26

through the hot air supply channel

61

, the flexible and expandable tube

62

and the gushing mouth

60

. The temperature within the inner tub

13

goes up. By the rotation of pulsator

16

, the washing

35

is made to have contact with the hot air to be dried up. The hot air heats the washing

35

and evaporates the humidity contained in the washing, and then passes through the holes in the side wall of inner tub

13

and the space between a fluid balancer

15

and the separation board

63

reaching to the heat exchanger

31

via the connection duct

29

. At the heat exchanger

31

, the humid hot air is cooled and dehydrated, and dehydration water is discharged through the drain hole

33

. The drying process proceeds along with the circulation and dehydration of hot air. In the meantime, pulsator

16

repeats the forward and reverse rotations to haul up and agitate the washing

35

in order to help drying up.

Because of the smoothly contracting flow area in the cross section of the gushing mouth

60

, the hot air flow is sharpened at a least pressure loss and blown into the inner tub

13

at an increased flow velocity. The hot air is blown with strength against the washing

35

and permeates at a sufficient velocity down to the bottom portion of the inner tub

13

. In this way, the washing

35

is efficiently provided with the heat and the convection. Thus a washing is dried up within a short period of time with least unevenness of drying. The reduced drying time contributes to the save-energy initiative.

In the present exemplary embodiment, it is to be noted that the time needed for drying and the evenness of the drying, which being the essential factors determining a drying performance, are closely interrelated to each other. Therefore, it is difficult in practice to clearly distinguish the cause from the countermeasure in each of the respective factors.

A twelfth exemplary embodiment of the present invention is described in the following with reference to FIG.

14

and FIG.

15

.

As shown in FIG.

14

and

FIG. 15

, a freely openable lid

66

is provided in the separation board

65

attached on the top of the outer tub

14

. The lid

66

is disposed in the front forward portion of the separation board

65

so as to be openable by a butterfly action around an axis supported by the separation board

65

. The contact area of the separation board

65

and the lid

66

is provided with an airtight packing and a latch, or a magnet, so as it does not make an unwanted sudden unclosing. The separation board

65

is also provided with a hot air entrance hole

67

at the rear portion, being isolated from the freely openable lid

66

. The hot air entrance hole

67

is provided with a gushing mouth

68

, which is directly connected to and opens it mouth towards the bottom center of the inner tub

13

. The hot air entrance hole

67

and the hot air supply channel

70

are connected by the flexible and expandable tube

69

. Other structures remain the same as those of the embodiment 11 above, using the same symbols represents these portions and the description is omitted here.

The operation under the above-described structure is described in the following. The operations from the washing process through the spin-drying process remain the same as those in the embodiment 1; therefore description on which is not repeated here.

In the drying process, the water discharge-switching valve

30

is opened and the hot air created by the heat generation of heater

25

is delivered into the inner tub

13

by the operation of the drying air blower

26

. The hot air goes through the hot air supply channel

70

, the flexible and expandable tube

69

and the gushing mouth

68

, and the temperature within the inner tub

13

is raised. The washing

35

is made to have contact with the hot air by the rotation of pulsator

16

to be dried up.

During the operation from the washing process through the spin-drying process and in the drying process, the pulsator

16

or the inner tub

13

is rotating. Therefore, vibration is caused on the outer tub

14

and other vibrating members. Although the suspension gear

19

, the connection duct

29

, the flexible and expandable tube

69

absorb the vibration for a certain extent, the vibration can not be totally absorbed and the remaining part of vibration is conveyed to cabinet

20

.

In the present embodiment, a freely openable lid

66

is provided in the front forward portion of the separation board

65

, and the gushing mouth

68

and the hot air entrance hole

67

are provided in the rear portion. The above disposition layout on the separation board

65

, namely, the isolation of the gushing mouth and the hot air entrance hole from the lid, makes the structure on an outer tub

14

simpler and lighter in weight as compared with that in the above embodiment 11. This contributes to suppress the vibration of the outer tub

14

during each of the processes.

The freely openable lid

66

seems to be most convenient for the practical use when disposed in such a layout that it opens to the direction as illustrated in the drawing with dotted lines. However, it may of course be provided instead in a form of an accordion curtain, or as a sliding shutter, for example. As another alternative, the separation board

65

itself may be made openable, eliminating the freely openable lid

66

. This alternative, however, does not seem to be practical, because in practice the top portion of the cabinet

20

is occupied by an operation panel, a top cover and the like items.

Like in the embodiment 11 above, it is to be noted that the time needed for drying and the evenness of the drying, which being the essential factors determining the drying performance, are closely interrelated to each other. Therefore, in practice, it is difficult to clearly distinguish the cause from the countermeasure for each of the respective factors.

A thirteenth exemplary embodiment of the present invention is described with reference to FIG.

16

.

As shown in

FIG. 16

, a water discharge valve

71

for discharging wash water is provided at the bottom of outer tub

72

and is connected to a drain channel

73

. An overflow channel

74

is attached fixed to the outer wall surface of outer tub

72

. The upper end of the overflow channel

74

is coupled with an overflow inlet

75

provided at the inner wall surface of the outer tub

72

, while the lower end is connected to the drain channel

73

at a point in the down stream of the water discharge valve

71

. The overflow channel

74

discharges redundant wash water exceeding a certain predetermined highest level (the level of overflow inlet

75

) through the drain channel

73

. A trap

76

is provided in the drain channel

73

after the overflow channel

74

is merged, the trap having a shape for retaining a certain amount of discharged water. The water kept in the trap

76

prevents the hot air from escaping during the drying process. An expandable connection duct

77

connects the water discharge channel at a place above the level of water discharge valve

71

to the heat exchanger

31

. After the heat exchanger

31

, the hot air supply channel

70

containing heater

25

and drying air blower

26

, the flexible and expandable tube

69

, and the gushing mouth

68

follow in the channel. The hot air blows out towards the bottom center of the inner tub

13

. The heater

25

and the drying air blower

26

are disposed at a level higher than the overflow inlet

75

. Other structures remain the same as those of the embodiment 12 above; providing the same symbols represents these portions and the description of which is not repeated here.

The operations under the above structure are described in the following. In the washing process, the washing

35

and detergent is thrown into the inner tub

13

through the freely openable lid

66

, water is supplied from a water supply tap into the inner tub

13

upto a predetermined level, and then the pulsator

16

is put into operation. During washing, the wash water exceeding the certain predetermined level, caused by too much volume of the washing

35

or too high water level, is discharged from the overflow inlet

75

provided in the outer tub

72

; going through the overflow channel

74

, the drain channel

73

and the trap

76

. Meanwhile, the heat exchanger

31

is also filled with water coming through the connection duct

77

upto a level identical to that in the outer tub

72

. After the washing process is over, a rinsing process proceeds in a similar way.

Then it proceeds to a spin-drying process. The water in the inner tub

13

is discharged through the unclosed water discharge valve

71

, and then the inner tub

13

is rotated at a high speed in an ordinary manner for spin-drying. Then a drying process follows.

In the drying process, the water discharge valve

71

is closed. Pulsator

16

is rotated quickly in the forward and reverse directions in order to peel off the washing

35

being stuck to the inner wall of inner tub

13

because of a centrifugal force exerted during the spin-drying process. Hot air heated by the heater

25

is blown by the drying air blower

26

to be delivered into the inner tub

13

through the gushing mouth

68

. The hot air heats the washing

35

and evaporates the humidity contained in the washing

35

. Then the hot air proceeds through the holes in the side wall of inner tub

13

, the gap between fluid balancer

15

and separation board

65

, the gap between pulsator

16

and inner tub

13

, etc. eventually arriving at the bottom part of outer tub

72

, and then goes to the heat exchanger

31

guided by the connection duct

77

. The humid hot air, after having evaporated the humidity of washing

35

, is cooled and dehydrated at the heat exchanger

31

, and then goes to the drying air blower

26

again. The drying process proceeds along with the circulation and dehydration of hot air. The dehydration water generated as a result of heat exchange conducted in the heat exchanger

31

is gradually accumulated on the water discharge valve

71

. Therefore, the water discharge valve

71

is unclosed for several seconds at a certain interval to discharge the dehydration water, so as it does not block the hot air circulation channel. In the meantime, the pulsator

16

repeats the forward and reverse rotations to haul up and agitate the washing

35

in order to help dry up the washing. The water discharge valve

71

may be kept open during drying process. In this case, the trap

76

prevents escaping of the hot air outside. However, the overflow channel

74

may serve as a detour for the hot air and the drying performance might deteriorate for a certain extent.

The drying air blower

26

and the heater

25

belong to the electric component. If the water invades the terminal, wiring or inner circuit of these components, there will be a risk of breakage in the components, or the leakage/short-circuiting of electricity. However, in the present embodiment, there is no such a danger and the safety is assured, because the drying air blower

26

and the heater

25

are disposed at a level higher than that of the overflow inlet

75

and the water does not exceed the level; hence, the water level never reaches the drying air blower

26

and the heater

25

in the washing and the rinsing processes.

The trap

76

disposed in the drain channel

73

at a place after merging with the overflow channel

74

functions, besides the draining function, to prevent the escaping of hot air outside through the overflow channel

74

or the unclosed water discharge valve

71

during the drying process. Furthermore, because the heat exchanger

31

coupled with the hot air supply channel

70

is connected to the water discharge channel at a point above the water discharge valve

71

with the expandable connection duct

77

, a hot air circulation channel has been formed between the cabinet (stationary end)

20

and the outer tub (vibrating end)

72

in a space-saving configuration using only one water discharge valve

71

.

Although the flexible and expandable tube

69

and the hot air supply channel

70

, etc. in the present embodiment have been structured in the same manner as in the embodiment 12, these items may of course be structured instead in the same manner as in the embodiments 1 through 11 described earlier.

A fourteenth exemplary embodiment of the present invention is described in the following with reference to the drawings FIG.

17

through FIG.

19

.

As shown in

FIG. 17

, a water supply valve

78

is fixed to the cabinet

20

for supplying tap water into the inner tub

13

; the water is supplied to inner tub

13

through a faucet

80

provided in the separation board

79

. An expandable water supply duct

81

connects the water supply valve

78

and the faucet

80

to form a water supply channel. The water supply channel comprises a dual system as shown in

FIG. 18

; corresponding respectively to a detergent dispensing section

82

a

and a softening agent dispensing section

82

b

of a detergent dispenser

82

provided at the faucet

80

.

A hot air supply channel

70

comprising a heater

25

for heating the air and a drying air blower

26

for delivering the hot air into the inner tub

13

is fixed to the cabinet

20

. The hot air supply channel

70

is connected to a gushing mouth

68

via the flexible and expandable tube

69

of bellows shape. The separation board

79

is fixed covering the top part of an outer tub

14

, for preventing the hot air from escaping upward. The separation board

79

is provided with a lid

83

, which is freely openable to take in and out a washing

35

. The faucet

80

and the gushing mouth

68

are also provided in the separation board

79

at an area far from the operator, and the water supply duct

81

is structured in a compact configuration so as to afford a largest possible area for the freely openable lid

83

.

At the upstream end of the hot air supply channel

70

is the heat exchanger

31

for cooling and dehydrating. The heat exchanger

31

is connected to the bottom part of outer tub

14

via an expandable connection duct

84

and an air channel valve

85

for opening/closing the air flow channel. A trapped drain channel

86

, which retains water in the route, is branching out from the connection duct

84

at the lowest point, discharges the dehydration water from heat exchanger

31

, and prevents the air from escaping. A water discharge valve

87

is unclosed for discharging washing water and at the spin-drying operation.

Now in the following, detailed structure of the faucet

80

and the vicinity is described referring to FIG.

19

. On the upper surface (or the reverse surface) of the separation board

79

, a detergent dispenser

82

is provided in the form of a drawer. Detergent or softening agent kept in the detergent dispenser

82

is delivered mixed with water to the inside of inner tub

13

. A non-return valve

88

is a valve of elastic film that easily opens for only one direction; when a pressure of water comes from upward it opens to a funnel shape, and the film shrinks to close as soon as the water pressure is lifted. A shower nozzle

89

is provided at the tip end of the faucet

80

, for showering the water into the inner tub

13

through a number of small holes. The shower nozzle

89

is detachable; the nozzles of other configuration are prepared to meet different types of needs for the water supply. Other structures remain the same as those of the above embodiment 12; using the same symbols represents these portions and the description is not repeated here.

The operation under the above structure is described in the following. In a washing process, the openable lid

83

is opened and a washing

35

is thrown into the inner tub

13

, and detergent and softening agent, if necessary, are put into the detergent dispenser

82

, and then operation is started. With the water discharge valve

87

and the air channel valve

85

kept closed, water is supplied from the water supply valve

78

to the detergent dispensing section

82

a.

The water dissolves and includes the detergent to become a washing water, which is delivered through the non-return valve

88

and the shower nozzle

89

into the inner tub

13

upto a certain predetermined level. A clutch built in a motor

21

conveys the rotating force of the motor

21

to a washing shaft in order to rotate the pulsator

16

. The rotating pulsator

16

agitates the washing

35

.

If in the washing process the level of water is raised very high due to too much volume of the washing, foam of the detergent might come close to the faucet

80

and enter into the water supply duct

81

, in the worst case it might ascend to the tap water facility. However, the non-return valve

88

prevents it. The outer tub

14

is provided with an overflow inlet (not shown) for preventing the water from overflowing. Even if water overflows despite the overflow inlet, the non-return valve

88

prevents the worst case to happen.

In the final rinsing course, the water supply valve

78

opens at the softening agent dispensing section

82

b,

and the softening agent is supplied to the inner tub

13

accompanied by the water. After the washing and rinsing processes are over, a spin-drying process starts; the water discharge valve

87

is opened to discharge the water in the inner tub

13

, the rotating force of motor

21

is conveyed via a clutch built in the motor

21

to the inner tub

13

. The inner tub

13

is rotated together with the pulsator

16

at a high speed, and the washing

35

is spin-dried by a centrifugal force.

In the drying process, the pulsator

16

is rotated quickly in the forward and reverse directions to peel off the washing

35

being stuck to the inner wall of inner tub

13

because of the centrifugal force exerted during the spin-drying process. The water discharge valve

87

is closed; the air channel valve

85

is opened. The wind created by the drying air blower

26

is heated while passing through the heater

25

to become a hot air, which is delivered via the flexible and expandable tube

69

into the inner tub

13

by way of the gushing mouth

68

. The hot air can not escape upward because of the separation board

79

. The hot air heats the washing

35

and evaporates the humidity contained in the washing

35

, and proceeds through the holes in the side wall of inner tub

13

and the gap between fluid balancer

15

and separation board

79

, reaching to the heat exchanger

31

guided by the connection duct

84

attached to the bottom part of the outer tub

14

. The humid hot air is cooled and dehydrated at the heat exchanger

31

, and then goes to the drying air blower

26

again. The drying process proceeds along with the circulation and dehydration of hot air. The dehydration water is discharged outside through the trapped drain channel

86

. In the meantime, the pulsator

16

repeats the forward and reverse rotations to haul up and agitate the washing

35

in order to help drying up.

In a washer-dryer of the present embodiment, a separation board

79

is provided, also a water supply duct

81

is provided which couples a water supply valve

78

with a faucet

80

disposed on the separation board

79

. Therefore, the water can be supplied through the water supply duct

81

and the hot air is prevented from escaping during a drying process. The washer-dryer exhibits a high drying performance, and does not bring about an increased humidity in the room air.

Furthermore, as the faucet

80

is disposed on the separation board

79

at a place far from the operator the water supply channel can be formed in a compact configuration. As a result, and a sufficiently large area can be secured for throwing in and out a washing

35

. Thus the ease of putting in and out a washing

35

is improved.

The non-return valve

88

provided at the faucet

80

prevents the washing foams and waters from invading the water supply duct

81

and the tap water facility. The safety is thus improved.

Although the flexible and expandable tube

69

, the hot air supply channel

70

, etc. of the present embodiment have been structured in the same manner as in the embodiment 12 above, these items may of course be structured instead in the same way as those of the embodiment 1 through 11.

Although the non-return valve

88

has been structured using an elastic film material in the present embodiment, it is not limited to such a structure. It may be structured with a sort of flap that opens by the force of a fluid only in downward direction, or an electrical control valve may be used.

Although the non-return valve

88

has been disposed at a place lower than the detergent dispenser

82

, it may rather be desirable to dispose it at a place higher than the detergent dispenser

82

, because foams can be generated within the detergent dispenser

82

.

Although the shower nozzle

89

has been structured so as it delivers water through a number of small holes into the inner tub

13

in the form of a shower, it is not limited to such a structure. The water may be delivered through a slit nozzle or a sprinkler. Other mode of supplying the water includes a supply with foams, a high-speed jet, etc.

Number	Date	Country
10-060874	Mar 1998	JP
10-157283	Jun 1998	JP
10-157284	Jun 1998	JP
10-283695	Oct 1998	JP
11-027549	Feb 1999	JP
11-027555	Feb 1999	JP

Number	Name	Date
2782622	Candor	Feb 1957
2818719	Cline	Jan 1958
2863311	Brucken	Dec 1958
3323336	Johnson et al.	Jun 1967
3401052	Berger et al.	Sep 1968
4204339	Muller	May 1980
5537761	Oh	Jul 1996

Number	Date	Country
0 501 747	Sep 1992	EP
0 704 569	Apr 1996	EP
2215826	Sep 1989	GB
9-774	Jan 1997	JP
9410370	May 1994	WO

Electric washer-dryer

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Abstract

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Priority Claims (6)

US Referenced Citations (7)

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Non-Patent Literature Citations (1)