JP7148423B2 - washing machine - Google Patents

Description

Embodiments of the present invention relate to washing machines.

In recent years, attention has been paid to fine bubbles (ultra-fine bubbles or microbubbles) having a diameter of, for example, several tens of nanometers to several hundreds of micrometers as microbubbles formed in water. For example, in Patent Document 1, in a washing machine, an ultra-fine bubble generator (hereinafter simply referred to as a "fine bubble generator") is provided in the water supply channel to generate a large number of fine bubbles, and the fine bubbles are included. A technique using fine bubble water for washing is disclosed. By using such fine-bubble water, the dispersibility of the detergent and the permeability to clothes can be improved, and an excellent washing action can be obtained.

JP 2018-42989 A

In the fine bubble generator described above, by rapidly reducing the pressure of the liquid that has flowed into the interior using the principle of a venturi tube, the gas dissolved in the liquid, such as air, is precipitated to generate fine bubbles. However, it is conceivable to provide an outside air introduction pipe in order to include more fine bubbles in the inflowing water. According to this, in addition to the fine bubbles generated by the venturi effect when the water that has flowed into the fine bubble generator passes through the throttle, The amount of fine bubbles can be increased by introducing outside air.
However, in such an outside air introduction type, water may leak from the outside air introduction pipe due to the closing operation of the water supply valve that opens and closes the water supply path, the freezing of the water supply path, and the like. That is, since the outside air introduction pipe has an open end for taking in the outside air, when backflow water occurs, the water may spill into the washing machine or splash on electrical equipment.

Therefore, the present invention provides a washing machine capable of solving the problem of water leaking from an external air introduction type fine bubble generator.

A washing machine according to an embodiment includes a water tank in which clothes are stored, a fine bubble generator that causes water supplied from a water source to the water tank to contain fine bubbles, and a drainage path that discharges water in the water tank. The fine bubble generator comprises a device main body having a narrowed portion, an outside air introduction path for introducing outside air into the water by a venturi effect when water flowing into the device main body passes through the narrowed portion, The outside air introduction path communicates with the main body of the device at its base end side and with the drainage area connected to the water tank or the drainage path at the tip side thereof.

1 is an external perspective view of a washing machine according to a first embodiment with a lid opened; FIG. Longitudinal sectional view showing the lid of the washing machine in a closed state Appearance perspective view showing the water supply mechanism with the detergent housing case omitted Perspective view showing the detergent storage case alone Longitudinal cross-sectional view of the water supply mechanism Cross-sectional view of the water supply mechanism along line XI-XI in FIG. An exploded perspective view of a fine bubble generating unit shown together with a water supply valve and a water injection case. Cross-sectional view in the vicinity of the fine bubble generation unit Enlarged sectional view of the fine bubble generation unit Longitudinal cross-sectional view of water supply mechanism along line XX in Fig. 3 A longitudinal sectional view showing the water supply mechanism of the second embodiment. The appearance perspective view which shows the water supply mechanism of 3rd Embodiment. The top view which shows the water supply mechanism of 4th Embodiment.

Hereinafter, a plurality of embodiments applied to a so-called vertical shaft type fully automatic washing machine will be described with reference to the drawings. In addition, in each embodiment, substantially the same components are denoted by the same reference numerals, and the description thereof is omitted.

<First Embodiment>
A first embodiment will be described with reference to FIGS. 1 to 10. FIG. As shown in FIG. 1, in the washing machine 1, an outer case 2 forming an outer shell has a rectangular box shape as a whole, and a top cover 3 is provided on the upper portion of the outer case 2. As shown in FIG.
As shown in FIG. 2, a water tank 4 capable of storing washing water is provided inside the outer box 2 . The water tank 4 is elastically supported by a well-known elastic suspension mechanism (not shown). Although not shown, a drain port is formed at the bottom of the water tank 4, and the drain port is connected to a drain channel having a drain valve as is well known. Such a drain valve and a drain path on the downstream side of the drain port correspond to a drain path for discharging the water in the water tank 4 . In addition, an overflow port 5 is provided at a position higher than the maximum water level in the upper portion of the back wall side of the water tank 4 . An overflow hose 6 for discharging water overflowing from the overflow port 5 is provided outside the water tank 4, and the tip of the overflow hose 6 is connected to the drainage channel.

In the water tub 4, a vertical shaft type washing tub 7 that also serves as a dewatering tub is rotatably provided. The washing tub 7 has a cylindrical shape with a bottom, and a large number of dewatering holes (not shown) are formed in its peripheral wall. At the upper end of the washing tub 7, for example, a liquid-filled rotary balancer 8 is attached. A pulsator 9 as a stirring means is arranged at the inner bottom of the washing tub 7 . Clothes (not shown) are accommodated in the washing tub 7, and a washing operation consisting of washing, rinsing, dehydration, etc. of the clothes is performed.

In addition, as shown in FIG. 2, a drive mechanism 10 having a well-known structure is arranged on the outer bottom of the water tank 4. As shown in FIG. Although detailed illustration and description are omitted, the drive mechanism 10 includes a washing machine motor, for example, an outer rotor type DC three-phase brushless motor, a tub shaft 11, an agitating shaft 12 penetrating the tub shaft 11, and the washing machine motor. A clutch mechanism or the like for selectively transmitting rotational driving force to the shafts 11 and 12 is provided. A washing tub 7 is connected to the upper end of the tub shaft 11 , and a pulsator 9 is connected to the upper end of the stirring shaft 12 .

The clutch mechanism uses, for example, a solenoid as a drive source, and is controlled by a control device 18, which will be described later. Thus, the clutch mechanism transmits the driving force of the washing machine motor to the pulsator 9 via the stirring shaft 12 while the washing tub 7 is stopped during washing and rinsing (washing process). Direct forward and reverse rotation drive. During dehydration (drying process), etc., the clutch mechanism transmits the driving force of the washing machine motor to the washing tub 7 via the tub shaft 11 while the tub shaft 11 and the stirring shaft 12 are connected to each other. The tank 7 (and the pulsator 9) is directly rotated in one direction at high speed.

As shown in FIGS. 1 and 2, a water tank cover 13 is attached to the top of the water tank 4 . The water tank cover 13 is provided with an opening 13a for putting in and out laundry at a substantially central portion, and an inner lid 14 for opening and closing the opening 13a is attached. Further, a water supply port 15 (see FIG. 2) for supplying water into the water tank 4 by a water supply mechanism, which will be described later, is provided in the rear part of the water tank cover 13 . Although not shown, a drying unit is provided in the top cover 3 for supplying dry air to the water tank 4 to dry the clothes. and a connection port to which the exhaust duct is connected, respectively.

As shown in FIGS. 1 and 2, the top cover 3 has a thin hollow box shape with an open bottom and an upper surface that slopes forward. At the center of the top cover 3, a substantially circular entrance 3a for laundry is formed above the washing tub 7. As shown in FIG. On the upper surface of the top cover 3, a rectangular panel-shaped lid 16 for opening and closing the entrance 3a is provided so as to be openable and closable with the lower rear side of the cover 3 being the base end side.

On the upper surface of the front side of the top cover 3, there is an operation panel provided with an operation unit for the user to turn on/off the power of the washing machine 1, perform various settings and instructions, and a display unit for performing necessary displays. 17 are provided. A control device 18 is provided on the back side of the operation panel 17 . The control device 18 is mainly composed of a computer, and controls the washing machine 1 as a whole to perform washing operation processes such as washing, rinsing, dehydration, etc., and a drying process by the drying unit.

As shown in FIG. 2, a water supply mechanism 20 is provided at the rear side of the top cover 3 to supply water supplied from a water supply source into the water tub 4 through a water supply path. As shown in FIG. 3, the water supply mechanism 20 includes a connection port 21, first, second, and third water supply paths 101, 102, and 103 extending in three directions from the connection port 21, and water supply paths 101 to 103, respectively. A water supply valve unit 22 for opening and closing, an ultra-fine bubble generator (hereinafter referred to as "fine bubble generation units 31 and 33" provided in the first water supply path 101 and the third water supply path 103, respectively. See FIG. 7), water injection A case 24 and the like are provided.

First, as shown in FIG. 3, the water injection case 24 has a horizontally long rectangular box shape as a whole and is made of a synthetic resin material. The water injection case 24 integrally has a lower case portion 24b in which the detergent accommodation case 23 (see FIG. 4) is accommodated, and an upper case portion 24a. The water injection case 24 is provided with the water supply valve unit 22 on the right end side and a pump arrangement portion 26a on the left end side. A water supply pump 26 (illustrated only in FIG. 5) is assembled to the pump arrangement portion 26a.

As shown in FIG. 3, the water supply valve unit 22 is provided with a connection port 21 at the top. The connection port 21 is connected to the tip of a connection hose (not shown) connected to a water faucet serving as an external water source. The water supply valve unit 22 includes, for example, a first water supply valve 27 as a main opening/closing valve, a second water supply valve 28 as a softening agent opening/closing valve, and a third water supply valve 28 as a lower opening/closing valve. The water supply valve 29 and three on-off valves are provided. Among them, the first water supply valve 27 and the second water supply valve 28 positioned on the upper side in FIG. 3 open and close the first water supply path 101 and the second water supply path 102, respectively. The third water supply valve 29 located on the lower side opens and closes the third water supply path 103 .

Out of these, the outlet 27a of the first water supply valve 27 that constitutes the first water supply path 101 is connected to the inlet 24 _IN1 on the right side wall of the water injection case 24 via the fine bubble generating unit 31 as shown in FIG. ing. By opening the first water supply valve 27, the water supplied from the connection port 21 passes through the fine bubble generation unit 31 and flows from the inlet portion 24 _IN1 to the main flow path in the water injection case 24 (the upper case portion 24a). supplied to M. At this time, the water flowing through the first water supply path 101 passes through the fine bubble generation unit 31 and is supplied into the water injection case 24 as fine bubble water containing a large amount of fine bubbles. 6 is a cross-sectional view taken along line XI-XI of FIG. 5, and for convenience of explanation, the upper case portion 24a is cut away. Fine bubble water will be described later in detail.

As shown in FIGS. 6 and 7, the outlet 28a of the second water supply valve 28, which constitutes the second water supply path 102, is connected to an inlet pipe (hereinafter referred to as "inlet 24 _IN2 ") on the right side wall of the water injection case 24. , and the water supplied from the connection port 21 is supplied to the softener flow path S by opening the second water supply valve 28 . In FIG. 6, the flow of water in each of the channels S and M is indicated by thick arrows. It is assumed that the flow path S and the three-dimensional crossing are performed.

On the other hand, an outlet pipe 26b (shown only in FIG. 5) is connected to the water supply pump 26, and the outlet pipe 26b is connected to an inlet portion 24 _IN4 (two points in FIGS. (see dashed circle). Bath water taken from the water supply pump 26 is supplied from the inlet portion 24 _IN4 to the pump flow path P (see FIG. 6) through the outlet pipe 26b.

Further, as shown in FIG. 7, the outlet 29a of the third water supply valve 29 constituting the third water supply path 103 is connected to the inlet 24 _IN3 of the right side wall of the water injection case 24 via the fine bubble generation unit 33. ing. By opening the third water supply valve 29 , the water supplied from the connection port 21 is supplied from the inlet portion 24 _{IN 3} through the fine bubble generation unit 33 to the lower flow path D in the water injection case 24 . The lower flow path D is a flow path through which water flows into the space between the lower case portion _24b of the water injection case 24 shown in FIG. Water is allowed to flow in a direction (a direction perpendicular to the plane of FIG. 5).

The water supply pump 26 and the water supply valve unit 22 are controlled by the controller 18 . In addition, the main channel M and its inlet 24 _IN1 , the softening agent channel S and its inlet 24 _IN2 , and the lower channel D and its inlet 24 _IN3 are connected to the first water supply channel 101 and the first water supply channel 101, respectively. It is included in the second water supply route 102 and the third water supply route 103 .

FIG. 4 is a perspective view showing the detergent storage case 23 alone pulled out from the front opening 25 (see FIGS. 1 and 3) of the water injection case 24. As shown in FIG. The detergent storage case 23 has a front lid 34 on the front surface that closes the front opening 25 when stored in the water injection case 24 . A handle portion 34a (see FIG. 5) is provided on the front lid 34, and the storage case 23 can be pulled out by putting a hand on the handle portion 34a.

A powder detergent storage portion 35, a liquid detergent storage portion 36, and a softener storage portion 37 are integrally provided side by side on the back side of the front lid 34 of the detergent storage case 23. As shown in FIG. Each of these accommodating portions 35 to 37 has a rectangular container shape with an open top. As shown in FIG. 4, on the upper surface of the front lid 34, there are detergent storage units for storing "powder detergent", "liquid detergent" and "softener" at positions corresponding to these storage units 35 to 37, respectively. is provided.

Among them, the powder detergent storage section 35 on the left has a bottom surface that slopes gently downward toward the rear, and has an outlet 35a at the rear side of the bottom surface. When water is poured into the powder detergent containing portion 35 from above, the water flows backward along the bottom surface and is discharged from the outlet 35a.

The liquid detergent storage part 36 has an outflow hole 36a (see FIG. 5) formed in the lowest part of its bottom surface, and a siphon part 38 is provided in the upper part of the outflow hole 36a. As is well known, the siphon portion 38 has a tubular portion 38a connected to the outflow hole 36a and a cap portion 38b (not shown in FIG. 5) fitted from above. When water is poured into the liquid detergent containing portion 36 from above and the water level gradually rises, the water level rises between the outer periphery of the cylindrical portion 38a and the inner periphery of the cap portion 38b accordingly, and the water flows into the cylindrical portion. After passing the upper end of 38a, the water in the accommodating portion 36 passes through the cylindrical portion 38a and is discharged from the outflow hole 36a by the siphon principle.

The softener container 37 also has an outflow hole (not shown) formed at the lowest portion of its bottom surface, and a siphon part 39 similar to the siphon part 38 is provided above the outflow hole. Therefore, when water is poured into the softener containing portion 37 from above, the water in the containing portion 37 passes through the cylindrical portion of the siphon portion 39 and is discharged from the outflow hole according to the siphon principle.

The interior of the water injection case 24 of this embodiment is partitioned into an upper case portion 24a and a lower case portion 24b by a horizontal partition wall 40 shown in FIG. The interior is partitioned by a vertical partition wall 41 shown in FIG. In other words, the areas within the water injection case 24 include an area A1 of the upper case portion 24a, a main area _A2-1 of the lower case portion 24b (also referred to as an arrangement area _A2-1 of the detergent housing case 23), and A remaining right area _A2-2 (an area in which the detergent housing case 23 is not arranged) is provided.

Among them, a vertical rib 40a is provided in a region A1 of the upper case portion 24a as shown in FIG. The ribs 40a extend vertically from the lateral partition wall 40 to the ceiling wall 30, and are bent in a labyrinthine manner within the case portion 24a as indicated by hatching in FIG. extend to

FIG. 6 shows the positional relationship between the flow paths M to P and the storage portions 35 to 37 of the detergent storage case 23. As shown in FIG. The channels M to P have a plurality of water injection holes 35h, 36h, and 37h penetrating the horizontal partition wall 40 in its plate thickness direction. Of these, the water injection hole 35h is a hole within the range H35 corresponding to the powder detergent storage portion ₃₅ , the water injection hole 36h is a hole within the range H36 corresponding to the liquid detergent storage portion ₃₆ , and the water injection hole 37h is It is a hole within the range H ₃₇ corresponding to the softener containing portion 37 . As a result, water is supplied to the flow paths M to P in the form of a shower from the water injection holes 35h to 37h. Among the flow paths M to P, the main flow path M is a flow path that guides water introduced from the inlet portion 24 _IN1 to flow paths M1, M2, M3, and M4, as indicated by arrows in FIG. including.

On the other hand, as shown in FIG. 3, the main region _A2-1 of the lower case portion 24b is opened at the front side by the front opening 25, and the right end region _A2-2 is opened at the front side by the front opening 25a. there is Bottom walls 43, 43a of the lower case portion 24b (areas A2 _-1 , A2 _-2 ) are formed with water outlets 45, 45a positioned on the front side. Each bottom wall 43, 43a gently slopes downward toward the outlets 45, 45a. The outlets 45, 45a are connected to the water supply port 15 (inside the water tank 4) via a bellows-shaped hose 15a (see FIG. 1).

The bottom wall 43 of the main area _A2-1 in the lower case portion 24b is separated below the detergent housing case 23 shown in FIG. 5 to secure a space for water flow. This water passage space is a bottom water passage portion 44 that communicates with the inlet portion 24 _IN3 (see FIG. 7). The water discharged from is directed to the outlet 45.

On the other hand, the right end region _A2-2 of the lower case portion 24b is a narrow, substantially rectangular parallelepiped space separated from the main region _A2-1 by the vertical partition wall 41. As shown in FIG. This area _A2-2 is a drainage area (hereinafter referred to as "drainage area _A2-2 ") connected to the water tank 4 through the hose 15a.

Specifically, the drainage area _A2-2 of the lower case portion 24b projects to the right with respect to the upper case portion 24a (see FIG. 3). It forms a space as shown. This drainage area _A2-2 is stepped so as to leave a space for arranging the fine bubble generating unit 33 with the bottom wall 43a having the outlet 45a, the ceiling wall 46a located below the fine bubble generating unit 31, and the fine bubble generating unit 33. It is surrounded by the formed rear wall 47a, the vertical partition wall 41 as the left wall, and the right wall 48a (see FIG. 7). Here, the detergent storage case 23 has a front lid 34 that covers the front openings 25 and 25a of the areas _A2-1 and _A2-2 when the storage parts 35 to 37 are arranged in the area _A2-1 . state (see FIGS. 5 and 6). Even in such a state, the drainage area _A2-2 can drain water to the water tank 4 through the hose 15a on the outlet 45a side of the bottom wall 43. FIG.

As shown in FIG. 10, the ceiling wall 46a of the drainage area _A2-2 is provided with an insertion hole 51 at a position slightly forward of the fine bubble generating unit 31. As shown in FIG. The insertion hole 51 is formed by partially cutting out the ceiling wall 46a and the right wall 48a as a hole through which an outside air introduction pipe 60 of the fine bubble generating unit 31, which will be described later, can be inserted (see FIG. 7). ). Further, an insertion hole 53 is provided in the rear wall 47a of the drainage area _A2-2 so as to be positioned in the stepped portion of the rear wall 47a. The insertion hole 53 is formed by partially cutting out the rear wall 47a and the right wall 48a as a hole through which the outside air introduction pipe 60 of the fine bubble generating unit 33 can be inserted (FIGS. 7 and 10). reference).

Next, the fine bubble generation units 31 and 33 will be described. As shown in the exploded perspective view of FIG. 7, both the fine bubble generating units 31 and 33 are configured using the same parts, so the fine bubble generating unit 31 will be mainly described below. 8 is a cross-sectional view along the central axis of the outside air introduction pipe 60, showing the fine bubble generating unit 31 and its vicinity, and FIG. 9 shows the fine bubble generating unit 31 in an enlarged manner.

As shown in FIGS. 7 and 8, the fine bubble generating unit 31 is provided between the first water supply valve 27 of the first water supply path 101 and the inlet 24 _IN1 of the water injection case 24 . In this case, the fine bubble generating unit 31 is assembled between the outlet 27a of the first water supply valve 27 and the inlet 24 _IN1 of the water injection case 24 so as to be sandwiched between them. The fine bubble generating unit 33 is assembled between the outlet 29a of the third water supply valve 29 and the inlet 24 _IN3 of the water injection case 24 so as to be sandwiched therebetween, similarly to the fine bubble generating unit 31. ing.

As shown in FIG. 8, the outlet portion 27a of the first water supply valve 27 has a tubular shape and extends toward the inlet portion 24 _IN1 side of the water injection case 24 (leftward in the figure). The distal end portion of the outlet portion 27a has a step formed on the outer peripheral surface of the outlet portion 27a so that the diameter of the outlet portion 27a becomes gradually smaller. . The inlet 55a of the fine bubble generating unit 31 (on the side of the flange portion 55b in FIG. 9, which will be described later) is fitted to the inner peripheral portion of the first small diameter portion 27b.

On the other hand, the inlet portion 24 _IN1 of the water injection case 24 protrudes rightward in the figure toward the first water supply valve 27 side. A step is formed on the outer peripheral surface of the inlet portion 24 _IN1 between the small diameter portion 54a on the distal end side and the large diameter portion 54b on the proximal end side, and the O-ring 63 is engaged with this step. A tapered portion 54c that widens toward the tip is formed on the inner peripheral surface of the inlet portion 24 _IN1 , and the outflow port 56a of the fine bubble generating unit 31 is concentrically fitted therein.

The fine-bubble generating unit 31 is a fine-bubble generating device that utilizes the principle of a venturi tube, and includes a device main body 55 and an outer shell member 56 that accommodates the device main body 55 . As shown in FIG. 9, the device main body 55 and the shell member 56 are combined to form a channel 57 through which water flows in the direction of the arrow.

The flow path 57 has an inlet 55a at the opening of the apparatus main body 55 on the right side in FIG. 9, and an outlet 56a at the opening of the outer shell member 56 on the left. A narrowed portion 58 is formed in the intermediate portion of the flow path 57 so as to protrude inward. The channel 57 is formed in a tapered shape in which the cross-sectional area of the channel gradually decreases from the inflow port 55a in the device main body 55, and the rest of the channel 57 is formed in a straight shape with a substantially constant inner diameter except for the constricted portion 58. As shown in FIG. As described above, the fine bubble generating unit 31 includes the device main body 55 integrally having the throttle portion 58 that narrows the cross-sectional area of the flow channel 57 on the upstream side of the flow channel 57, and the device main body 55 on the downstream side of the flow channel 57. are combined with an outer shell member 56 that forms the outer shell of the unit 31.

Among them, the device main body 55 is made of synthetic resin, for example, and is integrally provided with a body portion 55c having a slightly smaller diameter on the tip side (left side in FIG. 9) of the flange portion 55b. Further, a small diameter portion 55d having a smaller diameter is integrally provided. The outer diameter dimension of the flange portion 55b corresponds to the outer diameter dimension of the distal end side of the outlet portion 27a of the first water supply valve 27 (see FIG. 8). 27a abut.

An upstream half of the flow path 57 is formed inside the apparatus main body 55, and the constricted portion projecting from the inner peripheral surface of the flow path 57 toward the center is provided at the tip of the small diameter portion 55d. 58 are integrally formed. Although detailed illustration is omitted, for example, the constricted portion 58 is formed at four locations at intervals of 90 degrees on the inner peripheral surface of the small diameter portion 55d. Consists of four protrusions of pointed form. With this projecting portion, the flow path 57 in the constricted portion 58 is formed in a cross shape (X-shaped flow path) when viewed from the axial direction of the device main body 55 (the direction of the arrow in FIG. 9), with each tip of the projecting portion facing each other with a slight gap. ), and the channel cross-sectional area is the narrowest at this portion.
A through hole 55e (see FIGS. 8 and 9) is formed in the device main body 55 at a position corresponding to the outside air introduction pipe 60 in the small diameter portion 55d. The through-hole 55e extends in a direction orthogonal to the axial direction of the small-diameter portion 55d (direction connected to the outside air introduction pipe 60), and penetrates so as to merge with the flow path 57 in the narrowed portion 58. As shown in FIG.

The outer shell member 56 is made of, for example, a transparent material (transparent synthetic resin material) whose interior is visible, and has a cylindrical shape with a slightly constricted central portion in the axial direction (see FIG. 7). An outside air introduction pipe 60 is integrally provided in the portion.

On the inner peripheral surface of the outer shell member 56 on one end side (the right half in FIG. 9), there is a step that gradually increases in diameter toward the right side from the portion of the first small diameter portion 56b that communicates with the outside air introduction pipe 60. are formed, and are referred to as a first small diameter portion 56b, a second small diameter portion 56c, a third small diameter portion 56d, and a fourth small diameter portion 56e in order from the small diameter side. Of these, the first small diameter portion 56b of the outer shell member 56 has an inner diameter corresponding to the outer diameter of the small diameter portion 55d of the device main body 55 (dimension to fit with the small diameter portion 55d). A space is formed to accommodate the distal end side of the small portion 55d. 8 and 9, the second small diameter portion 56c and the fourth small diameter portion 56e of the outer shell member 56 form steps 59c and 59d for engaging the O-rings 61 and 62, respectively. , the body portion 55c of the device main body 55 and the second small diameter portion 27c of the first water supply valve 27, while ensuring watertightness and airtightness through the O-rings 61 and 62. As shown in FIG. In this way, the apparatus main body 55 and the tip end side of the outlet portion 27a of the first water supply valve 27 are abutted against the inner peripheral surface of the outer shell member 56 from the right side, and are watertight and airtightly fitted.

The other end side (the left part in FIG. 9) of the outer shell member 56 is integrally provided with an inner cylindrical portion 56e forming the outflow port 56a and an outer cylindrical portion 56f on the outer peripheral side thereof. As shown in FIG. 8, the outer diameter dimension of the inner cylindrical portion 56e and the inner diameter dimension of the outer cylindrical portion 56f correspond to the inner diameter dimension of the inlet portion 24 _IN1 and the outer diameter dimension of the large diameter portion 54b of the water injection case 24, respectively. there is A tapered portion 56g corresponding to the tapered portion 54c of the inlet portion 24 _IN1 is formed on the outer peripheral portion of the inner cylindrical portion 56e so as to be located on the proximal end side. The outer shell member 56 is inserted into the inlet portion 24 _IN1 of the water injection case 24 to a position where the tapered portion 56g and the tapered portion 54c of the inlet portion 24 _IN1 abut. As a result, the inner cylindrical portion 56e and the outer cylindrical portion 56f are watertight and airtightly fitted to the inlet portion 24 _IN1 in which the O-ring 63 is interposed.

Thus, in the fine bubble generation unit 31, the shell member 56 functions as a connection member that connects the outlet 27a of the first water supply valve 27 and the inlet 24 _IN1 of the water injection case 24, and The device main body 55 is sandwiched between the outlet 27 a of the water supply valve 27 and the shell member 56 .

As shown in FIG. 7, also in the fine bubble generating unit 33, the outer shell member 56 functions as a connecting member that connects the outlet 29a of the third water supply valve 29 and the inlet 24 _IN3 of the water injection case 24. In addition, the device body 55 is sandwiched between the outlet portion 29 a of the third water supply valve 29 and the outer shell member 56 . In addition, since the outer shell member 56 of the fine bubble generating units 31 and 33 is made of a transparent material, the device main body 55 and the O-rings 61 to 63, which are housed in the assembly as shown in FIG. etc. can be seen through.

An external air introduction pipe 60 is provided integrally with the outer shell member 56 at a substantially intermediate portion in the axial direction thereof. The outside air introduction pipe 60 has a circular tubular shape, for example, and is provided so as to extend radially outward from the outer peripheral surface of the outer shell member 56 . In the fine bubble generation unit 31 of the present embodiment, the outside air introduction pipe 60 is directly inserted through the insertion hole 51 of the water injection case 24, and the outside air introduction pipe 60 is aligned with the insertion hole 51 as shown in FIG. It faces downward and obliquely forward. That is, the fine bubble generation unit 31 is configured such that the outside air introduction pipe 60 is provided downward so as to face downward from the horizontal plane.

Further, in the fine bubble generating unit 33 as well, the outside air introduction pipe 60 is provided downward so as to be directly inserted into the insertion hole 53 of the water injection case 24 . As a result, the tip ends of the outside air introduction pipes 60, 60 of the fine bubble generating units 31, 33 are directly connected to the common drain area _A2-2 in the water injection case 24. As shown in FIG. In addition, "α" in the figure represents the angle formed by the outside air introduction pipe 60 and the horizontal plane.

On the other hand, the base end side of the outside air introduction pipe 60 communicates with the inner peripheral surface of the first small diameter portion 56b of the outer shell member 56 (that is, the storage space of the device main body 55) as shown in FIG. The inside of the outside air introduction pipe 60 has a funnel shape with a small hole portion 60a on the proximal end side and an enlarged diameter portion 60b on the other side in the same sectional view. The enlarged diameter portion 60b is set larger than the hole portion 60a. The base end side (small hole portion 60 a side) of the outside air introduction pipe 60 faces the outer peripheral surface (the through hole 55 e ) of the small diameter portion 55 d of the device main body 55 inside the outer shell member 56 . The small hole portion 60a and the through hole 55e are aligned by forming a D-cut surface (not shown) on the outer peripheral surface of the apparatus main body 55 and engaging the inner peripheral surface (D-cut hole portion not shown) of the outer shell member 56, for example. A well-known method such as performing by Therefore, on the base end side of the outside air introduction pipe 60 , it merges with the flow path 57 of the narrowed portion 58 through the through hole 55 e of the device main body 55 . Thus, in the fine bubble generating unit 31 , the outside air introduction pipe 60 is configured as an outside air introduction path capable of introducing outside air (outside air) into the apparatus main body 55 .

In the fine bubble generating unit 31 described above, when water flows into the flow path 57 from the inlet 55a by opening the first water supply valve 27, the cross-sectional area of the flow path is narrowed down to the narrowed portion 58, so that the Venturi effect The flow velocity is increased and the pressure is dropped sharply. As a result, a large amount of gas, such as air, dissolved in water can be precipitated as fine bubbles. These fine bubbles are generated in large quantities as ultra-fine bubbles with a diameter of about 50 nm to 1 μm and fine bubbles containing microbubbles with a diameter of about 1 μm to several hundred μm. bubble water) is discharged from the outlet 56a.
In addition, due to the venturi effect, outside air is introduced into the fine bubble water through the outside air introduction pipe 60 into the negative pressure region of the narrowed portion 58, where it is subdivided into fine bubbles. can be included.

Next, the operation of the above configuration will be described.
To start the washing operation, the user puts clothes in the washing tub 7, pulls out the detergent housing case 23, and puts powder detergent into the powder detergent housing portion 35 (or puts liquid detergent into the liquid detergent housing portion 36). do). Moreover, when using a softening agent, the softening agent is thrown into the softening agent accommodating part 37 beforehand. After that, after housing the detergent housing case 23 in the water injection case 24 , the user performs a start operation on the operation panel 17 .

As a result, the control device 18 controls each mechanism of the washing machine 1 based on input signals from each sensor and pre-stored control programs according to user's setting operation etc. on the operation panel 17, and performs well-known washing. , rinsing, and spin-drying are performed automatically. It should be noted that the user can specify water supply such as bath water using the water supply pump 26 in addition to water supply using normal tap water by setting the operation panel 17. A description of the washing operation using water is omitted.

At the start of the washing process, the controller 18 opens the first water supply valve 27 . As a result, the tap water passes through the fine bubble generating unit 31 , and a large amount of fine bubbles are generated at that time, and the fine bubble water is supplied into the water injection case 24 . The fine bubble water flows through the main channel M in the water injection case 24 while dissolving the detergent in the detergent storage case 23 , and is supplied into the water tank 4 .

In this case, the fine _bubble water supplied from the fine bubble generation unit 31 shown in FIG. is poured into the liquid detergent container 36 like a shower. The fine-bubbled water, together with the liquid detergent stored in the liquid detergent storage section 36, flows through the siphon section 38 and the outflow hole 36a (see FIG. 5) down to the bottom water passage section 44, and is supplied to the water tank 4 through the outlet 45. be done.

In the main flow path M, the fine bubble water guided from M1 to M2 is poured into the powder detergent storage section ₃₅ in a shower form from the water injection hole 35h in the range H35 corresponding to the powder detergent storage section 35. be The fine bubble water melts the powdered detergent contained in the powdered detergent container 35, flows down from the outlet 35a (see FIG. 4) to the bottom water passage 44, and is supplied to the water tank 4 through the outlet 45. .

Furthermore, in the main channel M, the fine bubble water guided from M2 to M3 and M4 is poured like a shower from the water injection holes in the range _H33 corresponding to the rear of the detergent housing case 23 (see FIG. 6). reference). The fine bubble water flows down to the bottom water passage 44 through the space between the rear edge of the detergent housing case 23 and the rear wall of the lower case portion 24b (see FIG. 5). Therefore, this fine bubble water joins with the water flowing out from the outlets 35a and 36a of the storage portions 35 and 36 at the bottom water passage portion 44, and promotes the flow through the outlet 45 and dropping into the water tub 4. .

Also, in this case, the third water supply valve 29 is opened by the control device 18 . As a result, the tap water passes through the fine bubble generating unit 33 and becomes fine bubble water and is supplied into the water injection case 24 (see the lower flow path D in FIG. 7). The fine bubble water is vigorously supplied in the lateral direction (direction intersecting the flow flowing down the bottom water passage 44) through the bottom water passage 44 without passing through the detergent housing case 23 in the water injection case 24. be. Therefore, the liquid detergent and powder detergent that have flowed down from the water injection case 24 can be sufficiently dispersed and dissolved.

After the washing process ends, the second water supply valve 28 is opened to supply water through the softener flow path S in the rinsing process. In this case, by opening the second water supply _valve 28 shown in FIG. It is poured into the agent containing portion 37 . As a result, while the softener contained in the softener container 37 is being dissolved in the water, the water in which the softener is dissolved is discharged from the outflow hole through the siphon portion 39, flows down to the bottom water passage portion 44, and flows through the outlet 45. It is supplied to the water tank 4 through.

The fine bubbles described above undergo Brownian motion, which causes irregular motion in water, and the speed of the fine bubble is faster than the floating speed, so they have the property of remaining in the liquid for a long time. Since the surface of the fine bubbles is negatively charged, it absorbs the clumps of detergent (surfactant) contained in the washing water while loosening them, thus improving the dispersibility of the detergent. fulfill Fine bubbles repel each other and do not combine. In addition, the fine bubbles that have adsorbed the detergent in this way can easily enter into the gaps (for example, 10 μm) between the fibers of the clothes, efficiently carry the detergent into the clothes, and remove the dirt. Suppresses reattachment to

In the present embodiment, fine bubble water is generated in both of the fine bubble generation units 31 and 33, and then the detergent is added to the fine bubble water. can be distributed in Conversely, if fine bubbles are generated after the detergent is added to the water, the washing water will be excessively foamed and fine fine bubbles cannot be sufficiently generated, resulting in a decrease in the concentration of fine bubbles. There is

Further, in the fine bubble generating units 31 and 33 using the venturi effect, it is necessary to flow water at a relatively high water pressure in order to generate fine air bubbles. In this regard, tap water is generally used as a water supply source for the washing machine 1, and by using this tap water pressure without lowering it as much as possible, the fine bubble generating units 31 and 33 can generate water without using special pressurizing means. , it is possible to effectively generate a large amount of fibrous. In this embodiment, the direction of flow of water discharged from the outlet 27a of the first water supply valve 27 and the direction of flow of water in the flow path 57 of the fine bubble generation unit 31 are the same (see FIG. 8), Since the direction of flow of water discharged from the outlet 29a of the third water supply valve 29 and the direction of flow of water in the channel 57 of the fine bubble generation unit 31 are configured to be the same, the water supply path 101 , 103 to the fine bubble generating units 31 and 33, the resistance of each flow path is small, and the decrease in water pressure can be suppressed to effectively generate fine bubbles.

Thus, by performing the washing step using the washing water in which the detergent is dissolved in the fine bubble water containing a large amount of fine bubbles, an excellent washing effect can be obtained. The water supply mechanism 20 is provided with a second water supply path 102 that does not pass through the fine bubble generating units 31 and 33, and water containing no fine bubbles is supplied to the water tank 4 during rinsing. It is possible to supply water in a short time by increasing the flow rate of the water.

By the way, after the inside of the water tub 4 reaches a predetermined water level in the above-described washing process, the first water supply valve 27 and the third water supply valve 29 are closed by the control device 18 when water supply is finished. At this time, the pressure that had decreased due to the venturi effect in the fine bubble generating units 31 and 33 returns to the original pressure, and the water in the flow path 57 flows back from the base end side to the tip side of the outside air introduction pipe 60. . Although the backflow in the outside air introduction pipe 60 when the water supply valves 27 and 29 are closed is relatively small, it is assumed that the backflow water flows out from the outside air introduction pipe 60 . Further, for example, when the water supply paths 101, 103 on the water injection case 24 side are frozen and the insides of the water supply paths 101, 103 are clogged, even if the first and third water supply valves 27, 29 are opened, normal A situation in which a relatively large amount of backflow water overflows from the outside air introduction pipe 60 is also assumed.

In this regard, in the present embodiment, as shown in FIG. 10, the tip end side of the outside air introduction pipe 60 of each of the fine bubble generating units 31 and 33 is directly inserted through the insertion holes 51 and 53 of the water injection case 24 to provide common drainage. It communicates with the area _A2-2 . Therefore, even if the water in each channel 57 flows back through the outside air introduction pipe 60, it will be drained to the drain area _A2-2 as it is. In the water injection case 24, the water discharged from the outside air introduction pipe 60 to the drainage area _A2-2 is supplied to the water tank 4 through the hose 15a on the outlet 45a side of the bottom wall 43. FIG. Note that the hose 15a is not always necessary. For example, even if the hose 15a is omitted, the water in the drainage area _A2-2 flows directly from the outlet 45a of the water injection case 24 to the water tank 4.

As described above, the fine bubble generating units 31 and 33 of the present embodiment are configured by the device main body 55 having the narrowed portion 58 and the venturi effect when the water flowing into the device main body 55 passes through the narrowed portion 58. and an outside air introduction pipe 60 for introducing outside air into the water. _-2 .
According to this, for example, in the fine bubble generating units 31 and 33, even if backflow water occurs from the proximal end side to the distal end side of the outside air introduction pipe 60, this is discharged to the drainage area _A2-2 and the water tank 4, and it is possible to prevent the water from spilling into the washing machine 1 and splashing on electrical equipment.

Incidentally, unlike the present embodiment, the outlet 45a of the drainage area _A2-2 and the overflow hose 6 may be connected by a drainage pipe (not shown). Although not shown, the outlet 45a of the drainage area _A2-2 and the drainage channel may be connected by a drainage pipe. In either case, the water drained into the drain area _A2-2 can flow through the drain pipe to the overflow hose 6 or drain.

The drainage area _A2-2 is located in the water injection case 24 for supplying water to the water tank 4, and is separated from the arrangement area _A2-1 of the detergent storage units 35 to 37 arranged in the water injection case 24. A water discharge area _A2-2 is provided as another area provided. According to this, even if the backflow water in the fine bubble generating units 31 and 33 is drained using the water injection case 24, the water can be partitioned so as not to splash on the detergents in the detergent accommodating parts 35-37. As in the present embodiment, the fine bubble generation units 31 and 33 are provided adjacent to the water injection case 24, and the outside air introduction pipe 60 is directly faced to the drainage area _A2-2 , so that the backflow water drainage path is minimized. It can be shortened, resulting in a compact arrangement.

Since each of the outside air introduction pipes 60 in the plurality of fine bubble generating units 31 and 33 is configured to communicate with the common drainage area _A2-2 , only one drainage area _A2-2 is required.
Since the outside air introduction pipe 60 is provided downward as a tubular outside air introduction passage, even if backflow water occurs, the water can flow down without remaining in the outside air introduction pipe. In addition, "downward" means the direction in which the tip of the outside air introduction pipe is positioned below the horizontal plane, or the direction in which the tip is positioned directly below, and the angle formed with the horizontal plane is the angle α shown in FIG. is not limited to

The fine bubble generating units 31 and 33 are provided with an outer shell member 56 which is provided with an outside air introduction pipe 60 and accommodates the apparatus main body 55. The outer shell member 56 is made of a transparent material that allows the inside thereof to be visually recognized. According to this, even when the fine bubble generating units 31 and 33 are incorporated in the washing machine 1, the device main body 55 inside can be seen through. Therefore, for example, even if the device body 55 and the O-rings 61 to 63 are housed in the outer shell member 56 as in the present embodiment, it is possible to determine if the device body 55 and the O-rings 61 to 63 are missing. can be confirmed without dismantling the fine bubble generating units 31 and 33.

The outer shell member 56 in the fine bubble generating units 31 and 33 includes water supply valves 27 and 29 connected to a water source, a water injection case 24 that receives water supplied by the water supply valves 27 and 29 and supplies water to the water tank 4, , and between the water supply valves 27 and 29 and the outer shell member 56, the apparatus main body 55 is provided. According to this, it is possible to efficiently generate fine bubbles using a relatively high water pressure, and to improve workability in assembling the fine bubble generating units 31 and 33 . Moreover, when the outer shell member 56 is configured as a connection member between the water supply valve and the water injection case 24 as in the present embodiment, the number of parts can be reduced as much as possible.

<Second embodiment>
FIG. 11 shows a longitudinal side view of a water supply mechanism 20' showing a water injection case 24' and a fine bubble generation unit 31' of the second embodiment. For convenience, hatching is omitted in FIG. The water supply mechanism 20' of the second embodiment differs from the water supply mechanism 20 of the first embodiment in the following points.

That is, the case portion 24b on the lower side of the water injection case 24' is not partitioned by the vertical partition wall 41 inside, and is defined as an arrangement area _A2-1 for the detergent housing case 23 without the drainage area _A2-2 . (See water injection case 24' in FIG. 12). A connecting member 65 is provided instead of the fine bubble generating unit 33 between the outlet 29a of the third water supply valve 29 and the inlet _24IN3 of the water injection case 24'. The connection member 65 has a tubular shape (see FIG. 11) and is used as a tubular member for passing the tap water supplied from the outlet 29 a of the third water supply valve 29 to the inlet 24 _{IN 3} of the water injection case 24 .

As shown in FIG. 11, the fine bubble generating unit 31' is installed so that the tip of the external air introduction pipe 60' in the outer shell member 56 faces upward. Such an outside air introduction pipe whose tip is directed upward is referred to as an "outside air introduction pipe 60'". The outside air introduction pipe 60' is positioned, for example, above the device main body 55 and extends at an angle β perpendicular to the horizontal plane, that is, vertically upward.

In this case, the small hole portion 60a and the enlarged diameter portion 60b (see FIG. 9) of the outside air introduction pipe 60' are formed as a volume portion, and the backflow water is stored therein. That is, in the outside air introduction pipe 60', the combined volume of the small hole portion 60a and the enlarged diameter portion 60b is the backflow water flowing from the lower end side to the upper end side of the outside air introduction pipe 60' as the first water supply valve 27 is closed. It is set to a size that can store the amount of the backflow water (for the freshness) when this occurs. Therefore, if the outside air introduction pipe 60' is provided upward as shown in FIG. 11, the backflow water stays in the small hole portion 60a and the enlarged diameter portion 60b and does not overflow from the tip side. It's becoming The backflow water stored in the outside air introduction pipe 60' is released when the static water pressure due to gravity exceeds the pressure in the flow path 57, or when the first water supply valve 27 is opened after that, the fine bubble generation unit 31 ' returns to the original flow path 57 .

As described above, the outside air introduction pipe 60' of the second embodiment is provided upward as a tubular outside air introduction passage. in the case of backflow associated with the closing action of the valve), the backflow water can be prevented from overflowing. In addition, "upward" means the direction in which the tip of the outside air introduction pipe is positioned above the horizontal plane, or the direction in which it is positioned directly above, and the angle formed with the horizontal plane is the angle shown in FIG. It is not limited to β (see FIG. 13 described later).

Since the outside air introduction pipe 60' has a small hole portion 60a and an enlarged diameter portion 60b having a volume capable of storing backflow water inside, the backflow water can be stored with that volume. The volume portion is not limited to the funnel-shaped small hole portion 60a and the enlarged diameter portion 60b shown in the cross-sectional view of FIG. , the overall diameter and axial dimensions of the outside air introduction pipe 60' may be appropriately changed in accordance with the amount of backflow water.

<Third Embodiment>
FIG. 12 is a perspective view of the water supply mechanism 20' shown together with the fine bubble generating unit 70 of the third embodiment. Regarding the fine bubble generation unit 70 of the third embodiment, differences from the fine bubble generation unit 31' of the second embodiment will be described.

A fine bubble generating unit 70 of the third embodiment has a bowl member 71 connected to the distal end side of the outside air introduction pipe 60 . The bowl member 71 is made of the same transparent material as the outer shell member 56, for example, and has a bowl shape with an open upper surface as shown in FIG. Although detailed illustration is omitted, the bottom portion 71a of the bowl member 71 is formed as a through hole portion, and is connected to the tip portion of the outside air introduction pipe 60' by a cylindrical member 72 disposed around the outside air introduction pipe 60'. It is connected to the. As a result, in the fine bubble generating unit 70, outside air is introduced into the flow path 57 on the device main body 55 side through the bowl member 71 and the outside air introduction pipe 60'.

In addition, in the fine bubble generating unit 70, the interior of the bowl member 71 forms a space 73 capable of storing a predetermined amount of water. , a large amount of water can be stored for the volume of the bowl member 71 . Therefore, even if the amount of backflow water that exceeds the volume of the outside air introduction pipe 60 ′ flows, the backflow water can be stored in the bowl member 71 . The water stored in the bowl member 71 and the outside air introduction pipe 60' returns to the original flow path 57 as described in the second embodiment.

As described above, the outside air introduction pipe 60' of the third embodiment communicates with the device main body 55 at its proximal end, and communicates with the space 73 of the bowl member 71 capable of storing a predetermined amount of water at its distal end. According to this, in the fine bubble generating unit 70 , even if water flows backward through the outside air introduction pipe 60 ′, it can be stored in the space 73 of the bowl member 71 . Further, by appropriately setting the size of the space 73 of the bowl member 71 in anticipation of the amount of backflow water, it is possible to solve the problem that the backflow water leaks out and splashes on electrical equipment. It has the same effect.
The external air introduction pipe 60' and the bowl member 71 in the shell member 56 may be integrally formed. Even in this case, the outside air introduction pipe 60' and the bowl member 71 function as a volume part, and the backflow water can be stored inside. Moreover, the space 73 capable of storing a predetermined amount of water may be formed by other hollow member than the bowl member 71 .

<Fourth Embodiment>
FIG. 13 is a plan view showing the water supply mechanism 75 of the fourth embodiment. Regarding the water supply mechanism 75 of the fourth embodiment, differences from the water supply mechanism 20' of the second embodiment will be described.
As shown in FIG. 13, the ceiling wall 30 of the water injection case 24' (the upper case portion 24a) of the water supply mechanism 75 is provided with an inlet portion _24IN5 . The inlet portion 24 _IN5 is located at a position corresponding to the circular portion Z indicated by the dashed line in FIG. One end of a drain pipe 76 is connected to the inlet 24 _IN5 of the upper case portion 24a. The other end of the drain pipe 76 is connected to the upper end of the outside air introduction pipe 60' of the fine bubble generating unit 31'. In addition, the outside air introduction pipe 60' of the fourth embodiment is slightly inclined forward, and is directed obliquely upward and forward.

The drain pipe 76 is, for example, a rubber tube. The drain pipe 76 is fitted so that the inner peripheral surface on one end side thereof is in close contact with the outer peripheral surface of the inlet portion _24IN5 , and the inner peripheral surface on the other end side is in close contact with the outer peripheral surface of the outside air introduction pipe 60'. For this reason, in the fine bubble generation unit 31', even if the internal water flows back through the outside air introduction pipe 60', if the amount of backflow water is relatively small, stored.

When the amount of backflow water is relatively large (for example, when the water supply path 101 on the water injection case 24 side is frozen), the backflow water passes through the outside air introduction pipe 60 ′ and the drain pipe 76 and flows into the upper case part. 24a from the inlet 24 _IN5 into the case portion 24a. The water that has flowed down to the flow path M in the case portion 24a reaches the frozen water supply path 101 or flows from the water injection holes 35h and 36h of the horizontal partition wall 40 to the detergent housing case 23 side. Therefore, the frozen portion of the water supply path 101 can be melted using the backflow water, and it is possible to prevent the water supply path 101 from being damaged due to freezing. In the fourth embodiment, the area A1 (space) in the upper case portion 24a corresponds to a drainage area connected to the water tank 4 (hereinafter referred to as "drainage area A1").

As described above, the outside air introduction pipe 60' of the fourth embodiment communicates with the drainage area A1 of the upper case portion 24a via the drainage pipe 76, and the drainage pipe 76 and the outside air introduction pipe 60' are connected. is formed as a tubular external air introduction passage that can be directly connected to the . According to this, even if water inside the fine bubble generation unit 31' flows back from the proximal end side to the distal end side of the outside air introduction pipe 60', it is discharged to the drainage area A1 of the water injection case 24. It can be poured into the water tank 4.

In each of the above-described embodiments, the washing machine is applied to the vertical axis type washing machine, but it is not limited to the vertical axis type washing machine, and can be applied to general washing machines such as drum type washing machines. Further, in each of the above-described embodiments and modifications thereof, such configurations may be appropriately combined, and some configurations may be changed or omitted.

Although embodiments of the present invention have been described above, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and modifications can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the scope of the invention described in the claims and equivalents thereof.

In the drawings, 1 is a washing machine, 2 is an outer box, 4 is a water tank, 24 and 24' are water injection cases, 27 to 29 are water supply valves, 31, 31', 33 and 70 are fine bubble generation units (fine bubble generators ), 35 to 37 are a detergent containing portion, 55 is an apparatus main body, 56 is an outer shell member, 58 is a throttle portion, 60 and 60′ are external air introduction pipes (external air introduction passages), 60a is a small hole (capacity portion), 60b denotes an enlarged diameter portion (volume portion), 71 a bowl member (volume portion), 73 a space, and A1, _A2-2 drain areas.

Claims (10)

a water tank in which clothes are stored;
a fine bubble generator that causes water supplied from a water source to the water tank to contain fine bubbles;
a drainage path for discharging water in the water tank,
The fine bubble generator is
It is of an outside air introduction type, comprising a device body having a narrowed portion, and an outside air introduction path for introducing outside air into the water by a venturi effect when water flowing into the device main body passes through the narrowed portion. ,
The washing machine has a base end side of which communicates with the apparatus main body, and a tip side of the outside air introduction path communicates with the water tank or a drainage area connected to the drainage path. The drainage area is located in an area within the water injection case for supplying water to the water tank, and is provided as a separate area separated from the arrangement area of the detergent storage section arranged in the water injection case. The washing machine according to claim 1, wherein Equipped with a plurality of the fine bubble generators,
3. The washing machine according to claim 1, wherein the outside air introduction passages of the plurality of fine bubble generators communicate with the common drainage area. 4. The method according to any one of claims 1 to 3, wherein the outside air introduction path communicates with the drainage area through a drainage pipe, and the drainage pipe and the outside air introduction path are formed as a tubular outside air introduction pipe that can be directly connected. A washing machine according to any one of the preceding paragraphs. a water tank in which clothes are stored;
a fine bubble generator that causes water supplied from a water source to the water tank to contain fine bubbles,
The fine bubble generator is
It is of an outside air introduction type, comprising a device body having a narrowed portion, and an outside air introduction path for introducing outside air into the water by a venturi effect when water flowing into the device main body passes through the narrowed portion. ,
The washing machine, wherein the outside air introduction path is directed upward, and has a base end side communicating with the device main body and a tip side side communicating with a space capable of storing a predetermined amount of water. The washing machine according to any one of claims 1 to 5, wherein the outside air introduction path is provided upward as a tubular outside air introduction pipe. The washing machine according to any one of claims 1 to 4 , wherein the outside air introduction path is provided downward as a tubular outside air introduction pipe. The fine bubble generator includes an outer shell member provided with the outside air introduction path and housing the device main body,
8. The washing machine according to any one of claims 1 to 7, wherein the outer shell member is made of a transparent material that allows the inside thereof to be visually recognized. The fine bubble generator includes an outer shell member provided with the outside air introduction path and housing the device main body,
The outer shell member connects between a water supply valve connected to a water source and a water injection case that receives water supplied by the water supply valve and supplies water to the water tank, and the water supply valve and the outer shell member. The washing machine according to any one of claims 1 to 7, wherein the washing machine is provided so as to sandwich the device main body between. a water tank in which clothes are stored;
a fine bubble generator that causes water supplied from a water source to the water tank to contain fine bubbles ,
The fine bubble generator is
It is of an outside air introduction type, comprising a device body having a narrowed portion, and an outside air introduction path for introducing outside air into the water by a venturi effect when water flowing into the device main body passes through the narrowed portion. ,
The washing machine, wherein the outside air introduction path has a volume part capable of storing backflow water from the device main body side, which is the base end side, to the tip side thereof.

Images