JP2020089535A - Washing machine - Google Patents

Abstract

To provide a washing machine capable of preventing fastening of a washing treatment agent in a tank of an automatic input device.SOLUTION: A washing machine includes: a water tub disposed in an outer case; and an automatic input device including a treatment agent tank which can store a washing treatment agent for a plurality of times, and which inputs a predetermined amount out of the washing treatment agent stored in the treatment agent tank into the water tub during a washing operation. The treatment agent tank includes a water pouring port connected to a water pouring path on the outside, and discharges the water poured to the inside from the water pouring port or the washing treatment agent from a discharge port. By the pouring water from the water pouring port via the water pouring path, the inside of the treatment agent tank is washed.SELECTED DRAWING: Figure 4

Description

Embodiments of the present invention relate to a washing machine.

In recent years, in order to meet the user's demand for improved convenience, laundry treatment agents such as detergents and softeners have been stored in advance in a tank for automatic loading several times, and the required amount can be automatically output from the tank during washing operation. A configuration has been developed in which the water is poured into a water tank (see, for example, Patent Document 1).

JP, 2008-11618, A

However, in the above-mentioned tank, there is a problem that detergent or the like is likely to adhere to or adhere to the inner wall of the tank, and the detergent remains inside even if the detergent remaining amount is exhausted. The detergent remaining inside may be mixed with other detergents, and may impede the introduction (discharge) of the detergent into the aquarium. For this reason, the user needs to regularly clean the tank, but every time this cleaning is performed, the tank must be removed from the washing machine body, and hands must be put in the tank to wash with water. It takes time and effort to attach and remove the tank to and from the washing machine body.

Therefore, the present embodiment provides a washing machine capable of preventing the washing treatment agent from sticking to the tank of the automatic dosing device.

The washing machine according to the present embodiment has an outer box, a water tank arranged in the outer box, and a treatment agent tank capable of storing a laundry treatment agent for a plurality of times, and the treatment agent tank is stored in the treatment agent tank. An automatic charging device for charging a predetermined amount of the laundry treatment agent into the water tank during the washing operation, and the treatment agent tank includes a water injection port connected to an external water injection path, and It is configured to discharge the water that has been poured into the interior from the water injection port or the laundry processing agent through the discharge port, and the inside of the processing agent tank is washed away by the water injection from the water injection port through the water injection path.

A vertical sectional side view showing a schematic configuration of a washing machine in the first embodiment. A perspective view showing an automatic charging device incorporated as a unit together with a water tank Perspective view showing a state in which the ceiling wall of the processing agent tank is removed from the unit Conceptual diagram showing the water supply route and water injection route together with the manual charging device and the automatic charging device A vertical cross-sectional side view for explaining the configuration of the processing agent tank and its vicinity Block diagram showing electrical configuration Perspective view of the automatic dosing device in the second embodiment A vertical cross-sectional side view for explaining the configuration of a treatment agent tank in the third embodiment.

Hereinafter, a plurality of embodiments of a washing machine will be described with reference to the drawings. In each embodiment, substantially the same elements are designated by the same reference numerals, and the description thereof will be omitted.

<First Embodiment>
The first embodiment will be described with reference to FIGS. The washing machine 1 shown in FIG. 1 is a so-called horizontal shaft type drum washing machine, and hereinafter, the door 2 side which is the opening 10a side of the rotary tub 10 in the washing machine 1 is referred to as the front side. Further, the width direction of the washing machine 1 which is orthogonal to the paper surface of FIG. 1 is the left-right direction, and the vertical direction which is orthogonal to the front-back direction and the left-right direction is the up-down direction. The washing machine 1 may have a drying function such as a so-called heat pump or a heater (neither is shown).

The outer box 3 of the washing machine 1 shown in FIG. 1 is in the shape of a rectangular box as a whole, and a laundry inlet/outlet 4 is provided on the front face portion 3a thereof, and a door for opening/closing the laundry inlet/outlet 4 is provided. 2 is rotatably provided. Although not shown in detail, an operation panel 5 is provided on the upper end side of the front surface portion 3a of the outer box 3, and the operation panel 5 includes an input unit for turning the power on/off and setting a driving course, and a user. Has a display unit for performing various displays. On the back side of the operation panel 5, a control device 6 (illustrated only in FIG. 6) that constitutes control means is provided.

As shown in FIG. 1, a rotating tank 10 and a water tank 7 that houses the rotating tank 10 are provided inside the outer box 3. The water tank 7 is a bottomed cylindrical tank capable of storing water, and the rotary tank 10 is a bottomed cylindrical drum capable of accommodating clothes therein.
The water tank 7 is elastically supported by a suspension (not shown) in a state where the axis of the water tank 7 is in the lateral direction with the front-rear direction and slightly inclined forward. The front opening 7a of the water tub 7 is connected to the laundry inlet/outlet 4 via a bellows 4a.

A water supply mechanism 8 is provided in the upper part of the outer box 3. As described later in detail, the water supply mechanism 8 includes a hose connection port 9a connected to an external water source such as water supply, a water supply valve 9, a water supply path 23, and the like. By opening the water supply valve 9, water is supplied and stored in the water tank 7 through the water supply path 23. A drain port 7b is provided at the bottom of the rear part of the water tank 7, and the drain pipe 12 is connected to the drain port 7b via a drain valve 12a. With the opening of the drain valve 12a, the water stored in the water tank 7 is discharged to the outside of the machine through the drain pipe 12.

Similar to the water tank 7, the rotary tank 10 is arranged laterally with its axis extending in the front-rear direction, and in a slightly inclined frontward inclination state. The front opening 10a of the rotary tub 10 communicates with the front opening 7a of the water tub 7 and the laundry entrance/exit 4, and by opening the door 2, the front of the water tub 7 and the front of the rotary tub 10 is opened from the laundry entrance/exit 4. Clothing can be taken in and out of the rotary tub 10 through the openings 7a and 10a. Many holes (not shown) are formed in the rotary tank 10. The hole portion functions as a water passage hole that allows water to move between the water tank 7 and the rotary tank 10 at the time of washing and rinsing in the washing operation and during dehydration.

A drum motor 13 including, for example, a DC brushless motor is provided on the back surface of the water tank 7. The rotating shaft 13 a of the drum motor 13 penetrates the back surface of the water tank 7 and is connected to the back surface of the rotating tank 10, and the rotating tank 10 is directly driven to rotate by the drum motor 13.

A manual loading device 20 and an automatic loading device 30 are provided in the upper part of the outer box 3 at one corner in the left-right direction (for example, the left corner) (see FIGS. 1 and 2). ). The manual loading device 20 and the automatic loading device 30 are devices for loading various types of laundry processing agents such as powder or liquid detergents and softening agents, and as shown in FIGS. It is lined up.
Of these, the manual loading device 20 disposed on the front side has a treatment agent storage portion 21 (see FIGS. 1 and 4) capable of storing one-time laundry treatment agent, and is stored in the treatment agent storage portion 21. The entire amount of the treated laundry treatment agent is put into the water tank 7 during the washing operation. On the other hand, the automatic dosing device 30 arranged on the rear side has a processing agent tank 31 (see FIGS. 4 and 5) capable of storing a plurality of times of laundry processing agents, and stores the same in the processing agent tank 31. A predetermined amount of the washed treatment agent is put into the water tank 7 during the washing operation.

The manual pouring device 20 and the automatic pouring device 30 are configured as a unit 8U type combined with the water supply mechanism 8 together with a tank water pouring device 32 (see FIG. 4) described later. Hereinafter, the unit 8U (also referred to as the water supply unit 8U) will be described with reference to the enlarged perspective view of FIG. 3 and the schematic view of FIG. 4. In FIG. 3, the water supply unit 8U is shown with the ceiling wall 8a of the unit case 8C forming the outer shell removed.

As shown in FIGS. 2 and 3, the unit case 8C of the water supply unit 8U has a substantially rectangular box shape that is long in the front-rear direction, and is made of a synthetic resin material. Unit case 8C, the front and casing part _{8 C2} (manual feeding device 20 side), and the case portion _{8 C3} side (automatic insertion device 30) after the stepped, case part _{8 C1} which overhangs the upper right And have a stepped shape. The case portion _8C1 on the upper right side has a water supply path 23 (main flow path M1) and a water injection path 33 (flow path T1 for tank) inside, and a water supply valve unit is provided on the rear end side of the case portion _8C1. 15 are provided.

The water supply valve unit 15 has the water supply valve 9 and the flow path switching valve 16. The water supply valve 9 is composed of an electromagnetic valve, and can switch between a water supply state (open state) and a water supply stop state (closed state). In the open state, tap water (water from the water source) supplied from the hose connection port 9a flows out to the flow path switching valve 16 side, and in the closed state, water does not flow out.

The flow path switching valve 16 is composed of a so-called three-way valve having an inlet 16a connected to the water supply valve 9 and a first outlet 16b and a second outlet 16c as shown in FIG. It is possible to switch to the second state. In the first state, the second outlet 16c is closed and the inlet 16a and the first outlet 16b are in communication. In the second state, the first outlet 16b is closed and the inlet 16a and the second outlet 16c are communicated with each other. The water supply valve 9 and the flow path switching valve 16 are drive-controlled by the control device 6, respectively. The flow path switching valve 16 is drive-controlled so as to always be in the first state except when water is poured into the treatment agent tank 31, which will be described later in detail.

First outlet 16b of the flow path switching valve 16 is connected to the inlet portion 8 _IN1 of the right upper portion of the casing portion 8 _C1 rear side _(see FIG. 3) in the unit case 8C, are supplied from the water supply valve 9 in the first state The water is supplied to the main flow path M1 through the inlet portion 8 _IN1 . The second outlet 16c of the flow path switching valve 16 is connected to the inlet 8 _IN2 (see FIG. 3) on the rear end side of the unit case 8C, and the water supplied from the water supply valve 9 in the second state is the inlet 8 _IN2. Is supplied to the tank flow path T1. In FIG. 3, the flow of water in the main flow path M1 is indicated by a two-dot chain line thick arrow, and the flow of water in the tank flow path T1 is indicated by a solid thick line arrow. It is assumed that the flow path T1 passes under the main flow path M1 and intersects with the flow path M1 in a three-dimensional manner.

Inside of the housing part 8 _C1 in unit case 8C, the partition wall 8 _R1 to form a main flow passage M1 and the tank flow path T1 as shown in FIG. 3 is formed. Inside the unit case 8C, as shown by the thick arrows the two-dot chain line, communicates with the main flow passage M1 of the case portion 8 _C1, a main flow passage M2 of the front case part 8 _C2, bottom The main flow path M3 of the side case portion _8C4 is formed. Bottom side of the case portion 8 _C4 is connected to the water tank 7 via a hose 17 having a bellows portion (see FIGS. 2 and 3). Thus, in the water supply unit 8U, the flow passage switching valve 16, the main flow passages M1, M2, M3, and the hose 17 constitute the water supply passage 23 for supplying the water supplied from the water supply valve 9 to the water tank 7 ( (See FIG. 4). In this case, the water supply path 23, the middle on the main flow path M2, through the front case part 8 _C2.

Front housing part 8 _C2 in the unit case 8C, the front opening 20a (see FIG. 3) faces the upper corner portion of the outer box 3 front portion 3a, withdraw the treatment agent storage unit 21 (see FIGS. 1 and 4) A manual charging device 20 that can be stored is configured.
That is, the manual dosing device 20 includes the case portion _8C2 and the processing agent accommodating portion 21. The treatment agent accommodating portion 21 is made of a synthetic resin material and has a container-like shape whose upper surface is open and which can store a washing treatment agent for about one time. As shown in FIG. 1, the processing agent accommodating portion 21 is in the accommodating state accommodated in the outer box 3 (the case portion 8 _C2 ), and the front surface portion 21 a of the treating agent accommodating portion 21 is moved to the left and right with the operation panel 5. It is arranged so as to be continuous. Further, the treatment agent storage portion 21 is arranged at a position for receiving the water flowing through the main flow path M2 in the storage state. Further, the processing agent container 21 is exposed to the outside of the outer box 3 by the user's operation.

In the manual dosing device 20, when the washing treatment agent is manually put into the water tub 7 for each washing operation, the user puts one time of the washing treatment agent into the treatment agent container 21 before starting the washing operation. To do. In this case, for example, the user pulls out the front surface portion 21a of the treatment agent accommodating portion 21 together with the accommodating portion 21, exposes the treatment agent accommodating portion 21 from the outer box 3, and then inserts the laundry treatment agent, and thereafter, the treatment. The agent container 21 is housed in the outer box 3.

Then, when the water supply valve 9 is opened during the washing operation, the water supplied from the water supply valve 9 passes through the flow path switching valve 16 in the first state and flows through the main flow paths M1 to M3. It is poured into the processing agent accommodating part 21 in the part 8 _C2 . The water poured into the treatment agent storage unit 21 flows out from the bottom of the treatment agent storage unit 21 (see FIG. 4) and is poured into the water tank 7 via the hose 17. At this time, if the user puts the laundry treatment agent into the treatment agent storage unit 21, the laundry treatment agent is poured into the water tank 7 together with the water flowing out from the treatment agent storage unit 21. In this way, the water is supplied into the water tank 7, and the entire amount of the one-time laundry treatment agent stored in the treatment agent storage unit 21 is thrown into the water tank 7 during the washing operation.

The manual throwing device 20 is provided in the middle of the water supply path 23 as described above (see FIG. 4) and can be said to constitute a part of the water supply path 23. That is, the water supply path 23 is a path that goes through the manual throwing device 20 and reaches the water tank 7 without passing through the automatic feeding device 30.

Case portion 8 _C3 of the rear side of the unit case 8C constitutes a treatment agent tank 31 of the automatic dosing device 30.
As shown in FIG. 4, in the automatic charging device 30, the discharge port 35 side of the treatment agent tank 31 is on the downstream side of the manual charging device 20 and on the upstream side of the water tank 7 (that is, between the manual charging device 20 and the water tank 7). It is connected to the middle part of the flow path M3). Alternatively, the discharge port 35 side of the processing agent tank 31 may be connected to another main flow path M2 or the hose 17 (see FIG. 3). Therefore, the automatic dosing device 30 is not included in the constituent elements of the water supply path 23 and directly inputs a predetermined amount of the laundry processing agent into the water supply path 23 without using the water flow from the water supply valve 9. As a result, the laundry treatment agent necessary for the laundry operation can be put on the water flowing through the water supply path 23 and poured into the aquarium 7.

The treatment agent tank 31 can store the laundry treatment agent used in a plurality of operations, and therefore its capacity is larger than the capacity of the treatment agent container 21. Therefore, it can be said that the frequency with which the user replenishes the laundry treatment agent to the treatment agent tank 31 is reduced and the convenience of the user is improved.

Here, FIG. 5 is a vertical cross-sectional side view of the unit case 8C taken along the line VV in FIG. 3, and shows the rear case portion _8C3 forming the processing agent tank 31, for convenience of description.
That is, the processing agent tank 31 shown in FIG. 5 has the left wall 36a, the right wall 36b, the rear wall 36c, the front wall (not shown in the figure), which are the side walls 36, and the bottom wall 37 and the upper wall 38. and, these walls 36 to 38 are formed in housing part _{8 C3} (see the right wall 36b in FIG. 3). Since the case portion _8C3 is located in the upper left corner of the outer box 3, the space between the outer box 3 and the water tank 7 in the upper left corner is used to maximize the capacity of the treatment agent tank 31. I am trying.

As shown in FIG. 4, the automatic charging device 30 includes a treatment agent tank 31, a discharge valve 42 connected to a discharge port 35 of the treatment agent tank 31, a piston pump 40, and check valves 41a and 41b. .. For example, the piston pump 40 and the check valves 41a and 41b are connected in parallel with the discharge valve 42, and are not shown in FIG. 5 for convenience. The discharge valve 42 can be switched between a discharge state that is an open state and a discharge stop state that is a closed state. The discharge valve 42 is always in a closed state except when the water poured into the treatment agent tank 31 is discharged.

The piston pump 40 and the check valves 41a and 41b function as an automatic charging mechanism for automatically charging, into the water supply path 23, a predetermined amount of the laundry processing agent stored in the processing agent tank 31 necessary for the washing operation. .. The automatic charging mechanism is not limited to this configuration.

The input side of the piston pump 40 (the inlet 40a side shown in FIG. 4) is connected to the discharge port 35 of the processing agent tank 31 via a check valve 41a. The check valve 41a opens the path only from the processing agent tank 31 to the piston pump 40 side. The check valve 41a prevents the laundry processing agent in the piston pump 40 from flowing back into the processing agent tank 31. The output side (outlet 40b side) of the piston pump 40 is connected to the water supply path 23 via the check valve 41b. The check valve 41b opens the path only from the piston pump 40 to the water supply path 23 side. The check valve 41b prevents the washing treatment agent supplied to the water supply path 23 and the water flowing through the water supply path 23 from flowing back into the piston pump 40.

The piston pump 40 is configured to be drivable by an actuator such as a motor or a solenoid. The piston pump 40 draws in the piston to draw a fixed amount of the laundry processing agent stored in the processing agent tank 31 into the piston pump 40. Then, the piston pump 40 pushes out the piston to push out the laundry processing agent drawn into the piston pump 40 to the water supply path 23 side. In this case, the amount of the laundry treatment agent pushed out by one reciprocating motion of the piston is sufficiently smaller than the amount of the laundry treatment agent used in one washing operation. Therefore, the washing machine 1 can adjust the predetermined amount of the laundry processing agent to be added during the washing operation by adjusting the number of times the piston of the piston pump 40 operates.

Next, the water injection path 33 for injecting water into the treatment agent tank 31 and the internal configuration of the treatment agent tank 31 will be described in detail.
As shown in FIG. 3, the water injection path 33 is a tank flow path that guides the water supplied from the water supply valve 9 to the upper wall 38 side of the processing agent tank 31 via the flow path switching valve 16 in the second state. They are T1 and T2. Of the tank flow paths T1 and T2, the tank flow path T1 on the upstream side is provided in the case portion _8C1 on the water supply valve unit 15 side, and the tank flow path T2 on the downstream side is the treatment agent. It is provided on the case wall 8 _C3 upper wall 38 side of the tank 31.

That is, the upper wall 38 of the treatment agent tank 31, the tank flow path T2 that communicates with the tank passage T1 is, is partitioned and formed by the partition walls 8 _R2 portrait from the upper wall 38 over the top wall 8a There is. The partition wall 8 _R2 is inside the case portion 8 _C3 (that is, between the upper wall 38 and the ceiling wall 8a), extends upward from the upper wall 38, and has a labyrinth-like shape in the inside as shown in FIG. It bends and extends so as to partition the tank flow path T2. As a result, the tank flow path T2 constitutes an upper wall side path that allows water to spread over substantially the entire upper wall 38 of the treatment agent tank 31, as indicated by the thick arrow in FIG.

In addition, a plurality of water injection holes 43 that vertically penetrate the upper wall 38 of the processing agent tank 31 are provided in the upper wall 38. As shown in FIGS. 3 and 5, the water injection hole 43 is formed over substantially the entire area of the upper wall 38 of the processing agent tank 31 so as to correspond to the tank flow path T2. Of these, the water injection hole 43 formed along the side wall 36 (so as to cover the entire circumference) near the side wall 36 is referred to as a “water injection hole 43a”. That is, among the plurality of water injection holes 43, the “water injection holes 43a” are the water injection holes 43a near the left wall 36a, the water injection holes 43a near the right wall 36b, the water injection holes 43a near the rear wall 36c, and the water near the front wall. Including a water injection hole 43a (see FIGS. 3 and 5).

The water injection hole 43a is connected to a small cylindrical tube portion 44a integrally formed on the lower surface side of the upper wall 38. The cylindrical portion 44a illustrated in FIG. 5 is inclined in a direction intersecting the vertical direction (inclined toward the left wall 36a side downward) so that the side wall 36 (left wall 36a) of the treatment agent tank 31 is hit with water. ing. The water injection hole 43a and the cylinder portion 44a constitute a water injection port 45a, and the water injection port 45a as a whole is inclined. The water injection port 45a includes the water injection port 45a near the left wall 36a shown in FIG. 5, the water injection port 45a near the right wall 36b (the cylinder portion 44a is omitted in the figure), and the water injection port 45a near the rear wall 36c (similarly). And a water injection port 45a (not shown) near the front wall. Therefore, by providing the water injection ports 45a for the respective side walls 36 with the plurality of water injection ports 45a all around the side wall, the water can be washed from the upper side of the side wall 36. ing.

In addition, the water injection holes 43b and 43c shown in FIG. 5 are connected to small cylindrical tubular portions 44b and 44c integrally formed on the lower surface side of the upper wall 38. The water injection hole 43c and the cylinder portion 44c on the right side are located almost directly above the discharge port 35 so that the water injected from the cylinder portion 44c hits the inside of the discharge port 35 or the peripheral portion of the discharge port 35. The water injection port 45c is configured. On the other hand, the water injection hole 43b and the tube portion 44b are not located directly above the discharge port 35, but the tip side of the tube portion 44b is directed to the discharge port 35, so that the inside of the discharge port 35 or the discharge port 35 is formed. It is a water injection port 45b configured so that water may hit the peripheral portion. As described above, by providing the water injection ports 45b and 45c for the discharge port 35 with the plurality of water injection ports 45b and 45c, the washing treatment agent which is particularly easily adhered to the discharge port 35. You can wash it away.

In FIG. 5, the discharge port 35 is arranged at the position close to the right wall 36b in the bottom wall 37 of the treatment agent tank 31, but may be arranged near the center. Further, the water injection port is not limited to the water injection holes 43a to 43c with the tubular portions 44a to 44c, and it goes without saying that the water injection port may be configured by only the water injection hole 43. Hereinafter, the water injection holes 43 will be collectively referred to as “water injection ports 45” regardless of the presence or absence of the tubular portions 44a to 44c.

As shown in FIG. 5, the bottom wall 37 of the treatment agent tank 31 has an inclined surface 37a that is inclined downward toward the discharge port 35 so that the discharge port 35 side is at the lowest position. The bottom wall 37 is not limited to the inclined surface 37a in the figure, but may be appropriately changed by forming an inclined portion that lowers the discharge port 35 side as a groove (not shown) recessed downward.

As shown in FIG. 3, a pair of front and rear inlets 46 a and 46 b are provided on the upper wall 38 of the processing agent tank 31. Further, the ceiling wall 8a is also provided with insertion openings 46a' and 46b' at positions corresponding to the insertion openings 46a and 46b of the upper wall 38. These inlets 46a, 46b, 46a', 46b' penetrate the upper wall 38 and the ceiling wall 8a in the plate thickness direction so as to communicate the inside and outside of the processing agent tank 31. The input ports 46a, 46b, 46a', 46b' are used as filling ports when the user fills (stores) the laundry treatment agent in the treatment agent tank 31, and a cover member (not shown) on the upper surface side of the outer box 3 ( Cover with the tank lid). The treatment agent tank 31 may be divided into a tank for storing a detergent as a laundry treatment agent and a tank for storing a softening agent so as to correspond to the pair of front and rear inlets 46a to 46b'. Of course, detailed description thereof will be omitted.

The treating agent tank 31 is provided with a remaining amount detecting means 47 for detecting the remaining amount of the laundry treating agent stored therein. The remaining amount detecting means 47 is composed of, for example, a well-known water level detecting means having a float portion 47a, a rail portion 47b, and a reed switch 47c (only shown in FIG. 6) schematically shown in FIG.

Specifically, the rail portions 47b are a pair of rails that linearly extend from the bottom wall 37 toward the upper wall 38, and the float portions 47a match the water level in the treatment agent tank 31 and the rail portions 47b. Move up and down along. The float portion 47a is a float body made of a laundry processing agent or a material that floats on water, and a magnet (not shown) is provided on the float body. As a result, the reed switch 47c can detect the position of the magnet of the float portion 47a and detect the remaining amount of the laundry processing agent in the processing agent tank 31 or the water level based on the detection of the magnetism. it can. The remaining amount detecting means 47 or the water level detecting means is not limited to the detecting means having the float portion 47a, and may be constituted by other detecting means. The reference numeral H shown in FIG. 5 is used as a reference when the maximum water level detected by the float 47a, that is, when the laundry treatment agent is filled or the water is stored.

The water injection path 33, the water supply valve 9, the flow path switching valve 16, the discharge valve 42, and the like described above are used as a tank water injection device 32 that flushes the inside of the treatment agent tank 31 by water injection from the water injection port 45 through the water injection path 33. Equivalent to.

FIG. 6 is a block diagram schematically showing an electrical configuration of the washing machine 1. The control device 6 is mainly composed of a microcomputer having a storage unit 6a including a CPU, a ROM and a RAM, and controls the overall operation of the washing machine 1 including a washing operation for washing the clothes in the rotary tub 10. .. The storage unit 6a stores an operation control program for all processes, including a washing operation step or a drying operation step relating to the drying function.

The control unit 6 is connected to the input unit and display unit of the operation panel 5, the reed switch 47c, and the door open/close detection switch 49, and the drum motor 13, the water supply valve 9, the flow path switching valve 16, the drain valve 12a, Drive circuits 51, 52, 53, 54, 55, 56 that drive the piston pump 40 and the discharge valve 42, respectively, are connected. The door open/close detection switch 49 is composed of, for example, a limit switch that detects opening/closing of the door 2.

Next, the operation of the above configuration will be described focusing on the operation of the tank water injection device 50 (water injection into the treatment agent tank 31).
Here, it is assumed that the flow path switching valve 16 is always in the first state where it is switched so as to supply water to the water supply path 23 side except when water is poured into the treatment agent tank 31. Further, the discharge valve 42 is always in the closed state except when the water poured into the treatment agent tank 31 is discharged, and further, in the piston pump 40 (see FIG. 4), the washing process of the washing operation is easy. Except when operating during water injection in the rinsing process, it shall be in a closed state that does not pass laundry treatment agent or water.

The control device 6 determines the remaining amount of the laundry treatment agent in the treatment agent tank 31 based on the detection result of the reed switch 47c, and when it is determined that the remaining amount is not present, stores the determination result in the storage unit 6a. .. In addition, the control device 6 completes all the steps of the washing operation and the drying operation of the clothes in the rotary tub 10 based on the operation control program and the detection result of the door open/closed detection switch 49, and the inside of the rotary tub 10 concerned. When it is determined that there is no clothes, and the storage unit 6a stores “no remaining amount of the laundry processing agent”, the tank water injection device 50 automatically executes a process of flushing the inside of the processing agent tank 31.

Specifically, the control device 6 switches the flow path switching valve 16 to the second state in which water is supplied to the water injection path 33 side, opens the water supply valve 9, and injects water through the water injection path 33 to treat the treatment agent tank 31. Rinse the inside. At this time, in the water injection path 33, tap water is guided from the flow path switching valve 16 to the flow paths T1 to T2 in the tank flow path T by opening the water supply valve 9 shown in FIG. From 45, water is injected in a shower shape to the inner wall (side wall 36, bottom wall 37) of the treatment agent tank 31 and the discharge port 35 portion.

In this case, of the water injection ports 45 of FIG. 5, water directly hits the upper part of the left wall 36a (above the two-dot chain line H in the figure) by water injection from the water injection port 45a, and the other side walls 36b to. Water also hits the top directly. Further, the water injected from the water injection ports 45b and 45c directly hits the vicinity of the discharge port 35, and the water injected from the remaining water injection port 45 directly hits the bottom wall 37.

At this time, since the discharge valve 42 is in the closed state, the injected water is stored in the treatment agent tank 31 and gradually raises the water level inside the treatment agent tank 31. After that, when the control device 6 determines that the water level in the treatment agent tank 31 has reached a predetermined water level (for example, the water level H shown by the two-dot chain line in FIG. 5) based on the detection result of the reed switch 47c, the water supply valve 9 is switched from the open state to the closed state to stop the water injection, and the discharge valve 42 is switched from the closed state to the open state to discharge the water stored in the treatment agent tank 31 from the discharge port 35. As a result, even if the laundry treatment agent adheres to the inner wall of the treatment agent tank 31 before water injection, the adhering laundry treatment agent is treated by the above-described series of flows of water injection, water storage, and discharge. It is possible to wash away the agent tank 31 so as not to leave it in the agent tank 31.

As described above, the washing machine 1 of the present embodiment has the water tank 7 arranged in the outer box 3 and the treatment agent tank 31 that can store the washing treatment agent for a plurality of times. An automatic charging device 30 for charging a predetermined amount of the laundry processing agent stored in 31 into the water tank 7 during the washing operation, and the processing agent tank 31 is connected to the water injection path 33 outside thereof. The water injection port 45 is provided, and the water or the laundry treatment agent that has been injected into the interior from the water injection port 45 is configured to be discharged from the discharge port 35. By the water injection from the water injection port 45 via the water injection path 33, The inside of the processing agent tank 31 is washed away.

According to this, even when the laundry treatment agent is likely to adhere to the inside of the treatment agent tank 31 and the laundry treatment agent remains inside, the treatment agent can be injected through the water injection path 33. The inside of the tank 31 can be washed away. As a result, it is possible to prevent the laundry treatment agent from sticking to the treatment agent tank 31, the remaining laundry treatment agent is mixed with other laundry treatment agents, and the laundry treatment agent is charged (discharged) into the water tank 7. It is possible to solve the problem of blocking. Further, for example, the inside of the processing agent tank 31 can be cleaned without removing the processing agent tank 31 from the outer box 3 and without putting a hand into the processing agent tank 31.

The water injection port 45 is located on the side of the upper wall 38 of the treatment agent tank 31. According to this, the washing processing agent in the processing agent tank 31 can be washed off by pouring water from the upper wall 38 side of the processing agent tank 31. The water injection port is not limited to the water injection port 45 having the above-described arrangement, and the same effect can be obtained even when the water injection port is configured by at least one water injection port 45.

Further, the water injection port 45 includes an inclined water injection port 45a for injecting water in a direction intersecting the vertical direction so that the side wall 36 of the treatment agent tank 31 is contacted with water. According to this, wasteful water injection can be suppressed and the side wall 36 of the processing agent tank 31 can be washed away.
The discharge port 35 is located on the bottom wall 37 side of the processing agent tank 31, and the processing agent tank 31 has a bottom wall 37 such that the discharge port 35 side is at the lowest position, or downward toward the discharge port 35 side. An inclined surface 37a that is inclined is formed. According to this, even if water is poured into the treatment agent tank 31, it is possible to prevent water from remaining inside.
The term “the discharge port is located on the bottom wall side of the treatment agent tank” is not limited to the discharge port 35 of the first embodiment formed in the bottom wall 37 itself, but may be the bottom wall as in the third embodiment described later. This means that the discharge port 92b (see FIG. 8) formed in the vicinity of 37 is also included. Similarly, the term “the water inlet is located on the upper wall side of the treatment agent tank” is not limited to the water inlet 45 of the first embodiment, and the water inlet formed in the vicinity of the upper wall 38 (upper side wall 36) (illustration) (Omitted) is also meant to be included.

The water injection port 45 includes water injection ports 45b and 45c for the discharge port 35, which inject water toward the discharge port 35 so that the water may hit the discharge port 35. According to this, particularly, the laundry treatment agent in the vicinity of the discharge port 35 can be washed out more reliably, and the adhesion of the laundry treatment agent that hinders the introduction of the laundry treatment agent into the water tank 7 can be eliminated. Becomes
A discharge valve 42 is provided on the downstream side of the discharge port 35 as a switching unit for switching between storage and discharge of the water injected into the treatment agent tank 31. According to this, by the discharge valve 42, the water that has been poured into the treatment agent tank 31 can be stored, or the stored water can be discharged together with the laundry treatment agent from the discharge port 35, thereby saving water. The discharge valve 42 may be arranged in the vicinity of the discharge port 35 and upstream of the discharge port 35, that is, in the processing agent tank 31.

As the water level detecting means for detecting the water level of the water stored when water is injected into the treatment agent tank 31, for example, a detecting means using a float such as the float portion 47a described above is provided. According to this, based on the detection result of the water level detecting means as described above, it becomes possible to automatically store the water up to the predetermined water level H, for example, by switching the supply and stop of the water by the water supply valve 9. It is possible to prevent the stored water from overflowing the processing agent tank 31.

The detection means such as the float is provided as the remaining amount detection means 47 for detecting the remaining amount of the laundry treatment agent stored in the treatment agent tank 31, and the condition for performing the water injection is determined by the remaining amount detection means 47. It is configured so that it is related to the remaining amount of the laundry processing agent detected. According to this, it is possible to avoid a situation where water is injected into the laundry processing agent stored (filled) in the processing agent tank 31. In other words, conventionally, it has not been planned to add water to the treatment agent tank of the automatic dosing device, and when the tank water injection device 32 is introduced as in this embodiment, water is not added to the laundry treatment agent that should be originally stored. It is possible to eliminate the adverse effect that water enters and to suppress the generation of bubbles due to water injection.
In the above-described embodiment, the condition that the remaining amount of the laundry processing agent detected by the remaining amount detecting means 47 is not present, but the condition is that the remaining amount is less than one wash. .. For any of these remaining amounts, "the condition for water injection is related to the remaining amount of the laundry treatment agent", and when it is determined that there is no clothes in the rotary tub 10 (or the user's The water may be injected according to the operation on the operation panel 5.

<Second Embodiment>
FIG. 7 is a perspective view showing a water supply unit 80U according to the second embodiment. The water supply unit 80U of the second embodiment differs from the water supply unit 8U of the first embodiment in the following points.

That is, the unit case 8C of the water supply unit 80U, only the water supply valve 9 (first water supply means) by located on the right side upper portion of the case portion 8 _C1 rear end is attached, the case portion 8 _C3 having a tank flow path T2 A water supply valve 81 (second water supply means) is provided at the rear end. The water supply valve 81 has a hose connection port 81a in the upper part, and like the hose connection port 9a, water is supplied from an external water source. Outlet of the water supply valve 81 is connected to the case part _{8 C3} rear end of the inlet portion _{8 IN3,} by the water supply valve 81 is opened, water supplied from the hose connecting port 81a is passed through inlet portion _{8 IN3} tank It is directly supplied to the flow channel T2.

Therefore, the water supply unit 80U, which is a flow path switching valve 16 and the tank flow path T1 in the right upper portion of the case portion 8 _C1 is a been a simple structure omitted in the first embodiment. Therefore, the distance from the water supply valve 81 to the treatment agent tank 31, that is, the water injection path 33 can be minimized as the distance of only the tank flow path T2, and a more compact and inexpensive structure can be realized.

As described above, in the second embodiment, the configuration including the water supply path 23 and the water supply valve 9, and the water supply valve 81 that switches the supply and stop of the water from the water source to the water injection path 33, that is, the water supply path 23. By providing the water supply valve 81 of the water injection path 33 different from the water supply valve 9, the tank water injection device 32 including the water injection path 33 can be simplified. Further, according to the second embodiment, the same effect as that of the first embodiment can be obtained such that the inside of the treatment agent tank 31 can be washed away by water injection through the water injection path 33.

<Third Embodiment>
FIG. 8 is a vertical sectional side view showing the treatment agent tank 91 of the third embodiment. The treatment agent tank 91 of the third embodiment is different from the treatment agent tank 31 of the first embodiment in the following points.
That is, inside the processing agent tank 91, as shown in FIG. 8, a suction tube 92 having an inverted L shape in a side view is provided. The suction pipe 92 is connected such that one end portion 92a of the horizontal portion thereof penetrates the upper end portion of the right wall 36b of the tank 91, and the lower end portion 92b of the vertical portion extends to the vicinity of the bottom wall 37. .. The upper end of the right wall 36b to which the one end 92a of the suction pipe 92 is connected is a tank outlet 91a, and the inlet 40a of the piston pump 40 is connected to the tank outlet 91a from the outside. The lower end portion 92b of the suction pipe 92 functions as a discharge port located on the bottom wall 37 side of the tank 91.

In other words, the suction pipe 92 is provided so as to communicate the inside and the outside of the tank 91, and the lower end portion 92b thereof has a discharge port (hereinafter, referred to as “discharge port 92b” instead of the discharge port 35 of the first embodiment. It is called). Therefore, in the bottom wall 37 of the tank 91, the discharge port 35 as in the first embodiment is not formed, the discharge port 92b side is inclined so as to be at the lowest position, and the suction pipe 92 The water injected from the water injection port 45b hits the discharge port 92b.

Further, as described above, the piston pump 40 is connected so that its inlet 40a communicates with the suction pipe 92 and its outlet 40b communicates with the water supply path 23, as in the first embodiment. Therefore, in the third embodiment, even if the discharge valve 42 of the first embodiment is omitted, water is poured into the tank 91 by switching the driving and driving stoppage of the piston pump 40 as a switching unit. The storage and discharge of water can be switched.
The switching means of the third embodiment is not limited to the piston pump 40 and may be another switching means. For example, as another switching means, a pump mechanism having a pump case having suction ports and discharge ports serving as an inlet 40a and an outlet 40b and having pump blades driven by a pump motor in the pump case is provided. You may comprise. The controller 6 can switch between driving and stopping of the pump, thereby switching between storage and discharge of the water injected into the tank 91.

The above-described respective embodiments and the modifications thereof may be combined with each other, or some of the structures may be changed. The washing machine is not limited to the drum type washing machine, and may be applied to a vertical type in which the axis of the rotary tub is oriented in the vertical direction.

The water injection port is not limited to the form of the water injection port 45a to 45c in which the water injection holes 43a to 43c and the tube portions 44a to 44c are combined, and the direction of the water injection holes 43a to 43c and the shape of the tube portions 44a to 44c are changed. It may be in the form. Specifically, instead of the tubular portion 44a, a rib or a protrusion (none of which is shown) extending along the arrangement of the water injection holes 43a is integrally formed on the lower surface side of the upper wall 38, and the rib or the protrusion is formed. The tip side can be inclined to the side wall 36a side so that the water flowing down the water injection hole 43a hits the side wall 36a.

The first water supply means and the second water supply means of the third embodiment are not limited to the valve mechanism such as the water supply valves 9 and 81, and the water supply valve 9 of the first embodiment is also limited to the valve mechanism. However, instead of these valve mechanisms, a pump such as the pump mechanism may be used.
That is, as a water supply means for switching supply and stop of water to the water injection path 33 (treatment agent tanks 31, 91), for example, a well-known bath water pump (not shown) that absorbs bath water through a water absorption hose (not shown) May be used. With this bath water pump, bath water can be supplied to the treatment agent tanks 31, 91 through the water absorption hose and the water injection path 33. Although not shown, a circulation pump that circulates a water source (water in the water tank 7) other than the tap water may be used as the water supply means, instead of the bath water. In this case, the flow path switching valve 16 is provided in the middle of the circulation path (not shown) that sucks the water at the bottom of the water tank 7 and supplies the water from the upper portion of the water tank 7. As a result, water can be supplied from the circulation path to the processing agent tanks 31, 91 via the flow path switching valve 16 and the water injection path 33.

Like the discharge port 35 of the first embodiment and the discharge port 92b of the third embodiment, the discharge port can be changed appropriately, and the water injection port can also be changed appropriately. For example, in the treatment agent tank, the discharge port may double as the water injection port (that is, the communication port that communicates the inside and the outside may function as the discharge port and the water injection port). In this case, even if the communication port is one communication port, the inside of the treatment agent tank can be washed by injecting water from the one discharge port and discharging the water from the one discharge port.

In the processing agent tank 31 of the first embodiment, the discharge valve 42 is closed during the cleaning, but the discharge valve 42 may be opened during the cleaning. According to this, it is possible to always wash the inside of the treatment agent tank 31 with water that does not contain the laundry treatment agent, and it is possible to shorten the washing time.
In the first embodiment, when the water level in the treatment agent tank 31 reaches the predetermined water level, the discharge valve 42 is switched from the closed state to the open state. However, the discharge valve 42 is discharged after a predetermined time has elapsed after reaching the predetermined water level. The valve 42 may be switched from the closed state to the closed state. According to this, even if the laundry processing agent is firmly fixed in the processing agent tank 31, it is possible to eliminate the adhesion without wasting water.
Although a plurality of 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 changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the scope equivalent thereto.

In the drawing, 1 is a washing machine, 3 is an outer box, 7 is a water tank, 9 is a first water supply means, 23 is a water supply path, 30 is an automatic charging device, 31 and 91 are treatment agent tanks, 32 is a tank water injection device, 33 is a water injection path, 35 and 92b are discharge ports, 36 is a side wall, 38 is an upper wall, 42 is a discharge valve, 45 is a water injection port, 47 is a remaining amount detecting means (water level detecting means), and 81 is a second water supplying means. Show.

Claims (9)

Outer box,
A water tank disposed in the outer box,
An automatic charging device that has a treatment agent tank capable of storing a plurality of times of laundry treatment agents and that injects a predetermined amount of the laundry treatment agents stored in the treatment agent tank into the water tank during a washing operation. Be equipped with
The treatment agent tank is provided with a water injection port connected to an external water injection path, and is configured to discharge the water or the laundry treatment agent injected from the water injection port to the inside through an outlet port, A washing machine for flushing the inside of the treatment agent tank by water injection from the water injection port via a water injection path. The washing machine according to claim 1, wherein the water injection port is located on an upper wall side of the treatment agent tank. 3. The washing machine according to claim 1, wherein the water injection port includes an inclined water injection port that injects water in a direction intersecting a vertical direction so that the side wall of the treatment agent tank is contacted with water. The discharge port is located on the bottom wall side of the processing agent tank,
4. The processing agent tank is formed with a bottom wall such that the discharge port side is at the lowest position, or an inclined surface that is inclined downward toward the discharge port side. The described washing machine. The washing machine according to any one of claims 1 to 4, wherein the water inlet includes a water inlet for the outlet that injects water toward the outlet so that water hits the outlet. The washing machine according to any one of claims 1 to 5, wherein a switching means for switching between storage and discharge of water poured into the treatment agent tank is provided in the vicinity of or downstream of the discharge port. The washing machine according to claim 6, further comprising water level detection means for detecting a water level of water stored by water being injected into the treatment agent tank. A residual amount detecting means for detecting the residual amount of the laundry treating agent stored in the treating agent tank is provided,
The washing machine according to any one of claims 1 to 7, wherein the condition for performing the water injection is related to the remaining amount of the laundry processing agent detected by the remaining amount detecting means. First water supply means for switching supply and stop of water from the water source to a water supply path for supplying water from the water source to the aquarium;
The washing machine according to any one of claims 1 to 8, further comprising: a second water supply unit that switches supply and stoppage of water from a water source to the water injection path.

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