KR100525334B1 - Cation Removing Device for Washer and Washer Using the Same and Control Mehtod of Washer - Google Patents

Abstract

Ion removal means containing the ion exchange member for removing the cation component of the tap water in the case and regeneration means for supplying regeneration water to the ion removal means for regenerating the ion exchange member on one side of the ion removal means, the washing tank of the washing machine The water supply valve which supplies tap water to the washing tank through the ion removal means at the time of water supply and the regeneration valve which supplies the regeneration water to the ion exchange member at the time of regeneration of the ion exchange member are integrally attached to the case, and the cation has been removed. Was used for washing to increase the cleaning efficiency of the detergent.

Description

Cation Removal Device for Washer and Washing Method Using the Same {Cation Removing Device for Washer and Washer Using the Same and Control Mehtod of Washer}

The present invention relates to a cation removal device for a washing machine for removing cations from washing water, a washing machine using the same and a control method thereof.

Tap water is typically used in washing machines, and water is supplied to a washing tank in a washing machine via a hose or the like from a tap and used for washing clothes.

This tap water contains anions such as hypochlorite ions for sterilization and cations such as calcium ions, magnesium ions and iron ions contained in the water source. It has been found to have adverse effects on eggplant.

The cause of the deterioration of the cleaning power is the presence of divalent cations represented by calcium ions and magnesium ions as hardness components.

Since these divalent cations react with the surfactant in the detergent to produce a water-insoluble metal soap, there is a phenomenon that the amount of the surfactant that contributes to the cleaning is reduced, thereby lowering the cleaning power.

In addition, since the produced metal soap is insoluble in water, if the rinse is insufficient, it may remain in the garment and become white spots, which may cause yellowing or odor. There is a possibility of frequent.

In order to solve such a problem, a detergent manufacturer has incorporated a zeolite as one of builders in synthetic detergents used at home to reduce the influence of hardness.

These zeolites are white microparticles which are insoluble in water mainly containing silicic acid and alumina, and have the effect of softening water by adsorbing polyvalent cations such as calcium and magnesium in water, but also cause the following problems.

When washing water such as tap water contains divalent cations such as calcium ions and magnesium ions, when a detergent containing zeolite is added thereto, divalent cations can be removed. Because of the reaction, the production of metal soap cannot be completely prevented, and the effect of adding zeolite is hindered.

In addition, when a water-insoluble zeolite is incorporated into a detergent in a large amount as a builder, there is a fear that the zeolite particles adhere to the clothes after washing, thereby deteriorating the finish.

On the other hand, as described in Japanese Patent Application Laid-open No. Hei 4-20395 or Japanese Patent Application Laid-open No. Hei 5-115681 as a method of removing the harmful effects of the cation separately from the improvement of the detergent, the divalent cation was removed from the washing water. Later, it is proposed to wash in a washing tank by dissolving detergent.

In Japanese Patent Laid-Open No. 4-20395 described above, it is proposed to provide ion removal means in the middle of a water supply passage of a water supply means for supplying water in a washing tank for washing clothes, and to use ion exchange resin or activated carbon as this ion removal means. Doing.

Further, Japanese Patent Application Laid-Open No. 5-115681 proposes to use water on the anode side from which metal ions have been removed as washing water by applying a voltage to the electrode pairs facing each other via a diaphragm.

In the washing method described in Japanese Patent Laid-Open No. 4-20395, a large amount of ion exchange resin is required to secure the flow rate of the washing water, and it becomes difficult to store or simply configure the ion removing means inside the washing machine.

On the other hand, when the amount of ion exchange resin is reduced and the ion exchange means is simplified, it is difficult to obtain a flow rate of 10 to 15 L per minute, which is usually required.

In addition, if the ion exchange means is to be placed below the washing machine in order to store the ion exchange means inside the washing machine, it is necessary to provide a long water supply passage before and after the ion exchange means, and the pressure loss in the water supply passage increases, thereby ensuring the flow rate. Becomes difficult.

In addition, since the ion exchange resin has no effect of removing the same after adsorbing a certain amount of ions, it is necessary to regenerate and use it after treating a certain amount of washing water, but no consideration is given to this.

In the washing method described in Japanese Patent Laid-Open No. 5-115681, washing water is energized between electrode pairs, metal ions contained therein are removed, and detergent is added to the washing water. It requires about 30 minutes as energization time in a still state.

Therefore, it is difficult to simply configure the ion removal means inside the washing machine to ensure a flow rate of 10 L to 15 L per minute.

In addition, consideration is given to consideration of an increase in a circuit for electric current treatment, an electric shock, and treatment of hydrogen gas generated by electrolysis of water.

A first feature of the invention is an ion removal means containing an ion exchange member for removing a cation component of tap water in a case, and a regeneration for supplying regeneration water to the ion removal means for regenerating the ion exchange member on one side of the ion removal means. The water supply valve is disposed in the case, and a water supply valve for supplying tap water to the washing tank through the ion removal means at the time of water supply to the washing tank, and a regeneration valve for supplying regeneration water to the ion exchange member at the time of regeneration of the ion exchange member. It is in the cation removal device for washing machines attached.

According to a second aspect of the present invention, there is provided a washing machine including an outer frame, a washing tank disposed in the outer frame, a water supply device for supplying water to the washing tank, and a drainage device for draining the water in the washing tank. The ion removal member containing the ion exchange member for removing the cation component of the tap water in the washing machine of the washing machine and the water supply valve for supplying the tap water to the washing tank through the ion removal member at the time of water supply and the ion removal member on one side of the ion removal member The washing machine is provided with the regeneration chamber which supplies regeneration water to the said ion removal member, and the regeneration valve which integrally attached the regeneration valve which supplies this regeneration water to the said ion exchange member for regenerating an exchange member.

A third aspect of the present invention is an ion removing means which is disposed in the main body of the washing machine to accommodate ion exchange resin for softening tap water, regeneration means for supplying regeneration water for regenerating the ion exchange resin, and the ion removal means. A water supply means for supplying tap water to the water supply unit, and a control means for controlling the water supply means and the regeneration means, and if regeneration is selected before the washing stroke, the control means supplies the tap water to the ion exchange resin by the water supply means. In the control method of the washing machine characterized by regenerating the ion-exchange resin by the regeneration means, water is supplied again by the water supply means.

A fourth feature of the present invention is an ion removal means for storing an ion exchange resin for softening tap water in the main body of the washing machine, regeneration means for regenerating the ion exchange resin, water supply means for supplying tap water to the ion removal means; And regeneration means and control means for controlling the water supply means, and when the user selects regeneration before water supply in a washing process using a detergent, after regenerating the ion exchange resin by the regeneration means, There is a control method for a washing machine characterized by water supply.

A fifth feature of the present invention is to provide ion removal means for storing an ion exchange resin for softening tap water in a main body of a washing machine, a water supply valve for supplying tap water to the ion removal means, and regeneration water for regenerating the ion exchange resin. And a control means for controlling opening and closing of the water supply valve and the regeneration valve. The control means divides the regeneration valve into a plurality of times in a state where the water supply valve is closed at the time of regeneration of the ion exchange resin. The control method of the washing machine characterized by opening and closing.

A sixth aspect of the present invention is an ion removing means containing an ion exchange resin for softening tap water in a main body of a washing machine, water supply means for supplying tap water to the ion removing means, regeneration means for regenerating the ion exchange resin, And control means for controlling the water supply means and the regeneration means, wherein the control means supplies tap water by the water supply means after regeneration by the regeneration means to wash away the ionic components remaining between the ion exchange resins. Control method of the washing machine.

A seventh aspect of the present invention provides an outer frame, an outer tub provided in the outer frame, a washing tank rotatably disposed in the outer tank, water supply means for supplying tap water to the washing tank, and ions for softening tap water in the water supply. A washing machine having ion removal means having an exchange resin, wherein the washing machine has regeneration means for supplying regeneration water for regenerating the ion exchange resin, and discharge means for discharging the regenerated water after the regeneration in the outer tank as lower than the washing tank. In the washing machine characterized in that it has a.

An eighth aspect of the present invention provides an ion removing unit containing an ion exchange resin for softening tap water in a main body of a washing machine, a regenerating unit for regenerating the ion exchange resin, a water supply unit for supplying tap water to the ion removing unit; And control means for controlling said regeneration means and said water supply means, said control means regenerating by said regenerating means after completion of water supply by said water supply means in the final rinsing stroke of washing. Is in.

Another feature of the invention is as described in the claims.

As shown in Figs. 1 and 2, the main body of the washing machine is composed of an outer frame 1 made of steel, an upper cover 2 made of synthetic resin on the upper side, and the like.

Inside the outer frame 1, an outer tub 3, which is a water support tank, is suspended by four hanging rods 4 hanging from the top of the outer frame 1.

The washing tank 5, which is a washing and dewatering tank, is rotatably arranged inside the outer tank 3, and a rotatable stirring blade 6 is provided on the inner bottom of the washing tank 5.

On the lower surface of the outer tub 3, a drive device for rotating the stirring blade 6 and the washing tub 5 is disposed, which is formed of a motor 7, a clutch mechanism 8, or the like.

The drain solenoid valve 9 which drains the water of the outer tank 3 is arrange | positioned at the lower surface of the outer tank 3, and the drain hose 10 connected to the drain solenoid valve 9 is made to the outer side of the outer frame 1 to the outside. It is extended and drained to sewerage etc.

The central part of the upper cover 2 is provided with an inlet 11 and a cover 12 for inserting and removing clothes, and inside the rear part of the upper cover 2, a tap water supply means, an ion removal means, and a water source different from the tap water are provided. An absorption pump or the like for sucking water is disposed, and these are covered by the back panel 13. Here, the back panel 13 is detachable from the upper cover.

A water hose 15 is connected to the water connection tap 14 which is a tap water supply means, and the outer cover 16 of the ion removal means is detachably attached to the back panel 13.

Next, the ion removing means, which is the main part of the present invention, will be described including the rear part of the upper cover 2 and other related parts disposed thereon.

As shown in Figs. 3, 4 and 5, the rear portion of the top cover 2 is a storage space having a short inner depth in the front-rear direction and a shallow transverse bottom.

A water supply unit 100 is formed in the center of the storage space, an ion removing unit and a water supply unit are disposed on the left side of the water supply unit 100, and an absorption pump for sucking the washing water from a different source than the tap water on the right side ( 101 is disposed.

The absorption pump 101 has a self-priming pump unit 102 and a motor unit 103, and is composed of a horizontal length as a whole. The self-priming pump unit 102 is located at the water supply unit 100 and the motor unit 103. ), The absorption pump 101 is placed horizontally so as to be on the side away from the water injection portion 100.

By adopting such an arrangement, the absorption pump 101 can be stored horizontally even when the rear storage space of the upper cover 2 is shallow.

The hose connecting port 104 communicating with the suction chamber of the self-suction pump section 102 is disposed upward, and is exposed through the back panel 13 to the outside.

Although the discharge hose 105 and the water discharge hose 106 which communicate with the discharge chamber of the self-suction pump part 102 extend to the water supply means side, it mentions later in detail.

Next, the structure of the ion removal means will be described with reference to FIGS. 4, 5, 6A, 6B, 7 and 8. FIG.

The storage case 17 of the ion removal means is formed in a cylindrical shape with a bottom, and the ion removal member 18 is detachably attached to the ion storage case 17.

The ion removal member 18 is fixed to the bottom side of the storage case 17 by the pressure lid 19.

In the upper part of the pressurization cover 19, the salt receiving member 20 which mounts salt for regenerating ion exchange resin is provided.

Here, the ion exchange resin is made of a material having a function of exchanging adsorbed magnesium ions or calcium ions with sodium ions of salt.

Moreover, the water outlet 21 is formed in the upper opening edge part of the storage case 17. As shown in FIG.

The storage case 17, the said absorption pump 101, etc. are covered by the back panel 13 so that it may be sealed from above.

The salt inlet 22 formed in the back panel 13 is connected to the upper opening of the storage case 17, and the outer lid 16 is detachably attached to the salt inlet 22.

The ion removal member 18 is comprised from the cylindrical inner container 18a and the mesh filters 18b and 18c fixedly attached to the upper and lower surfaces of this cylindrical inner container 18a, and the ion exchange resin is filled in the inside.

The particle diameter of the ion exchange resin is preferably a small one of about 0.1 mm or more and about 0.5 mm or less, and in this embodiment, that of 0.2 mm is used.

The amount of the ion exchange resin is preferably 80 ml or more and 150 ml or less, and 100 ml is used in this embodiment.

It is possible to soften the washing water for one time (about 60 liters) of high-level washing with this degree of ion exchange resin, but it is sufficient to determine the most appropriate amount by the capacity of the washing machine or the like.

As described above, since the particle diameter of the ion exchange resin is small, the meshes of the mesh filters 18b and 18c of the ion removing member 18 are about 180 mesh.

The ion removal member 18 is pressed by the press cover 19 to the some storage rib 23 formed in the bottom of the storage case 17, and forms the space through which water flows.

This space has a function of a passage for supplying tap water to the ion removing member 18 and a passage for facilitating removal of water from the ion exchange resin of the ion removing member 18.

A water drain hole 24 is formed in the bottom of the storage case 17, and a water drain tube 26 is connected to an outer water drain box 25 that is connected to the water drain hole 24.

As shown in FIG. 2, this water draining tube 26 is connected along the outer periphery of the outer tub 3, and is connected in the vicinity of the bottom part of the outer tub 3 so as to communicate with the inside of the outer tub 3.

Here, the place where the lower end of the water draining tube 26 is located is provided so that it may become lower than the lower part of the washing tank 5, and the water in the storage case 17 rides through the water draining tube 26, and the outer tank 3 Inflow).

A male screw is formed on the outer circumference of the cylindrical press cover 19, and a female screw that is screwed to this is formed on the inner circumference of the storage case 17. Therefore, since the pressure cover 19 is attached to the storage case 17 by screwing, it can attach or detach from the storage case 17 by rotating the pressure cover 19.

And the ion removal member 18 is accommodated in the inside of the pressurization cover 19, and the outer periphery upper end part of the ion removal member 18 is made to contact the inner edge part of the pressurization cover 19. As shown in FIG.

Moreover, the outflow window 27 is provided above the male screw formation part of the press cover 19, and the ceiling plate 28 is formed in this upper side.

The sealing ring 29a is provided in the outer peripheral part of the ceiling board 28 through the outflow window 27, and the sealing ring 29b is provided in the vicinity of the formation part of a male screw.

Since these sealing rings 29a and 29b seal with respect to the storage case 17 above and below the outflow window 27, water does not leak to the outer periphery of the cylindrical inner container 18a.

Next, a concave outflow hole 29 is formed in the center of the upper surface of the ceiling plate 28, and conversely, a downward downward guide portion surrounding the rotation of the outflow hole 29 in the center of the lower surface of the ceiling plate 28. 30) is formed.

On the other hand, in the center of the mesh filter 18b above the ion removal member 18, the upward guide part 31 which rises upwards is formed, and this upward guide part 31 of the ceiling plate 28 is carried out. The downward guide 30 is in an inserted state opposite to each other.

As shown in the figure, a ball-shaped check valve 32 is disposed inside the upward guide portion 31 and the downward guide portion 30.

The check valve 32 is made of a material that floats in water with a specific gravity of about 0.9, and the check valve 32 floats in water so that the water flow lower hole 29 is closed from the lower side.

As shown in Figs. 7 and 8, the salt receiving member 20 has a spherical mesh portion 20a which is raised in the center, and an inclined portion which rises upwardly inclined outward from the bottom of the mesh portion 20a. 20b and the ring wall part 20c which jumps upward from the inclination part 20b to the upper side are formed.

As shown in Fig. 7, the mesh portion 20a has a cross shape and an annular reinforcement rib 20e formed therein, and a handle rod that rises upward in the center of the cross shape reinforcement rib 20e. 20d is formed.

Since salt for regenerating the ion exchange resin is put into the salt receiving member 20, the mesh of the mesh portion 20a is about 130 mesh so that salt particles do not flow out of the ion exchange resin.

The salt support member 20 is combined with the press cover 19 by the technique of ultrasonic bonding, etc., and is integrated.

Four coupling grooves 20f are formed in the ring wall portion 20c of the salt support member 20. When the salt support member 20 is rotated by coupling a screw rotating tool to the coupling groove 20f, a pressure cover ( 19 also rotates, and the press cover 19 can be attached or detached with respect to the storage case 17. As shown in FIG.

As shown in FIG. 6B, a water discharge discharge portion 33 is provided on an outer circumference of the storage case 17 and communicates with an outlet 34 formed in the storage case 17. Specifically, the main water discharge connecting portion 33 is fixedly attached to the formation portion of the outlet port 34 by ultrasonic bonding or the like.

The outlet port 34 and the outlet window 27 are provided at substantially the same height, and the outlet port 34, the outlet window 27, and the main water discharge connection part 33 communicate with each other.

In addition, the water discharge port 35 is provided with a water discharge port 35, and the water discharge port 35 communicates with the water supply part 100 via the communication pipe 50.

As shown in FIG. 9, the communication pipe 50 is connected to the branch part 110 provided in the water injection part 100. As shown in FIG. The branch portion 110 is open to the atmosphere and communicates with the water supply portion 100 via the passage 110a, and also communicates with the water intake inlet 111 to which the water outlet hose 106 of the absorption pump 101 is connected. Doing.

For this reason, part of the tap water discharged from the communication pipe 50 to the branch part flows from the water intake intake port 111 to the water extraction hose 106, and the rest flows to the water injection part 100.

5 and 6A, the storage case 17 is provided with a water supply solenoid valve 37 for supplying water to the water supply unit 100 and a regeneration water supply solenoid valve 36 for supplying regeneration water. The connection tap 14 is arrange | positioned between the water feed solenoid valve 37 and each water supply solenoid valve for regeneration (center).

The discharge side of the feed water solenoid valve 37 is connected to the upstream side of the feed water introduction pipe 39, and the downstream side of the feed water introduction pipe 39 is connected to the bottom side of the storage case 17 via the O-ring 40. It is.

On the other hand, as shown in FIG. 7, the discharge side of the regeneration water supply solenoid valve 36 is connected to the regeneration water inlet 38 provided in the storage case 17, and this regeneration water inlet 38 is a salt supporting member. It is provided so that it may be located above 20.

And the direction of the regeneration water inlet 38 is provided so that it may become substantially tangential to the inner peripheral surface of the storage case 17.

For this reason, the regeneration water flowing into the upper portion of the storage case 17 rotates along the inner circumferential wall surface of the storage case 17, and the salt placed on the salt supporting member 20 is rotated from the surroundings by the rotating water. Because it is dissolved completely, well dissolved salt water is made.

In addition, if the operation state of the regeneration water supply solenoid valve 36 is bad and water flows out too much, since the water flows from the water outlet 21 to the water supply part 100, the salt water does not overflow to the floor in which the washing machine was installed.

In addition, even when a large amount of water flows into the upper side of the salt receiving member 20 due to a malfunction of the check valve 32 when the water supply solenoid valve 37 is opened, the water supply part 100 is discharged from the water supply port 21. As it flows in, it does not leak out to the floor.

The connecting tap 14 of the water supply means penetrates through the back panel 13 and protrudes upward, while the bath water hose connecting port 104 of the absorption pump 101 is upward, but from the surface of the back panel 13. The concave hose connection concave portion 112 is directed.

Next, the operation will be described.

First, the washing machine operates by turning on the power switch shown in FIG. 10 and operating the operation button of the operation button input circuit.

Prior to operation of the washing machine, the drain solenoid valve 9 is closed, the feed water solenoid valve 37 is opened, and water is supplied to the washing tank 5.

Here, in the case where the operation button input circuit is set in the absorption mode using a water source different from the tap water, the absorption water supply valve 101 is operated by the absorption pump 101 instead of opening the water feed solenoid valve 37 to open a water source different from the tap water. Water flows into the washing tank (5).

The amount of water supplied to the washing tank 5 is checked by the water level sensor and instructed by the microcomputer to stop the water supply by the water feed solenoid valve 37 to the absorption pump 101 when stored up to the set water level.

At the same time, the washing instruction is instructed from the microcomputer, and the clutch solenoid is set on the washing side, and washing is performed.

After a predetermined time has elapsed, the washing by the detergent is finished, and the drain solenoid valve 9 is opened by the instruction of the microcomputer, and drainage is performed.

Next, when the microcomputer instructs the dehydration, the clutch solenoid is switched to the dehydration side while the drain solenoid valve 9 is opened, and the washing tank 5 is rotated at high speed so that the water contained in the clothes is dehydrated by the high speed rotation. .

If dehydration is finished, a rinse command is instructed by the microcomputer, and rinsing is performed as in the washing. Usually, rinsing is performed twice, after which final dehydration is performed and the whole process of washing is complete | finished.

The whole stroke of the washing shown in Figs. 11 and 13 shows the above-described details in more detail, and its operation timing and its operation are determined so that the ion removing means operates efficiently in such a series of strokes.

The supply of tap water in the washing process with a detergent is performed by opening the feed water solenoid valve 37 by the instruction of the microcomputer.

Tap water flowing through the feed water introduction pipe 39 by the opening of the feed water solenoid valve 37 flows into the bottom of the storage case 17, and when the inside of the ion removal member 18 flows from the bottom to the top, the ion exchange resin In contact with the ionic components such as magnesium and calcium contained in the tap water is removed, the hardness of the tap water is lowered, the quality of the soft water is improved.

Since the outflow hole 29 is closed by the check valve, the tap water which has been softened by passing through the ion removing member 18 is discharged from the outflow window 27 of the pressurizing cover 19, and the main water discharge connection portion 33. ), The water discharge port 35, the communication tube 50, the branch 110 flows into the water injection unit 100, and is injected into the washing tank 5.

In this way, the tap water is softened and used as washing water, contributing to the improvement of the washing power.

While water for washing the detergent is supplied to the washing tank 5, the tap water which is not softened from the water draining hole 24 at the bottom of the storage case 17 passes through the water draining tube 26. Inflow).

However, since the water draining hole 24 is small, the incoming water is extremely small compared to the water flowing from the water supply part 100 to the washing tank 5, and there is no problem after washing, and from the water draining hole 24 This does not waste water, but contributes to use in washing, and this water waste prevention is the same in the next two rinsing strokes.

In this way, it is advantageous to save the water discharged from the water drain hole 24 into the outer tub 3 on the water-saving surface, but it is also possible to discard it directly to the drain hose 10 side, in which case all the water supplied to the washing tank is softened. As a result, cleaning performance can be improved to the limit.

In addition, softening is not performed when water is supplied by the absorption pump 101 instead of using tap water in the washing process with detergent.

In this case, if the absorption pump 101 is provided with ion removal means, it can be softened.

The softening of tap water is necessary in the washing process using a detergent, and since the detergent is not used in a rinsing stroke, softening is basically unnecessary.

Also in the rinsing water supply, the water supply through the ion removal means is because the amount of ion exchange resin is determined so that the ion removal effect of the ion exchange resin is almost saturated with the amount of water required for the washing process using a detergent.

Thereby, it can be made into one without dividing the water supply channel in a washing | cleaning process and a rinsing process, and can be finished by one main water supply solenoid valve 37.

This is also a solution to the problem that the storage space of the rear part of the upper cover 2 is narrow and it is unreasonable to increase the water feed solenoid valve.

Next, the regeneration operation | movement and operation timing of the ion exchange resin in which the ion removal function was reduced are demonstrated.

This regeneration operation timing is normally performed in the second rinsing stroke as shown in FIG. 11, and the regeneration operation is performed for the main water supply solenoid valve 37 (V ₁ ) and the regeneration water supply solenoid valve 36 in FIG. 12. (V ₂ )) and on / off (opening / closing) of the drain solenoid valve 9 (V ₃ ) are shown by passage of time.

After the water supply of the second rinse stroke is completed, the stirring blade 6 is reversed and inverted to shift to the stirring operation, but the regeneration operation of the ion exchange resin is performed in parallel with the stirring operation.

Specifically, when the water feed solenoid valve 37 (V ₁ ) is turned off (closed) after the water feed time V ₁ t ₁ elapses, the water feed is stopped and the flow shifts to the stirring operation.

After the time of T ₁ (5 to 7 seconds) elapses after the water supply solenoid valve 37 (V ₁ ) is turned off, the regeneration water supply solenoid valve 36 (V ₂ ) is turned on (opened).

Here, the reason for setting T ₁ (5 to 7 seconds) is as follows.

At the moment when the water supply solenoid valve 37 is closed, the water is discharged from the outlet 34 of the storage case 17 to the water discharge outlet 33 and the water supply 100, so that the check valve 32 floats. As a result, the outflow hole 29 is closed.

For this reason, even if the regeneration water solenoid valve 36 is immediately opened and the salt is dissolved, the salt water does not flow down. For example, even if it starts to flow down, it merges with the flow from the outlet 34 toward the water supply part 100 to ion exchange. It is not used for the regeneration of the resin.

Since it takes 2 to 7 seconds for the outflow from the outlet 34 to disappear, the regeneration water supply solenoid valve 36 is opened in consideration of this time delay.

In addition, the opening timing of the regeneration water supply solenoid valve 36 needs to be changed somewhat depending on the level of the wash water stored in the washing tank. It is preferable to open quickly at the low water level and to open slowly at the high water level.

This is because, after the outflow from the outlet 34 is stopped, the water in the storage case 17 is discharged from the water drain hole 24, but the water discharge rate is faster at the low water level and slower at the high water level so that the water is regenerated accordingly. It is necessary to change the opening start time of the water feed solenoid valve 36.

When the regeneration water supply solenoid valve 36 is opened at an appropriate timing, the salt water enters while the water contained in the ion exchange resin is discharged from the water drain hole 24, and the salt water is ion-exchanged so that the salt water is ion exchanged. As it passes through the resin, it flows quickly without delay.

Therefore, after the water feed solenoid valve 37 is closed, it is necessary to open the regeneration feed solenoid valve 36 with appropriate timing.

Then, the opening time of the regeneration water supply solenoid valve 36 (V ₂ ) is V ₂ t ₁ (0.7 to 1.2 seconds), and after this time is closed for the time of T ₂ (30 seconds), V _{2 is} again. It is opened for a time of t ₂ (0.7 to 1.2 seconds).

Thereafter, it is closed again by the time of T ₃ (20 seconds) and then operated to open again by the time of V ₂ t ₃ (0.7 to 1.2 seconds).

In this way, the regeneration water supply solenoid valve 36 is divided into three times, and short opening and closing is repeated, so that a small amount of tap water is supplied to the salt support member 20 located above the storage case 17.

In this embodiment, the number of times is set to three times, but two or more times may be necessary, and importantly, only a small amount of water may be continuously supplied in some cases.

According to such a method, since a large amount of tap water does not flow into the salt support member 20 at once, the salt placed on the salt support member 20 does not flow to the water outlet 21.

The regenerative feed water solenoid valve 36 has a small flow rate of about 2 L / min.

On the other hand, the feed water solenoid valve 37 for water injection is about 13-15 liter / min.

In this embodiment, a small amount of water of about 50 kPa flows in three times, so that the salt on the salt support member 20 is dissolved well, and the generated salt water passes through the mesh portion 20a to form a ceiling plate. It flows to 28, and naturally flows out inside the ion removal member 18 from the outflow hole 29. As shown in FIG.

At this time, the brine contacts the ion exchange resin of the ion removing member 18 to ion exchange the magnesium ions of the ion exchange resin, calcium and sodium ions in the brine, and the ion exchange resin having a reduced softening function is regenerated.

The ion-exchanged salt water flows through the water drain hole 24 and the water drain tube 26 from the bottom of the storage case 17 and flows into the tub 3.

After the _third water supply of the regeneration water supply solenoid valve 36 (V ₃ ) is finished, after the time of T ₄ (20 seconds) elapses, the water supply solenoid valve 37 (V ₁ ) is V ₁ t ₂ It is opened for a time of (5 to 10 seconds).

About 1000 kPa of water in this water supply is supplied to the bottom side of the storage case 17, and ion-exchanged remaining in the storage case 17, the water draining tube 26, and the ion removal member 18 by this water supply. You can wash off the brine later.

By performing such an operation, mixing of the salt water after ion exchange in the washing process performed next time can be avoided beforehand.

In addition, the amount of water used to wash the remaining brine is about 1000 kPa. However, if the amount is too large, magnesium ions or calcium ions of the new tap water are blown into the regenerated ion exchange resin. Quantity is determined experimentally the most appropriate amount.

The V ₃ t ₁ time shown in FIG. 12 shows the drainage operation of the drain solenoid valve 9 (V ₃ ), whereby the rinsing water is drained after the second rinsing is finished.

The second rinse water contains low salt and ionic components, but the concentration is extremely low and there is no problem in the washing process using detergent.

FIG. 13 discloses that the regeneration operation is performed immediately before the washing stroke, and is performed by operating the regeneration button input circuit shown in FIG.

This regeneration operation is performed when the regeneration is not performed in the previous washing or when the ion exchange resin is to be regenerated more.

This regeneration operation relates to turning on and off the water supply solenoid valve 37 (V ₁ ), the regeneration water supply solenoid valve 36 (V ₂ ), and the drain solenoid valve 9 (V ₃ ). Fig. 14 shows lungs in time.

Compared with the regeneration operation shown in FIG. 14 and the regeneration operation shown in FIG. 12, the first difference is that the water supply solenoid valve 37 (V) is operated before the regeneration water supply solenoid valve 36 (V ₂ ) is opened. ₁ )) is temporarily open.

The temporary opening of the feed water solenoid valve 37 (V ₁ ) for a time of V ₁ t ₃ (5 to 10 seconds) is intended to allow the brine to quickly pass through the ion exchange resin as described above. At this time, water of about 1000 kPa is injected into the storage case 17, and thereafter, the regeneration water supply described with reference to FIG.

The second difference is that the washing stroke is carried out after the washing of the ion exchanged brine is completed.

After the water supply solenoid valve 37 (V ₁ ) is opened for a time of V ₁ t ₂ (5 to 10 seconds) and washing of the ion-exchanged salt water is completed, the water is supplied again by button operation of the operation button input circuit. The water supply solenoid valve 37 (V ₁ ) is opened for V ₁ t ₅ hours and water supply necessary for the washing stroke is performed.

In addition, when the regeneration button input circuit and the operation button input circuit are set together, the cleaning process is performed without leaving a gap in the washing of the ion-exchanged salt water.

The third difference is that the drain solenoid valve 9 (V ₃ ) is left open until the washing of the ion exchanged brine is completed.

Since the ion-exchanged brine should not be mixed with the softened tap water, the drain solenoid valve 9 (V ₃ ) is opened to be discharged.

According to the embodiment described above, the following effects can be expected.

(1) If the ion exchange resin can be repeatedly used while being regenerated by the regeneration means and the regeneration becomes impossible, the ion removal member can be removed from the case and replaced with a new ion removal member.

(2) Before the brine is spilled into the ion exchange resin, the water supply solenoid valve for opening is opened to supply the ion exchange resin with water to accelerate the brine outflow rate, so that the brine outflow time is shortened as compared with the case without the water supply. .

(3) The ion exchange function of the ion exchange resin of the washing machine can be regenerated even when the ion exchange resin is not regenerated in the last washing or the washing machine is not used for a long time.

(4) Since tap water is supplied in multiple times to salt, which is a regeneration agent, it can be effectively used without overflowing tap water.

(5) Residual salt water can be suppressed in the ion exchange resin after regeneration.

(6) Since the salt water after the regeneration of the ion exchange resin has a low concentration due to a large amount of rinsing water in the rinsing cycle, the influence of salt is reduced.

According to the structure of the cation removal device for washing machines which becomes this invention, an ion remover can be used repeatedly, regenerating with a regeneration means.

In addition, if regeneration is not possible, the ion removal member can be removed from the case and replaced with a new ion removal member.

1 is an external view of a washing machine according to the present invention.

FIG. 2 is a sectional view taken along line AA of FIG.

3 is an enlarged view of a top cover rear portion of the washing machine shown in FIG.

4 is a cross-sectional view of FIG.

Fig. 5 shows the top cover back view from above with the back panel removed.

Fig. 6A is a sectional view of the ion removing means.

Fig. 6B is an external view showing a part of the storage case of the ion removing means in a cross section.

Figure 7 is a view of the storage case from above.

Figure 8 is a unitary view of the salt support member.

Fig. 9 is a sectional view showing a branching portion in which water is diverted to the water outlet side and the water intake side.

10 is a schematic circuit diagram of an entire washing machine.

Fig. 11 is a stroke / operation diagram showing the relationship between the previous administration and the operation regarding washing.

Fig. 12 shows the operation of the ion removing means in the order of opening and closing of the feed water solenoid valve, regeneration feed solenoid valve, and drain solenoid valve.

FIG. 13 is a view corresponding to FIG. 11 showing that the regeneration operation of the ion removing means is performed immediately before the washing stroke;

FIG. 14 is a view corresponding to FIG. 12, showing a case in accordance with FIG.

<Explanation of symbols for the main parts of the drawings>

17: storage case of ion removal means

18: ion removal member

18a: cylindrical inner container

20: salt support member for regeneration salt

21: Ilsu-gu

36: regeneration water solenoid valve

37: feed water solenoid valve

Claims (31)

Ion removal means which accommodates the ion exchange member which removes the cation component of tap water in a case, and the regeneration means which supplies regeneration water to the said ion removal means in order to regenerate the said ion exchange member to one side of this ion removal means, and the washing tank Integrally attached to the case a water supply valve for supplying tap water to the washing tank through the ion removal means at the time of water supply to the furnace and a regeneration valve for supplying the regeneration water to the ion exchange member at the time of regeneration of the ion exchange member. Cation removal device for a washing machine characterized by the above-mentioned. Ion removal means which accommodates the ion exchange member which removes the cation component of tap water in a case, and the regeneration means which supplies regeneration water to the said ion removal means in order to regenerate the said ion exchange member to one side of this ion removal means, and the washing tank A water supply valve for supplying tap water to the washing tank through the ion removal means at the time of water supply to the furnace, and a regeneration valve for generating regeneration water by flowing tap water to the regeneration means at the time of regeneration of the ion exchange member. A cation removal device for a washing machine, which is attached integrally to the case. An ion removing member containing an ion exchange member for removing the cation component of tap water in a bottomed cylindrical case having an open portion at one end and a bottom portion at the other end, and installed at the open side of the case to regenerate the ion exchange member. A regeneration chamber for generating regenerated water, a water supply solenoid valve portion connected to the faucet on the outer periphery of the case and connected to the ion removing member, and a regeneration solenoid valve portion connected to the regeneration chamber and connected to the faucet; When the water is supplied to the furnace, the water supply solenoid valve is opened to supply tap water to the washing tank through the ion removing member, and when the ion exchange member is regenerated, the regeneration solenoid valve is opened to allow tap water to flow into the regeneration chamber. Washing, characterized in that to generate and supply to the ion removing member Cation removal apparatus. An ion removing member containing an ion exchange member for removing the cation component of tap water in a bottomed cylindrical case having an open portion at one end and a bottom portion at the other end, and installed at the open side of the case to regenerate the ion exchange member. A space for supplying tap water for supplying tap water to the ion removing member and formed between a regeneration chamber for generating regeneration water and the bottom portion of the case and the ion removing member, and connected to a faucet at an outer circumference of the case. A regeneration solenoid valve portion connected to the water supply valve and the faucet connected to the space, and a regeneration solenoid valve portion connected to the regeneration chamber, and the water supply solenoid valve is opened at the time of water supply to the washing tank to pass through the ion removing member from the space Tap water is supplied to the washing tank, and the When the washing machine cation removal device for generating a Current Views by opening the solenoid valve spill playing the water in the reproduction room, characterized in that to be supplied to the ions on the removal member.  The ion removal member which accommodates the ion exchange member which removes the cation component of tap water in the bottomed cylindrical case which has an opening part in one end and a bottom part in the other end, and the said ion exchange in the opening part side of the said case of this ion removal member. A regeneration chamber in which the salt for regenerating the member is stored is disposed, and a tap water flows through the ion removing member and supplies tap water to the washing tank when the water is supplied to the washing tank, and tap water is flowed into the regeneration chamber to dissolve the salt. The washing machine characterized in that the regeneration valve which is supplied to the ion removing member at the time of regeneration of the ion exchange member is integrally attached to the case, and the mesh member for distributing the dissolved salt is disposed in the regeneration chamber. Cation removal device. The ion removal member which accommodates the ion exchange member which removes the cation component of tap water in the bottomed cylindrical case which has an opening part in one end and a bottom part in the other end, and the said ion exchange in the opening part side of the case of the said ion removal member. A regeneration chamber in which the salt for regenerating the member is stored at every regeneration; a water supply valve for supplying tap water to the washing tub through the ion removal member at the time of water supply to the washing tank; and the regeneration chamber at the time of regeneration of the ion exchange member. A reinforcing valve integrally attached to the case for flowing the tap water to dissolve the salt and supplying the salt to the ion removing member, and in the regeneration chamber, a supporting part having a mesh for allowing distribution of the dissolved salt is disposed; The support part is removed toward the opening part and at the same time the ion is removed in the same direction. A cation removal device for a washing machine, wherein the member is also removed and replaced. Ion removal means containing an ion exchange member for removing the cation component of the tap water and a regeneration chamber for storing the salt for regenerating the ion exchange member are disposed in the case, and connected to a faucet on the outer circumference of the case to the ion removal means. And a regeneration solenoid valve portion connected to the water supply solenoid valve portion connected to the water supply passage and the faucet connected to the faucet through the regeneration water passage for supplying the tap water to the regeneration chamber. Opens and supplies tap water to the washing tank through the ion removal means from the water supply tank, opens the regeneration solenoid valve at the time of regeneration of the ion exchange member, supplies tap water as a swirl flow to the regeneration chamber, and dissolves the salt. Three to the ion exchange member Appointed cation removal device. An ion removal member containing an ion exchange member for removing the cation component of the tap water and a regeneration chamber for generating a regeneration water for regenerating the ion exchange member and having a water passage leading to the washing tank are disposed, and the regeneration chamber and the ion removal are disposed. A check valve is provided between the members to allow the flow of regeneration water from the regeneration chamber, and a water supply solenoid valve portion connected to the faucet on the outer periphery of the case and connected to the ion removing member and the faucet to the regeneration chamber; Subsequently, a regenerative solenoid valve portion is provided, the water solenoid valve is opened at the time of water supply to the washing tank, the tap water is supplied to the washing tank through the ion removing member, and the regenerative solenoid valve is opened at the time of regeneration of the ion exchange member. To generate regeneration water by flowing tap water into the regeneration chamber. Through the check valve washer cation removal apparatus, characterized in that to be supplied to the ion-exchange member. An ion removing member containing an ion exchange member for removing the cation component of tap water in a bottomed cylindrical case having an open portion at one end and a bottom portion at the other end, and installed at the open side of the case to regenerate the ion exchange member. A tap water supply having a drainage passage formed between the bottom of the case and the ion removing member for supplying regeneration water to the ion removing member and supplying tap water to the ion removing member and draining the regeneration water. Arranging a space, supplying tap water to the washing tank through the ion removing member from the space at the time of water supply to the washing tank, and supplying regeneration water from the regeneration chamber to the ion removing member at the time of regeneration of the ion exchange member. Washing machine amount characterized in that it is discharged to the drain passage Deionizer. In a washing machine having an outer frame, a washing tank disposed in the outer frame, a water supply device for supplying water to the washing tank, and a drainage device for draining the water in the washing tank, An ion removal member containing an ion exchange member for removing the cation component of tap water in the washing machine above the washing tank, and a water supply valve for supplying tap water to the washing tank through the ion removing member at the time of water supply and the ion removing member. And a cation removal device integrally provided with a regeneration chamber for supplying regeneration water to the ion removal member and a regeneration valve for supplying the regeneration water to the ion exchange member to regenerate the ion exchange member on one side. In a washing machine having an outer frame, a washing tank disposed in the outer frame, a water supply device for supplying water to the washing tank, and a drainage device for draining the water in the washing tank, An ion removal member containing an ion exchange member for removing the cation component of tap water in the washing machine above the washing tank, and a water supply valve for supplying tap water to the washing tank through the ion removing member at the time of water supply and the ion removing member. A regeneration chamber for supplying regeneration water to the ion removing member and a regeneration valve for supplying the regeneration water to the ion exchange member to integrally attach a regeneration chamber on one side to regenerate the ion exchange member, The washing machine provided with the inlet opening for regeneration water which opens to the said washing machine outside. In a washing machine having an outer frame, an upper cover provided above the outer frame, a washing tank disposed in the outer frame, a water supply device for supplying water to the washing tank, and a drainage device for draining the water in the washing tank, An ion removal member containing an ion exchange member for removing the cation component of the tap water in the upper cover, a water supply valve for supplying tap water to the washing tank through the ion removal member at the time of water supply and the ion to one side of the ion removal member A cation removal device integrally attached with a regeneration chamber accommodating salt for regenerating the exchange member and a regeneration valve for supplying the salt dissolved by tap water to the regeneration chamber upon regeneration of the salt to the ion exchange member, And a lid for closing the opening, and an opening for injecting the salt from the outside into the regeneration chamber of the cation removal device. Ion removal means disposed in the main body of the washing machine to accommodate the ion exchange resin for softening the tap water, regeneration means for supplying regeneration water for regenerating the ion exchange resin, water supply means for supplying tap water to the ion removal means And control means for controlling the water supply means and the regeneration means, and when regeneration is selected before the washing stroke, the control means supplies the tap water to the ion exchange resin by the water supply means, and The control method of the washing machine characterized by regenerating water by the said water supply means after regenerating ion exchange resin. Ion removal means disposed in the main body of the washing machine to accommodate the ion exchange resin for softening the tap water, a regeneration valve for supplying brine to the ion exchange resin to regenerate the ion exchange resin, and supply of tap water to the ion removal means And a control means for controlling the opening and closing of the regeneration valve and the water supply valve, and when regeneration is selected before the washing stroke, the control means opens the water supply valve to supply a predetermined amount of tap water to the ion exchange resin. And after that, the regeneration valve is opened to supply salt water to the ion exchange resin for regeneration, and then the water supply valve is opened again to supply water. Ion removal means disposed in the main body of the washing machine to accommodate the ion exchange resin for softening the tap water, regeneration means for supplying regeneration water for regenerating the ion exchange resin, water supply means for supplying tap water to the ion removal means And control means for controlling the water supply means and the regeneration means, and when regeneration is selected before the washing stroke, the control means supplies the tap water to the ion exchange resin by the water supply means and then the ions by the regeneration means. The water supply means is supplied again by the water supply means after regenerating the exchange resin, and the drainage means of the washing machine is opened until the water supply of the water supply means which supplies the water after the ion exchange resin regeneration is left in a drained state. Control method. Ion removal means containing an ion exchange resin for softening tap water in a main body of a washing machine, regeneration means for regenerating the ion exchange resin, water supply means for supplying tap water to the ion removal means, the regeneration means and the water supply And a control means for controlling the means, and in the case where the user selects the regeneration before the water supply in the washing process using the detergent, after the ion exchange resin is regenerated by the regeneration means, water is supplied by the water supply means. Control method of washing machine. Ion removal means for storing an ion exchange resin for softening tap water in a main body of a washing machine, regenerating means for storing salt for regenerating the ion exchange resin, water feed solenoid valve for supplying tap water to the ion removal means, and A regeneration water supply solenoid valve for supplying tap water to the regeneration means, and control means for controlling opening and closing of the main water supply solenoid valve and the regeneration water supply solenoid valve, If the user selects regeneration before washing water in the washing stroke, the control means opens the regeneration water solenoid valve to generate salt water, and after regenerating the ion exchange resin by the salt water, the water supply solenoid valve for main water. The control method of the washing machine characterized in that for opening the water supply. Ion removal means containing an ion exchange resin for softening tap water in a main body of a washing machine, a water supply valve for supplying tap water to the ion removal means, a regeneration valve for supplying regeneration water for regenerating the ion exchange resin, and And a control means for controlling opening and closing of a water supply valve and the regeneration valve, wherein the control means opens and closes the regeneration valve in a plurality of times at the time of regeneration of the ion exchange resin. Ion removal means containing an ion exchange resin for softening tap water in a main body of a washing machine, a water supply valve for supplying tap water to the ion removal means, a regeneration valve for supplying regeneration water for regenerating the ion exchange resin, and And a control means for controlling opening and closing of the water supply valve and the regeneration valve, wherein the control means opens and closes the regeneration valve in a plurality of times in a state in which the water supply valve is closed at the time of regeneration of the ion exchange resin. Control method. Ion removal means containing an ion exchange resin for softening tap water in the main body of the washing machine, a feed water solenoid valve for supplying tap water to the ion removal means, and supplying brine to the ion exchange resin to supply the ion exchange resin A regeneration water supply solenoid valve for supplying regeneration water for regeneration, and control means for controlling opening and closing of the main water supply solenoid valve and the regeneration water supply solenoid valve, wherein the control means regenerates the regeneration of the ion exchange resin. The control method of the washing machine characterized by dividedly opening and closing the water supply solenoid valve multiple times. Ion removal means containing an ion exchange resin for softening tap water in the main body of the washing machine, a solenoid valve for supplying tap water to the ion removal means, and regeneration for supplying regeneration water for regenerating the ion exchange resin. A replenishment means for regenerating the ion exchange resin with salt water in which salt is stored and dissolved by the regenerated water; and control means for controlling opening and closing of the main water solenoid valve and regeneration water supply solenoid valve. And the control means opens and closes the regeneration water supply solenoid valve in a plurality of times in a state in which the main water supply solenoid valve is closed at the time of regeneration of the ion exchange resin. Ion removal means containing an ion exchange resin for softening tap water in the main body of the washing machine, a feed water solenoid valve for supplying tap water to the ion removal means, and regeneration for supplying regeneration water for regenerating the ion exchange resin. A water supply solenoid valve and regeneration means for regenerating the ion exchange resin by salt water stored in an upper portion of the ion exchange resin and dissolved by the regeneration water; And a control means for controlling the opening and closing of the water feed solenoid valve and the regenerative water feed solenoid valve, wherein the control means is configured to close the water feed solenoid valve after the water supply of the final rinsing stroke is finished. The control method of the washing machine characterized by opening and closing the electromagnetic valve divided into a plurality of times. Ion removal means containing an ion exchange resin for softening tap water in the main body of the washing machine, water supply means for supplying tap water to the ion removal means, regeneration means for regenerating the ion exchange resin, the water supply means and the regeneration And a control means for controlling the means, said control means supplying tap water by said water supply means after regeneration by said regeneration means to wash away the ionic components remaining between said ion exchange resins. Ion removal means containing an ion exchange resin for softening tap water in the main body of the washing machine, a water supply solenoid valve for supplying tap water to the ion removal means, and a regeneration water supply for supplying regeneration water for regenerating the ion exchange resin A solenoid valve, and a control means for controlling the main feed water solenoid valve and the regenerative feed water solenoid valve, wherein the control means opens the regenerative feed water solenoid valve to regenerate the ion exchange resin, and then the main feed water feed water. The control method of the washing machine characterized by opening the solenoid valve and supplying tap water to the ion exchange resin to wash away the ionic components remaining between the ion exchange resin. Ion removal means for storing the ion exchange resin for softening the tap water in the main body of the washing machine, water supply solenoid valve for supplying tap water to the ion removal means, and regeneration for supplying regeneration water for regenerating the ion exchange resin A water supply solenoid valve, regeneration means for regenerating said ion exchange resin by salt water stored and dissolved by said regeneration water, and a control means for controlling said water feed solenoid valve and said regeneration water solenoid valve, The control means opens the regenerative water supply solenoid valve to regenerate the ion exchange resin, closes the regenerative water supply solenoid valve, opens the main water supply solenoid valve, supplies tap water to the ion exchange resin, and supplies the ions. Control of the washing machine characterized by washing out the ionic component remaining between the exchange resin Way. Ion removing means having an outer frame, an outer tank provided in the outer frame, a washing tank rotatably disposed in the outer tank, water supply means for supplying tap water to the washing tank, and an ion exchange resin for softening tap water in the water supply. In the washing machine having a, The washing machine has regeneration means for supplying regeneration water for regenerating the ion exchange resin, and a washing machine having discharge means for discharging the regenerated water after the regeneration into the outer tank below the washing tank. An outer frame, an outer tub disposed in the outer frame, a washing and dewatering tank rotatably disposed in the outer tank, a water supply solenoid valve for supplying tap water to the washing and dewatering tank, and water in the washing and dewatering tank A washing machine having drainage means for draining water and ion removal means having an ion exchange resin for softening tap water in water supply, The washing machine has a regeneration water supply solenoid valve for supplying regeneration water for regenerating the ion exchange resin, and has a discharge means for discharging the regeneration water after the regeneration into the outer tank as lower than the washing / dehydration tank. washer. An outer frame, an outer tank provided in the outer frame, a washing and dewatering tank rotatably disposed in the outer tank, a water supply solenoid valve for supplying tap water to the washing and dewatering tank, and water in the washing and dewatering tank A washing machine having drainage means for draining water and ion removal means having an ion exchange resin for softening tap water in water supply, The washing machine includes a regeneration water supply solenoid valve for regenerating the ion exchange resin, regeneration means for regenerating the ion exchange resin with salt water stored and dissolved by the regeneration water, and the salt water after regeneration by a tube. And a discharging means for discharging into the outer tub as lower than the washing and dehydrating tank. Ion removal means containing an ion exchange resin for softening tap water in a main body of a washing machine, regeneration means for regenerating the ion exchange resin, water supply means for supplying tap water to the ion removal means, the regeneration means and the water supply And a control means for controlling the means, wherein the control means regenerates by the regeneration means after completion of water supply by the water supply means in the final rinse stroke of washing. Ion removal means for storing an ion exchange resin for softening tap water in a main body of a washing machine, a regeneration valve for supplying regeneration water for regenerating the ion exchange resin, a water supply valve for supplying tap water to the ion removal means, And a control means for controlling opening and closing of the water supply valve and the regeneration valve, the control means controlling the washing machine by reopening the regeneration valve to perform regeneration after closing the water supply valve in the final rinsing stroke of washing. Way. The ion removal member which accommodates the ion exchange resin which softens tap water in the main body of a washing machine, the salt accommodating part which receives the salt which regenerates the said ion exchange resin, and the said salt water between the ion removal member and the said salt accommodating part. A valve that allows flow from a lead portion to the ion removing member, a water supply solenoid valve for supplying tap water to the ion removing member, a regeneration water supply solenoid valve for supplying tap water to the salt receiving portion, and the water supply for water supply It has a control means for controlling the opening and closing of the solenoid valve and the regeneration water supply solenoid valve, And the control means performs the regeneration by opening the regenerative water supply solenoid valve after closing the main water feed solenoid valve in the final rinsing cycle of washing.