JP5825967B2 - Washing machine - Google Patents

Description

  The present invention relates to a washing machine such as a drum type washing machine or a vertical washing machine.

  In the washing machine, when the laundry in the rotating tub is washed by rotating the rotating tub, soap scum accumulates on the inner wall surface of the rotating tub, the inner wall surface of the drainage hose, and the like. Microorganisms such as bacteria or molds propagate using this soap residue as a nutrient source.

  For this reason, a washing machine capable of antibacterial and sterilizing a rotating tub with silver ions has been proposed (see, for example, Japanese Patent Application Laid-Open No. 2004-166940 (Patent Document 1)). In this washing machine, when the user sets the silver mode, a predetermined concentration of silver ion water is introduced into the water tank in the final rinsing step.

JP 2004-166940 A

  By the way, in the said conventional washing machine, it is only when the user sets silver mode that silver ion water is thrown in in a water tank. In other words, if the user does not set the silver mode, the silver ion water is not put into the water tank.

  Therefore, if the user does not know the silver mode, or if the user forgets to set the silver mode, antibacterial / sterilization by silver ions is not performed, and microorganisms such as bacteria and mold propagate. is there.

  In particular, the drainage hose for draining the washing water in the aquarium tends to collect water and soap debris at the bend and bellows, except when it is connected to the drain outlet straight at the shortest distance. And microorganisms such as bacteria and molds are easy to propagate. In many cases, the odor caused by the microorganisms flows back into the washing machine, and the odor is generated from the washing machine, resulting in user complaints.

  Then, the subject of this invention is providing the washing machine which can prevent the propagation of microorganisms, such as bacteria and mold, and can keep clean.

In order to solve the above problems, the washing machine of the present invention is:
An outer box,
A water tank disposed in the outer box;
A rotating tub that is rotatably arranged in the water tub, and stores the laundry;
A drainage hose for draining the liquid in the water tank or the rotating tank,
A driving device for rotationally driving the rotating tank;
A metal ion water generating device that converts the water flowing toward the water tank or the rotary tank into metal ion water;
A control device for controlling the driving device and the metal ion water generating device to perform the rinsing process once or a plurality of times;
The control device
Standard mode control means for controlling the metal ion concentration of metal ion water supplied into the water tank or the rotating tank to a preset standard concentration;
A memory for storing the number of operations,
An operation frequency determination means for determining whether or not the operation frequency stored in the memory has reached a preset number of times;
When it is determined by the operation number determination means that the operation number has reached the set number of times, the metal ion concentration of the metal ion water supplied into the water tank or the rotating tank is set higher than the standard concentration. First metal ion concentration setting means for setting;
In the final rinsing step of the rinsing step, the first metal ion water forcibly supplying the metal ion water having the metal ion concentration set by the first metal ion concentration setting means into the water tank or the rotating tank. And a supply means.

  According to the above configuration, the operation number determination means determines whether or not the operation number stored in the memory has reached a preset number of times. When the operation number determination means determines that the operation number has reached the set number of times, the first metal ion concentration setting means sets the metal ion concentration of the metal ion water supplied to the inside of the water tank or the rotating tank from the standard concentration. Set to be higher. The first metal ion water forced supply means forces the metal ion water having the metal ion concentration set by the first metal ion concentration setting means into the water tank or the rotary tank in the final rinse step of the rinse process. To supply.

  As described above, when the number of operations reaches the set number of times, in the final rinsing step of the rinsing step, metal ion water having a metal ion concentration higher than the standard concentration is forcibly supplied into the water tank or the rotating tank. Therefore, even if the user does not know the mode that uses metal ion water or the user forgets to set the mode, the microorganisms that have propagated in the water tank or the rotating tank are sterilized and moved out of the water tank with the metal ion water. Can be discharged. That is, the sterilization and removal of the microorganism can be performed automatically and periodically. Therefore, the washing machine can be kept clean.

  Moreover, the metal ion water forcedly supplied in the said water tank or a rotation tank flows through a drainage hose after completion | finish of the last rinse process. As a result, even if the drainage hose is bent and soap scum accumulates in the bent part of the drainage hose, metal ion water can be stored in the bent part. Can be sterilized. Therefore, it is possible to prevent the off-flavor caused by the microorganisms from flowing back into the washing machine.

In one embodiment of the washing machine,
The control device
Mode determining means for determining whether or not a mode for supplying metal ion water into the water tank or the rotating tank is set;
When it is determined by the mode determination means that the mode for supplying metal ion water into the water tank or the rotary tank is not set, the metal ion concentration of metal ion water supplied into the water tank or the rotary tank is A second metal ion concentration setting means for setting to be lower than the standard concentration;
In the final rinsing step of the rinsing step, the second metal ion water forcing that forcibly supplies the metal ion water having the metal ion concentration set by the second metal ion concentration setting means into the water tank or the rotating tank. Supply means.

  According to the said embodiment, the said mode determination means determines whether the mode which supplies metal ion water in a water tank or a rotation tank is set. When it is determined by this mode determination means that the mode for supplying metal ion water into the water tank or the rotation tank is not set, the metal ion water supplied by the second metal ion concentration setting means into the water tank or the rotation tank. Is set to be lower than the standard concentration. In the final rinsing step of the rinsing step, the second metal ionic water forced supply unit forces the metal ion water having the metal ion concentration set by the second metal ion concentration setting unit into the water tank or the rotating tank. To supply.

  Thus, even if the mode for supplying metal ion water into the water tank or the rotating tank is not set, in the final rinse step of the rinse step, the metal ion water having a metal ion concentration lower than the standard concentration is the water tank. Or since it is forcibly supplied into the rotating tank, the water tank, rotating tank and drainage hose can be automatically and regularly antibacterial.

  In the washing machine of the present invention, when it is determined by the operation number determination means that the operation number has reached the set number of times, the first metal ion concentration setting means is a metal ion water supplied to the water tank or the rotating tank. The ion concentration is set to be higher than the standard concentration, and the first metal ion water forced supply means sets the metal ion concentration set by the first metal ion concentration setting means in the final rinse step of the rinse step. If the user does not know the mode to use the metal ion water or forgets to set the mode, the water ion or water tank will be supplied to the water tank or the rotary tank. Bacteria that have propagated can be sterilized and discharged together with metal ion water automatically and regularly outside the aquarium. Therefore, the washing machine can be kept clean.

  In addition, the metal ion water forcibly supplied into the water tank or the rotating tank flows through the drain hose after the final rinsing process, so that even if the drain hose has a bent part, Can store metal ion water, so that microorganisms in the bent portion can be surely sterilized. Therefore, it is possible to prevent the off-flavor caused by the microorganisms from flowing back into the washing machine.

FIG. 1 is a schematic perspective view of a drum type washing / drying machine according to an embodiment of the present invention. FIG. 2 is a schematic sectional view of the drum type washing and drying machine. FIG. 3 is a control block diagram of the drum type washing and drying machine. FIG. 4 is a flowchart of the washing process of the drum type washing and drying machine. FIG. 5 is a flowchart of the rinsing process of the drum type washing and drying machine. FIG. 6 is a part of a flowchart of the final rinsing process of the drum type washing and drying machine. FIG. 7 is another part of the flowchart of the final rinsing process of the drum type washing and drying machine. FIG. 8 is another part of the flowchart of the final rinsing process of the drum type washing and drying machine. FIG. 9 is a flowchart of the silver ion concentration determination process of the drum type washing and drying machine.

  Hereinafter, a washing machine of the present invention will be described in detail with reference to embodiments shown in the drawings.

  FIG. 1 is a schematic view of a drum type washing / drying machine according to an embodiment of the present invention as viewed obliquely from above.

  The drum-type washing and drying machine includes an outer box 1 having an outer box opening 6 on the front side. A door 7 for closing the outer box opening 6 is attached to the front surface of the outer box 1 by a hinge so as to be rotatable in the left-right direction. When the door opening button 8 is pressed while the outer box opening 6 is closed by the door 7, the door 7 is slightly opened by a biasing force of a biasing member (not shown). In addition, an operation unit 9 having operation keys and a display unit is provided on the outer box 1. A control device 11 (see FIG. 2) for controlling the operation of the drum type washing and drying machine is arranged on the back side of the operation unit 9 (inside the outer box 1).

Although not shown, the operation unit 9 has an Ag ⁺ button for setting the Ag ⁺ (silver ion) standard mode or the Ag ⁺ strong mode. By default, neither the Ag ⁺ standard mode nor the Ag ⁺ strong mode is set, but when the Ag ⁺ button is pressed once, the Ag ⁺ standard mode is set. Further, when the Ag ⁺ standard mode is set, when the Ag ⁺ button is pressed once, the Ag ⁺ strong mode is set. In addition, when the Ag ⁺ strong mode is set, when the Ag ⁺ button is pressed once, neither the Ag ⁺ standard mode nor the Ag ⁺ strong mode is set. Note that Ag ⁺ standard mode is an example of the standard mode.

The Ag ⁺ standard mode is a mode for supplying silver ion water having a silver ion concentration of 150 ppb into the water tank 2 using the silver ion elution device 40 (see FIG. 2). On the other hand, the Ag ⁺ strong mode is a mode for supplying silver ion water having a silver ion concentration of 300 ppb into the water tank 2 using the silver ion elution device 40 (see FIG. 2). Regardless of whether the Ag ⁺ standard mode or the Ag ⁺ strong mode is set, a time for immersing the laundry in the metal ion water is provided. 150 ppb is an example of a standard concentration.

  FIG. 2 is a schematic cross-sectional view of the drum type washing and drying machine as viewed from the side.

  The drum-type washing and drying machine includes a bottomed cylindrical water tank 2 disposed in the outer box 1, a bottomed cylindrical drum 3 that is rotatably disposed in the water tank 2, and stores laundry. A brushless motor 4 that is attached to the rear part of the water tank 2 and rotationally drives the drum 3 and two dampers 12 (only one is shown in FIG. 2) that elastically supports the rear part of the water tank 2 are provided. The drum 3 is an example of a rotating tub, and the brushless motor 4 is an example of a driving device.

  A water supply port 10 is provided at the rear of the upper surface of the outer box 1. The water supply port 10 is connected to a water tap through a water supply hose (not shown). Further, the water supply port 10 is connected to the injection port of the water supply valve 13 in the outer box 1. Thereby, the tap water flows into the water tank 2 from the upper part of the water tank 2 via the water supply duct 15 and the detergent case (not shown), or flows through the cooling water duct 14 and flows into the water tank 2. It is possible to flow into the water tank 2 from the lower part.

  A water tank opening 16 facing the outer box opening 6 is provided on the front surface of the water tank 2 so as to face obliquely upward. The opening edge of the water tank opening 16 is connected to the opening edge of the outer box opening 6 via a cylindrical connecting member 17. A packing 18 made of an elastic material such as rubber or soft resin is fixed to the opening edge of the water tank opening 16. Thereby, when the door 7 is closed, the door 7 is brought into close contact with the packing 18 so that the liquid in the water tank 2 can be prevented from leaking out of the water tank 2. Further, when the drain motor 23 opens the drain valve 22, the liquid in the water tank 2 sequentially flows through the drain duct 19, the connection case 20 and the drain hose 21 and flows out of the outer box 1. Further, when the circulation pump 24 is driven with the drain valve 22 closed, the liquid in the water tank 2 can be taken out of the water tank 2 and returned to the water tank 2 through the drain duct 19 and the circulation duct 25. . Further, the connection case 20 accommodates the lint filter 70.

  The drum 3 is arranged so as to be inclined with respect to the horizontal direction so that the rear side is lowered with respect to the front side. Further, a drum opening 26 facing the outer box opening 6 and the water tank opening 16 is provided on the front surface of the drum 3. Further, a plurality of small holes 27 (only six are shown in FIG. 2) are provided on the peripheral wall of the drum 3 over the entire circumference. A plurality of baffles 28 (only one is shown in FIG. 2) are provided on the inner surface of the peripheral wall of the drum 3 so as to protrude radially inward. A liquid balancer 29 is attached to the drum opening 26 of the drum 3.

  The drum type washing and drying machine includes a metallic cooling plate 30, a blower 33, and a heater 34 in order to dry the laundry. During the drying operation, after the air around the cooling plate 30 exits the water tank 2 from the outlet 31 at the bottom of the rear surface (bottom) of the water tank 2, the outlet duct 32, the blower 33, the heater 34 and the introduction duct 35 are connected. It flows in sequence and blows out into the drum 3 from the annular introduction hole 36 in the rear surface portion of the drum 3. Reference numeral 37 denotes an air filter.

  Further, a nozzle 38 for ejecting silver ion water is attached to the introduction duct 35. The nozzle 38 is connected to the lower end of a branch duct 39 branched from the upper end of the cooling water duct 14. Moreover, the tap water in the branch duct 39 becomes silver ion water via the silver ion elution device 40. Further, a check valve 41 is provided at the lower end portion of the branch duct 39 so that silver ion water does not flow backward. The silver ion elution device 40 is an example of a metal ion water generator.

  The silver ion elution device 40 is configured in the same manner as the ion elution unit disclosed in Japanese Patent Application Laid-Open No. 2004-166940, and adds silver ions to tap water. The tap water (silver ion water) to which the silver ions have been added flows out into the drum 3 through the nozzle 38, the introduction duct 35 and the introduction hole 36.

  The damper 12 has a cylinder part 42 in which oil is sealed, and a piston rod 43 whose upper end part is in the cylinder part 42. The lower end of the piston rod 43 is attached to a damper support bracket 45 via a damper bush 44 made of an elastic material (for example, NBR (nitrile rubber)).

  FIG. 3 is a control block diagram of the drum type washing machine.

  The control device 11 includes a microcomputer and an input / output circuit, and includes a brushless motor 4, an operation unit 9, a water supply valve 13, a drainage motor 23, a circulation pump 24, a blower 33, a heater 34, a silver ion elution device 40, a first A temperature sensor 46A, a second temperature sensor 46B, and a buzzer 47 are connected. Based on the signal from the operation unit 9 and the detection signals from the first temperature sensor 46A and the second temperature sensor 46B, the control device 11 includes the brushless motor 4, the water supply valve 13, the drain motor 23, the circulation pump 24, By controlling the blower 33, the heater 34, the silver ion elution device 40, the buzzer 47, etc., the washing process, the rinsing process, the dehydrating process or the drying process is performed. Although not shown in FIG. 2, the first temperature sensor 46 </ b> A is attached to the upstream end portion of the lead-out duct 32 and sends a detection signal indicating the temperature of the air in the end portion to the control device 11. On the other hand, the second temperature sensor 46 </ b> B is attached to the downstream end portion of the introduction duct 35, and sends a detection signal indicating the temperature of the air in the end portion to the control device 11.

  In addition, the control device 11 includes a readable / rewritable nonvolatile memory 48, a timer 49, a standard mode control unit 50 as an example of a standard mode control unit, and a process execution number determination as an example of an operation number determination unit. Unit 51, a first silver ion concentration setting unit 52 as an example of a first metal ion concentration setting unit, a first silver ion water forced supply unit 52 as an example of a first metal ion water forced supply unit, and mode determination A mode determination unit 54 as an example of means, a second silver ion concentration setting unit 55 as an example of second metal ion concentration setting means, and a second silver ion water forcing as an example of second metal ion water forced supply means And a supply unit 56. The memory 48 stores in advance a control program for controlling the brushless motor 4, the water supply valve 13, the drain motor 23, the circulation pump 24, the blower 33, the heater 34, the silver ion elution device 40, and the like. The standard mode control unit 50, the process execution number determination unit 51, the first silver ion concentration setting unit 52, the first silver ion water forced supply unit 52, the mode determination unit 54, the second silver ion concentration setting unit 55, and the second The silver ion water forced supply unit 56 is configured by a program.

When the Ag ⁺ standard mode is set by the Ag ⁺ button of the operation unit 9, the standard mode control unit 50 controls the silver ion concentration of silver ion water supplied into the water tank 2 to a preset 150 ppb.

  The process execution number determination unit 51 determines whether or not the process execution number stored in the memory 48 has reached a preset number of times. In addition, the said process implementation frequency is an example of the frequency | count of operation.

  The first silver ion concentration setting unit 52 sets the silver ion concentration of silver ion water to be supplied into the water tank 2 to 450 ppb when the process execution number determination unit 51 determines that the process execution number has reached the set number of times. Set to.

  The first silver ion water forced supply unit 52 forcibly supplies silver ion water having a silver ion concentration of 450 ppb into the water tank 2 in the final rinsing step.

The mode determination unit 54 determines whether or not Ag ⁺ standard mode and Ag ⁺ strong mode by the Ag ⁺ button are set.

When the mode determination unit 54 determines that the Ag ⁺ standard mode and the Ag ⁺ strong mode are not set, the second silver ion concentration setting unit 55 has silver ions of silver ion water supplied into the water tank 2. Set the concentration to 90 ppb.

  The second silver ion water forced supply unit 56 forcibly supplies silver ion water having a silver ion concentration of 90 ppb into the water tank 2 in the final rinsing step.

  The brushless motor 4 is equipped with a hall sensor 57, and a signal indicating the rotational position of the rotor (not shown) of the brushless motor 4 is sent from the hall sensor 57 to the control device 11.

  FIG. 4 is a flowchart of the entire washing process of the drum type washing and drying machine.

  When the washing process is started, first, in step S101, it is determined whether or not the washing process is selected. If it is determined in step S101 that the washing process is not selected, the process immediately proceeds to step S102. On the other hand, if it is determined in step S101 that the washing process is selected, the washing process in step S200-1 and the process execution count in step S200-2 are sequentially performed, and then the process proceeds to step S102.

  In step S200-2, the memory 48 stores the number of process executions. For example, when the washing process in step S200-1 is performed for the first time after purchasing a product, the memory 48 stores “1” in step S200-2. Here, the number of process executions stored in the memory 48 is retained even when the power is turned off.

  Next, in step S102, it is determined whether or not a rinsing process is selected. If it is determined in step S102 that the rinsing process is not selected, the process immediately proceeds to step S103. On the other hand, if it is determined in step S102 that the rinsing process is selected, the rinsing process in step S300-1, the final rinsing process in step S300-2, and the process execution count in step S300-3 are sequentially performed. The process proceeds to S103.

  In step S300-3, as in step S200-2, the memory 48 stores the number of process executions. For example, when the washing process in step S200-1, the rinsing process in step S300-1, and the final rinsing process in step S300-2 are performed for the first time after purchasing the product, in step S300-3, the memory 48 stores “ 3 ”is stored. Here, the number of process executions stored in the memory 48 is retained even when the power is turned off. In step S300-3, the process execution count of the memory 48 is normally incremented by 2. However, when the process execution count clear of step S502 of FIG. 9 to be described later is performed, the addition of the process execution count of the memory 48 is added. Do not do.

  Next, in step S103, it is determined whether or not the dehydration process is selected. If it is determined in step S103 that the dehydration process has not been selected, the process immediately proceeds to step S104. On the other hand, if it is determined in step S103 that the dehydration process is selected, the dehydration process is performed in step S400, and then the process proceeds to step S104.

  Finally, in step S104, the termination process by the control device 11, particularly the microcomputer included therein, is automatically advanced according to the procedure. At this time, the control device 11 causes the buzzer 47 to output an end sound in order to notify the user that the washing process has been completed. Then, the washing process ends, and the drum type washing and drying machine returns to a standby state in preparation for the next washing process.

  In addition, in the flowchart of FIG. 4, although the determination of the drying process was not performed, you may perform after step S103. More specifically, after the dehydration process in step S400 is completed, the process may proceed to a drying process. In this drying step, for example, the laundry is dried by supplying warm air into the drum 3. The hot and humid air discharged from the drum 3 is cooled by tap water entering the lower part of the water tank 2 from the cooling water duct 14. Thereby, condensed water is generated from the moisture in the air and flows out of the outer box 1 through the drainage duct 19 and the like.

  FIG. 5 is a flowchart of the rinsing process.

  When the rinsing process is started, intermediate dehydration is performed in step S301. In the intermediate dehydration in step S301, the same control as in the dehydration process in step S400 is performed.

  Next, in step 302, the water supply valve 13 is opened, and tap water is supplied into the water tank 2 until the water level in the drum 3 reaches the set water level.

  Next, in step S303, acclimation tumbling is performed. In this tamping, the drum 3 rotates at a low speed, and the laundry is taken out of the tap water and dropped again into the tap water so that the laundry can sufficiently absorb the tap water.

  Next, in step S304, the drum 3 is rotated with the control pattern of the rinsing tumbling according to the setting of the user. The drum 3 causes the laundry to pass through tap water by rotation, and is lifted upward and dropped. Thereby, the laundry is rinsed. Such rinsing tumbling is performed for a set time.

  Finally, in step S305, the drum 3 is gently rotated to loosen the laundry, and the water used for rinsing the laundry is drained, thereby ending the rinsing process.

  FIG. 6 is a flowchart of the final rinsing process.

  When the final rinsing process is started, intermediate dehydration is performed in step S311 as in step S301 of FIG.

Next, in step S312, it is determined whether or not there is an Ag ⁺ mode. That is, in step S312, it is determined whether Ag ⁺ standard mode or Ag ⁺ strong mode is set. If it is determined in step S312 that neither the Ag ⁺ standard mode nor the Ag ⁺ strong mode is set, the process proceeds to step S313. On the other hand, if it is determined in step S312 that the Ag ⁺ standard mode or the Ag ⁺ strong mode is set, the process proceeds to step S318 in FIG.

  When the process proceeds from step S312 to step S313, the silver ion concentration of silver ion water supplied into the water tank 2 is set to 90 ppb or 450 ppb, as shown in FIG. The silver ion concentration set in step S313 is determined by a silver ion concentration determination step described separately with reference to the flowchart of FIG. Then, in step S314, the water supply valve 13 is opened, and the tap water is supplied into the water tank 2 and the silver ion concentration is set to 90 ppb or 450 ppb until the water level in the drum 3 reaches the set water level. Is supplied into the water tank 2. Thereafter, similarly to steps S303, S304, and S305 in FIG. 5, steps S315, S316, and S317 are performed, and the final rinsing process is completed.

When the process proceeds from step S312 to step S318, as shown in FIG. 7, it is determined whether or not Ag ⁺ standard mode is set. If it is determined in step S318 that the Ag ⁺ standard mode is set, the process proceeds to step S319. On the other hand, if it is determined in step S318 that the Ag ⁺ standard mode is not set, the process proceeds to step S325 in FIG.

When the process proceeds from step S318 to step S319, as shown in FIG. 7, the silver ion concentration of silver ion water supplied into the water tank 2 is set to 150 ppb in Ag ⁺ standard mode. Then, in step S314, the water supply valve 13 is opened, and the tap water is supplied into the water tank 2 and the silver ion water whose silver ion concentration is set to 150 ppb is supplied to the water tank until the water level in the drum 3 reaches the set water level. 2 to supply. Then, similarly to step S313 in FIG. 5, after performing step S321, in step S322, the laundry is soaked in silver ion water for a preset time. Then, similarly to steps S304 and S305 in FIG. 5, steps S323 and S324 are performed, and the final rinsing process is completed. In step S322, at least a part of the laundry may be immersed in the silver ion water in the water tank 2.

Further, when the process proceeds from step S318 to step S325, the silver ion concentration of silver ion water supplied into the water tank 2 is set to 300 ppb in the Ag ⁺ strong mode, as shown in FIG. In step S323, the water supply valve 13 is opened, and the tap water is supplied into the water tank 2 and the silver ion water whose silver ion concentration is set to 300 ppb is supplied until the water level in the drum 3 reaches the set water level. 2 to supply. Then, similarly to steps S321, S322, S323, and S324 in FIG. 7, steps S327, S328, S329, and S330 are performed, and the final rinsing process is completed.

  FIG. 9 is a flowchart of the silver ion concentration determination step.

  When the silver ion concentration determination step starts, first, in step S501, it is determined based on the stored contents of the memory 48 whether or not the number of process executions has reached a preset number of times (for example, seven times). If it is determined in step S501 that the number of process executions has reached the set number, the process proceeds to the next step S502. On the other hand, if it is determined in step S501 that the number of process executions has not reached the set number of times, the silver ion concentration of silver ion water supplied into the water tank 2 is determined to be 90 ppb, and the silver ion concentration determination step ends. .

  Next, in step S502, the numerical value indicating the number of process executions stored in the memory 48 is cleared.

  Finally, in step S503, the silver ion concentration of silver ion water supplied into the water tank 2 is determined to be 450 ppb, and the silver ion concentration determination step ends.

Thus, even when the user does not select either the Ag ⁺ standard mode or the Ag ⁺ strong mode, the silver ion concentration 450 ppb higher than the silver ion concentration 150 ppb in the Ag ⁺ standard mode at the time of water supply in the final rinsing process. Ionized water is forcibly supplied into the aquarium 2, or silver ionized water having a silver ion concentration of 90 ppb lower than Ag ⁺ standard mode silver ion concentration of 150 ppb is forcibly supplied into the aquarium 2.

  Therefore, when the silver ion water having a silver ion concentration of 450 ppb is forcibly supplied into the aquarium 2, the microorganisms that have propagated in the aquarium 2 and the drum 3 are sterilized and discharged out of the aquarium 2 together with the silver ion water. it can. As a result, since the microorganisms can be sterilized and removed automatically and regularly, the drum type washing and drying machine can be kept clean.

  Moreover, the silver ion water of the said silver ion concentration 450ppb flows into the drainage hose 21 after completion | finish of the last rinse process. As a result, even if the drainage hose 2 has a bent portion, and soap scum accumulates in the bent portion, silver ion water can be stored in the bent portion, so that microorganisms in the bent portion can be reliably sterilized. it can. Therefore, it is possible to prevent the off-flavor due to the microorganisms from flowing back into the water tank 2.

  Further, when the silver ion water having a silver ion concentration of 90 ppb is forcibly supplied into the water tank 2, the water tank 2 and the drum 3 can be antibacterial. Therefore, propagation of microorganisms in the water tank 2 and the drum 3 can be suppressed.

When the user selects either the Ag ⁺ standard mode or the Ag ⁺ strong mode, the laundry is soaked in silver ion water for a preset time. On the other hand, when the silver ion water having a silver ion concentration of 450 ppb is forcibly supplied into the water tank 2 and when the silver ion water having the silver ion concentration of 90 ppb is forcibly supplied into the water tank 2 Do not immerse the laundry in silver ion water during such time. Therefore, when the silver ion water having a silver ion concentration of 450 ppb is forcibly supplied into the water tank 2 and when the silver ion water having the silver ion concentration of 90 ppb is forcibly supplied into the water tank 2, The final rinsing process can be made shorter than when either the Ag ⁺ standard mode or the Ag ⁺ strong mode is selected.

  Hereinafter, an experiment conducted for examining a silver ion concentration suitable for exhibiting a bactericidal effect against mold will be described.

  An agar medium in which sodium oleate, which is a surfactant used in a detergent, and silver ions were mixed, was prepared, and the number of mold colonies formed on this medium was examined. As mold, three kinds of Scolecobasidium, Exophiala and Cladosporium were used. Four types of agar media were prepared with a sodium oleate concentration of 0.1% and silver ion concentrations of 0 ppb, 90 ppb, 450 ppb, and 900 ppb. However, in an experiment using Exophiala as mold, PDA (PotatoDextroseAgar) was used instead of sodium oleate.

  The experimental results are shown in Table 1 below. In Table 1, a value obtained by dividing the number of mold colonies in an agar medium with a silver ion concentration of 0 ppb by the number of mold colonies in an agar medium with each silver ion concentration is a logarithmic value of two effective figures, and the value is 0 to 0. When it was 1.9, x, when it was 2.0 to 3.9, Δ when it was 4.0, and ○ when it was 4.0. For example, when the number of mold colonies is reduced to 1/100 due to silver ions, the above numerical value becomes 2.0 and becomes Δ.

  From the results shown in Table 1 above, it can be seen that fungi are very effective against mold when silver ion water having a silver ion concentration of 900 ppb is used. In particular, it can be seen that Scolecobasidium and Exophiala, which are often found in washing machines, have a sufficient bactericidal effect even when silver ion water having a silver ion concentration of 450 ppb is used.

  As described above, the bacteria have a sufficient bactericidal effect at a silver ion concentration of 90 ppb. Further, by increasing the silver ion concentration to 450 ppb or more, a sufficient bactericidal effect can be exhibited not only against bacteria but also against mold.

  In the above embodiment, the silver ion elution device 40 having the silver electrode is mounted on the drum type washing and drying machine. However, the metal ion elution device having the copper electrode, the electrode made of an alloy of silver and copper, or the zinc electrode is used. You may mount in a drum type washing-drying machine.

  In the above embodiment, the silver ion elution device 40 is provided in the branch duct 39, but the silver ion elution device 40 may be provided in the water supply duct 15.

  In the above embodiment, the number of process executions is stored in the memory 48 as an example of the number of operations. However, for example, the number of times the main power of the drum type washing and drying machine is turned on is stored in the memory 48 as an example of the number of operations. Also good.

  In the above embodiment, as a means for periodic sterilization removal, it is carried out according to the number of times of operation, but not limited to the number of times of operation, and periodically according to the number of times of operation such as easy washing and the time of operation, etc. You may make it perform sterilization removal operation | movement. In this case, the washing machine includes an outer box, a water tank disposed in the outer box, a rotating tank that is rotatably disposed in the water tank, and stores the laundry, and the water tank or the rotating tank. A drainage hose for draining the liquid, a drive device for rotationally driving the rotary tank, a metal ion water generator for converting the water flowing toward the water tank or the rotary tank to metal ion water, the drive device, and A control device capable of controlling the metal ion water generating device and performing each of the washing step and the rinsing step at least once, and the control device supplies the metal ion water supplied into the water tank or the rotating tank. Standard mode control means for controlling the metal ion concentration of the sample to a preset standard concentration and the total number of times of washing and rinsing steps, or at least the washing and rinsing steps A memory for storing one total execution time, a determination means for determining whether the total execution count or the total execution time stored in the memory has reached a preset set count or set time, and When it is determined by the determination means that the total number of executions or the total execution time has reached the set number of times or the set time, the metal ion concentration of metal ion water supplied into the water tank or the rotary tank is determined as the standard. In the final rinsing step of the rinsing step, the metal ion water having the metal ion concentration set by the metal ion concentration setting unit is supplied to the water tank or the rotation. It is good also as what has a metal ion water forced supply means forcibly supplied in a tank. In the washing machine thus configured, when the total number of executions or the total execution time reaches the set number of times or the set time, the metal having a metal ion concentration higher than the standard concentration in the final rinsing step of the rinsing step. Since ionic water is forcibly supplied into the aquarium or rotating tank, even if the user does not know the mode using metal ionic water or the user forgets to set the mode, it will propagate in the aquarium or rotating tank. Sterilized microorganisms can be sterilized and discharged out of the water tank with metal ion water. That is, the sterilization and removal of the microorganism can be performed automatically and periodically. Therefore, the washing machine can be kept clean. Moreover, the metal ion water forcedly supplied in the said water tank or a rotation tank flows through a drainage hose after completion | finish of the last rinse process. As a result, even if the drainage hose is bent and soap scum accumulates in the bent part of the drainage hose, metal ion water can be stored in the bent part. Can be sterilized. Therefore, it is possible to prevent the off-flavor caused by the microorganisms from flowing back into the washing machine.

  In the above embodiment, if it is determined in step S102 that the rinsing process is selected, the rinsing process in step S300-1 and the final rinsing process in step S300-2 are performed. Only the rinsing process may be performed.

  In the above embodiment, the rinsing process of step S300-1 is performed once before the final rinsing process of step S300-2, but the rinsing of step S300-1 is performed before the final rinsing process of step S300-2. You may make it perform a process in multiple times.

  In the above embodiment, when it is determined in step S501 that the number of process executions has not reached the set number of times, the silver ion concentration of silver ion water supplied into the water tank 2 has been determined to be 90 ppb. The silver ion concentration of silver ion water supplied to may be determined to be 0 ppb. That is, if it is determined in step S501 that the number of process executions has not reached the set number, the silver ion water may not be supplied to the water tank 2. When it does in this way, the lifetime of the expensive silver electrode which the silver ion elution apparatus 40 has can be extended rather than the said embodiment.

  In the above embodiment, in steps S322 and S328, the drum 3 may be rotated in a preset rotation pattern, or the rotation of the drum 3 may be stopped.

  In the above embodiment, 150 ppb is used as an example of the standard concentration. However, a concentration other than 150 ppb (for example, a concentration in the range of 100 ppb to 200 ppb) may be used as an example of the standard concentration.

  In the above embodiment, the washing water flows out from the front end of the water supply duct 15 toward the space between the water tub 2 and the drum 3, but from the front end of the water supply duct 15 toward the space in the drum 3. Washing water may flow out.

  Although specific embodiments of the present invention have been described, the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the present invention. For example, the present invention can be applied to all types of washing machines such as a drum-type washing machine having no drying function, a drum-type washing / drying machine, a vertical washing machine having no drying function, and a vertical washing / drying machine. When the present invention is applied to a vertical washing machine such as Japanese Patent Application Laid-Open No. 2007-215593, a washing machine according to an embodiment of the present invention includes an outer box, a water tank disposed in the outer box, and the water tank. A rotating tub for storing laundry, a drain hose for draining the liquid in the rotating tub, a driving device for rotating the rotating tub, and a flow toward the rotating tub A metal ion water generating device that converts water into metal ion water, and a control device that controls the drive device and the metal ion water generating device to perform a rinsing step once or a plurality of times. Standard mode control means for controlling the metal ion concentration of the metal ion water supplied into the rotating tank to a preset standard concentration, a memory for storing the number of operations, and the number of operations stored in the memory are preset. To the set number of times The metal ion concentration of the metal ion water to be supplied into the rotary tank when the operation frequency determination means and the operation frequency determination means determine that the operation frequency has reached the set frequency. In the final rinsing step of the rinsing step, the metal ion concentration set by the first metal ion concentration setting unit is set in the first rinsing step. A first metal ion water forced supply means for forcibly supplying metal ion water into the water tank rotation tank.

DESCRIPTION OF SYMBOLS 1 ... Outer box 2 ... Water tank 3 ... Drum 4 ... Brushless motor 11 ... Control apparatus 21 ... Drain hose 48 ... Memory 50 ... Standard mode control part 51 ... Process execution frequency determination part 52 ... 1st silver ion concentration setting part 53 ... 1st 1 Silver ion water forced supply unit 54 ... Mode determination unit 55 ... Second silver ion concentration setting unit 56 ... Second silver ion water forced supply unit

Claims (2)

An outer box,
A water tank disposed in the outer box;
A rotating tub that is rotatably arranged in the water tub, and stores the laundry;
A drainage hose for draining the liquid in the water tank or the rotating tank,
A driving device for rotationally driving the rotating tank;
A metal ion water generating device that converts the water flowing toward the water tank or the rotary tank into metal ion water;
A control device for controlling the driving device and the metal ion water generating device to perform the rinsing process once or a plurality of times;
The control device
Standard mode control means for controlling the metal ion concentration of metal ion water supplied into the water tank or the rotating tank to a preset standard concentration;
A memory for storing the number of operations,
An operation frequency determination means for determining whether or not the operation frequency stored in the memory has reached a preset number of times;
When it is determined by the operation number determination means that the operation number has reached the set number of times, the metal ion concentration of the metal ion water supplied into the water tank or the rotating tank is set higher than the standard concentration. First metal ion concentration setting means for setting;
In the final rinsing step of the rinsing step, the first metal ion water forcibly supplying the metal ion water having the metal ion concentration set by the first metal ion concentration setting means into the water tank or the rotating tank. A washing machine comprising a supply means. The washing machine according to claim 1,
The control device
Mode determining means for determining whether or not a mode for supplying metal ion water into the water tank or the rotating tank is set;
When it is determined by the mode determination means that the mode for supplying metal ion water into the water tank or the rotary tank is not set, the metal ion concentration of metal ion water supplied into the water tank or the rotary tank is A second metal ion concentration setting means for setting to be lower than the standard concentration;
In the final rinsing step of the rinsing step, the second metal ion water forcing that forcibly supplies the metal ion water having the metal ion concentration set by the second metal ion concentration setting means into the water tank or the rotating tank. A washing machine comprising a supply means.

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