JP2017077465A - Washing system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a washing system which washes clothing and the like without using a detergent, with a simple structure.SOLUTION: A washing system 1 includes: an alkali ion water generation part 10; an alkali ion water generation medium supply part 20 for supplying an alkali ion water generation medium 21 to the alkali ion water generation part; an alkali ion water storage part 30 for storing the alkali ion water generated in the alkali ion water generation part; a washing tank 200 for washing a washing object; and a control valve 40 at a third pipeline 52 for connecting the washing tank from the alkali ion water storage part. By controlling the ratio of the amount of water to the alkali ion water, in the washing tank, washing can be performed with hydrogen ion concentration suitable for the washing object such as clothing.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a washing system for washing clothes and the like.

  Conventionally, when clothes are washed at home or in a coin laundry provided with a plurality of washing machines, washing is performed using a detergent. At this time, the onset of skin irritation and allergies due to the surfactant used in the synthetic detergent is a problem. There are also concerns about the impact on the environment and pollution. For this reason, Patent Document 1 discloses a washing apparatus that reduces environmental pollution and pollution problems by using alkaline ionized water and acidic ionized water generated from electrolysis of salt water so that a small amount of detergent can be used. ing.

JP 2003-144793 A

  However, in the apparatus described in Patent Document 1, it is necessary to prepare a salt water tank and prepare an ionic water generator for electrolysis. For this reason, there are disadvantages due to the influence of corrosion on peripheral devices due to salt and the complexity and enlargement of equipment such as the installation of an ionic water generator.

  On the other hand, alkaline ionized water with high alkalinity has high detergency, has a very small amount of detergent, or has sufficient detergency even without detergent, and does not cause skin irritation or allergic problems. It is known that it will not be a pollution problem. However, it has been difficult to stably supply alkaline ionized water having high alkalinity.

  In view of the above problems, the present invention is to provide a cleaning system for washing clothes and the like with a simple configuration without using a detergent.

  The cleaning system according to the present invention includes an alkaline ionized water generation unit, an alkaline ionized water generation medium supply unit that supplies an alkaline ionized water generation medium to the alkaline ionized water generation unit, and an alkaline ionized water generated by the alkaline ionized water generation unit. An alkaline ionized water storage unit and a cleaning tank for cleaning a cleaning target.

  Preferably, a pipe connecting the alkali ion water storage part to the washing tank is provided with an adjustment valve, and the adjustment valve supplies water directly to the washing tank, and water is supplied from the alkali ion water storage part to the washing tank. Adjust the ratio of alkaline ionized water supply.

  Preferably, the adjustment valve adjusts the ratio of the amount of water supplied directly to the cleaning tank to the ratio of the amount of alkali ion water supplied to the cleaning tank from the alkaline ion water storage unit to be 5: 1. .

  Preferably, the alkaline ionized water generation medium supply unit has a timer, and automatically supplies the alkaline ionized water generation medium to the alkaline ionized water generation unit according to the timer.

  Preferably, the alkaline ionized water generation medium supply unit supplies the alkaline ionized water generation medium to the alkaline ionized water generation unit in accordance with the amount of alkaline ionized water stored in the alkaline ionized water storage unit.

  Preferably, a plurality of washing tanks are included, and the number of alkali ion water generating units is smaller than the number of washing tanks.

  With a simple configuration, clothes and the like can be washed without using a detergent.

It is explanatory drawing which shows the washing | cleaning system which concerns on the 1st Embodiment of this invention. It is a control block diagram of the washing system concerning a 1st embodiment of the present invention. It is a processing flow figure of the washing system concerning a 1st embodiment of the present invention. It is another process main flow figure of the washing system concerning a 1st embodiment of the present invention. It is a flowchart of the subroutine of the content confirmation of the washing | cleaning system which concerns on the 1st Embodiment of this invention. It is a flowchart of the subroutine of the washing process of the washing system concerning a 1st embodiment of the present invention. It is a flowchart of the subroutine of the other content confirmation of the washing | cleaning system which concerns on the 1st Embodiment of this invention. It is explanatory drawing which shows the washing | cleaning system which concerns on the 2nd Embodiment of this invention. It is explanatory drawing which shows the washing | cleaning system which concerns on the 3rd Embodiment of this invention. It is explanatory drawing which shows the alkaline ionized water production | generation medium supply part of the washing | cleaning system which concerns on embodiment of this invention. It is explanatory drawing which shows the alkaline ionized water production | generation medium supply part of the washing | cleaning system which concerns on embodiment of this invention.

<First Embodiment>
FIG. 1 is an explanatory diagram showing a cleaning system according to the first embodiment of the present invention.

  The cleaning system 1 includes an alkali ion water generation unit 10, an alkali ion water generation medium supply unit 20 that supplies the alkali ion water generation medium 21 to the alkali ion water generation unit 10, and alkali ions generated by the alkali ion water generation unit. An alkaline ionized water storage unit 30 for storing water and a cleaning tank 100 for cleaning a cleaning target are provided. The cleaning tank 100 includes a drum tank 200.

  Water is supplied to the drum tank 200 of the cleaning tank 100 through the first pipe 50. Water is supplied to the alkaline ionized water generator 10 through the second pipe 51. The alkaline ionized water generation unit 10 is also supplied with the alkaline ionized water generation medium 21 from the alkaline ionized water generation medium supply unit 20. Therefore, the alkali ion water generation medium supply unit 20 includes a plurality of alkali ion water generation media 21. The alkaline ionized water production medium 21 reacts with water and changes to alkaline ionized water having a pH of 12.5 or higher, for example.

  The alkali ion water produced | generated in the alkali ion water production | generation part 10 is produced | generated over time. For this reason, the alkaline ionized water storage unit 30 stores the generated alkaline ionized water in preparation for use in the cleaning tank 100.

  Alkaline ion water is supplied from the alkali ion water storage unit 30 to the drum tank 200 of the cleaning tank 100 through the third pipe 52. The supply of alkaline ionized water is performed by a pump (not shown). The third pipe 52 is provided with an adjustment valve 40. The adjustment valve 40 adjusts the amount of alkaline ionized water from the alkaline ionized water storage unit 30 to the drum tank 200. Thereby, the ratio of the water supply amount from the first pipe 50 and the water supply amount of the alkaline ionized water from the third pipe 52 is adjusted. By adjusting the ratio of the amount of water and alkaline ionized water, cleaning can be performed at a hydrogen ion concentration suitable for the object to be cleaned, such as clothes, in the cleaning tank.

  The ratio between the amount of water supplied from the first pipe 50 and the amount of supplied alkaline ion water from the third pipe 52 is preferably 5: 1. The water from the first pipe 50 has a pH of about 7, and the alkaline ionized water from the third pipe 52 has a pH of about 12.5. By supplying these water and alkaline ionized water 5 to 1 to the washing tank 100, alkaline ionized water having a pH of about 12 is obtained, and clothes and the like are washed without detergent.

  As will be described later, the alkali ion water generation medium supply unit 20 includes a timer, and automatically supplies the alkali ion water generation medium 21 to the alkali ion water generation unit 10 according to the timer. Good. Further, the alkali ion water generating medium supply unit 20 is configured to supply the alkali ion water generating medium 21 to the alkali ion water generating unit 10 according to the amount of alkaline ion water stored in the alkali ion water storing unit 30. Also good. In this case, the alkali ion water storage unit 30 is provided with detection means for detecting the storage amount of the alkali ion water, and the detected information is sent to the alkali ion water generation medium supply unit 20.

  The water supplied to the alkaline ion water generator 10 may be water distributed from the first pipe 50. In this case, an adjustment valve or a distribution path for distributing water supplied to the drum tank 200 of the cleaning tank 100 and water supplied to the alkaline ionized water generation unit 10 is provided.

  The route supplied to the drum tank 200 of the cleaning tank 100 via the alkaline ionized water generation unit 10 and the alkaline ionized water storage unit 30 is a route in which a detergent is mixed with hot water and sent to the cleaning tank 100 in a normal cleaning system. is there. Accordingly, in a normal cleaning system, clothes and the like can be washed without using a detergent by attaching the alkali ion water generation unit 10 and the alkali ion water storage unit 30 provided with the alkali ion water generation medium supply unit 20. Can do. Moreover, you may make it comprise the alkali ion water production | generation part 10 and the alkali ion water storage part 30 provided with the alkali ion water production | generation medium supply part 20 as one unit, and to attach.

  In addition, the alkaline ionized water production | generation medium 21 can use the electrolytic auxiliary agent shape | molded in the solid form which consists of potassium carbonate, for example. When potassium carbonate is used, it is possible to generate about 15 liters of 12.5 pH alkaline ionized water per hour. The amount of potassium carbonate supplied to the alkaline ionized water generation unit 10 is adjusted according to the amount of alkaline ionized water required in the cleaning tank 100, the amount stored in the alkaline ionized water storage unit 30, and the like.

  Further, in the present embodiment, the alkali ion water generating medium 21 molded in a solid form is used. However, it may be in the form of powder, and depending on the amount of the alkali ion water to be generated or stored, the alkali ion water is generated. The amount of potassium carbonate supplied to the unit 10 may be adjusted.

  Moreover, in this invention, it wash | cleans with the alkaline ionized water suitable for the washing | cleaning defined as strong alkaline ionized water exceeding pH10. Furthermore, in this invention, it is preferable to wash | clean with the strong alkaline ionized water exceeding pH12 which also has a microbe elimination effect | action. Since dirt on clothes, etc. is acidic, the more alkaline the water is, the more dirt is removed. Particularly, alkaline ionized water having a pH of 12 or more decomposes and cleans oil stains and tobacco dust.

  Since alkaline ionized water does not use a synthetic surfactant, it can be rinsed simultaneously with washing without foaming. For this reason, it leads to significant water saving and also to cost reduction. In addition, since no detergent is used, there is no color and no odor, and removal of bacteria by the sterilization effect with alkaline ionized water leads to a deodorization effect.

  Next, based on FIGS. 2-7, the process in the washing | cleaning system which concerns on the 1st Embodiment of this invention is demonstrated. FIG. 2 is a control block diagram of the cleaning system according to the first embodiment of the present invention.

  The cleaning system includes a regulating valve 40, a regulating valve 50A, an input unit 101 provided in the washing tub 100, and a control unit 60 that controls the regulating valve 40 and the regulating valve 50A according to a signal from the input unit 101. Is done.

  Next, based on FIG. 3, the process in the cleaning system according to the first embodiment of the present invention will be described in detail. FIG. 3 is a process flow diagram of the cleaning system according to the first embodiment of the present invention. Here, a coin-type washing machine is assumed as the cleaning system.

  First, it is determined by the user that a coin has been inserted into the coin compartment provided in the coin-operated washing machine (step ST10). When coins are inserted, the regulating valve 40 is opened and alkaline ionized water is supplied to the cleaning tank 100. The adjustment valve 50 </ b> A is also opened, and tap water is supplied to the cleaning tank 100. At the same time, the timers of the regulating valve 40 and the regulating valve 50A start counting (step ST11).

  It is determined whether or not the timer count T is greater than a predetermined time t1 (step ST12). When the timer count T is greater than the predetermined time t1 (Yes in step ST12), the control unit 60 closes the regulating valve 40 (step ST13).

  It is determined whether or not the timer count T is greater than a predetermined time t2 (step ST14). When the timer count T is greater than the predetermined time t2 (Yes in step ST14), the control unit 60 closes the regulating valve 50A (step ST15).

  Washing tub 100 rotates to wash the laundry (step ST16).

  After washing, rinsing is performed by a rinsing process (step ST17). Finally, the laundry is dried by the drying process (step ST18). The above is a detailed processing flow in the case where the washing process is performed in a coin-type washing machine with a preset water amount and alkali ion water ratio.

  Next, another process in the cleaning system according to the first embodiment of the present invention will be described in detail with reference to FIGS. FIG. 4 is another processing main flowchart of the cleaning system according to the first embodiment of the present invention. FIG. 5 is a flowchart of a subroutine for confirming the contents of the cleaning system according to the first embodiment of the present invention. FIG. 6 is a flowchart of a subroutine of the cleaning process of the cleaning system according to the first embodiment of the present invention.

  Another processing main flow of the cleaning system according to the first embodiment of the present invention will be described with reference to FIG. First, it is determined by the user that a coin has been inserted into the coin compartment provided in the coin-operated washing machine (step ST10). When a coin is inserted, the content is confirmed (step ST100). When the content confirmation is completed, the laundry is washed by the washing process (step ST200). After washing, rinsing is performed by a rinsing process (step ST17). Finally, the laundry is dried by the drying process (step ST18).

  Next, the flow of the content confirmation subroutine will be described with reference to FIG. In the content confirmation subroutine, first, the laundry weight is measured (step ST110). Based on the measured laundry weight, the amount of water M necessary for washing is calculated (step ST111). A ratio K of alkaline ionized water to water amount M is determined (step ST112).

  The opening time t1 of the regulating valve 40 and the opening time t2 of the regulating valve 50A are determined according to the ratio K of the water amount M and the alkaline ionized water (step ST113).

  Next, the flow of the washing process subroutine will be described with reference to FIG. In the washing process subroutine, the regulating valve 40 is opened and alkaline ionized water is supplied to the washing tub 100. The adjustment valve 50 </ b> A is also opened, and tap water is supplied to the cleaning tank 100. At the same time, the timers of the regulating valve 40 and the regulating valve 50A start counting (step ST210).

  It is determined whether or not the timer count T is greater than a predetermined time t1 (step ST211). When the timer count T becomes larger than the predetermined time t1 (Yes in step ST211), the control unit 60 closes the regulating valve 40 (step ST212).

  It is determined whether or not the timer count T is greater than a predetermined time t2 (step ST213). When the timer count T is greater than the predetermined time t2 (Yes in step ST213), the control unit 60 closes the regulating valve 50A (step ST214).

  Washing tub 100 rotates to wash the laundry (step ST215). After washing, as described above, rinsing is performed by the rinsing process (step ST17), and finally the laundry is dried by the drying process (step ST18).

  Next, the flow of another subroutine for confirming the contents of the cleaning system according to the first embodiment of the present invention will be described with reference to FIG. FIG. 7 is a flowchart of another subroutine for confirming the content of the cleaning system according to the first embodiment of the present invention.

  A function using the degree of contamination (d) by the contamination degree sensor provided in the washing tub 100, the number of bacteria (v) by the bacteria detection sensor, the odor (s) by the odor sensor, and the mode selected by the input unit 101 as variables. Digitization is performed by f (d, v, s, mode) (step ST301).

  The numerical value of the function f (d, v, s, mode) is compared with the predetermined value α (step ST302). If the numerical value of the function f (d, v, s, mode) is equal to or greater than the predetermined value α (Yes in step ST302), it is determined that it is necessary to wash more strongly than usual, and the amount of alkaline ionized water becomes larger than usual. Such a ratio is set (step ST303).

  If the numerical value of the function f (d, v, s, mode) is smaller than the predetermined value α (No in step ST302), it is determined that it is necessary to perform washing weaker than usual, and the amount of alkaline ionized water is less than usual. (Step ST304).

<Second Embodiment>
FIG. 2 is an explanatory diagram of a part of the cleaning system according to the second embodiment of the present invention.

  The cleaning system 2 according to the second embodiment of the present invention includes four cleaning tanks 110, 120, 130, and 140, and one alkaline ionized water less than the number of cleaning tanks 110, 120, 130, and 140. A generation unit 10 is provided. The alkaline ionized water generation unit 10 includes an alkaline ionized water generation medium supply unit 20. The fourth pipe 53 is divided into a pipe that supplies water directly to the four cleaning tanks 110, 120, 130, and 140 and a pipe that supplies water to the alkaline ionized water generation unit 10 via the adjustment valve 41. The adjustment valve 41 adjusts the amount of water supplied to the alkaline ionized water generator 10.

  Adjustment piping 111,121,131,141 which adjusts the amount of water supply to each washing tank 110,120,130,140 is provided in piping which is directly supplied to four washing tanks 110,120,130,140. .

  The alkaline ionized water produced by the alkaline ionized water production unit 10 by the alkaline ionized water production medium from the alkaline ionized water production medium supply unit 20 is stored in the alkaline ionized water storage unit 30. Alkaline ion water is supplied from the alkali ion water storage unit 30 to the cleaning tanks 110, 120, 130, and 140. Adjustment piping 112,122,132,142 which adjusts the amount of water supply of alkaline ionized water is provided in piping of each washing tank 110,120,130,140 from the alkaline ionized water storage part 30. As shown in FIG.

<Third Embodiment>
FIG. 3 is an explanatory diagram of a part of the cleaning system according to the third embodiment of the present invention.

  The cleaning system 3 according to the third embodiment of the present invention includes four cleaning tanks 110, 120, 130, and 140, and two alkaline ionized waters smaller than the number of cleaning tanks 110, 120, 130, and 140. Generation units 11 and 12 are provided. The alkali ion water generation units 11 and 12 include alkali ion water generation medium supply units 23 and 24, respectively. On the way, the fifth pipe 54 is divided into a pipe that supplies water directly to the four cleaning tanks 110, 120, 130, and 140 and a pipe that supplies water to the alkaline ionized water generator 11. On the other hand, water is directly supplied from the sixth pipe 55 to the alkali ion water generator 12.

  Adjustment piping 111,121,131,141 which adjusts the amount of water supply to each washing tank 110,120,130,140 is provided in piping which is directly supplied to four washing tanks 110,120,130,140. .

  Alkaline ion water generated in the alkali ion water generation unit 11 by the alkali ion water generation medium from the alkali ion water generation medium supply unit 23 is stored in the alkali ion water storage unit 31. Alkaline ion water is supplied from the alkali ion water storage unit 31 to the cleaning tanks 110 and 120. Adjustment piping 112 and 122 which adjusts the amount of water supply of alkaline ion water is provided in piping of each washing tank 110 and 120 from alkaline ion water storage part 31. As shown in FIG.

  The alkaline ionized water produced by the alkaline ionized water production unit 12 by the alkaline ionized water production medium from the alkaline ionized water production medium supply unit 24 is stored in the alkaline ionized water storage unit 32. Alkaline ion water is supplied from the alkali ion water storage unit 32 to the cleaning tanks 130 and 140. The piping from the alkaline ion water storage part 32 to each of the cleaning tanks 130 and 140 is provided with adjusting valves 132 and 142 for adjusting the amount of supplied alkaline ion water.

  As described above, a sufficient amount of alkaline ionized water is washed by providing one alkaline ionized water generating medium supply unit, an alkaline ionized water generating unit, and an alkaline ionized water storage unit for two cleaning tanks. Can be supplied to. In particular, when it takes a long time to generate alkaline ion water in the alkaline ion water generator, or when there is a large amount of alkaline ion water required in the washing tank, the alkali ion water can be efficiently supplied.

  4 and 5 are explanatory diagrams showing an alkaline ionized water generating medium supply unit of the cleaning system according to the embodiment of the present invention. The alkaline ionized water generation medium supply unit 20 includes a timer 20T. The alkaline ionized water generating medium supply unit 20 is configured so that alkaline ionized water generating media 21A, 21B, 21C, and 21D can be placed from above. The alkaline ionized water generating medium supply unit 20 is provided with a first plate 25 fixed to the first rotating jig 26 and a second plate 27 fixed to the second rotating jig 28. The first plate 25 holds the alkaline ionized water generation medium 21A. The 2nd board 27 hold | maintains the alkali ion water production | generation medium 21B, 21C, 21D.

  The alkaline ionized water generation medium supply unit 20 automatically supplies the alkaline ionized water generation medium 21A to the alkaline ionized water generation unit 10 according to the timer 20T. At this time, the first rotating jig 26 rotates the first plate 25, and the alkaline ion water generating medium 21 </ b> A slides on the first plate 25 (see FIG. 5), thereby generating alkaline ion water to the alkaline ion water generating unit 10. Medium 21A is supplied. Since the second plate 27 fixed to the second rotating jig 28 holds the alkaline ion water generation media 21B, 21C, and 21D when supplying the alkaline ion water generation medium 21A to the alkaline ion water generation unit 10, Alkaline ion water generating media 21 </ b> B, 21 </ b> C, and 21 </ b> D are not supplied to the alkali ion water generating unit 10. Thereby, the alkali ion water production | generation medium is performed to the alkali ion water production | generation part 10 one by one.

  The timer 20T outputs a signal to the first rotating jig 26 and the second rotating jig 28 according to a set time such as every 6 hours or every 8 hours, and drives them. The second rotating jig 28 is driven after a predetermined time from the driving of the first rotating jig 26 or after receiving a signal detecting that the alkaline ionized water generating medium 21A has slipped down the first plate 25. You may make it do.

  In addition, a detecting means for detecting the amount of alkali ion water stored in the alkali ion water storage unit is provided, and the alkali ion water generation medium is supplied to the alkali ion water generation unit according to the amount of alkali ion water stored in the alkali ion water storage unit. You may make it supply.

<Configuration and Effect of Embodiment>
The cleaning system according to the present invention includes an alkaline ionized water generation unit, an alkaline ionized water generation medium supply unit that supplies an alkaline ionized water generation medium to the alkaline ionized water generation unit, and an alkaline ionized water generated by the alkaline ionized water generation unit. An alkaline ionized water storage unit and a cleaning tank for cleaning a cleaning target.

  Since it has such a configuration, it is possible to supply a necessary amount of alkaline ionized water from the alkaline ionized water storage unit to the washing tank.

  Preferably, a pipe connecting the alkali ion water storage part to the washing tank is provided with an adjustment valve, and the adjustment valve supplies water directly to the washing tank, and water is supplied from the alkali ion water storage part to the washing tank. Adjust the ratio of alkaline ionized water supply.

  Since it has such a structure, it can wash | clean with the hydrogen ion concentration suitable for washing | cleaning objects, such as clothes, in a washing tank.

  Preferably, the adjustment valve adjusts the ratio of the amount of water supplied directly to the cleaning tank to the ratio of the amount of alkali ion water supplied to the cleaning tank from the alkaline ion water storage unit to be 5: 1. .

  Since it has such a structure, it can wash | clean in a washing tank by using hydrogen ion density | concentration optimal for clothes etc., without using a detergent.

  Preferably, the alkaline ionized water generation medium supply unit has a timer, and automatically supplies the alkaline ionized water generation medium to the alkaline ionized water generation unit according to the timer.

  Since it has such a configuration, it is possible to automatically generate alkali ion water in the alkali ion water generator and store the alkali ion water in the alkali ion water reservoir.

  Preferably, the alkaline ionized water generation medium supply unit supplies the alkaline ionized water generation medium to the alkaline ionized water generation unit in accordance with the amount of alkaline ionized water stored in the alkaline ionized water storage unit.

  Since it has such a configuration, it is possible to automatically generate alkaline ionized water in the alkaline ionized water generating unit with respect to the required amount in the alkaline ionized water storage unit.

  Preferably, a plurality of washing tanks are included, and the number of alkali ion water generating units is smaller than the number of washing tanks.

  Since it has such a configuration, even when a plurality of cleaning tanks are arranged like a coin laundry, it is possible to perform cleaning with an appropriate hydrogen ion concentration.

1, 2, 3 Washing systems 10, 11, 12 Alkaline ion water generating units 20, 23, 24 Alkaline ion water generating medium supply unit 20T Timers 21, 21A, 21B, 21C, 21D Alkaline ion water generating medium 25 First plate 26 First rotating jig 27 Second plate 28 Second rotating jig 30, 31, 32 Alkali ion water reservoir 40 Adjusting valve 41 Adjusting valve 50 First piping 51 Second piping 52 Third piping 53 Fourth piping 54 Fifth Pipe 55 Sixth pipe 100 Cleaning tank 110, 120, 130, 140 Cleaning tank 111, 121, 131, 141 Adjusting valve 112, 122, 132, 142 Adjusting valve 200 Drum tank

Claims (6)

An alkaline ionized water generator,
An alkaline ionized water generation medium supply unit for supplying an alkaline ionized water generation medium to the alkaline ionized water generation unit;
An alkaline ionized water storage unit that stores the alkaline ionized water generated in the alkaline ionized water generation unit;
A cleaning system comprising a cleaning tank for cleaning the object to be cleaned. Provided with a regulating valve in the pipe connecting the washing tank from the alkaline ionized water storage unit,
The cleaning system according to claim 1, wherein the adjustment valve adjusts a ratio between a water supply amount directly supplied to the cleaning tank and an alkali ion water supply amount supplied to the cleaning tank from the alkali ion water storage unit. The adjustment valve adjusts the ratio of the amount of water supplied directly to the cleaning tank and the ratio of the amount of alkali ion water supplied to the cleaning tank from the alkali ion water storage unit to be 5: 1. 2. The cleaning system according to 2. The alkali ion water generation medium supply unit includes a timer, and automatically supplies the alkali ion water generation medium to the alkali ion water generation unit according to the timer. The cleaning system described.   The cleaning system according to claim 1, wherein the alkaline ionized water generation medium supply unit supplies the alkaline ionized water generation medium to the alkaline ionized water generation unit according to a storage amount of the alkaline ionized water in the alkaline ionized water storage unit. The cleaning system according to any one of claims 1 to 5, comprising a plurality of the cleaning tanks and comprising a smaller number of alkaline ion water generation units than the number of the plurality of cleaning tanks.