JP2018148997A - Coin laundry system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a coin laundry system that can eliminate the need for installing an alkali ion water generator in each facility.SOLUTION: A coin laundry system 100 comprises an alkali ion water storage part 131 that stores alkali ion water generated outside a coin laundry facility 2, in the coin laundry facility 2, and a plurality of washing tanks 110 that washes a cleaning object in the coin laundry facility 2. The number of alkali ion water storage parts 131 is smaller than that of washing tanks.SELECTED DRAWING: Figure 2

Description

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

Conventionally, when washing clothes at home or in a coin landry equipped with a plurality of washing machines, washing is performed by 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.
Patent Document 2 discloses a coin land system in which an alkaline ionized water generator is provided for each coin land facility by the same inventor as the present application.

JP 2003-144793 A Japanese Patent Laying-Open No. 2015-181765

  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 caused by alkaline ionized water and the complexity and enlargement of devices such as the installation of ion water generators.

  Moreover, in patent document 2, since it became necessary to install an expensive alkali ion water generator for every facility, there existed a problem in the point of cost.

  In view of the above problems, the present invention is to provide a coin land system that does not require an alkaline ionized water generator to be installed in each facility.

  A coin landry system according to the present invention includes an alkali ion water storage unit that stores alkali ion water generated outside a coin landry facility in the coin landry facility, and a plurality of cleaning tanks that wash a cleaning target in the coin landry facility. The number of alkaline ion water reservoirs is smaller than that of the washing tank.

  Preferably, the apparatus includes a pump that stores the alkali ion water generated outside the coin landry facility and transports the alkali ion water from the alkali ion water transport container required for transport to the alkali ion water storage unit.

  Preferably, a sensor capable of detecting the amount of water in the alkaline ionized water storage unit and a communication unit capable of communicating with the headquarter control unit via a communication network are provided.

  Preferably, the sensor can continuously detect the amount of water in the alkaline ionized water storage unit.

  Preferably, a control unit is included, and the control unit determines whether or not the alkali ion water is to be transported in the alkali ion water transport container based on the information on the amount of water from the sensor.

  Suitably, the said control part has a notification means which notifies a user of the said abnormality, when the fluctuation | variation of the water quantity of the said alkali ion water storage part is abnormal.

  With a simple configuration, it has become possible to provide a coin land system that does not require an alkali ion water generator at each facility.

It is explanatory drawing of the alkali ion water production | generation system part which is a part which produces | generates the alkali ion water of the coin land system which concerns on the 1st Embodiment of this invention. It is explanatory drawing of the coin land facility facility which uses the alkali ion water of the coin land system which concerns on the 1st Embodiment of this invention. It is explanatory drawing which shows the alkali ion water production | generation medium supply part of the coin land system which concerns on embodiment of invention. It is explanatory drawing which shows the alkali ion water production | generation medium supply part of the coin land system which concerns on embodiment of invention. 1 is a block diagram of a control system of a coin land system according to a first embodiment of the present invention. FIG. It is an example of the flowchart of a process of the head office computer.

<First Embodiment>
The coin land system 100 has a head office that manages a plurality of coin land lines, and each coin land line facility 2 (see also FIG. 2).
Here, the coin land facility is assumed to be a plurality of facilities in the end, but may be one facility.
The coin landry facility 2 is currently cleaned using coins, but will be able to settle electronically in the future. Such a thing is also referred to as a coin land in this embodiment.
Also, within the premises of this coin landry facility 2, water, alkaline ionized water, information, etc. are sent without using public facilities (= indicating that they can be used by unspecified third parties). Or the range which can be received (in the case of information, transmission and reception).

  FIG. 1 is an explanatory diagram of an alkaline ionized water generation system 1 portion that is a portion that generates alkaline ionized water of the coin land system 100 according to the first embodiment of the present invention.

  The alkali ion water generation system 1 is generated by an alkali ion water generation unit 10, an alkali ion water generation medium supply unit 20 that supplies an alkali ion water generation medium 21 to the alkali ion water generation unit 10, and an alkali ion water generation unit. The alkaline ion water storage unit 30 for storing the alkaline ion water and the alkaline ion water transport container 101 are provided.

Water is supplied to the alkaline ionized water generator 10 through the first 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.

Specifically, for example, alkali ion water is generated using a method disclosed in Japanese Patent Application Laid-Open No. 2004-275841 which is a technique already disclosed.
However, in this method, it takes a relatively long time to generate alkaline ionized water, and it is not possible to use alkaline ionized water immediately in use unless the alkaline ionized water is generated and stored in advance. There is a problem.
Therefore, in Patent Document 2, the alkali ion water transport container 101 is provided.
However, the alkaline ionized water generating unit 10 has a problem that it is relatively expensive. When this system is introduced at a plurality of facilities, there is a problem that the introduction cost increases.

Therefore, in the present embodiment, the alkali ion water generation unit 10 is generated collectively in a factory such as the headquarters instead of every facility, and the alkali ion is generated using a physical distribution network such as a courier for each facility. Providing water solved this problem.
In addition, in Patent Document 2, it was thought that such a mechanism became possible because it was necessary to use alkali ion water with a relatively high alkali concentration. This was made possible by discovering the fact that a similar cleaning action was observed at much lower alkali concentrations than was possible.
In other words, when using at a relatively high alkali concentration as in the prior art, if alkali ion water is transported, it is necessary to transport a very large amount of alkali ion water, which is not practical. It was supposed to produce alkaline ionized water.
However, if the alkali concentration may be low, it can be used by diluting hundreds of times in each facility, and if so, the alkaline ionized water generating unit 10 that is expensive and requires a place. The method of the present embodiment (the present invention) has become possible by discovering that it is sufficient to transport a slightly high concentration of alkaline ionized water rather than providing the above.

As described above, the alkaline ionized water generated by the alkaline ionized water generating unit 10 is generated over time.
For this reason, the generated alkali ion water is sequentially stored in the alkali ion water transport container 101.
Alkali ion water is supplied from the alkali ion water storage unit 30 to the alkali ion water transport container 101 through the second pipe 52.
. The second 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 alkaline ionized water transport container 101.
In this embodiment, the flow of alkaline ionized water is formed so as to flow based on gravity, but it goes without saying that a pump or the like may be used.

A water amount sensor (not shown) is provided to detect the amount of water inside the alkali ion water transport container 101.
This water amount sensor detects that the amount of water in the alkaline ionized water transport container 101 is constant, and sends the information to the adjustment valve 40.
Thereby, the regulating valve 40 automatically stops the supply of alkaline ionized water.
The alkali ion water transport container 101 filled with alkali ion water is delivered to each facility through a distribution network.

The top part (mouth part) of the alkaline ionized water transport container 101 may be provided with a mechanism for preventing the backflow of contents, that is, a backflow prevention valve. As a result, even when the tank filled with the contents is loaded on a transfer truck by a belt conveyor or the like, smooth loading can be performed without performing extra manual work.
In some cases, a structure in which the mouth portion of the alkaline ionized water transport container 101 is covered with a screwed cap or the like is preferable.

The alkaline ionized water generation medium supply unit 20 may have a timer and automatically supply the alkaline ionized water generation medium 21 to the alkaline ionized water generation unit 10 according to the timer.
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.

  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, when using the above-mentioned technique. When potassium carbonate is used, it is possible to generate about 15 liters of 12.5 pH alkaline ionized water per hour. It is also possible to adjust the amount of potassium carbonate supplied to the alkaline ionized water generation unit 10 according to the amount stored in the alkaline ionized water storage unit 30.

Moreover, in this embodiment, although it was set as the alkali ion water production | generation medium 21 shape | molded by solid form, in a modification, a powdery thing may be sufficient.
Furthermore, in a modification, you may make it adjust the quantity of the potassium carbonate supplied to the alkali ion water production | generation part 10 according to the quantity of the alkali ion water to produce | generate or store.
Moreover, in a modification, you may make it the system which supplies the alkaline ionized water conveyance container 101 automatically sequentially, and is filled with alkaline warm water.

  FIG. 2 is an explanatory diagram of a coin landry facility 2 portion using alkaline ionized water of the coin land system 100 according to the first embodiment of the present invention.

More specifically, in FIG. 1, it is an explanatory view of a portion for washing clothing using alkaline ionized water filled in an alkaline ionized water carrying container 101.
The coin landry facility 2 in FIG. 2 includes four cleaning tanks 110, a first cleaning tank 110a, a second cleaning tank 110b, a third cleaning tank 110c, and a fourth cleaning tank 110d.
Although not shown, the coin landry facility 2 has facilities, equipment, and stores that other coin landries normally have, but it is not an essential part of the present embodiment, and thus the description thereof is omitted.

In addition, the number of (one) alkali ion water reservoirs 131 is smaller than the number of washing tanks 110 (four).
The second pipe 104 supplies alkali ion water from the alkali ion water storage part 131 to each cleaning tank 110.
Specifically, water is supplied from the first alkaline water opening 114a to the first washing tank 110a, water is supplied from the second alkaline water opening 114b to the second washing tank 110b, and the third alkaline water use is supplied. Water is supplied from the opening 114c to the third cleaning tank 110c, and water is supplied from the fourth alkaline water opening 114d to the fourth cleaning tank 110d.
Moreover, the alkaline ionized water supplied to the 1st washing tank 110a is adjusted with the adjustment valve 112a for 1st alkaline water.
Similarly, the supply to the second cleaning tank 110b by the second alkaline water adjustment valve 112b, the supply to the third cleaning tank 110c by the third alkaline water adjustment valve 112c, and the fourth alkaline water adjustment valve 112d. The supply to the fourth cleaning tank 110d is adjusted.

The third pipe 53 is a pipe for water used in normal washing that does not contain alkali ions such as tap water to the four washing tanks 110. From the first water opening 113a to the first washing tank 110a. Water is supplied.
Similarly, water is supplied from the second water opening 113b to the second cleaning tank 110b, water is supplied from the third water opening 113c to the third cleaning tank 110c, and the water is supplied from the fourth water opening 113d. Water is supplied to the 4 washing tank 110d.
Moreover, the water supplied to the 1st washing tank 110a is adjusted with the 1st adjustment valve 111a.
Similarly, supply to the second cleaning tank 110b by the second water adjustment valve 111b, supply to the third cleaning tank 110c by the third water adjustment valve 111c, and fourth cleaning by the fourth water adjustment valve 111d. The supply to the tank 110d is adjusted.

The alkaline ionized water storage unit 131 is replenished with alkaline ionized water in the alkaline ionized water transport container 101 through the fourth pipe 55.
More specifically, the alkali ion water is supplied to the alkali ion water storage unit 131 by draining the alkali ion water sucked by the pump 54 from the water supply port 55a from the drain groove 55b.

The alkali ion water storage unit 131 is provided with a sensor 132 for detecting the water level.
For example, the sensor 132 is a pressure gauge, so that the water level can be known in detail.
Of course, methods other than a pressure gauge may be used.
Although not preferred, it is possible to provide one or more sensors that can detect when the water level is below or above a predetermined amount.
In addition, it is preferable that the sensor 132 can detect a dangerous water amount that is expected to be incapable of coin landry business due to a shortage of alkaline ionized water.
This sensor 132 may have this function, or a dedicated sensor for this function may be arranged.

Alkaline ion water is supplied through the second pipe 104. At this time, it is preferable to supply the alkali ion water to each cleaning tank 110 by gravity without using a pump or the like. Of course, it is not intended to exclude the use of a pump.
If the third pipe 53 is also possible, it is more appropriate to supply water to each cleaning tank 110 directly connected to the water main and using the pressure of the water main.

In the present invention, washing is performed with alkaline ionized water suitable for washing.
Further, this alkaline ionized water is preferably washed with alkaline ionized water that also has a sterilizing and bactericidal action. Since dirt such as clothes is acidic, the stronger the alkalinity of water during washing, the more dirt can be removed. With relatively strong alkaline ionized water, it is possible to decompose and clean oil stains and tobacco dust.

Here, since the alkaline ionized water does not use a synthetic surfactant or the like, 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.

  3 and 4 are explanatory diagrams showing an alkaline ionized water generating medium supply unit of the coin land system 100 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. 3), 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.

  FIG. 5 is a block diagram of the control system of the coin land system 100 according to the first embodiment of the present invention.

Based on FIG. 5, processing in the coin land system 100 according to the first exemplary embodiment of the present invention will be described.
The coin land system 100 includes an alkali ion water generating system 1, a coin land facility 2 that uses alkali ion water, a communication network 63 such as the Internet, and a physical distribution network such as a home delivery service.

Moreover, the alkaline ionized water production | generation system 1 also has the headquarters control part 65 (refer also FIG. 1).
The coin landry facility 2 that uses alkaline ionized water has a water regulating valve 111, an alkaline water regulating valve 112, a sensor 132, an input unit 61, and a communication unit 62.

The control unit 60 controls various information of the coin land facility 2. The control unit 60 may exist for each cleaning tank 110, or one or a plurality of the control units 60 may be present depending on the case.
Further, there may be one that controls the entire coin land facility 2 while being present for each cleaning tank 110.
Furthermore, depending on the case, the headquarters control unit 65 may perform all of them.

The input unit 61 is for the user to input coins, select courses, and the like.
Information input by the user is transmitted to the control unit 60.
This input unit 61 is preferably present for each cleaning tank 110.
Although not shown, it is more preferable that there is a display unit for notifying the user of information in the coin landry facility 2 (may be for each cleaning tank 110).
This display unit may be displayed on the user's smartphone or the like. Similarly, the input unit 61 can naturally serve as the user's smartphone.

The sensor 132 measures the water level of the alkaline ionized water storage unit 131 and transmits the water level information to the control unit 60.
The sensor 132 is preferably capable of measuring the water level in real time.
However, it may be possible to detect when the water level is below (or above) a predetermined water level.

  The water adjustment valve 111 is provided in each cleaning tank 110 as shown in FIG. 2, and can adjust the amount of water supplied to the cleaning tank 110.

  The adjustment valve 112 for alkaline water is provided in each washing tank 110 as shown in FIG. 2, and can adjust the amount of water supplied from the alkaline ion water reservoir 131 to the washing tank 110.

The communication unit 62 can notify various information from the control unit 60 to the headquarter control unit 65 via a communication network 63 such as the Internet.
Conversely, the communication unit 62 can receive information from the communication network 63 headquarter control unit 65.

The headquarter control unit 65 can analyze, accumulate, and manage information from each coin landry facility 2 and send instructions and information to each coin landry facility 2 when necessary.
Moreover, the headquarters control unit 65 controls the alkaline ionized water generation system 1 described in FIG.
Furthermore, the headquarter control unit 65 manages the shipment to the alkaline ionized water transport container 101 to each coin land facility, as will be described later.

When the control unit 60 receives information indicating that the user wants to perform cleaning from the user to the input unit 61, the control unit 60 controls the water adjustment valve 111 and the alkaline water adjustment valve 112 to adjust water and alkaline ionized water.
Although the control unit 60 performs various controls for washing clothes and the like, it is not important in the present embodiment, and is omitted.

  The amount of water and alkali ion water supplied by the control unit 60 may be 1 for alkali ion water and 1000 for water.

  FIG. 6 is an example of a flowchart of processing of the headquarter control unit 65.

The following processing is processing for one coin land facility 2.
The headquarters control unit 65 manages the following processing for each coin land facility 2, but the description thereof is omitted here.

In step ST101, it is determined whether the amount of dangerous water that is expected to be insufficient for alkaline ionized water and become incapable of operating the coin land is below.
If the amount is less than the dangerous water amount, the process proceeds to step ST107.
When that is not right, it transfers to step ST102.
By having this processing, it becomes possible to detect and deliver the alkaline ionized water urgently due to some abnormal situation.
Of course, it is possible to notify the administrator of the headquarters control unit 65 to that effect and take measures.

In step ST102, it is determined whether it is time to detect the amount of water in the target coin land facility 2.
If it is the timing, the process proceeds to step ST103.
Otherwise, the process returns to step ST101.
By having this processing, the load of communication and processing can be reduced.
This timing can be set in a range from several seconds to several days.
This setting can be set by an administrator of the head office control unit 65 or can be set by step ST108 described later.

In step ST103, the current water level information is acquired from the sensor 132.
In step ST104, the previous water level information is acquired from the memory or the like as the water level information when the processing is performed.
In step ST105, the water level decrease rate is calculated.
Specifically, the rate of decrease = (previous water level information−current water level information) / Δt is calculated.
Here, Δt is an elapsed time from when the water level information was acquired last time to when the current water level information was acquired.

In ST109, it is determined whether or not the decrease rate is an abnormal value.
Specifically, an abnormal value is when the rate of decrease is extremely fast. Conversely, an abnormal value is when the decrease rate is extremely slower than the conventional rate.
In addition, although there is no plan to increase the number of shipments of the alkali ion water transport container 101, an abnormal value is obtained when the amount is increased rather than decreased.
Furthermore, even when the alkali ion water transport container 101 is shipped, the increase amount is large.
And when it is an abnormal value, it transfers to step ST110.
On the other hand, when it is not an abnormal value, it transfers to step ST106.
It should be noted that the determination of the abnormal value is merely an example described here, and it goes without saying that a simpler or more complicated determination may be made. For example, a more complicated determination may be made according to the day of the week, season, event, or the like.

In step ST110, notification to the administrator of the headquarter control unit 65 that there is an abnormality is performed using a notification means.
For example, there may be means for displaying on a display, mailing, and the like.

In step ST106, it is determined whether or not it is necessary to replenish with alkaline ionized water.
If it is determined that replenishment is necessary, the process proceeds to step ST107.
On the other hand, if there is no need for replenishment, the routine proceeds to step 108.
Here, the necessity of replenishment is determined to be necessary if replenishment is required when the absolute value of the alkaline ionized water present in the alkaline ionized water storage unit 131 is not more than a predetermined value.
Further, even if it is equal to or greater than the predetermined value, it is determined that there is a need for replenishment even when the rate of decrease is fast.

In step ST107, the headquarters control unit 65 issues an instruction to send the alkaline ionized water transport container 101 to the coin land facility 2 that needs to be replenished.
Here, the contents of the instruction (how many liters have been sent, how many times have been sent, etc.) are stored in the storage unit and used in the next determination in step ST109 and step 106.

In step ST108, the next acquisition timing is determined from the decreasing speed.
This next acquisition timing is used in step ST102.
The next acquisition timing is shortened when the decrease rate is large, and is extended when the decrease rate is slow.

<Other embodiments>
In the above, the alkali ion water conveyance container 101 and the alkali ion water storage part 131 were provided separately.
However, the alkaline ion water transport container 101 may be attached as a replacement cartridge and used as the alkaline ion water storage unit 131.
However, in this case, if a plurality of alkali ion water transport containers 101 can be attached, or if the alkali ion water reservoir 131 is not prepared separately, the timing at which the alkali ion water cannot be used is generated. The object of the present invention can be achieved.

<Configuration and Effect of Embodiment>
The coin landry system 100 according to the present embodiment includes an alkali ion water storage unit 131 that stores alkali ion water generated outside the coin landry facility 2 in the coin landry facility 2, and a plurality of objects that wash the object to be cleaned in the coin landry facility 2. And a cleaning tank 110.
And the number of the alkali ion water storage parts 131 is fewer than the said washing tank.
Since it has such a structure, the coin land system 100 which does not need to provide an alkali ion water generator in each facility can be provided.

Preferably, there is provided a pump 54 that stores the alkali ion water generated outside the coin landry facility 2 and transports the alkali ion water from the alkali ion water transport container 101 required for transport to the alkali ion water storage unit 131. .
Since it has such a configuration, it is possible to supplement the alkaline ionized water storage unit 131 with alkaline ionized water with a simple configuration.
Further, this method is more preferable because it is not necessary to lift the alkaline ionized water carrying container 101 and it is not necessary to place a burden on the waist of the owner.

Preferably, a sensor 132 capable of detecting the amount of water in the alkaline ionized water storage unit 131 and a communication unit 62 capable of communicating with the headquarter control unit 65 via the communication network 63 are provided.
Since it has such a configuration, the headquarters of the coin landry can grasp the amount of alkaline ionized water in the alkaline ionized water storage unit 131 and replenish the alkaline ionized water.

Preferably, the sensor 132 can continuously detect the amount of water in the alkali ion water reservoir 131.
Since it has such a structure, the headquarters of coin landry can grasp | ascertain the quantity of the alkali ion water of the alkali ion water storage part 131 more correctly.
In addition, the replenishment timing can be appropriately determined.
Furthermore, if there is any abnormality, it can be detected appropriately.

Preferably, it has a control part (headquarters control part 65 and / or control part 60), and a control part judges whether alkaline ion water is conveyed with an alkaline ion water conveyance container based on information on the amount of water from sensor 132. To decide.
Since it has such a configuration, it is possible to appropriately determine the replenishment timing.

Preferably, the control unit includes notification means for notifying the user of the abnormality when the variation in the amount of water in the alkaline ionized water storage unit 131 is abnormal.
Since it has such a configuration, it is possible to notify the user (for example, an administrator of the headquarters control unit 65) of the abnormality, and the user can respond.

<Definition etc.>
The coin landry facility 2 is currently cleaned using coins, but will be able to settle electronically in the future. Such a thing is also called a coin land in the present invention.
Also, within the premises of this coin landry facility 2, water, alkaline ionized water, information, etc. are sent without using public facilities (= indicating that they can be used by unspecified third parties). Or the range which can be received (in the case of information, transmission and reception).
The control unit of the present invention may be physically located anywhere. For example, the control unit 60 in the coin landry facility 2 or the headquarter control unit 65 may be used. Furthermore, it may be in a completely different place. Moreover, the control part 60 and the headquarters control part 65 may share a process.

1: Alkali ion water generation system 2: Coin landry facility 10: Alkaline ion water generation unit 20: Alkaline ion water generation medium supply unit 20T: Timer 21: Alkaline ion water generation medium 25: First plate 26: First rotating jig 27 : Second plate 28: Second rotating jig 30: Alkaline ion water reservoir 40: Adjustment valve 51: First pipe 52: Second pipe 53: Third pipe 54: Pump 55: Fourth pipe 55a: Water supply port 55b : Drainage groove 60: control unit 61: input unit 62: communication unit 63: communication network 65: headquarter control unit 100: coin land system 101: alkali ion water transport container 102: step 104: second pipe 106: step 108: step 110 : Cleaning tank 111: Water adjustment valve 112: Alkaline water adjustment valve 113a: First water opening 114a: No. Alkaline water opening 131: alkali ion water stock unit 132: sensor

Claims (6)

An alkaline ionized water storage unit for storing alkaline ionized water generated outside the coin landry facility inside the coin landry facility;
A plurality of cleaning tanks for cleaning objects to be cleaned in the coin land facility;
With
The number of alkaline ionized water storage units is smaller than that of the washing tank. The coin land supply according to claim 1, further comprising a pump that stores the alkali ion water generated outside the coin land facility and transports the alkali ion water from the alkali ion water transport container required for transport to the alkali ion water storage unit. system. A sensor capable of detecting the amount of water in the alkali ion water reservoir;
The coin land system according to claim 1, further comprising a communication unit capable of communicating with the headquarter control unit via a communication network. The coin land system according to claim 3, wherein the sensor is capable of continuously detecting the amount of water in the alkaline ionized water storage unit. Having a control unit,
3. The coin land system according to claim 3, wherein the control unit determines whether or not the alkali ion water is to be transported by an alkali ion water transport container based on the information on the amount of water from the sensor. The control unit, when the variation in the amount of water in the alkaline ion water storage unit is abnormal,
The coin land system according to claim 5, further comprising a notification unit that notifies the user of the abnormality.

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