JPH07265875A - Mineral water supplying device - Google Patents

Abstract

PURPOSE:To provide a mineral water supplying device capable of supplying mineral water suitable for drinking at all times. CONSTITUTION:This mineral water supplying device is provided with a city water controller 10, a cartridge exchange sensor 30, a mineral mixer 40, a cooler 50, a water purifying device 60, a mineral sensor 70, a solenoid valve 80 for discharging water, a sensor faucet 90, a calendar timer 130, a water drain timer 140, the solenoid valve 80 for discharging water, the cooler 50 and the mineral mixer 40 based on the calendar timer 130. The device is provided with a controller 100 which emits operation commands thereto, emits operation commands to the solenoid valve 80 for discharging water, cooler, mineral mixer in accordance with the water drain time 140, emits a command to drive and stop the mineral mixer 40 and to open or close the solenoid valve 80 for discharging water in accordance with the information on the mineral quantity from the mineral mixer 50 and the information on the mineral concn. from the mineral sensor 70 and emits a command to open the solenoid valve 80 for discharging water in accordance with the information on opening from the sensor faucet 90.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sink equipped with a mineral water supply device for treating tap water as raw water.

[0002]

2. Description of the Related Art Tap water has a bad smell of mustard and musty and is getting worse year by year. In terms of safety and hygiene, problems such as microbial contamination of elevated tanks of buildings and condominiums and generation of red water, as well as asbestos, trihalomethane, and other carcinogenic substances in drinking water have been pointed out, and the demand for safe and delicious water has increased. One of the manifestations is the expansion of demand for mineral water.

Mineral water is commercially available as safe and delicious water by filling glass bottles and polyester bottles with water containing specific minerals such as boiling water and groundwater. However, it is troublesome to purchase it each time it is used, and the price is much higher than that of tap water.

Therefore, as a device for easily and inexpensively obtaining mineral water, conventionally, a cartridge is filled with rocks such as coral sand or barley stone, limestone containing mineral components such as calcium and magnesium, and drinking water is filled therein. A device is used in which mineral water is eluted to pass mineral water to obtain mineral water.

[0005]

However, in the above-mentioned apparatus for obtaining mineral water, the elution of mineral components from coral sand, rocks, etc. varies greatly depending on the water flow conditions such as the water flow rate and water flow time, and is constant. Since it is not possible to increase the mineral content and it is impossible to individually adjust the elution amount of each component such as calcium and magnesium, it is not possible to obtain a mineral water in which the mineral component is adjusted.

[0006] Therefore, in order to solve such a conventional problem, the present inventor has previously applied for a mineral water supply device (Japanese Patent Application No. 4-344310). This mineral water supply device is a constant water flow rate device connected to a clean water pipeline, a mineral addition tank provided on the secondary side of the constant water flow rate device, and a mineral injection pump that communicates with this mineral addition tank. A plurality of mineral tanks that communicate with each of the mineral infusion pumps, a water purifier that communicates with the secondary side of the mineral addition tank, a faucet that communicates with the secondary side of the water purifier, and the water supply constant flow rate device. The second solenoid valve provided between the secondary side and the primary side of the faucet, the mineral sensor provided between the mineral addition tank and the primary side of the faucet, and the detection value of this mineral sensor is a predetermined value. It is provided with the mineral infusion pump and a control device for issuing a command to stop the water supply constant flow rate device when it exceeds.

According to this mineral water supply device,
It has the following advantages. It is possible to inject a fixed amount of mineral components into the tap water that is flowing at a constant flow rate by the tap water constant flow rate device by the mineral injection pump, and always supply a stable mineral water.

Moreover, since mineral water removes odorous substances, trihalomethanes, organic substances, residual chlorine, bacteria, colloids, etc. with a water purifier, it can be supplied as safe and delicious water.

As for the mineral component, by adjusting the mineral component that precipitates when mixed to a different tank and injecting them separately, stable mineral water can be supplied. Further, the water pressure is constantly measured, and if it exceeds the set water pressure, it is determined that the hollow fiber membrane filter of the water purifier is clogged, and the replacement is indicated or the device is stopped.

Regarding the life of the activated carbon of the water purifier,
If the accumulated value of the flow rate exceeds a certain accumulated value, it is judged that the activated carbon has reached the end of its life, and a replacement is displayed or the device is stopped. Therefore, the replacement time of the filter material such as the hollow fiber membrane filter and the activated carbon is clear, and the problem due to the life of the filter material is eliminated.

However, when this mineral water supply device is applied, there are the following problems. The mineral water produced the day before remains in the purifier unless drained, but this residual water is not suitable as drinking water. Therefore, it was necessary to manually discharge the residual water in the purifier before use.

Further, when the generated mineral water is not discharged for several hours, there is a similar problem.
The present invention has been made to solve such conventional problems, and an object thereof is to provide a mineral water supply device that can always supply mineral water suitable for beverages.

[0013]

According to a first aspect of the present invention, there is provided a water supply control device which is connected to a water supply pipe line, and two of the water supply control device.
Cartridge exchange sensor communicating with the secondary side, mineral mixing device communicating with the secondary side of this cartridge exchange sensor, cooling device communicating with the secondary side of this mineral mixing device, communicating with the secondary side of this cooling device Water purifier, a mineral sensor that communicates with the secondary side of this water purifier, a water discharge solenoid valve that communicates with the secondary side of this mineral sensor, and a sensor faucet that communicates with the secondary side of this water discharge solenoid valve And a faucet that communicates with the secondary side of this sensor faucet, a calendar timer that sets the start time and end time every day, a drainage timer that sets the unused time, and a water discharge solenoid based on the calendar timer. An operation command is issued to the valve, the cooling device, and the mineral mixing device, and an operation command is issued to the electromagnetic valve for water discharge, the cooling device, and the mineral mixing device based on the drainage timer, and the mi Lal amount information, based on the mineral density information from minerals sensor, driving and mineral mixing device
And a controller for issuing a stop command and a command for opening and closing the water discharge solenoid valve, and for issuing a command for opening the water discharge solenoid valve based on the opening information from the sensor faucet.

According to a second aspect of the present invention, the clean water control section is composed of a pressure regulating valve with a check valve and a constant flow rate device. According to a third aspect of the invention, the cartridge exchange sensor includes a water pressure switch and an integrating time meter.

According to a fourth aspect of the present invention, there is provided a mineral mixing device,
It is composed of a mineral mixer, a mineral infusion pump, a mineral tank, and a water level sensor provided in the mineral tank.

In a fifth aspect of the invention, the cooling device comprises a cooling tank, a compressor, a radiator, and a temperature controller. In the invention of claim 6, a safety valve is provided between the mineral sensor and the sensor faucet.

[0017]

In the first to sixth aspects, the main power source is turned on when the start time input in advance to the calendar timer is reached.

As a result, the control device sends an open signal to the water discharge solenoid valve for, for example, 30 seconds, and the accumulated water in the cooling tank is drained. At the same time, the compressor of the cooling device and the mineral injection pump are activated.

When the water inside the cooling tank reaches the set temperature,
The operation of the compressor was stopped, and at the same time, an open signal was sent from the control concept to the discharge solenoid valve for 30 seconds, the mineral injection pump was activated, and the accumulated water in the water purifier was drained.
Replaced with new cooling water.

At the same time when the main power is turned on, tap water is supplied from the water supply port to a constant flow rate by the clean water control device, and then introduced into the mineral mixing device through the cartridge exchange sensor.

During this period, the cartridge exchange sensor determines the clogging state of the water purifier cartridge of the water purifier.
Further, in the mineral mixing device, a fixed amount of mineral concentrated liquid is added to and diluted with tap water to generate mineral water.

This mineral water is cooled to a predetermined temperature by a cooling device and then sent to a water purifier. The mineral water supplied to the water purifier is subjected to removal of odorous components, trihalomethanes, residual chlorine, bacteria, colloidal components, etc. by the water purifier cartridge in the water purifier.

Therefore, when the user brings a cup or the like close to the sensor faucet, the sensor faucet senses this and notifies the control device. In the control device, an open signal is sent to the water discharge solenoid valve and an operation signal is sent to the mineral injection pump.

As a result, the cooled mineral water in the water purifier is discharged from the faucet. At the same time, mineral water commensurate with the amount of water discharged is stored in the water purifier.
When the user removes the cup or the like from the sensor faucet, the sensor faucet senses this and notifies the control device. The control device sends a close signal to the water discharge solenoid valve and a stop signal to the mineral infusion pump.

Further, when the operation signal from the sensor faucet does not exist for a predetermined time or longer (when water is not discharged)
First, the drainage timer 140 sends a time-up signal to the control device. In response to this, the control device sends an open signal to the water discharge solenoid valve and an operation signal to the mineral injection pump, discharges the cooling water in the water purifier for a predetermined time and replaces it with new cooling water.

[0026]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is an explanatory view showing an embodiment of the mineral water supply device according to claims 1 to 6, and 1 is a water supply port.

The water supply port 1 communicates with a water pipe, which is a water supply pipe (not shown), through a branch plug or the like. In this example, the water supply rate was 3 ± 0.2 liters per minute.

The water supply port 1 is connected to a clean water control device 10 via a pipe line 2. The tap water control device 10 controls the tap water supplied to the mineral water supply device according to the present embodiment to a constant flow rate, and includes a pressure control valve 11 with a backflow prevention valve and a constant flow rate device 12. ing.

The backflow prevention valve-equipped pressure control valve 11 prevents the treated water from flowing back when the constant flow rate device 12 fails. The pressure of tap water passing through the pressure control valve 11 with the check valve is, for example, 2.1 Kgf / c.
Although it is at least m ^2, it is set to 2.1 Kgf / cm ² by the pressure regulating valve 11 with a check valve.

As the constant flow rate device 12, a constant flow rate pump such as a gear pump or a diaphragm pump or a constant flow rate valve is used. In this embodiment, as the constant flow rate device 12,
A constant flow valve is used.

With this constant flow valve, the flow rate of tap water is 3.0.
Adjust to a constant flow rate of 1 / min. The operating pressure range of the constant flow valve is a differential pressure of 0.2 to ² Kgf / cm ² . When the constant flow device 12 is a constant flow pump, the constant flow device 12 is connected so that the operation can be stopped by a command from the control device 100.

When the constant flow rate device 12 is a constant flow rate pump, a pressure reducing valve is used to reduce the load on the constant flow rate pump and improve the constant flow rate. An electromagnetic valve 20 for opening and closing communicates with the secondary side of the water supply control device 10. In this embodiment, the clean water control device 10 is provided between the backflow prevention valve-equipped pressure control valve 11 and the constant flow device 12, but the opening / closing solenoid valve 20 and the constant flow device 12 are replaced with each other. Is also good.

The open / close solenoid valve 20 shuts off the conduit 2 in response to a command from the control device 100 when an abnormality is detected by the mineral sensor 70 such as an electric conductivity sensor. A cartridge exchange sensor 30 communicates with the secondary side of the constant flow rate device 12.

The cartridge exchange sensor 30 is composed of a water pressure switch 31 and an integration use timer 32 in this embodiment. The water pressure switch 31 senses the water pressure of the water, determines the degree of clogging of the hollow fiber membrane filter of the water purifier 60, and notifies the control device 100 of the cartridge replacement timing of the water purifier 60.

Further, the integration use timer 32 integrates the open time based on the open signal of the sensor faucet 90 input to the control device 100. In this embodiment, when the accumulated usage time reaches 2700 minutes, the control device 100 is notified,
As shown in Table 1 and Table 2 from the control device 100, the inspection LED 112 of the faucet display part 110 and the device front display 120
A blinking command is sent to the cartridge replacement LED 123 of the above, and a lighting command is sent to the reset switch 121 of the device front display 120.

For example, the pressure of tap water was set to 2.1 Kgf / cm ² by the pressure regulating valve 11 with the backflow prevention valve, but the water passing pressure became high due to clogging of the hollow fiber membrane filter of the water purifier 60. To go.

The water pressure is 1.5 Kgf / cm ²
Then, in the water pressure switch 14, this is changed to the control device 10
0, and the control device 100 sends a blink command to the inspection LED 112 of the faucet display unit 110 and the cartridge exchange LED 123 of the device front display 120 as shown in Tables 1 and 2 to reset the device front display 120. 1
A lighting command is sent to 21.

[0038] A notification when the accumulated use time reaches 2700 minutes from the accumulated use timer 32, and the water pressure switch 14
Among the notifications when the water flow pressure of 1.5 kgf / cm ² has been reached, the control device 100 blinks from the one that comes first,
Send a lighting command.

Further, when used, the water flow pressure is 1.9K.
When gf / cm ² is reached, the water pressure switch 31 notifies the control device 100 of this, and in response to this, the control device 100
Then, a lighting command is sent to the inspection LED 112 of the water faucet display unit 110 and the cartridge replacement LED 123 of the device front display 120, a closing command is sent to the opening / closing solenoid valve 20, and a stop command is sent to the mineral infusion pumps 42A, 42B and the compressor 55. The mineral water supply device according to the present embodiment is stopped.

Regarding the notification when the cumulative usage time from the cumulative usage timer 32 reaches 3000 minutes and the notification when the water flow pressure reaches 1.9 Kgf / cm ² ,
The control device 100 sends each command from the one entered first.

A mineral mixing device 40 is connected to the secondary side of the water pressure switch 31. Mineral mixing device 40
Is a method for producing mineral water by adding and diluting a certain amount of mineral concentrated liquid to tap water.

The mineral mixing device 40 includes a mineral mixer 41A, 41B and a mineral mixer 41.
Mineral infusion pump 42A, 42 which communicates with A, 41B
B, mineral tanks 43A and 43B connected to the mineral infusion pumps 42A and 42B, and water level sensors 44A and 44B arranged in the mineral tanks 43A and 43B, respectively.

The mineral mixers 41A and 41A are
It is only necessary that the minerals from the mineral tanks 43A and 43B are uniformly mixed in tap water, and an obstacle (so-called static mixer) that disturbs the flow is inserted in the pipeline or a mixer that actively agitates. Is used.

The mineral injection pumps 42A, 42B supply the minerals in the two mineral tanks 43A, 43B to the mineral mixers 41A, 41B at a constant flow rate, and reliably supply tap water supplied at a constant flow rate by the water supply control device 10. It enables mixing at a fixed ratio.

This mineral injection pump 42A, 42B
A constant flow pump such as a diaphragm pump or a tube pump is used as the pump. Mineral tank 43A, 43B
May be any as long as it can store a mineral solution and does not have an eluate that causes a drinking problem, and a tank made of stainless steel, polyethylene, or the like is used.

The mineral injection pumps 42A and 42B are driven / stopped in response to a command from the control device 100. For example,
Abnormal sensing of the amount of mineral addition from the mineral sensor 70,
The operation is stopped in response to a command from the control device 100, such as a command that the mineral amount has reached the second set value L.

The two mineral tanks 43A and 43B are
The mineral components that precipitate when mixed are separately filled. For example, Ca and Mg are necessary as components of mineral water, but when these make carbonate,
It becomes insoluble. Therefore, it cannot be filled in the same tank as the carbonic acid component.

For example, one of the mineral tanks 43A is filled with CaCl ₂ .2H ₂ O, MgCl ₂ .6 H ₂ O and KCl, and the other mineral tank 43B is filled with NaHCO ₃ . Or, in one mineral tank 43A, CaCl ₂ · 2
H ₂ O and MgCl ₂ · 6H ₂ O are filled, and the other mineral tank 43
B is filled with K ₂ CO ₃ and NaHCO ₃ .

The water level sensors 44A and 44B arranged in the two mineral tanks 43A and 43B are for monitoring the remaining amount of the mineral tanks 43A and 43B and for additionally displaying.

In this embodiment, for example, Table 1 and Table 2
As shown in, the first set value H is provided at a position 46 mm from the bottoms of the mineral tanks 43A and 43B, and the first set value L is set at a position 19 mm from the bottoms of the mineral tanks 43A and 43B.
Is provided.

When the first set value H is reached, the fact that the mineral amount has reached the first set value H is sent to the control device 100. In response to this, in the control device 100, the sensor faucet 9
Faucet check LED 112 of the display unit 110 provided at 0
A blinking signal is sent to the mineral addition LED 122 of the device front display unit 120, and a lighting signal is sent to the reset switch 121 of the device front display unit 120.

When the second set value L is reached, the fact that the mineral amount reaches the second set value L is transmitted to the control device 100. In response to this, in the control device 100, the sensor faucet 9
Inspection LED 112 of the faucet display section 110 provided at 0
And a lighting signal to the mineral addition LED 122 of the device front display 120, a closing command to the opening / closing solenoid valve 20, and a stop command to the mineral injection pumps 42A and 42B and the compressor 50, and the mineral water supply device according to the present embodiment. To stop.

[0053]

[Table 1]

[0054]

[Table 2]

2 of these mineral mixers 41A and 41B
The cooling device 50 communicates with the next side. The cooling device 50 includes a cooling tank 51, a temperature controller 54, a compressor 55, a radiator 56, and a blower 57.

A cooling coil 52 is arranged in the cooling tank 51, and a drain plug 53 is provided in the lower part.
The temperature controller 54 constantly monitors the water temperature in the cooling tank 51 and adjusts the temperature of the cooling water to an arbitrary value of 7 to 15 ° C. The temperature of this cooling water is preferably 10 to 15 ° C., which is the temperature of delicious water.

The compressor 55 is controlled by the temperature controller 54. The radiator 56 and the blower 57 are the compressor 55
It is designed to be linked to the operation of. 2 of the cooling device 50
The water purifier 60 is in contact with the next side.

The water purifier 60 has a water purifier cartridge made of non-woven fabric, silver-impregnated granular activated carbon, and a polyethylene hollow fiber membrane filter in a heat-insulated container.

The mineral water supplied to the water purifier 60 has its odor components, trihalomethanes, residual chlorine, bacteria, colloid components, etc. removed by a water purifier cartridge.

In the present embodiment, the replacement period of the water purifier cartridge was set to 3 months by using 100 liters a day. This is cumulative usage of 9000 liters, cumulative usage time of 300
Equivalent to 0 minutes.

Here, assuming that the amount of water supplied is 3 liters per minute, the water purifier 60 has a capacity of removing residual chlorine of 9 tons or more and turbidity of 9 tons or more (according to the Japan Water Works Association, water purifier type test method). ).

A mineral sensor 70 is connected to the secondary side of the water purifier 60. This mineral sensor 70
Ion electrodes such as calcium and magnesium and conductivity sensors are used.

In the case of the conductivity sensor, the setting range was 400 to 1600 μS / cm ² (20 ° C.) in this embodiment. The mineral sensor 70 is preferably provided immediately before spouting water, which is the final treatment state, in order to detect a state in which minerals are uniformly mixed in tap water. Therefore, in this embodiment, the mineral sensor 70 is provided between the water purifier 60 and the water discharge solenoid valve 80.

The mineral sensor 70 has a water discharge solenoid valve 80.
If it is provided in front of, the water discharge can be immediately stopped when an abnormality is detected. A water discharge solenoid valve 80 and a safety valve 81 are connected in parallel to the secondary side of the mineral sensor 70.

The safety valve 81 discharges water from the faucet 91 when the pressure inside the apparatus according to this embodiment rises above a set value due to an abnormal operation of the pressure regulating valve 11 with the backflow prevention valve of the water supply control apparatus 10. This is to prevent damage.

The working pressure of the safety valve 81 was 3 Kgf / cm ² in this embodiment. A sensor faucet 90 and a faucet 91 are connected to the secondary side of the water discharge solenoid valve 80 and the safety valve 81.

The sensor faucet 90 is composed of a known object detection sensor or a push button switch. Sensor faucet 90
Is an object detection sensor, when a shield such as a cup or a human hand approaches the front surface, the control device 100 senses it.
To the water discharge solenoid valve 80 from the control device 100 based on this signal.
Is opened and water is spouted from the faucet 91.

A calendar timer 130 and a drainage timer 140 are further connected to the control device 100. The calendar timer 130 has a function of setting an operation mode according to the usage situation of the setting place, and can set the operation for one week.

The calendar timer 130 sets daily operating times (start time and end time). At the start time, the main power source of the device according to the present embodiment is turned on,
00 causes the water discharge operation to be performed before the normal operation is started. This is done to refresh the water in the pipe because it is stopped at night.

At the end time, the main power supply of the apparatus according to this embodiment is turned off, and the apparatus according to this embodiment is stopped.
The drainage timer 140 sends a time-up signal to the control device 100 when the operation signal from the sensor faucet 90 is not present for a set time or longer (when water is not discharged).

In response to this, the control device 100 sends an open signal to the water discharge solenoid valve 80 and sends an operation signal to the mineral injection pumps 42A and 42B to discharge the cooling water in the water purifier 60 for a predetermined time. , Replace with new cooling water.

In this embodiment, the drainage timer 140 can be set to any time between 2 hours and 5 hours. Next, the operation of the present embodiment configured as described above will be described.

First, when the start time (for example, 9:00 am) previously input to the calendar timer 130 comes, the main power supply of the apparatus according to the present embodiment is turned on. As a result, an open signal is sent from the control device 100 to the water discharge solenoid valve 80, and the accumulated water inside the water purifier 60 is drained. At the same time, the compressor 5
5 and the mineral infusion pumps 42A and 42B, the operation signal is sent to the compressor 55 and the mineral infusion pumps 42A and 42A.
B operates.

When the water inside the cooling tank 51 reaches the set temperature, the operation of the compressor is stopped, and at the same time, the controller 100 sends an open signal to the water discharge solenoid valve 80 for 30 seconds, and the water purifier 6
The accumulated water inside 0 is drained for 30 seconds and replaced with new cooling water. At the same time, mineral infusion pumps 42A, 4
A stop command is issued to 2B and the mineral infusion pump 42
A and 42B are in operation.

When the replacement work is completed, the operation LED 111 of the display portion 110 of the sensor faucet 90 is turned on. Here, the drainage time is set to twice for 30 seconds because the accumulated water in the water purifier 60 and the cooling tank 51 in this embodiment is about 3 liters in total, and the water supply amount of the mineral water supply device according to this embodiment is Is 3 liters / minute,
There are a total of 30 liters of water discharged by running twice for 30 seconds,
This is because all the accumulated water inside the purifier 60 and the cooling tank 51 is discharged and replaced with new water.

Therefore, this drainage time can be arbitrarily changed depending on the size of the apparatus. At the same time when the main power is turned on, an opening signal is output from the control device 100 to the opening / closing solenoid valve 20, the opening / closing solenoid valve 20 opens the pipe line 2, and tap water is supplied from the water supply port 1 to control the water supply. After the flow rate is kept constant by the device 10, it is introduced into the mineral mixing device 40 through the opening / closing solenoid valve 20 and the cartridge exchange sensor 30.

During this period, the cartridge exchange sensor 30 determines the clogging state of the water purifier cartridge of the water purifier 60. Further, in the mineral mixing device 40, a fixed amount of mineral concentrated liquid is added to and diluted with tap water to generate mineral water.

Here, the mineral infusion pumps 42A, 4A
In 2B, the mineral components in the two mineral tanks 43A and 43B are supplied at a constant flow rate. Therefore, the two mineral components are accurately added and mixed into the tap water at a constant flow rate to form a stable mineral water.

This mineral water is cooled to 7 to 15 ° C. by the cooling device 50 and then sent to the water purifier 60. The mineral water supplied into the water purifier 60 is the water purifier 6
Odor components, trihalomethanes, residual chlorine, bacteria, colloid components, etc. are removed by the water purifier cartridge in No. 0.

Then, when the user brings the cup close to the sensor faucet 90, the sensor faucet 90 senses this and notifies the control device 100. In the control device 100, an open signal is sent to the water discharge solenoid valve 80, and the mineral injection pump 4
Send an operation signal to 2A and 42B.

As a result, the cooled mineral water in the water purifier 60 is discharged from the faucet 91. at the same time,
Mineral water commensurate with the amount of water discharged is stored in the water purifier 60.

When the user releases the cup from the sensor faucet 90, the sensor faucet 90 senses this and notifies the control device 100. In the control device 100, a closing signal is sent to the water discharge solenoid valve 80, and the mineral injection pumps 42A, 42
Send a stop signal to B.

In the above embodiment, as the cartridge exchange sensor 30, the water pressure switch 31 and the integrated time meter 32 are used.
Although the case of using the flowmeter has been described, the flowmeter and the pressure sensor may be used together, or either one of the flowmeter and the pressure sensor may be used.

The flow meter constantly measures the flow rate, and when it falls below the set flow rate, it sends an abnormal signal to the control device.
The control device determines that the water purifier cartridge is clogged.

Further, the integrated value of the flow meter is monitored by the control device, and when it exceeds a predetermined value, it is regarded as the life of the activated carbon of the purifier. When a flow meter is used, the integrated value of the flow meter is processed by the control device 100, or the integrated value of the flow meter is simply displayed as a display value and replaced when it exceeds a predetermined value. May be.

The pressure sensor constantly measures the pressure, and when it rises above the set pressure, it sends an abnormal signal to the control device. The control device determines that the water purifier cartridge is clogged.

Two mineral tanks 43A and 43
The case where different mineral components are filled in B has been described, but it is also possible to make two or more. Further, although the case where the opening / closing solenoid valve 20 is provided has been described, it may be omitted.

FIG. 2 shows an example in which the mineral water supply device shown in FIG. 1 is applied to a sink. The mineral water supply device 200 incorporates each device other than the sensor faucet 90, the faucet 91, and the water supply port 1. The sensor faucet 90 and the faucet 91 are located above the sink 202, and the water supply port 1 is connected to the raw water intake section 203.

Reference numeral 201 denotes a device front display section. Figure 3
An example in which the mineral water supply device shown in FIG. 1 is applied to a water cooler is shown.

The mineral water supply device 300 is housed in the water cooler 301. The present invention is not limited to a sink or a water cooler, but may be of a form placed on a table.

[0091]

As described above, according to the mineral water supply device according to the first to sixth aspects, the fresh water is replaced with the fresh water in the water purifier at the start of the operation. Stop drinking water.

When the water is not discharged for a predetermined time, the accumulated water in the water purifier is replaced with a new mineral water by the drainage timer, so that the mineral water having a stable component can be always supplied.

Further, since the mineral sensor is provided between the water purifier and the water discharge solenoid valve, the mixed state of the minerals in the mineral water can be detected under almost the same conditions as the water discharge, and the accurate mineral concentration is constantly monitored. can do.

Since the mineral sensor is provided between the water purifier and the water discharge solenoid valve, the water discharge can be stopped immediately when an abnormality is detected.

[Brief description of drawings]

FIG. 1 is a simplified diagram showing a basic configuration of an embodiment of a mineral water supply device according to claims 1 to 6.

FIG. 2 is a simplified diagram showing an example in which the mineral water supply device shown in FIG. 1 is applied to a water cooler.

FIG. 3 is a schematic view showing an example in which the mineral water supply device shown in FIG. 1 is applied to a water cooler.

[Explanation of symbols]

 1 Water Supply Port 2 Pipeline 10 Water Supply Control Device 11 Pressure Control Valve with Backflow Prevention Valve 12 Constant Flow Rate Device 20 Solenoid Valve for Opening / Closing 30 Cartridge Replacement Sensor 31 Water Pressure Switch 32 Integration Timer 40 Mineral Mixing Device 41A, 41B Mineral Mixer 42A, 42B Mineral injection pump 43A, 43B Mineral tank 44A, 44B Water level sensor 50 Cooling device 51 Cooling tank 54 Temperature controller 55 Compressor 56 Radiator 57 Blower 60 Water purifier 70 Mineral sensor 80 Water discharge solenoid valve 81 Safety valve 90 Sensor faucet 91 Faucet 100 Control device 130 Calendar timer 140 Drainage timer

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification number Reference number within the agency FI Technical indication C02F 1/68 540 A D G (72) Inventor Naomi Kawato 1 Otsuka, Inzai-cho, Inba-gun, Chiba Prefecture No. 5 Incorporated Takenaka Corporation Technical Research Institute (72) Inventor Kenichi Unno 1-5 Otsuka, Inzai-cho, Inba-gun, Chiba Prefecture Incorporated Takenaka Corporation Technical Research Institute (72) Yasushi Nakayama Otsuka, Inzai-cho, Inba-gun, Chiba Prefecture 1-5 5 Takenaka Corporation Technical Research Institute (72) Inventor Yukio Kobayashi 4-chome 1-60 Sunadabashi, Higashi-ku, Nagoya, Aichi Prefecture Mitsubishi Rayon Co., Ltd. Product Development Laboratory (72) Inventor Tatsuhiro Kato Nagoya, Aichi Prefecture 4-chome, Sunadabashi, Higashi-ku, Yokohama-shi, Product Development Laboratory, Mitsubishi Rayon Co., Ltd. 4-160 Sunadabashi, Higashi-ku, Tokyo Inside Mitsubishi Rayon Co., Ltd. Product Development Laboratory (72) Inventor Yoshinori Kawai 2-33-1 Kyobashi, Chuo-ku, Tokyo Inside Cleanse Division, Mitsubishi Rayon Co., Ltd. (72) Inventor Okano Masaaki 2-3-19 Kyobashi, Chuo-ku, Tokyo Mitsubishi Rayon Co., Ltd. Cleanse Sui Division

Claims (6)

[Claims] 1. A water supply control device connected to a water supply pipe, a cartridge exchange sensor communicating with the secondary side of the water supply control device, and a mineral mixing device communicating with the secondary side of the cartridge exchange sensor, A cooling device communicating with the secondary side of this mineral mixing device, a water purifier communicating with the secondary side of this cooling device, a mineral sensor communicating with the secondary side of this water purifier, and a secondary side of this mineral sensor The water discharge solenoid valve that communicates with the sensor, the sensor faucet that communicates with the secondary side of this water discharge solenoid valve, the faucet that communicates with the secondary side of this sensor faucet, and the setting of the start time and end time every day. A calendar timer to perform, a drainage timer to set the non-use time, and an operation command to the solenoid valve for water discharge, the cooling device, and the mineral mixing device based on the calendar timer, and the solenoid valve for water discharge based on the drainage timer. An operation command is issued to the cooling device and the mineral mixing device, and based on the mineral amount information from the mineral mixing device and the mineral concentration information from the mineral sensor, a mineral mixing device drive / stop command and a water discharge solenoid valve opening / closing command are issued. And a controller for issuing an opening command for the water discharge solenoid valve based on opening information from the sensor faucet. 2. The mineral water supply device according to claim 1, wherein the clean water control unit is composed of a pressure regulating valve with a check valve and a constant flow rate device. 3. The mineral water supply device according to claim 1, wherein the cartridge exchange sensor includes a water pressure switch and an integrating time meter. 4. The mineral water supply device according to claim 1, wherein the mineral mixing device comprises a mineral mixer, a mineral infusion pump, a mineral tank, and a water level sensor provided in the mineral tank. . 5. The cooling device includes a cooling tank, a compressor, and
The mineral water supply device according to claim 1, wherein the mineral water supply device comprises a radiator and a temperature controller. 6. The mineral water supply device according to claim 1, wherein a safety valve is provided between the mineral sensor and the sensor faucet.