JP2000051854A - Water softener and its controlling method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable use by easy installation at a specified place in a general home by providing a power generation means for generating power by a waster flow in a water passage process and an accumulation means for accumulating electricity generated by the power generation means. SOLUTION: A power generation means 7 such as a generator is installed in a raw water line 6 connected to a raw water inlet part 5. The means 7 converts part of the energy of a water flow in a raw water line 6 into electric energy during water passage process. An accumulation means such as an accumulator is installed to accumulate electricity generated by the means 7. In a regeneration process, water-washing process, and an external cleaning process, the electric energy which was generated by the means 7 during the water passage process and accumulated in the accumulation means is used. By this constitution, since the wiring work of a power source from the outside of an apparatus is obviated, and danger such as an electric shock is eliminated, the apparatus can be installed easily in a specified use place in a general home and used.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water softener and a control method thereof.

[0002]

2. Description of the Related Art As is well known, a water softening treatment for softening raw water using an ion exchange resin has been conventionally performed by various water softeners, and is widely used as an industrial or household water softener. are doing. This household water softener is installed mainly in a place where a home AC power supply can be used, and power is supplied from outside the apparatus. The soft water generated by the household water softener is used as domestic water such as drinking water and washing water, and the function of the water softener is sufficiently exhibited.

[0003] However, there is a need for a water softener that can be installed and used in a specific place in a general household, for example, a bathroom dedicated to a bath. In such a place, it is difficult to supply power to the water softener. Therefore, when a conventional domestic water softener that supplies power from the outside is installed, complicated construction such as a measure for preventing leakage of electric current is involved. Therefore, it is practically difficult to apply a conventional household water softener.

[0004]

SUMMARY OF THE INVENTION An object of the present invention is to provide a water softener which can be easily installed and used at a specific place of use in a general household in view of the above problems.

[0005]

Means for Solving the Problems The present invention has been made to solve the above-mentioned problems, and the invention according to claim 1 is a power generation means for generating power by a water flow in a water passing step; Power storage means for storing electricity generated by the power generation means.

The invention according to claim 2 is characterized in that the regeneration step and the washing step are performed using the power storage means as a power supply.

Further, the invention according to claim 3 is characterized in that an external cleaning step is performed using the power storage means as a power supply.

[0008]

Next, an embodiment of the present invention will be described. INDUSTRIAL APPLICATION This invention can be implemented suitably in the water softener installed in the bathroom of a general household. In the water softener according to the present invention, power generation means, for example, a power generator is provided in a raw water line connected to the resin cylinder. Further, this power generation means may be provided in a soft water line connected to the resin cylinder.
Then, in the water passing step, when the raw water flows into the resin cylinder via the raw water line, a part of the energy of the water flow is converted into electric energy by the action of the power generation means. The converted electric energy is stored in power storage means, for example, a storage battery (secondary battery), a capacitor, or the like.

[0009] The electric energy stored in the power storage means is used as a power source in a regeneration step and a washing step. That is, the electric energy is energy for operating a drive motor for opening and closing a water supply valve, a makeup water valve, a salt water valve, a raw water valve, and a drain valve configured to control the flow of water in the water softener according to the present invention. Used as Further, in a water softener that performs an external cleaning step, the electric energy is used as a power source in this external cleaning step, as in the regeneration step and the water cleaning step.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 showing an embodiment of the present invention will be described. FIG. 1 is a schematic explanatory view showing a pipe connection state of an embodiment of a water softener according to the present invention.

In FIG. 1, a resin tube 2 filled with an ion exchange resin 1, a raw water tank 3 for storing raw water, and a salt water tank 4 for storing saturated brine for regenerating the ion exchange resin 1 are arranged in parallel. It is provided in. A raw water inlet 5 is provided below the resin tube 2, and a raw water line 6 is connected to the raw water inlet 5. This raw water line 6
A power generating means 7, for example, a generator, and a switching valve (three-way valve) 8 for switching between a softening treatment for generating soft water and a non-treatment for not generating soft water are sequentially provided from the upstream side. Have been. The power generation means 7 converts part of the energy of the water flow in the raw water line 6 into electric energy during the water passing step. This switching valve 8 is
This is a so-called temporary water stoppage switching valve, and when the user does not use water, switches to a neutral position to stop water.

A soft water outlet 9 is provided above the resin cylinder 2.
And a soft water line 10 is connected to the soft water outlet 9. The soft water line 10 is provided with a first check valve 11 for preventing the flow in the direction of the soft water outlet 9 and a water purification section 12 containing activated carbon and the like in order from the upstream side. The positions of the first check valve 11 and the water purification unit 12 may be in the reverse order, that is, the order of the water purification unit 12 and the first check valve 11 from the upstream side.

The switching valve 8 and the soft water line 1
0 is connected by a bypass line 13. First connection point 1 between the bypass line 13 and the soft water line 10
4 is a downstream side of the water purification section 12. The bypass line 13 avoids water interruption during regeneration of the ion exchange resin 1. When the user switches the switching valve 8 to the non-treatment side, that is, so that the raw water flows toward the bypass line 13, the raw water is in a hard water state via the bypass line 13 and the soft water line 10. Supplied outside the system.

The lower part of the raw water tank 3 and the raw water line 6 are connected by a water supply line 15. A second connection point 16 between the water supply line 15 and the raw water line 6
Is on the upstream side of the power generation means 7. The water supply line 15 is provided with a water supply valve 17 and a constant flow valve 18 sequentially from the upstream side. Further, a lower part of the raw water tank 3 and a lower part of the salt water tank 4 are connected by a makeup water line 19. The outlet end of the makeup water line 19 is provided at a position at a predetermined height in the salt water tank 4. The makeup water line 19 is provided with a makeup water valve 20 and a second check valve 21 for preventing flow toward the raw water tank 3 from the upstream side.

The lower part of the salt water tank 4 and the soft water outlet 9 are connected by a salt water falling line 22. In this embodiment, the soft water line is located upstream of the first check valve 11. 10 are connected in a state where they are joined. The salt water flow-down line 22 is provided with a salt water valve 23 and a third check valve 24 for preventing a flow toward the salt water tank 4 from the upstream side. Further, a lower portion of the raw water tank 3 and the salt water flowing line 22 are connected by a raw water flowing line 25. A third connection point 26 between the raw water flow down line 25 and the salt water flow down line 22 is on the downstream side of the third check valve 24. The raw water flowing line 25 is provided with a raw water valve 27 and a fourth check valve 28 for preventing flow toward the raw water tank 3 from the upstream side.

A drain line 29 is connected to the raw water inlet 5. In this embodiment, the drain line 29 is connected to the downstream side of the switching valve 8 in a state branched off from the raw water line 6. . In this drain line 29,
A drain valve 30 and an atmosphere opening part 31 are sequentially provided from the upstream side.

The raw water overflow portion 32 of the raw water tank 3 is provided above the upper end of the packed bed of the ion exchange resin 1. The raw water overflow section 32 and the drain line 29 are connected by a raw water overflow line 33. The fourth connection point 34 between the raw water overflow line 33 and the drain line 29 is:
It is on the downstream side of the atmosphere opening part 31.

The salt water overflow section 35 of the salt water tank 4 is provided above the salt water tank 4. Then, the salt water overflow section 35 and the raw water overflow line 33 are connected to a salt water overflow line 36.
Connected with. Salt 37 is appropriately charged into the salt water tank 4, and the salt 37 is dissolved in the raw water supplied from the raw water tank 3 to the salt water tank 4 via the makeup water line 19 to generate saturated brine. I do.

Here, the water supply valve 17, the makeup water valve 2
0, the opening and closing control of the salt water valve 23, the raw water valve 27 and the drain valve 30 will be described with reference to FIG. FIG.
FIG. 3 is a schematic explanatory view showing an electrical configuration of this embodiment.
Although not shown in FIG. 2, each of the valves (the water supply valve 1)
7, the makeup water valve 20, the salt water valve 23, the raw water valve 27, and the drain valve 30) are integrally formed, and the drive motor 3
8 is connected. The operation of the drive motor 38 causes the valves 17, 20, 23, 27, and 30 to
Opening and closing operations are performed in each of the water passing step, the regeneration step, the water washing step, and the external washing step. The drive motor 38 is connected to a controller 40 via a signal line 39. On the other hand, the power generation means 7 is connected to a power storage means 41 for storing electricity generated by the power generation means 7, for example, a storage battery (secondary battery) via a first transmission line 42.
The storage means 41 and the controller 40 are connected to a second transmission line 43.
Connected with.

Next, a control method of the water softener in the embodiment will be described.

First, the water passing step will be described. During this water passing step, each of the valves 17, 20, 23, 27,
30 is closed. When the user switches the switching valve 8 to the water softening treatment side, that is, the raw water flows toward the resin cylinder 2, the raw water is supplied via the raw water line 6 to the raw water inlet provided at the lower portion of the resin cylinder 2. Water is passed from section 5 as upward flow. In this water passing process, the raw water is softened by the action of the ion exchange resin 1 in the resin tube 2, and is supplied as soft water from a soft water outlet 9 provided in an upper portion of the resin tube 2 via a soft water line 10. Supplied outside the system. Further, when passing through the soft water line 10, the action of the water purification section 12 provided on the way also removes chlorine and the like contained in the soft water. Further, when the raw water passes through the raw water line 6, a part of the energy of the water flow is converted into electric energy by the operation of the power generation means 7 provided on the way, and then the electric power is stored through the first transmission line 42. 41, and the power storage means 41 is charged.

Next, the regeneration step will be described. This regeneration step is performed after the water passage time reaches a predetermined time or after a predetermined amount of water passage. First, the controller 4
0 activates the drive motor 38 for a predetermined time using the power storage means 41 charged during the water passage process as described above as a power supply. Thus, when the water supply valve 17 is opened, the raw water flows into the raw water tank 3 via the water supply line 15 at a constant flow rate by the action of the constant flow valve 18. Then, when the water level of the raw water tank 3 rises and reaches the raw water overflow section 32, the raw water overflows via the raw water overflow line 33.

Then, the controller 40 operates the drive motor 38 for a predetermined time using the power storage means 41 as a power supply. Thereby, the makeup water valve 20, the salt water valve 2
3. When the raw water valve 27 and the drain valve 30 are opened, the saturated brine in the brine tank 4
Flow down. At the same time, the raw water in the raw water tank 3 flows down the raw water flow-down line 25, and at the third connection point 26, the saturated brine and the raw water mix to become a brine of a predetermined concentration. Then, the salt water flows down from the upper part of the resin tube 2 to regenerate the ion exchange resin 1. The salt water after regeneration, that is, the drainage water flows down the drainage line 29 and is mixed with the raw water flowing down the raw water overflow line 33 at the fourth connection point 34 as described above. As a result, the concentration of chloride in the wastewater is reduced, and the wastewater is discharged out of the system through the wastewater line 29.

During the regeneration step, a constant flow of raw water is always supplied to the raw water tank 3 and the raw water in the raw water tank 3 is supplied to the makeup water line 1 by utilizing the head pressure difference.
9 to the salt water tank 4. As a result, the head pressure difference between the raw water tank 3 and the salt water tank 4 and the resin cylinder 2 required for performing the gravity regeneration as described above is always maintained (secured). The regeneration of the ion exchange resin 1 is performed.

Next, the washing step will be described. After performing the regeneration step for a predetermined time, the controller 40 operates the drive motor 38 for a predetermined time using the power storage means 41 as a power source, as in the reproduction step. This allows
When the makeup water valve 20 and the salt water valve 23 are closed,
Only the raw water in the raw water tank 3 flows down from the upper part of the resin tube 2 via the raw water flowing down line 25 and the salt water flowing down line 22, and pushes out the salt remaining in the ion exchange resin 1 for washing. On the other hand, the raw water tank 3
The overflow of raw water from has been continued from the regeneration step. Therefore, the raw water after the washing, that is, the waste water, is mixed with the raw water flowing down the raw water overflow line 33 at the fourth connection point 34 and then discharged out of the system through the drain line 29. During this washing step, a constant flow of raw water is always supplied to the raw water tank 3, as in the regeneration step. As a result, the water level of the raw water tank 3 is always maintained above the upper end of the packed bed of the ion exchange resin 1, and the water pressure difference caused by the water level difference causes the ion exchange resin 1 to be washed as described above. .

Next, the external cleaning step will be described.
After performing the water washing step for a predetermined time, the controller 40
As in the regeneration step and the water washing step, the drive motor 38 is operated for a predetermined time using the power storage means 41 as a power source. Thereby, when the raw water valve 27 and the drain valve 30 are closed, the raw water is discharged from the raw water tank 3 to the outside of the system via the raw water overflow line 33 and the drain line 29, and the floor surface of the bathroom etc. Wash off any residual chloride. After the external cleaning is performed for a predetermined time, the water supply valve 17 is closed, the flow returns to the water passage step, and the power storage unit 41 is charged again.

As described above, in the regeneration step, the water washing step and the external washing step, the electric energy of the electricity storage means 41 stored in the water passing step is used. Here, the electric energy converted by the power generation means 7 during the water passing step is equivalent to one regeneration of the ion exchange resin,
That is, it is sufficient if the same amount or more of the electric energy consumed in the series of regeneration step, water washing step, and external washing step.

[0028]

As described above, according to the present invention, it is possible to provide a water softener which can be easily installed and used at a specific place of use in a general household. As a result, in the water softener embodying the present invention, wiring work of a power supply from the outside of a device such as a conventional household water softener is not required, and danger such as electric shock is eliminated.

[Brief description of the drawings]

FIG. 1 is a schematic explanatory view showing a pipe connection state of an embodiment of a water softener according to the present invention.

FIG. 2 is a schematic explanatory view showing an electric configuration of an embodiment of a water softener according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Ion exchange resin 2 Resin cylinder 3 Raw water tank 4 Salt water tank 6 Raw water line 7 Power generation means 10 Soft water line 41 Power storage means

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Saburo Nakamura 7th Horie-cho, Matsuyama-shi, Ehime Miura Industrial Co., Ltd. (72) Inventor Yoshiyuki 7th Horie-cho, Matsuyama-shi, Ehime Miura Industrial Co., Ltd. (72 ) Inventor Hideo Furukawa 7, Horie-cho, Matsuyama-shi, Ehime F-term in Miura Research Laboratories Co., Ltd. (Reference) 3H074 AA12 BB09 CC43 CC50 4D025 AA02 AB19 BA07 BA22 BB12 BB19 CA10 DA03 DA10

Claims (3)

[Claims] 1. A water softener comprising: a power generating means 7 for generating power by water flow in a water passing step; and a power storage means 41 for storing electricity generated by the power generating means 7. 2. A method for controlling a water softener, wherein a regeneration step and a washing step are performed using the power storage means 41 as a power supply. 3. A method for controlling a water softener, wherein an external cleaning step is performed using the power storage means 41 as a power supply.