JP2001327966A - Control method of water softener - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform regeneration operation at proper regeneration timing according to the hardness content in raw water. SOLUTION: This control method is a method for controlling a water softener 1 comprising a raw water line 2, a water softening means 3, and a treated water line 4. The regeneration timing of the water softening means 3 is controlled based on the detection value of a hardness detection means 9 installed in the raw water line 2 and the operation state of an apparatus 15 that uses soft water, installed in the treated water line 4.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for controlling a softening device for removing water from raw water to make the water soft.

[0002]

2. Description of the Related Art As is well known, in a water supply line of cooling equipment such as a boiler, a water heater, and a cooler, hardness of raw water is removed in order to prevent adhesion of scale in the cooling equipment. A softening device is provided to soften the water. This water softener uses a Na ⁺ -type ion exchange resin, and is configured to replace the hardness contained in the raw water, that is, metal cations such as Ca ²⁺ and Mg ²⁺ with Na ⁺ and remove them. Then, when the ion-exchange resin is replaced by the hardness and becomes saturated, salt water is supplied to regenerate the capacity.

When performing a regeneration operation for regenerating the capacity of the ion exchange resin, a flow regeneration system is used in order to efficiently perform the regeneration operation. In this flow rate regeneration method, the amount of hardness in raw water is measured in advance, and based on the measured value, the amount of treated water that can be collected by the predetermined volume of the ion exchange resin before the next regeneration operation is performed. The regenerating operation is performed when the calculated amount of raw water reaches the amount of treated water.

However, the amount of hardness in raw water may fluctuate due to seasonal factors. Also, when groundwater and tap water are used in combination, the amount of treated water is different because the amount of hardness contained in groundwater is different from the amount of hardness contained in tap water. Therefore, in order to prevent the hardness from leaking, a value reduced to a safe side is set as the treated water amount, so that a relatively large supply amount of the salt water for regeneration is provided. Then, the regeneration operation is performed even if the ion exchange resin has not reached the saturated state. Further, the salt water for regeneration is wastefully consumed by the margin.

[0005]

An object of the present invention is to perform a reproducing operation at an appropriate reproducing timing according to the amount of hardness in raw water.

[0006]

Means for Solving the Problems The present invention has been made to solve the above-mentioned problems, and the invention according to claim 1 has a soft water comprising a raw water line, a soft water treatment means, and a treated water line. A control method of the apparatus, wherein a regeneration timing of the soft water treatment means is controlled based on a detection value of a hardness detection means provided in the raw water line and an operation state of soft water using equipment provided in the treated water line. It is characterized by:

[0007]

Next, an embodiment of the present invention will be described. The water softener according to the present invention includes a raw water line, a soft water treatment means, and a treated water line.
The raw water line supplies raw water to the soft water treatment means, and is provided with a hardness detecting means for detecting an amount of hardness in the raw water. Further, the soft water treatment means includes a resin cylinder containing the ion exchange resin and a control valve for switching a flow path. A salt water tank is connected to the control valve via a salt water line, and a drain line is connected to the control valve. Also,
The treated water line is provided with equipment using soft water such as a boiler, a water heater, and a cooler.

[0008] In the water softener, the hardness detecting means and the control valve are respectively connected to a controller via a signal line. Further, an operation status signal of the soft water usage equipment is sent from the soft water usage equipment to the controller, and the soft water usage is determined based on a detection value of the hardness detection unit and an operation status of the soft water usage equipment. The reproduction timing of the processing means is controlled.

That is, data which is a criterion for performing the operation of regenerating the ion exchange resin is input to the controller. This data is data on the operation status of the equipment using soft water corresponding to the amount of hardness in raw water, and is set based on the amount of treated water that can be sampled as soft water before the ion exchange resin becomes saturated. Have been. That is, the amount of operating condition of the equipment using soft water corresponding to the amount of treated water is input as the data. Therefore, the predetermined operating condition amount of the soft water-using equipment for determining the timing of performing the regenerating operation of the ion exchange resin is determined based on the detection value of the hardness detecting means. And
The amount of operation status of the device using soft water is integrated based on the operation status of the device using soft water, and when the predetermined amount of operation status is reached, a signal for performing a regeneration operation of the ion exchange resin is output. Further, the detection of the hardness amount in the raw water by the hardness detection means is performed based on a preset hardness detection cycle, for example, every 24 hours.

[0010] When the equipment using soft water is a boiler, for example, the amount of evaporation is used as the operating state quantity. That is, since the soft water from the water softener is heated in the boiler to be steam, the supply amount of the soft water from the water softener and the evaporation amount in the boiler are substantially equal. Therefore, when the integrated value of the evaporation amount in the boiler reaches a value set based on the detection value of the hardness detecting means, a signal for performing the operation of regenerating the ion exchange resin is output from the controller. Further, in a boiler of a type in which a part of the can water is blown when the can water is concentrated, a value obtained by adding the blow amount to the evaporation amount is used as the operation state amount.

Here, the evaporation amount of the boiler is calculated from the combustion time of the boiler, and the blow amount is calculated from the open time of the blow valve. That is,
Since the boiler is usually set so as to burn at a constant combustion amount, the evaporation amount and the combustion time are in a proportional relationship, and the evaporation amount can be calculated based on the combustion time. On the other hand, the blow amount can be calculated based on the blow valve open time since the flow rate per unit time is substantially constant.

In the above-mentioned boiler, the water supply is usually performed by turning on and off the water supply pump according to the water level in the can, so that the amount of water supplied at one time is substantially constant. Therefore, the number of times of water supply can be used as the operation status quantity. Further, in a boiler in which the amount of water supply per unit time at the time of water supply is substantially constant, the water supply time can be used as the operation state quantity. For example, the water supply time is detected based on the operation time of the water supply pump, or the water supply time is detected based on the operation time of a flow switch provided in a water supply line to the boiler. Further, a water level in a water supply tank attached to the boiler may be detected, and a water supply amount detected based on a change in the water level may be used as the operation state amount.

In the above description, the case where the equipment using soft water is a boiler has been described. However, when the equipment using soft water is another equipment such as a water heater or a cooler, similarly, the equipment using soft water may be used. The regeneration timing of the soft water treatment means is controlled based on the operation status of the water softener.

As described above, according to the above configuration, the regeneration operation can be performed at an appropriate regeneration timing according to the amount of hardness in the raw water, and the ion exchange resin can be efficiently regenerated. At the same time, the amount of salt water required for regeneration can be saved. In addition, since the regeneration timing is controlled based on the operation state of the equipment using soft water, it is not necessary to provide a special device such as a flow meter for measuring the amount of treated water in the soft water treatment means.

[0015]

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 is an explanatory diagram showing a schematic configuration of one embodiment of the present invention. In FIG. 1, a water softening device 1 includes a raw water line 2, a soft water treatment unit 3 and a treated water line 4, and the soft water treatment unit 3 includes Na ⁺
It comprises a resin tube 5 containing a mold ion exchange resin (not shown) and a control valve 6 for switching the flow path. The raw water line 2 has a ball tap mechanism 7.
A raw water tank 8 equipped with a raw water line and hardness detection means 9 for detecting the amount of hardness in the raw water are provided. The downstream end of the raw water line 2 is connected to the control valve 6.

Here, as the hardness detecting means 9, for example, a liquid drop type is used. In this droplet type, a liquid reagent is intermittently injected into a transparent container containing a predetermined amount of raw water in a fixed amount, a change in the hue of the raw water due to the reaction of the reagent is detected, and the hue of the raw water is preset. When the hue is reached, the injection of the reagent is stopped,
The amount of hardness in the raw water is detected based on the injection amount.

A salt water tank 11 is connected to the control valve 6 via a salt water line 10.
In the salt water tank 11, a predetermined amount of salt 13 is stored on a mesh member 12, and the salt water tank 11
The lower half of the inside stores salt water for regenerating the ion exchange resin. The control valve 6
Is connected to a drain line 14, and drainage during regeneration of the ion exchange resin is discharged to the outside via the drain line 14.

The treated water line 4 is provided with a boiler 15 as a device using soft water. An upstream side of the boiler 15 is provided with a water supply pump 16 and a check valve 17. The upstream end of the treated water line 4 is connected to the control valve 6.
The boiler 15 is provided with a burner 18. The burner 18 heats the soft water supplied through the treated water line 4 to be turned into steam. This steam is supplied to an external steam-using device (not shown) via a steam line 19.
Supplied to Further, the boiler 15 is provided with a boiler controller 20.
Thus, the operations of the water supply pump 16 and the burner 18 are controlled according to a preset program.

Further, the control valve 6, the hardness detecting means 9 and the boiler controller 20 are connected to a controller 22 via signal lines 21, 21 and 21, respectively. The controller 22 has a function of controlling a regenerating operation of the ion exchange resin in the soft water treatment means 3 according to a preset program. That is, an operation status signal of the boiler 15 is sent from the boiler controller 20 to the controller 22. Based on the detection value of the hardness detection means 9 and the operation status of the boiler 15, The regeneration timing of the soft water treatment means 3 is controlled.

In the above configuration, when the water supply pump 16 is operated, the raw water in the raw water tank is sucked and flows into the soft water treatment means 3, and the raw water passes through the soft water treatment means 3. Is ion-exchanged by the ion-exchange resin into soft water.
5. Then, when the ion exchange resin is saturated, the salt water in the salt water tank 11 is caused to flow down by gravity into the resin cylinder 5 via the control valve 6 to regenerate the ion exchange resin. I have.

Next, a method of controlling the reproduction timing in the above configuration will be specifically described. Controller 2
2, data serving as a criterion for performing a regenerating operation of the ion exchange resin is input. For example, FIG.
The data of the amount of evaporation in the boiler 15 corresponding to the amount of the hardness in the raw water as shown in FIG. This data shows the amount of evaporation that can be taken out as steam by heating the soft water sampled before the ion exchange resin becomes saturated, and the amount of evaporation varies depending on the amount of hardness in the raw water. Value. Therefore, based on the amount of hardness in the raw water detected by the hardness detection means 9,
A predetermined evaporation amount for determining the timing of performing the regenerating operation of the ion exchange resin is determined. When the evaporation amount integrated based on a signal from the boiler controller 20 reaches the predetermined evaporation amount, the controller 22 Outputs a signal for performing a regeneration operation to the control valve 6.

Here, a signal of the combustion time in the boiler 15 is sent from the boiler controller 20 to the controller 22. For example, when the boiler 15 performs combustion control at three positions of high combustion, low combustion, and stop, the combustion amount at the time of high combustion and the combustion amount at the time of low combustion are set to constant values. , The amount of evaporation becomes a value proportional to the combustion time. Here, since the combustion amount at the time of low combustion is set to about half of the combustion amount at the time of high combustion, the combustion time at the time of low combustion is reduced to half and converted to the combustion time at the time of high combustion. . The evaporation amount of the boiler 15 is integrated based on the combustion time obtained in this manner.

Therefore, according to the above control method, even if the amount of hardness in the raw water fluctuates due to seasonal factors or a combination of tap water and groundwater, the reproducing operation is always performed at an appropriate reproducing timing. And the regeneration of the ion exchange resin can be performed efficiently. In addition, the amount of salt water used for regeneration can be reduced with respect to the required amount, and the amount of salt water used for regeneration can be saved. Further, since the regeneration timing is controlled based on the signal from the boiler 15, there is no need to provide a special device such as a flow meter for measuring the amount of treated water in the soft water treatment means 3. Therefore, a compact and low-cost configuration can be achieved.

By the way, in the above configuration, the water softening device 1 may be built in the inside of a casing (not shown) of the boiler 15 so that both are integrated.
In this case, since it is not necessary to additionally provide a special device such as a flow meter, the layout of the water softening device 1 can be easily designed, and the size can be further reduced.
It is also preferable to combine the controller 22 and the boiler controller 20 into one controller depending on the implementation.

[0025]

According to the present invention, the regenerating operation can be performed at an appropriate regenerating timing according to the amount of the hardness in the raw water, and the ion exchange resin can be efficiently regenerated. The required amount of salt water can be saved. In addition, since the regeneration timing is controlled based on the operation state of the equipment using soft water, it is not necessary to provide a special device such as a flow meter for measuring the amount of treated water in the soft water treatment means.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram showing an embodiment of the present invention.

FIG. 2 is an explanatory diagram showing data serving as a criterion for performing a regenerating operation of an ion exchange resin in one embodiment of the present invention.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 soft water device 2 raw water line 3 soft water treatment means 4 treated water line 9 hardness detection means 15

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Go Yoneda, 7 Horie-cho, Matsuyama-shi, Ehime Miura Kogyo Co., Ltd. (72) Inventor Hitoshi Asamura 7 Horie-cho, Matsuyama-shi, Ehime Miura Kogyo Co., Ltd. (72) Inventor Katsufumi Isshiki 7 in Horie-cho, Matsuyama-shi, Ehime Miura Kogyo Co., Ltd.

Claims (1)

[Claims] 1. A control method for a water softening device 1 comprising a raw water line 2, a soft water treatment means 3, and a treated water line 4, the method comprising: a detection value of a hardness detection means 9 provided in the raw water line 2; A method for controlling a water softening device, comprising: controlling a regeneration timing of the water softening means 3 based on an operation state of a water softening device 15 provided in a treated water line 4.