JP2012139684A - Water treating system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a water treating system controlling an optional water feed according to the operation state of a water treating apparatus.SOLUTION: In the water treating system including the water treating apparatus 22, a water feed tank 3 storing water to be treated, a water level detecting means 14, a water-feed controlling means 4 for controlling the feed of water to be treated to the water feed tank 3, the water-feed controlling means 4 possesses a limit water level setting means respectively setting plurally the upper limit water level and the lower limit water level composing limit water levels, an operation state detecting means 26 for detecting the operation state of the water treating apparatus 22 and a switching instruction means 26 for instructing the switching of the limit water level to the water-feed controlling means 4 based on the detected results of the operation detecting means 26, and the water-feed controlling means 4 changes the limit water level based on the instruction of the switching instruction means 26.

Description

  The present invention relates to a water treatment system, and more particularly to a water treatment system that performs water supply control while managing the water level in a water supply tank.

  2. Description of the Related Art Conventionally, water treatment systems that produce high-purity treated water from raw water such as groundwater and factory wastewater and supply the treated water to a boiler, a cooling tower, or the like, or can be used for drinking water are known.

  In this type of water treatment system, raw water containing various impurities is treated with regenerative filtration equipment, soft water equipment, membrane filtration equipment, etc. to produce treated water, and the treated water is temporarily stored in a water supply tank. After that, it is used for boiler water supply.

  Therefore, it is necessary to perform water supply control to the water supply tank while managing the water level in the water supply tank.

  And in patent document 1, as shown in FIG. 14, while arrange | positioning the water level detection apparatus 103 which detects a water level height in three steps to the deaeration water supply tank 102 provided in the downstream of the membrane module 101, water flow amount is set. A membrane deaeration device is disclosed that includes a three-position valve 104 that can be increased or decreased in the middle of a water line 106 and a control device 105 that controls the three-position valve 104 by a signal from a water level detection device 103. Further, in this membrane degassing apparatus, the membrane module 101 is connected to the vacuum pump 108 via the vacuum line 109, and the replenishment line 107 branched from the water passage line 106 is connected to the vacuum pump 108. When the vacuum pump 108 is operated, oxygen in the water removed by the membrane module 101 is exhausted from the vacuum pump 108, and at the same time used seal water is drained from the vacuum pump 108.

  In this Patent Document 1, a water level detection device 103 having three sensing rods having different lengths is inserted from above the deaeration water tank 102, and a three-position valve 104 corresponding to the water level H, water level M, and water level L is inserted. The amount of water flow is controlled so that the opening degree is fully closed, half open, and fully open, thereby performing water supply control in accordance with the water level in the deaerated water supply tank 102.

  Moreover, in a water treatment system using a regenerative filtration apparatus, it is widely performed to stop the water flow to the water supply tank during the regeneration and to use the treated water stored in the water supply tank for the regeneration treatment.

  For example, Patent Document 2 discloses a fine filtration system in which a water supply tank in which filtered water is stored and a fine filtration device having a predetermined filter medium are connected by piping, and a cleaning pump is interposed in the pipe. ing.

In this patent document 2, when it becomes a backwash mode, a washing pump will drive, the filtrate stored in the feed water tank will be supplied to a fine filtration apparatus, a filter medium will be backwashed, and will be regenerated.
JP-A-8-266808 (FIG. 1) JP 2006-136753 A (FIG. 1)

The water supply control in the water treatment system is performed while managing the water level of the water supply tank as described above. When the tank water level drops to the lower limit water level, water supply is started, and when the tank water level reaches the upper limit water level, the water supply is stopped.

  And, for example, when the night and business offices are on holidays, it is desirable to stop the supply of treated water to the water supply tank or limit it in terms of time in consideration of the impact on neighboring residents. It is done.

  Moreover, when drainage from the boiler is collected in the feedwater tank by the boiler feedwater facility, the water temperature in the feedwater tank becomes high as the drain recovery rate increases. Therefore, in such a case, it is desirable to forcibly replenish treated water treated by the water treatment device to the water supply tank.

  As described above, the optimum water supply into the water supply tank varies depending on the use state and use environment (hereinafter referred to as “use state”) of the user, and therefore water that can be optimally controlled according to the use state and the like. Realization of a processing system is desired.

  However, although Patent Document 1 links the water level detection device 103 and the three-position valve 104 to switch the water flow amount to three stages according to the water level, this Patent Document 1 can be applied to all water treatment systems. It is difficult to realize optimal water supply control in accordance with various usage situations of the above-described user.

  It is also conceivable to control the water supply by mechanically cutting the sensing rods of Patent Document 1 so as to have a desired length according to the user's request, and installing these cut sensing rods in a water supply tank. However, it may be necessary to arrange a large number of sensing rods in the water supply tank depending on the use situation, etc., resulting in a complicated structure, which is not a practical method.

  Moreover, in patent document 2, since it backwashes using the water of a water supply tank, the water of a water supply tank is consumed in large quantities at the time of backwashing. That is, during the regeneration process, the water supply to the water supply tank is forcibly stopped and a large amount of water is consumed, so that the water level of the water supply tank may be excessively lowered at the end of the regeneration process.

  For this reason, when water supply to a boiler or the like is resumed, there may be cases where it becomes impossible to stably supply treated water at a desired flow rate to the boiler or the like, and means for performing water supply control so that the amount of water stored in the water supply tank can be increased before regeneration processing Is requested.

  This invention is made | formed in view of such a situation, Comprising: It aims at providing the water treatment system which can perform optimal water supply control according to the driving | running state of a water treatment apparatus.

  In order to achieve the above object, a water treatment system according to the present invention includes a water treatment device that produces treated water from raw water, a water supply tank that stores the treated water, and a water level of the treated water in the water supply tank. In a water treatment system comprising water level detection means for continuously detecting, and water supply control means for controlling the supply of the treated water to the water supply tank based on the detection result of the water level detection means, the water supply control means comprises: Based on a detection result of the operation state detection means, an operation state detection means for detecting an operation state of the water treatment device, and a limit water level setting means for setting a plurality of upper limit water levels and lower limit water levels constituting the limit water level. Switching command means for commanding the water supply control means to switch the limit water level, and the water supply control means is configured to control the limit water level based on a command from the switching command means. It is characterized in that to change.

  In the water treatment system, the water treatment device includes at least a regenerative filtration device and a peripheral device that performs a regeneration treatment of the regenerative filtration device.

  Further, the water treatment apparatus is supposed to stop water treatment during regeneration, and the switching command means switches the setting of the upper limit water level from the main setting to a sub-setting higher than the main setting immediately before entering the regeneration processing, and It is characterized by increasing the amount of treated water stored in the water supply tank.

  The water treatment system of the present invention is characterized in that the switching command means and the water supply control means are electrically connected via an external signal line.

  Furthermore, in the water treatment system of the present invention, when the water supply control means receives the switching command for the limit water level by the switching command means, and the water level after switching is equal to or lower than the upper limit water level specified after the switching, A water supply command to the water supply tank is issued until the upper limit water level is reached.

  In the water treatment system of the present invention, the water treatment apparatus includes a soft water device and a membrane filtration device.

  Further, in the water treatment system of the present invention, the limit water level setting means sets an extreme water level consisting of an extreme upper limit water level and an extreme lower limit water level, and the water supply control means is such that the water level of the water supply tank is equal to or higher than the extreme upper limit water level. And an abnormality notifying means for notifying an abnormality when any of the above-mentioned minimum lower limit water level is reached.

  According to the water treatment system of the present invention, a water treatment device (for example, a soft water device, a membrane filtration device, etc.) that produces treated water from raw water, a water supply tank that stores the treated water, and the treatment in the water supply tank In the water treatment system comprising: a water level detection means for continuously detecting the water level of water; and a water supply control means for controlling the supply of the treated water to the water supply tank based on the detection result of the water level detection means. The control means includes limit water level setting means for setting a plurality of upper limit water levels and lower limit water levels constituting the limit water level, an operation state detection means for detecting the operation state of the water treatment device, and the operation state detection means. Switching command means for commanding the water supply control means to switch the limit water level based on a detection result, and the water supply control means is based on a command from the switching command means. Since the limit water level is changed, if the treated water is consumed in large quantities, such as regeneration processing of a regenerative filtration device, by changing it to a limit water level suitable for the operating condition, the amount of water stored in the water tank is increased in advance. Therefore, it is possible to perform optimum water supply control according to the usage situation.

  Further, since the switching command means and the water supply control means are electrically connected via an external signal line, a plurality of limit water levels are set and standardized in the water supply control means, and the water level is switched from the outside. Optimal water supply control can be performed simply by issuing a command, and a desired water treatment system can be realized at low cost.

  In addition, when the water supply control means receives the switching instruction for the limit water level by the switching instruction means and the water level after switching is equal to or lower than the upper limit water level specified after the switching, the water supply control means until the upper limit water level is reached. Since the water supply command to the tank is issued, after switching, water is supplied to the water supply tank until the upper limit water level after switching is reached, and the desired water supply control can be performed after the water level in the water supply tank is set to the upper limit water level. .

  Further, the limit water level setting means sets an extreme water level consisting of an extreme upper limit water level and an extreme lower limit water level, and the water supply control means is configured such that the water level of the water supply tank is higher than the upper upper limit water level and lower than the lower lower limit water level If the water tank reaches an abnormal water level, the user quickly knows the abnormality of the water tank by the alarm sound or the lighting or flashing of the warning light. be able to.

<First Comparison of the Present Invention>
Before describing the embodiment of the present invention, a first comparative example related to the present invention (related to the present invention but not included in the embodiment of the present invention) will be described based on the drawings.

  FIG. 1 is a system configuration diagram showing a first comparative water treatment system, which illustrates a case where the water treatment system is used for boiler water supply.

  That is, this water treatment system includes a raw water pump 1 that pumps raw water such as ground water, a water treatment device group 2 that removes impurities in the raw water and produces high-purity treated water, and a treatment from the water treatment device group 2. A water supply tank 3 for storing water, a water supply control unit (water supply control means) 4 for controlling each device of the water treatment device group 2 to control water supply to the treated water supply tank 3, and the water supply control unit 4 A water level switching command unit 5 that commands switching of the water level of the water supply tank 3 and a pump control unit 6 that controls on / off of the raw water pump 1 are provided.

  Specifically, the water treatment device group 2 includes a water softening device 7 for softening raw water containing a hardness component, and a reverse osmosis membrane device (hereinafter referred to as “the raw water softened by the water softening device 7”). These are arranged on a water supply line 9 that connects the raw water pump 1 and the water supply tank 3.

  The water softening device 7 is of a two-cylinder type, and the three-way valve 10 allows water to pass through either the first water softening device 7a or the second water softening device 7b so that the raw water softening treatment is not interrupted. It is configured.

  Specifically, the water softener 7 includes a sodium-type cation exchange resin (not shown), and saturated saline is stored in the cation exchange resin. Then, when the raw water is supplied to, for example, the first soft water device 7a, hardness components such as calcium ions and magnesium ions in the raw water are ion-exchanged and removed with sodium ions contained in the saturated saline solution. As a result, the raw water is softened. Further, when the exchange capacity of the cation exchange resin of the first water softening device 7a is saturated, the three-way valve 10 is operated by the built-in microcomputer of the water softening device 7 so that the second water softening device 7b can pass water. Can be switched. And the 1st water softener 7a will be in regeneration mode, and the 2nd water softener 7b will be in water flow mode. The first water softener 7a that has entered the regeneration mode supplies saturated saline from a salt water tank (not shown), thereby regenerating the cation exchange resin. Next, the first water softener 7a that has finished the regeneration process is in a standby mode until the second water softener 7b enters the regeneration mode.

  As described above, the water softening device 7 is configured such that one of the first water softening device 7a and the second water softening device 7b is in the water passing mode, and thus the soft water is not interrupted. Processing is possible.

  The RO device 8 includes, for example, an RO module 11 including an RO membrane element (hereinafter referred to as “RO membrane”) 11a wound in a spiral shape, and a pressurizing pump 12 that applies pressure to the RO membrane 11a. ing. The RO module 11 is separated into a primary side to which raw water is supplied and a secondary side that outputs permeated water that has passed through the RO membrane 11a, and a drainage valve 13 is disposed on the secondary side. Lines and circulation lines 50 are connected.

When the pressurization pump 12 is driven and a high pressure higher than the osmotic pressure is applied to the RO membrane 11a from the primary side, the high-purity permeated water from which dissolved salts and silica (SiO ₂ ) are removed is returned to the secondary side. Output, thereby producing treated water. A part of the concentrated water that has not permeated the RO membrane 11 a is returned to the pressurizing pump 12 through the circulation line 50, and the rest is drained from the drain valve 13.

  The water supply tank 3 has a pressure detection type water level sensor 14 inserted in the lower side wall thereof. The water level sensor 14 utilizes the fact that the water level of the water supply tank 3 is proportional to the water head, and can continuously detect the water level according to the change of the water head in the water supply tank 3. Is transmitted to the water supply control unit 4.

  The water supply control unit 4 is electrically connected to the soft water device 10 and the RO device 8 through control lines 17 and 18, and is further electrically connected to the pump control unit 6. When the water supply request signal 19 is transmitted from the water supply control unit 4 to the pump control unit 6, the pump control unit 6 is configured to transmit a drive signal 20 to the raw water pump 1.

  The water supply control unit 4 includes a storage unit (water level setting unit) in which a set water level of the water supply tank 3 and a predetermined calculation program are stored, a calculation processing unit that performs predetermined calculation processing and controls each of the above-described components. It has.

  The storage means stores a plurality of limit water levels in a rewritable manner. In the present embodiment, a main setting that prescribes the daytime limit water level (upper limit water level and lower limit water level), a sub setting that prescribes the nighttime limit water level, and the extreme water level for abnormality notification are stored. The main setting consists of a set of main upper limit water levels (hereinafter referred to as “main H water levels”) and main lower limit water levels (hereinafter referred to as “main L water levels”). (Hereinafter referred to as “sub-H water level”) and sub-lower limit water level (hereinafter referred to as “sub-L water level”), and the extreme water level is a set of extreme upper water levels (hereinafter referred to as “HH water level”). )) And the lower limit water level (hereinafter referred to as “LL water level”), and these limit water levels are stored in the storage means.

  Further, the water level switching command unit 5 is provided outside the water supply control unit 4, and the water supply control unit 4 and the water level switching command unit 5 are electrically connected. The water level switching command unit 5 has a built-in timer 5a, and a water level switching signal (external signal line) 16 is supplied to the water supply control unit so that the limit water level is switched according to the time zone according to the time of the timer 5a. 4 is transmitted. In the present embodiment, as described later, the limit water level of the water supply tank 3 is switched between a daytime zone (for example, 8 am to 8 pm) and a night time zone (8 pm to 8 am). For example, when the timer 5a measures 8 am or 8 pm, the water level switching signal 16 is transmitted to the water supply control unit 4.

  FIG. 2 is a schematic front view of the water supply tank 3 showing a water level setting example of the first comparative limit water level.

  That is, during the daytime, the water level of the water supply tank 3 (hereinafter, “tank water level”) is managed by the main H water level and the main L water level. The secondary H water level is set to a predetermined position higher than the main H water level, the secondary L water level is set to a predetermined position lower than the main L water level, and the tank water level in the nighttime zone is determined by the secondary H water level and the secondary L water level. Managed. The HH water level is set further above the secondary H water level, the LL water level is set further below the secondary L water level, and when the tank water level is higher than the HH water level or lower than the LL water level, an alarm sound or warning light is turned on. Alternatively, the user is notified by blinking or the like.

  In the first comparative example, for example, at 8:00 am, the water level switching signal 16 is transmitted from the water level switching command unit 5 to the water supply control unit 4, whereby the limit water level is set to the main setting, For example, at 8:00 pm, a water level switching signal 16 is transmitted from the water level switching command unit 5 to the water supply control unit 4, whereby the limit water level is switched from the main setting to the sub setting.

The reason for switching between the main setting and the sub setting according to the time zone as described above is as follows.

  In the case of a water treatment system for boiler water supply at business establishments and the like, since the boiler is usually not used in the nighttime, it is desirable to completely stop the water supply in the nighttime in consideration of the influence on neighboring residents.

  However, there are cases where the operating time of the boiler has to be extended due to a temporary extension of the operation time. In this case, if the water supply to the treated water tank 3 is completely stopped completely, the treated water in the water supply tank 3 may be insufficient, and the operation of the boiler may have to be stopped.

  Therefore, in this first comparison, the water level is switched by the water level switching signal 16 so that the limit water level in the daytime zone is the main setting, and the limit water level in the nighttime zone is the sub-setting, and the optimal water supply according to the time zone Control is performed.

  Next, the operation method of the water treatment system will be specifically described.

  First, when the tank water level in the water supply tank 3 drops to the main L water level during the daytime, the water supply control unit 4 transmits a water supply request signal 19 to the pump control unit 6, and the pump control unit 6 sends the drive signal 20 to the raw water pump. 1 and the raw water pump 1 starts driving. And raw | natural water is supplied to the soft water apparatus 7 through the water supply line 9, and the raw | natural water softened with this soft water apparatus 7 is membrane-separated by the RO apparatus 8, and is isolate | separated into permeated water and concentrated water. Next, the permeated water becomes treated water and is supplied to the water supply tank 3.

  The tank water level in the water supply tank 3 is continuously detected by the water level sensor 14, and a water level detection signal 15 is transmitted to the water supply control unit 4. When the water level sensor 14 detects the main H water level, the water supply control unit 4 that has received the water level detection signal 15 stops the water supply request signal 19 for the pump control unit 6. Thereby, the drive signal 20 is also stopped, the raw water pump 1 is stopped, and the operation of the water treatment system is stopped.

  After that, when the treated water in the feed water tank 3 is consumed by the boiler feed water and the tank water level drops to the main L water level, the operation of the water treatment system is restarted by the above-described operation procedure, and the treated water is supplied to the feed water tank 3. I do.

  Thereafter, the water supply control is performed so that the tank water level is managed between the main H water level and the main L water level.

  Thereafter, when the night time, for example, the timer 5a measures 8:00 pm, the water level switching command unit 5 issues a water level switching signal 16 to the water supply control unit 4, and the water supply control unit 4 switches the limit water level to the sub-setting.

  Immediately after switching, after supplying water to the secondary H water level and securing sufficient treated water, water supply control is performed while managing the tank water level between the secondary H water level and the secondary L water level in the same operating procedure as described above. .

  Thereafter, for example, when the timer 5a measures 8 am in the daytime, for example, the water level switching command unit 5 issues a water level switching signal 16 to the water supply control unit 4, and the water supply control unit 4 switches the limit water level to the main setting.

  Then, immediately after switching, after supplying water to the main H water level and securing sufficient treated water, water supply control is performed while managing the tank water level between the main H water level and the main L water level in the same operating procedure as described above. .

  FIG. 3 is a diagram illustrating an example of a change in the tank water level due to the water level switching, where the horizontal axis indicates time and the vertical axis indicates the tank water level. In the figure, T1 represents a daytime zone, T2 represents a nighttime zone, X1 represents a switching time from the main setting to the subsetting, and X2 represents a switching time from the subsetting to the main setting. Moreover, the solid line Y1 shows the case where the amount of water used is normal, the alternate long and short dash line Y2 shows the case where the amount of water used is less than normal, and the broken line Y3 shows the case where the amount of water used in the nighttime is larger than usual. .

  In the daytime zone T1, when the tank water level becomes the main H water level, the water supply stops and the treated water is consumed for boiler supply water, so the tank water level decreases. The critical water level is switched from the main setting to the sub-setting at the time X1 (for example, 8:00 pm) when entering the night zone T2, and the tank water level is supplied to the water supply tank 3 until it reaches the sub-H water level.

  When the amount of water used is normal and low, as shown by the solid line Y1 and the alternate long and short dash line Y2, the time X2 (for example, for entering the daytime zone T1 without lowering to the sub-L water level in the nighttime zone T2) 8am), and the critical water level is switched from the sub-setting to the main setting.

  That is, since the secondary H water level is set higher than the main L water level and the secondary L water level is set lower than the main L water level, the range of the limit water level is widened. Therefore, when the amount of water used is normal and small, water supply in the nighttime zone T2 can be substantially stopped.

  On the other hand, when the amount of water used in the nighttime zone T2 is large, the tank water level at the time of switching (time X1) is lower than when the amount of water used is normal or less than normal. The water supply time to reach will be longer. However, in the sub-setting, the range of the limit water level is wider than in the main setting, so the time until the lower limit water level (sub-L water level) is lowered (water supply stop time) is longer than that in the main setting. It becomes possible to shorten the water supply time of the belt T2, particularly midnight.

  In the first comparative example, in any pattern (Y1 to Y3), the limit water level is switched from the sub-setting to the main setting at the time X2 when the daytime zone T2 is entered. Water is supplied to the treated water tank 3 until the H water level is reached, and water supply control is performed within the main setting range after the treated water in the water supply tank 3 is full.

  As described above, in the first comparative example, the water supply control is performed by switching the limit water level between the main setting and the sub-setting in the daytime zone and the nighttime zone based on the time measured by the timer 5a. Even when treated water is required at night, when the amount of water used is not large (solid line Y1 and alternate long and short dash line Y2), it is possible to stop the water supply to the water supply tank and the amount of water used is large ( The broken line Y3) makes it possible to operate the water treatment system with a shorter water supply time than in the main setting. Therefore, it is possible to minimize the influence on neighboring residents and to realize a water treatment system that takes into consideration the living environment.

  In the first comparative example, the timer 5a is built in the water level switching command unit 5 and the water level switching signal 16 is issued from the water level switching command unit 5. However, the timer 5a is built in the water supply control unit 4 to The switching command may be directly performed by the water supply control unit 4.

  FIG. 4 is a schematic front view of the water tank 3 showing a water level setting example of the first modified example in the first contrast. In this first modified example, the sub-L water level is at the same level as FIG. Although it is set, the secondary H water level is set sufficiently lower than the main H water level. Therefore, when the critical water level is set to the sub-setting, the water supply control is performed within the comparatively low and narrow critical water level range.

FIG. 5 is a diagram illustrating an example of a change in the tank water level in the first modification, in which the horizontal axis indicates time and the vertical axis indicates the tank water level. As in FIG. 3, T1 represents the daytime zone, T2 represents the nighttime zone, X1 represents the switching time from the main setting to the subsetting, and X2 represents the switching time from the subsetting to the main setting. A solid line Y4 indicates a case where the water usage is normal, a broken line Y5 indicates a case where the water usage is large, and a two-dot chain line Y6 indicates a case where the tank water level is low when switching from the main setting to the sub-setting. Yes.

  In the first modification, the sub-L water level is lower than the main L water level, so that when the water usage is normal, the water supply in the night zone T2 can be stopped as indicated by the solid line Y4.

  On the other hand, when the amount of water used is large or the tank water level at the time of switching is low, the interval between the sub-H water level and the sub-L water level is narrow, so as shown by the broken line Y5 and the two-dot chain line Y6 in FIG. Continuous water supply is not performed, but is performed intermittently in a short time.

  As described above, according to the first comparative example, it is possible to perform optimum water supply control according to the user's request by setting the limit water level suitable for the tank capacity and the amount of treated water.

  FIG. 6 is a schematic front view of a water supply tank 3 showing a water level setting example of the first modified second modified example. In this second modified example, the sub-H water level is the first modified example. In the same manner as above, the water level is set sufficiently lower than the main H water level, the sub L water level is set to the same position as the main L water level, and the main setting and the sub setting are switched between the business day and the closed day of the office. ing.

  On business holidays, boilers often stop operating and water consumption is low. Therefore, if the treated water is stored in the water supply tank 3, the residence time of the treated water itself in the water supply tank 3 becomes longer, and there is a possibility that various germs and the like propagate and cause deterioration of the water quality. Therefore, it is considered desirable to lower the water level of the water supply tank 3 as much as possible on a business day off.

  In this case, it is conceivable to manually change the water level setting every closed day. However, if the water level is switched about 2 to 3 times a year due to seasonal fluctuations, it is easy to switch the water level manually. is not.

  Therefore, in the second modification, the water supply control is performed by switching to the limit water level set in advance by a command from the water level switching command unit 5. However, if the sub-L level of the water supply tank 3 is set too low to reduce the amount of water stored in the water supply tank 3, the frequency of driving and stopping the water treatment device (soft water device 7 and RO device 8) increases. For this reason, there is a possibility that the water quality of the staying water in the water treatment apparatus is deteriorated or the water treatment apparatus is damaged.

  For this reason, in the second modification, the sub L level is set to the same level as the main L level so that the sub L level does not become excessively low.

  FIG. 7 is a diagram illustrating a water level switching example of the second modification example, in which the horizontal axis indicates the day of the week and the vertical axis indicates the tank water level. In the second modification, Monday to Friday are business days, Saturdays and Sundays are closed days, and the timer 5a (weekly timer) is used to control water supply from Monday to Friday with the main setting, and the water supply control with Saturday and Sunday as the sub-setting. It is set to be.

  In this way, by switching the water level setting between the business day and the closed day of the establishment, and managing the tank water level so that the tank water level on the closed day becomes lower, a large amount of treated water stays in the water supply tank 3 for a long time. Can be avoided, and water quality deterioration can be prevented.

In this second modification, the main setting and the water level of the second limit water level are switched between Monday-Friday and Sunday over Saturday. However, the program timer etc. is used as a secondary setting for holidays and other temporary holidays. It is also preferable to control the water supply based on the above.
<Embodiment of the present invention>
FIG. 8 is a system configuration diagram of the water treatment system according to the embodiment of the present invention. In the embodiment of the present invention, the iron removal / manganese filtration device 22 as a regenerative filtration device is located upstream of the soft water device 7. The water supply line 23 on the side is forcibly supplied to the water supply tank 3 before the regeneration process, thereby avoiding a decrease in the amount of water stored in the water supply tank 3 due to the regeneration process.

  In the water treatment system having the regenerative filtration device 22, water cannot be supplied to the water supply tank 3 during the regeneration treatment. Therefore, when the filter medium is regenerated using the treated water stored in the water supply tank 3, the water level of the water supply tank 3 is excessively lowered during the regeneration process, and thus the amount of water supplied to the boiler or the like is temporarily insufficient. There is a risk.

  As a method of making up for such a shortage of water supply, it is conceivable to back up treated water from another route, but it is necessary to increase operational constraints or add new equipment, which is preferable. Absent.

  Therefore, in the embodiment of the present invention, as shown in FIG. 9, the secondary L water level is set to the same level as the main L water level, while the secondary H water level is set higher than the main H water level, and the regeneration process is started. Immediately before, the limit water level setting is switched from the main setting to the sub-setting to increase the amount of treated water stored in the water supply tank 3, thereby avoiding an excessive decrease in the amount of water stored in the water supply tank 3 due to regeneration processing. .

  Hereinafter, the embodiment of the present invention will be described in more detail.

  In FIG. 8, the water treatment device group 21 includes an iron removal / manganese removal filtration device 22 in addition to the water softening device 7 and the RO device 8, and the iron removal / manganese removal filtration device 22 passes through a backwash line 24. The backwash pump 25 is interposed on the backwash line 24.

  In the iron removal / manganese removal filter 22, anthracite pulverized anthracite is layered on a manganese oxidation catalyst, and iron in the raw water is oxidized by sodium hypochlorite injected into the raw water. As a result, iron is removed from the raw water. Further, the manganese component in the raw water is oxidized and removed by the manganese oxidation catalyst. In addition, the iron removal / manganese removal filter 22 has a built-in timer, which periodically shuts off the supply of raw water (for example, 0.5 to 1 / day), drives the backwash pump 25, and supplies a water tank. The treated water stored in 3 is supplied to the iron removal / manganese filtration device 22 to regenerate the filter medium.

  In the embodiment of the present invention, a pretreatment control unit 26 that is physically separate from the water supply control unit 4 is provided. The RO device 8 is electrically connected to the water supply control unit 4 through the control line 18 as in the first embodiment, while the iron removal / manganese removal device 22 and the water softening device 7 are respectively controlled. The pretreatment control unit 26 is electrically connected via lines 27 and 28, and the iron removal / manganese removal device 22 and the water softening device 7 are controlled by the pretreatment control unit 26. The pretreatment control unit 26 transmits drive signals 32 and 33 to the raw water pump 1 and the backwash pump 25, and the raw water pump 1 and the backwash pump 25 are controlled by the pretreatment control unit 26.

  Further, the water supply control unit 4 and the pretreatment control unit 26 are electrically connected, the water supply control unit 4 transmits a water supply request signal 29 to the pretreatment control unit 26, and the pretreatment control unit 26 controls the water supply control. An operation permission signal 30 is transmitted to the unit 26. That is, the pretreatment control unit 26 always outputs the operation permission signal 30 to the water supply control unit 4 when the pretreatment control unit 26 is operable in response to the water supply request signal 29 from the iron removal / manganese removal filter 22 and the water softening device 7. Send. If it is determined that water supply is necessary, the water supply control unit 4 transmits a water supply request signal 29 to the pretreatment control unit 26 if the operation permission signal 30 from the pretreatment control unit 26 is valid.

  The iron removal / manganese removal filtering device 22 issues a regeneration request signal to the pretreatment control unit 26 a predetermined time before entering the regeneration process, and the pretreatment control unit 26 that has received the regeneration request signal receives the water supply control unit. 4 transmits a water level switching signal 31.

  Here, the reason why the pretreatment control unit 26 is physically and independently provided from the water supply control unit 4 is as follows.

  Even if there is a difference in mechanical structure, the operation itself of supplying raw water to produce treated water is the same for the membrane filtration device. Therefore, it is relatively easy to handle various membrane filtration devices electrically and uniformly in the water supply control unit 4.

  On the other hand, in the regenerative filtration apparatus, water flow is stopped during the regeneration treatment, and the types, sizes, and numbers vary depending on the amount and quality of the treated water, and the capabilities of the raw water pump are also different. Therefore, unlike the water supply control, the pretreatment control including the regenerative filtration device is difficult to handle in a unified manner, and needs to be individually handled according to the quality of the raw water and the required treatment capacity.

  Therefore, it is more efficient and cost-effective to control the pretreatment and the water supply treatment separately and independently. Moreover, it becomes possible to implement | achieve the water treatment system which can respond to a various variation rapidly at low cost by constructing | assembling a pre-processing and a water supply process separately independently, and making both cooperate.

  Therefore, in the embodiment of the present invention, the water supply control unit 4 and the pretreatment control unit 26 are physically separately and independently constructed, and both are electrically connected to cooperate with each other to supply water from the pretreatment control unit 26. By transmitting a water level switching signal 31 to the control unit 4, optimal water supply control is realized.

  Next, the operation method of the embodiment of the present invention will be described in detail.

  First, when the operation of the water treatment system is possible, the pretreatment control unit 26 constantly transmits the operation permission signal 30 to the water supply control unit 4. And if the water level sensor 14 detects less than the main L water level, the water supply control part 4 will transmit the water supply request signal 29 to the pre-processing control part 26, after confirming that the operation permission signal 30 is received. The pretreatment control unit 26 that has received the water supply request signal 29 issues a drive command to the raw water pump 1. As a result, the raw water is pumped from the raw water pump 1 and passes through the water supply line 23, and sodium hypochlorite is injected into the raw water by a chemical injection device (not shown) and supplied to the iron removal / manganese removal device 22. The iron and manganese components in the water are removed.

  Next, the raw water is softened by the water softening device 7, and the softened raw water is supplied to the RO device 8. The raw water is membrane-separated into permeated water and concentrated water by the RO device 8, a part of the concentrated water is returned to the pressure pump 12 through the circulation line 50, and the rest is drained from the drain valve 13.

  On the other hand, the permeated water becomes treated water and is supplied to the water supply tank 3. When the water level sensor 14 detects the main H water level, the water supply request signal 29 is invalidated, the raw water pump 1 is stopped, and the iron removal / manganese removal filter 22 is in the standby mode. Next, the iron removal / manganese removal filter 22 transmits a regeneration request signal to the preprocessing control unit 26 via the control line 27 before a predetermined time before entering the regeneration mode. The preprocessing control unit 26 that has received the regeneration request signal transmits a water level switching signal 31 to the water supply control unit 4. The water supply control unit 4 that has received the water level switching signal 31 switches the limit water level from the main setting to the sub setting and transmits the water supply request signal 29 to drive the raw water pump 1. Thereafter, water supply is started in the same manner as described above, water supply processing is performed with sub-setting, and the water storage amount of the water supply tank 3 is increased.

  When the iron removal / manganese removal filter 22 enters the regeneration mode, the operation permission signal 30 is invalidated, thereby the water supply request signal 29 is invalidated, the water level switching signal 31 is switched to the main setting, and the raw water pump 1 is stopped. To do. Then, regeneration treatment is performed using the treated water in the water supply tank 3. Thereafter, when the regeneration process is completed, the pretreatment control unit 26 transmits the operation permission signal 30 to the water supply control unit 4, and the water supply control unit 4 that confirms the reception of the operation permission signal 30 indicates that the water level sensor 14 is less than the main L water level. Is detected, the water supply request signal 29 is transmitted to the pretreatment control unit 26, the raw water pump 1 is driven, and the operation of the water treatment system is restarted by the method described above.

  FIG. 10 is a diagram showing the relationship between the operating state and the tank water level.

  When the water level sensor 14 detects the main H water level, the raw water pump 1 stops, and the iron removal / manganese removal filter 22 enters the standby mode. In this standby mode, the operation permission signal 30 is valid, but the water supply request signal 29 is invalid, and the water treatment system stops operation.

  In the standby mode, the treated water in the water supply tank 3 is used for boiler water supply, so the tank water level is lowered. The iron removal / manganese removal filter 22 issues a regeneration request signal to the pretreatment control unit 26 a predetermined time before entering the regeneration mode. The predetermined time is set to, for example, the time from when the regeneration request signal is issued until the tank water level rises to the sub H water level, or an approximate time thereof.

  And the pre-processing control part 26 transmits the water level switching signal 31 with respect to the water supply control part 4, and, thereby, a water level setting is switched from a main setting to a sub setting. On the other hand, the water supply control unit 4 transmits a water supply request signal 29 to the pretreatment control unit 26, whereby the raw water pump 1 is driven under the control of the pretreatment control unit 4 to start water supply to the iron removal / manganese removal device 22. . Then, when the tank water level rises again and the tank water level reaches the sub-H water level or in the vicinity thereof, the iron removal / manganese filtering device 22 enters the regeneration mode, and drives the backwash pump 25 to drive the water in the water supply tank 3. The treated water is supplied to the iron removal / manganese removal filter 22 and backwashing is performed. Further, when the regeneration mode is entered, the operation permission signal 30 is invalidated, and accordingly, the water supply request signal 31 is also invalidated. Note that the water level setting in the regeneration mode may be either the main setting or the sub-setting, but is set to the main setting in the embodiment of the present invention.

  In the regeneration mode, after the back washing process is performed, the process is paused for a predetermined time, and then the water washing process is performed. At this time, the treated water in the water supply tank 3 is consumed in a large amount by the backwash process, and the tank water level further decreases during the subsequent washing period due to the use of the treated water being regenerated.

  When the regeneration process is completed, the operation permission signal 30 becomes valid, and the water supply control unit 4 that confirms the validity of the operation permission signal 30 sends the water supply request signal 29 to the front when the water level sensor 14 detects a level lower than the main L water level. It transmits to the process control part 26, and the iron removal and manganese removal filtration apparatus 22 will be in water flow mode. Then, the treated water is again supplied to the water supply tank 3, the tank water level rises, and then the water treatment system performs water supply control with the main setting.

  As described above, in the embodiment of the present invention, the limit water level is switched according to the operation state of the iron removal / manganese removal filter 22 and the water supply control is performed, so that the regeneration mode in which a large amount of treated water is consumed is entered. It is possible to increase the amount of treated water in the water supply tank 3 before, and it is possible to prevent the amount of water stored in the water supply tank 3 from being excessively reduced.

  In the embodiment of the present invention, a case where a large amount of treated water is used at the time of the regeneration treatment is exemplified. However, even if the water treatment system is not equipped with a regenerative filtration device, a large amount of treated water is used at a specific time. It is possible to apply the embodiment of the present invention when using.

<Second proportionality of the present invention>
FIG. 11 is a system configuration diagram of a second comparative water treatment system related to the present invention.

  In the second comparative example, a temperature switch 35 is attached to the side wall of the water supply tank 34, and the temperature of treated water in the water supply tank 3 (hereinafter referred to as “tank water temperature”) is a predetermined high temperature (for example, 80 ° C.). ), The water level switching signal 36 is transmitted to the water supply control unit 4.

  In addition, drainage from the boiler is collected in the water supply tank 34 via a drain line 37, and an overflow pipe 38 is provided on the upper side wall of the water supply tank 34.

  That is, in a boiler water supply system that recovers drain from the boiler to the water supply tank 34, if the drain recovery rate becomes too high, the water temperature in the water supply tank 34 may increase excessively.

  Therefore, in the second comparative example, when the tank water temperature reaches a predetermined high temperature, the water level setting is switched to the sub-setting, whereby the treated water can be drained from the overflow pipe 38 and supplied from the water supply line 9. I am doing so.

  FIG. 12 is a diagram illustrating a water level setting example of the processing tank in the second comparative example. The secondary L water level is the same level as the main L water level, but the secondary H water level is set higher than the HH water level and the overflow pipe 38.

  When the tank water temperature is low, the temperature switch 35 is turned off, the water level setting is maintained at the main setting, and the water supply control is performed while managing the water level between the main H water level and the main L water level.

  On the other hand, when collecting drain from the boiler, if a large amount of high-temperature drain from the drain line 37 is poured into the water supply tank 34, the tank water temperature rises. When the tank water temperature reaches a predetermined high temperature, the temperature switch 35 is turned on, a water level switching signal 36 is transmitted to the water supply control unit 4, and the water level setting is switched to the sub-setting.

  In the sub-setting, as shown in FIG. 13, water supply control is performed while managing the tank water level between the sub-H water level and the sub-L water level.

  That is, when the tank water level reaches the HH water level, an alarm is issued because the tank water level is abnormally high. However, if the water temperature does not fall below a predetermined low temperature (for example, 40 ° C.) even if the tank water level reaches the HH water level, the water supply from the water supply line 9 is continued while the drain is drained from the overflow pipe 38. This avoids as much as possible that the tank water temperature is kept at an excessively high temperature.

  When the tank water temperature falls below a predetermined low temperature, the temperature switch 35 is turned off, a water level switching signal 36 is transmitted to the water supply control unit 4, and the limit water level is switched from the sub setting to the main setting.

  Thus, in the second comparative example, it is possible to avoid the tank water temperature from being left in an excessively high temperature state, and it is possible to improve the safety of the boiler feed water treatment system.

Normally, the tank water level can be lowered without reaching the sub-H water level by draining the treated water from the overflow pipe 38 and replenishing the treated water to the water supply tank 34 from the water supply line 9. However, if the drainage capacity from the overflow pipe 38 is low, the water supply is stopped when the water level in the water supply tank 34 reaches the sub-H water level. Therefore, the treated water does not overflow from the water supply tank 34.

  As can be understood from the embodiment of the present invention, according to the present invention, it is possible to realize optimal water supply control according to the operating state of the water treatment apparatus.

  Needless to say, the present invention is not limited to the above-described embodiment, and can be changed without departing from the scope of the invention. For example, in the above-described embodiment of the present invention, water supply control is performed according to the operation state, time, etc. with one set of main settings and one set of sub-settings. For example, the first to nth sub-H water levels (n is an integer of 2 or more) and the 1st to m-th sub-L water levels (m is an integer of 2 or more) are stored in the storage means, and the sub-H It is also preferable to perform water supply control while managing the water level by appropriately combining the water level and the sub-L water level.

  In the above-described embodiment of the present invention, the RO device is used as the membrane filtration device. However, an ultrafiltration membrane device, a microfiltration membrane device, and a nanofiltration membrane device can be used in the same manner. Furthermore, the water treatment device can also be applied to other water treatment devices, for example, regenerative filtration devices such as sand filtration devices and activated carbon filtration devices.

  In the embodiment of the present invention, the water treatment system for boiler water supply has been described. However, other water treatment systems, for example, a water treatment system for drinking water, can be similarly applied. In this case, from the viewpoint of preventing propagation of various bacteria, treated water to which a chlorine-based compound such as sodium hypochlorite is added is supplied to the water supply tank. Therefore, it is preferable that when the residual chlorine concentration in the treated water tank becomes less than a predetermined value, a sub-setting is provided so that forced water supply is performed for a certain period of time, and water supply control is performed by appropriately switching between the main setting and the sub-setting.

  In addition, when applying to a water treatment system where piping is installed outdoors in cold regions, etc., a temperature sensor is installed at an appropriate location in the piping, and the temperature detected by the temperature sensor is below a predetermined temperature (for example, 4 ° C.). Then, a sub-setting is provided so that forced water supply is performed, and desired water supply control can be performed by appropriately switching between the main setting and the sub-setting.

  In the embodiment of the present invention, the pressure detection type water level sensor is used. However, the pressure detection type is not limited as long as the water level can be continuously detected. You may use the water level sensor of the other system from which a measurement principle differs, such as a formula.

It is a system configuration figure showing the 1st comparative water treatment system relevant to the present invention. It is a schematic front view of the water supply tank which shows the example of the water level setting of the limit water level in the 1st contrast. It is a figure which shows an example of the change of the tank water level in the 1st contrast. It is a schematic front view of the water supply tank which shows the example of the water level setting of the 1st modification of the 1st contrast. It is a figure which shows an example of the change of the tank water level of the 1st modification of the 1st contrast. It is a schematic front view of the water tank 3 which shows the water level setting example of the 1st contrast 2nd modification. It is a figure which shows the water level switching example in the 1st contrast 2nd modification. It is a system configuration figure of the water treatment system concerning an embodiment of the invention. It is a schematic front view of the water supply tank which shows the example of the water level setting of the limit water level of embodiment of this invention. It is a figure which shows the relationship between the driving | running state and tank water level in embodiment of this invention. It is a system block diagram which shows the 2nd comparative water treatment system relevant to this invention. It is a figure which shows the water level setting of the processing tank in a 2nd contrast. It is a figure which shows the state in a water supply tank when the limit water level is made into the subsetting in the 2nd contrast. 1 is a system configuration diagram of a conventional technique described in Patent Document 1. FIG.

2 Water treatment device groups 3, 34 Water supply tank 4 Water supply control unit (water supply control means)
5 Water level switching command section (switching command means)
5a Timer (time measuring means)
16 31, 36 Water level switching signal (external signal line)
22 Iron removal / manganese removal filtration equipment (water treatment equipment)
25 Backwash pump (peripheral equipment)
26 Pre-processing control unit (running state detection means, switching command means)
35 Temperature switch (temperature detection means, switching command means)

Claims (7)

A water treatment device that generates treated water from raw water, a water supply tank that stores the treated water, a water level detecting means that continuously detects the water level of the treated water in the water supply tank, and a detection result of the water level detecting means In a water treatment system comprising a water supply control means for controlling the supply of the treated water to the water supply tank based on
The water supply control means has limit water level setting means for setting a plurality of upper limit water levels and lower limit water levels constituting the limit water level, and
An operation state detection unit that detects an operation state of the water treatment device, and a switching command unit that instructs the water supply control unit to switch the limit water level based on a detection result of the operation state detection unit,
And the said water supply control means changes the said limit water level based on the instruction | command from the said switching instruction | command means, The water treatment system characterized by the above-mentioned.   The water treatment system according to claim 1, wherein the water treatment apparatus includes at least a regenerative filtration apparatus and a peripheral device that performs a regeneration process of the regenerative filtration apparatus.   The water treatment system according to claim 1, wherein the switching command unit and the water supply control unit are electrically connected via an external signal line.   If the water level after switching is equal to or lower than the upper limit water level specified after the switching when the limit command is received by the switching command means, the water supply control means is supplied to the water tank until the upper limit water level is reached. The water treatment system according to claim 1, wherein a water supply command is issued.   The water treatment system according to any one of claims 1 to 4, wherein the water treatment device includes a soft water device and a membrane filtration device. The limit water level setting means sets an extreme water level consisting of an extreme upper limit water level and an extreme lower limit water level,
The water supply control means has an abnormality notifying means for notifying an abnormality when the water level of the water supply tank reaches either the upper limit water level or more and the lower limit water level or less. The water treatment system according to any one of claims 1 to 5. The water treatment device shall be able to stop water treatment during regeneration,
The switching command means switches the setting of the upper limit water level from a main setting to a sub-setting higher than the main setting immediately before entering the regeneration process, and increases the amount of treated water stored in the water supply tank. Water treatment system as described in.

Images