JP2011224468A - Water purifier - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a water purifier washable of a filter medium with clean water.SOLUTION: The water purifier 1 includes a microfilter 114, a tank 301 only for washing, a pump 150, a solenoid valve A201, a solenoid valve C203, a solenoid valve D204, a solenoid valve E205, a solenoid valve F206, a solenoid valve I209 and a control part 131. In the case of determining that it is the time to wash the microfilter 114, the control part 131 supplies water to the tank 301 only for washing by the pump 150 and the solenoid valves A201, C203, E205, F206 and then supplies water to the microfilter 114 by the pump 150 and the solenoid valves D204, I209. In the case of not determining that it is the time to wash the microfilter 114, the control part 131 controls not to supply water to the tank 301 only for washing.

Description

  The present invention generally relates to a water purifier, and more specifically, to a water purifier of a type that generates raw water by filtering raw water with a filter medium such as a hollow fiber membrane or an ultrafiltration membrane (UF membrane).

  In a water purifier of a type that generates raw water by filtering raw water with a filter medium, the filter medium becomes clogged more as the water purification time, that is, the operation time of the water purifier becomes longer, and the water purification performance decreases. Therefore, conventionally, there is a water purifier capable of regenerating the filter medium by reverse cleaning the filter medium. In such a water purifier, water is stored in the water storage unit, and the filter medium is cleaned using the water stored in the water storage unit when performing reverse cleaning.

  For example, in JP 2009-160493 A (Patent Document 1), a membrane module containing a membrane in which micropores capable of removing inclusions such as turbidity and fine particles from raw water and a membrane module are delivered. A membrane filtration device comprising a backwash tank for storing a predetermined amount of filtered water is described. In this membrane filtration device, the backwash process of the membrane module is performed by sending filtered water stored in the backwash tank to the membrane module by a backwash pump.

  JP 2009-195893 (Patent Document 2) describes a water purification membrane filtration facility comprising a membrane module incorporating a hollow fiber MF membrane (microfiltration membrane) or a UF membrane (ultrafiltration membrane). Has been. In this water purification membrane filtration facility, filtered water from which turbidity and fine particles in raw water have been removed by the membrane module is stored in a filtrate tank installed on the downstream side of the membrane module. By driving the backwash pump, the water in the filtrate water tank is supplied to the membrane module from the secondary side of the membrane module, that is, from the filtrate water side.

JP 2009-160493 A JP 2009-195893 A

  However, in the membrane filtration apparatus described in JP2009-160493A (Patent Document 1) and the water purification membrane filtration facility described in JP2009-195893A (Patent Document 2), the membrane module is not washed. Even so, clean water is always stored in the backwash tank. Chlorine is removed from the purified water that has passed through the filter medium, so that bacteria are easy to propagate and easily rot. Therefore, if water, particularly purified water, is always stored in the backwash tank, the purified water may rot in the backwash tank. When the spoiled purified water is used for cleaning the filter medium, the filter medium is contaminated.

  Then, the objective of this invention is providing the water purifier which can wash | clean a filter medium with clean water.

  The water purifier according to the present invention includes a filter medium, a water storage unit, a first supply unit, a second supply unit, and a control unit. The filter medium is used to pass the raw water into purified water. The water storage unit stores water for cleaning the filter medium. The first supply unit is for supplying water to the water storage unit. The second supply unit is for supplying water stored in the water storage unit to the filter medium. The control unit determines whether it is time to clean the filter medium, and controls the first supply unit and the second supply unit.

  When it is determined that it is time to wash the filter medium, the control unit supplies water to the water storage unit by the first supply unit and then supplies water to the filter medium by the second supply unit. If it is not determined that it is time to perform cleaning, the first supply unit and the second supply unit are controlled so as not to supply water to the water storage unit by the first supply unit. Yes.

  When the control unit determines that it is time to wash the filter medium, after supplying water to the water storage unit by the first supply unit, water supply to the filter medium by the second supply unit is performed. The first supply unit and the second supply unit are controlled. Water is stored in the water reservoir. The water stored in the water reservoir is supplied to the filter medium. In this way, the filter medium can be washed with clean water that has not been spoiled immediately after being stored in the water storage section.

  On the other hand, if the control unit does not determine that it is time to wash the filter medium, the control unit controls the first supply unit so that the first supply unit does not supply water to the water storage unit. That is, water cannot be stored in the water storage section when the filter medium is not washed. Only when the control unit determines that it is time to wash the filter medium, water is stored in the water storage unit. Accordingly, it is possible to prevent water from being always stored in the water storage unit and the water from being spoiled in the water storage unit.

  By doing in this way, the water purifier which can wash | clean a filter medium with clean water can be provided.

  In the water purifier according to the present invention, the control unit calculates the remainder of the usable period of the filter medium, and when the remaining of the usable period of the filter medium is equal to or less than a predetermined value, the filter medium is washed. It is preferably configured to determine that there is.

  By doing in this way, a filter medium can be wash | cleaned when the water purification performance of a filter medium falls and the remainder of the period which can use a filter medium becomes below a predetermined value.

  The water purifier according to the present invention preferably includes a selection unit for the user to select that the filter medium is washed. It is preferable that the control unit is configured to determine that it is time to clean the filter medium when the user selects to clean the filter medium through the selection unit.

  By doing in this way, the user can choose to wash the filter medium as needed.

  In the water purifier according to the present invention, the control unit is configured to calculate the remaining amount of the filter medium usable period, and informs the user that the remaining period of the filter medium usable period is equal to or less than a predetermined value. It is preferable to further include a notification unit for notification. The control unit supplies water to the water storage unit by the first supply unit when the remaining amount of the filter medium usable period is equal to or less than a predetermined value, and then the remaining period of the filter medium usable period is the predetermined value. It is preferable to control the notification unit so that the notification unit notifies the user that the value is less than or equal to the value.

  In this way, the user does not have to wait while water is stored in the water storage section. In addition, after the informing unit notifies that the water has been stored in the water storage unit, the user adds a cleaning material such as a chemical for cleaning the filter medium to the water stored in the water storage unit, and then selects the selection unit. It is possible to choose to wash the filter media through.

  In the water purifier according to the present invention, the first supply unit is preferably configured to supply water that has passed through the filter medium to the water storage unit.

  By doing in this way, a filter medium can be washed with cleaner water. Even if the purified water is easily rotted due to the removal of chlorine, it is stored in the water storage section only when the control section determines that it is time to wash the filter medium, so it does not rot in the water storage section.

  As mentioned above, according to this invention, the water purifier which can wash | clean a filter medium with clean water can be provided.

It is a figure showing typically the whole water purifier concerning one embodiment of the present invention. It is a block diagram which shows the control relevant structure of the water purifier which concerns on one embodiment of this invention. It is a flowchart which shows the control process of the water purifier which concerns on one embodiment of this invention in order. It is a flowchart which shows another control process of the water purifier which concerns on one embodiment of this invention in order. It is a flowchart which shows another control process of the water purifier which concerns on one embodiment of this invention in order. It is a flowchart which shows another control process of the water purifier which concerns on one embodiment of this invention in order.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  As shown in FIG. 1, a water purifier 1 according to one embodiment of the present invention mainly includes a main water passage 101, a prefilter 111 disposed in the main water passage 101, activated carbon 112, and an ion exchange resin 113. A microfilter 114 as a filter medium, a flow rate sensor 121, a differential pressure sensor 122, a turbidity sensor 123, a control unit 131, a pump 150, an operation unit 160 as a selection unit, a notification unit 170, and a washing dedicated tank as a water storage unit 301. The controller 131 is a part of the microcomputer as will be described later. In addition, the water purifier 1 may include a heating device 141 and a cooling device 142.

  The main water channel 101 is for circulating water. Raw water such as tap water, well water, and river water is supplied to the main water passage 101 from the outside of the water purifier 1. The raw water passes through the pre-filter 111, the activated carbon 112, the ion exchange resin 113, and the microfilter 114 in order in the main water passage 101 to be purified, and is supplied to the outside of the water purifier 1.

  The pre-filter 111 is composed of a relatively coarse nonwoven fabric. The water passing through the prefilter 111 is filtered by the prefilter 111 to remove relatively large impurities in the water. The activated carbon 112 adsorbs organic substances in the water and removes them from the water. The ion exchange resin 113 ion-exchanges hard water into soft water. The microfilter 114 is composed of a relatively fine nonwoven fabric. The microfilter 114 may be configured by a film. As the water passes through the microfilter 114, fine impurities are also filtered out. The water that has passed through the microfilter 114 becomes purified water.

  The flow sensor 121 measures the instantaneous flow rate of water passing through the prefilter 111 and transmits a signal to the microcomputer including the control unit 131.

  The differential pressure sensor 122 detects a differential pressure between the water pressure on the raw water side and the water pressure on the filtered water side of the microfilter 114, and transmits a signal to the microcomputer including the control unit 131. The water purifier 1 may include a water pressure detection unit that detects the water pressure on the raw water side instead of the differential pressure sensor 122.

  The turbidity sensor 123 detects the turbidity of the water that has passed through the microfilter 114 and transmits a signal to the microcomputer including the control unit 131. The turbidity sensor 123 includes, for example, a light emitting unit and a light receiving unit.

  One end of the ion exchange resin regeneration water passage 104 is connected between the ion exchange resin 113 and the microfilter 114 in the main water passage 101. The other end of the ion exchange resin regeneration water passage 104 is connected to the main water passage 101 on the downstream side of the turbidity sensor 123.

  One end of a microfilter cleaning water passage 105 is connected between the microfilter 114 and the turbidity sensor 123 in the main water passage 101. The other end of the microfilter cleaning water passage 105 is connected to the main water passage 101 on the downstream side of the turbidity sensor 123.

  On the downstream side of the turbidity sensor 123, a cleaning dedicated tank 301 is connected to the main water passage 101 through the first sub water passage 102 and the second sub water passage 103. Water is stored in the cleaning tank 301. A pump 150 for sending the water in the cleaning dedicated tank 301 is arranged in the second sub-water passage 103. The second auxiliary water passage 103 is connected to the ion exchange resin regeneration water passage 104 and the microfilter cleaning water passage 105. That is, the cleaning dedicated tank 301 is connected to the ion exchange resin regeneration water passage 104 and the microfilter cleaning water passage 105 through the second sub water passage 103.

  The cleaning tank 301 is provided with a supply unit 302 for the user to supply salt and cleaning agent inside the cleaning tank 301. In addition, a water level sensor 303 for detecting the water level in the cleaning tank 301 is disposed. The water level sensor 303 detects the water level in the cleaning tank 301 and transmits a signal to the microcomputer including the control unit 131.

  The heating device 141 is for heating the purified water filtered by the microfilter 114. The cooling device 142 is for cooling the purified water filtered by the microfilter 114.

  The operation unit 160 includes switches and buttons for operation by the user. The operation unit 160 includes a switch for starting an ion exchange resin regeneration process and a cleaning button for selecting to clean the microfilter 114. Through the operation unit 160, the user can select, for example, a water purification mode in which the water purifier 1 supplies purified water and a raw water mode in which the water purifier 1 supplies raw water without purification. Moreover, the user can select the temperature of the purified water supplied by the water purifier 1 by operating the operation unit 160, for example.

  The notification unit 170 notifies the user that the remaining usable period of the microfilter 114 is equal to or less than a predetermined value by sound or light.

  A plurality of valves are arranged in the main water passage 101. The opening and closing of these valves is controlled by the control unit 131. A solenoid valve A201 is arranged at the end of the main water passage 101 on the side where raw water is supplied. The electromagnetic valve A201 is for switching between supply of raw water into the main water passage 101 and supply stop.

  Between the activated carbon 112 and the ion exchange resin 113, the first drainage channel 106 branches off from the main water channel 101. An electromagnetic valve B202 is disposed in the first drainage channel 106. The electromagnetic valve B202 is for switching between drainage for discharging the water in the main water passage 101 to the outside of the water purifier 1 through the first drainage channel 106 and stopping the drainage.

  In the main water passage 101, an electromagnetic valve C 203 is disposed between the upstream end of the ion exchange resin regeneration water passage 104 and the microfilter 114. Between the electromagnetic valve C203 and the microfilter 114, the second drainage channel 107 branches from the main water channel 101. An electromagnetic valve D204 is disposed in the second drainage channel 107. The electromagnetic valve D204 is for switching between drainage for discharging the water in the main channel 101 to the outside of the water purifier 1 through the second drainage channel 107 and stopping the drainage.

  An electromagnetic valve E205 is disposed between the turbidity sensor 123 and the end of the first auxiliary water passage 102 in the main water passage 101. In addition, an electromagnetic valve F206 is disposed in the first sub-water passage 102. The solenoid valve F206 is for switching between supply and stop of water supply from the main water passage 101 to the cleaning tank 301.

  In the main water passage 101, a third drainage passage 108 branches from the main water passage 101 on the downstream side of the end of the second sub water passage 103. An electromagnetic valve G207 is disposed in the third drainage channel. The electromagnetic valve G207 is for switching between drainage for discharging the water in the main water passage 101 to the outside of the water purifier 1 through the third drainage channel 108 and stopping the drainage. The third drainage channel 108 is further branched into a hot water supply channel 108a and a cold water supply channel 108b between the end on the main water channel 101 side and the electromagnetic valve G207, and the hot water supply channel 108a has an electromagnetic wave. A valve K211 and a heating device 141 are disposed, and an electromagnetic valve L212 and a cooling device 142 are disposed in the cold water supply path 108b.

  A solenoid valve H208 is disposed at the end of the main water passage 101 on the side where purified water is supplied. The solenoid valve H208 is for switching between supply and stop of supply of purified water from the main water passage 101 to the outside of the water purifier 1.

  An electromagnetic valve I209 is disposed in the water passage 105 for cleaning the microfilter. The electromagnetic valve I209 is for switching between supply and stoppage of water in the cleaning dedicated tank 301 from the microfilter cleaning water passage 105 to the microfilter 114.

  An electromagnetic valve J210 is disposed in the water passage 104 for ion exchange resin regeneration. The electromagnetic valve J210 is for switching between supply and stop of supply of water in the cleaning dedicated tank 301 from the ion exchange resin regeneration water passage 104 to the ion exchange resin 113.

  In the main water passage 101, a check valve 213 is disposed between the activated carbon 112 and the ion exchange resin 113.

  The pump 150, the electromagnetic valve A201, the electromagnetic valve C203, the electromagnetic valve E205, and the electromagnetic valve F206 are examples of the first supply unit. Further, the pump 150, the electromagnetic valve D204, and the electromagnetic valve I209 are examples of the second supply unit.

  As shown in FIG. 2, the water purifier 1 includes a flow rate sensor 121, a differential pressure sensor 122, a turbidity sensor 123, a water level sensor 303, an operation unit 160, a microcomputer 130, a solenoid valve A 201, and an electromagnetic component as control-related configurations. Valve B202, solenoid valve C203, solenoid valve D204, solenoid valve E205, solenoid valve F206, solenoid valve G207, solenoid valve H208, solenoid valve I210, solenoid valve J210, solenoid valve K211, solenoid valve L212, pump 150, and heating device 141 and the cooling device 142. The microcomputer 130 includes a control unit 131, a reading unit 132, a storage unit 133, and a time measuring unit 134.

  The flow sensor 121 detects the amount of water and transmits a signal to the reading unit 132. The differential pressure sensor 122 detects a differential pressure between the water pressure on the raw water side and the water pressure on the filtered water side of the microfilter 114 and transmits a signal to the reading unit 132. The turbidity sensor 123 detects turbidity and transmits a signal to the reading unit 132. The water level sensor 303 detects the water level in the cleaning tank 301 and transmits a signal to the reading unit 132.

  The operation unit 160 transmits a signal to the reading unit 132 when operated by the user.

  The reading unit 132 transmits and receives signals to and from the storage unit 133 and transmits signals transmitted from each member to the storage unit 133.

  The storage unit 133 stores the signal transmitted from the reading unit 132. The storage unit 133 also transmits and receives signals to and from the control unit 131 and transmits signals to the control unit 131.

  Based on the received signal, the control unit 131 controls the electromagnetic valve A201, the electromagnetic valve B202, the electromagnetic valve C203, the electromagnetic valve D204, the electromagnetic valve E205, the electromagnetic valve F206, the electromagnetic valve G207, the electromagnetic valve H208, the electromagnetic valve I209, and the electromagnetic valve. J210, electromagnetic valve K211, electromagnetic valve L212, pump 150, heating device 141, cooling device 142, and notification unit 170 are controlled. The control unit 131 also transmits and receives signals to and from the time measuring unit 134.

  The time measuring unit 134 transmits and receives signals to and from the control unit 131 and measures time.

  Operation | movement of the water purifier 1 comprised as mentioned above is demonstrated. First, in the initial state, all solenoid valves are closed.

  When supplying purified water, first, the control unit 131 controls to open the electromagnetic valve A201, the electromagnetic valve C203, and the electromagnetic valve E205. When it is selected that the user operates the operation unit 160 to supply clean water at room temperature, the control unit 131 opens the electromagnetic valve H208 and closes the electromagnetic valve K211 and the electromagnetic valve L212. To control. By doing in this way, normal temperature purified water is supplied from the water purifier 1.

  On the other hand, when it is selected that the user operates the operation unit 160 to supply purified water of hot water, the control unit 131 controls the heating device 141 to be driven, and the electromagnetic valve H208 is controlled. Control is performed so that the electromagnetic valve K211 is closed and the electromagnetic valve L212 is closed. By doing in this way, the purified water of hot water is supplied from the water purifier 1.

  In addition, when it is selected that the user operates the operation unit 160 to supply purified water of cold water, the control unit 131 performs control so that the cooling device 142 is driven, and the electromagnetic valve H208 and the electromagnetic valve Control is performed so that the valve K211 is closed and the electromagnetic valve L212 is opened. By doing in this way, the purified water of cold water is supplied from the water purifier 1.

  Next, the washing | cleaning process of the micro filter 114 of the water purifier 1 is demonstrated. In the cleaning process of the microfilter 114, all the solenoid valves are first closed.

  As shown in FIG. 3, in step S <b> 101, the control unit 131 determines whether it is time to clean the microfilter 114. If it is time to clean the microfilter 114, the process proceeds to step S102. If it is not time to clean the microfilter 114, the process returns to step S101. Whether or not it is time to clean the microfilter 114 may be determined, for example, based on whether or not the integrated value of the flow rate measured by the flow rate sensor 121 has reached a predetermined value, or measured by the differential pressure sensor 122. The controller 131 may calculate the pressure loss based on the differential pressure, and may determine whether the pressure loss value has reached a predetermined value. Alternatively, the determination may be made based on whether the turbidity value detected by the turbidity sensor 123 has reached a predetermined value. Alternatively, after the start of use of the water purifier 1, it may be determined whether or not the time measured by the time measuring unit 134 has reached a predetermined time.

  In step S <b> 102, the control unit 131 controls the electromagnetic valve so that water is stored in the cleaning tank 301. The controller 131 controls the solenoid valve A201, the solenoid valve C203, the solenoid valve E205, and the solenoid valve F206 to open. By doing in this way, the raw | natural water which flowed in into the main water flow path 101 from the exterior of the water purifier 1 passes along the main water flow path 101 and the 1st sub water flow path 102, as shown by the arrow A in FIG. It is stored in the dedicated tank 301. Based on the water level detected by the water level sensor 303, the control unit 131 controls the solenoid valve A201, the solenoid valve C203, the solenoid valve E205, and the solenoid valve F206 to be opened until the cleaning dedicated tank 301 becomes full. Next, the process proceeds to step S103.

  In step S103, the control unit 131 performs control so that the electromagnetic valve A201, the electromagnetic valve C203, the electromagnetic valve E205, and the electromagnetic valve F206 are closed, the electromagnetic valve I209 and the electromagnetic valve D204 are opened, and the pump 150 is driven. By doing so, the water stored in the cleaning tank 301 is fully filled and flows into the microfilter 114 in the direction indicated by the arrow B in FIG.

  The water that has flowed into the microfilter 114 cleans the microfilter 114 while passing through the microfilter 114. The water that has washed the microfilter 114 is drained to the outside of the water purifier 1 through the second drainage channel 107 in which the electromagnetic valve D204 is disposed. In this way, the microfilter 114 is washed with clean water.

  As described above, the water purifier 1 includes the microfilter 114, the cleaning dedicated tank 301, the pump 150, the electromagnetic valve A201, the electromagnetic valve C203, the electromagnetic valve D204, the electromagnetic valve E205, the electromagnetic valve F206, the electromagnetic valve I209, and the control. Part 131. The microfilter 114 is for purifying the raw water by passing it through. The dedicated cleaning tank 301 stores water for cleaning the microfilter 114. The pump 150, the electromagnetic valve A201, the electromagnetic valve C203, the electromagnetic valve E205, and the electromagnetic valve F206 are for supplying water to the cleaning tank 301. The pump 150, the electromagnetic valve D204, and the electromagnetic valve I209 are for supplying the microfilter 114 with water stored in the cleaning tank 301. The control unit 131 determines whether it is time to clean the microfilter 114, and controls the pump 150, the electromagnetic valve A201, the electromagnetic valve C203, the electromagnetic valve E205, the electromagnetic valve F206, the electromagnetic valve D204, and the electromagnetic valve I209. To do.

  When the control unit 131 determines that it is time to clean the microfilter 114, the water supply to the cleaning dedicated tank 301 by the pump 150, the electromagnetic valve A201, the electromagnetic valve C203, the electromagnetic valve E205, and the electromagnetic valve F206 is performed. If it is not determined that it is time to supply water to the microfilter 114 by the pump 150, the electromagnetic valve D204, and the electromagnetic valve I209 and the microfilter 114 is cleaned, the pump 150, the electromagnetic valve A201, The pump 150, the solenoid valve A201, the solenoid valve C203, the solenoid valve E205, the solenoid valve F206, the solenoid valve D204, and the like so as not to supply water to the cleaning tank 301 by the solenoid valve C203, solenoid valve E205, and solenoid valve F206. The electromagnetic valve I209 is configured to be controlled.

  When the control unit 131 determines that it is time to clean the microfilter 114, the pump 150, the electromagnetic valve A201, the electromagnetic valve C203, the electromagnetic valve E205, and the electromagnetic valve F206 supply water to the cleaning dedicated tank 301. After that, the pump 150, the electromagnetic valve A204, the electromagnetic valve C205, the electromagnetic valve E205, the electromagnetic valve F206, and the electromagnetic valve D204 are used so that the pump 150, the electromagnetic valve D204, and the electromagnetic valve I209 supply water to the microfilter 114. The electromagnetic valve I209 is controlled. Water is stored in the cleaning tank 301. The water stored in the cleaning tank 301 is supplied to the microfilter 114. In this way, the microfilter 114 can be washed with clean water that has not been spoiled immediately after being stored in the washing tank 301.

  On the other hand, when the control unit 131 does not determine that it is time to clean the microfilter 114, the water to the cleaning dedicated tank 301 by the pump 150, the electromagnetic valve A201, the electromagnetic valve C203, the electromagnetic valve E205, and the electromagnetic valve F206 is removed. The control unit 131 controls the pump 150, the electromagnetic valve A201, the electromagnetic valve C203, the electromagnetic valve E205, and the electromagnetic valve F206 so that the supply is not performed. That is, water is not stored in the cleaning tank 301 when the microfilter 114 is not cleaned. Water is stored in the cleaning tank 301 only when the control unit 131 determines that it is time to clean the microfilter 114. Accordingly, it is possible to prevent water from being always stored in the cleaning tank 301 and preventing the water from being spoiled in the cleaning tank 301.

  By doing in this way, the water purifier 1 which can wash | clean the micro filter 114 with clean water can be provided.

  In the water purifier 1, the pump 150, the electromagnetic valve A 201, the electromagnetic valve C 203, the electromagnetic valve E 205, and the electromagnetic valve F 206 are configured to supply water that has passed through the microfilter 114 to the cleaning dedicated tank 301.

  By doing so, the microfilter 114 can be washed with cleaner water. Even if the purified water is easily rotted due to the removal of chlorine, it is stored in the cleaning tank 301 only when the control unit 131 determines that it is time to clean the microfilter 114. There is nothing to do.

  Next, another example of the cleaning process of the microfilter 114 of the water purifier 1 will be described.

  As shown in FIG. 4, in step S <b> 201, the control unit 131 determines whether the remaining usable period of the microfilter 114 is equal to or less than a predetermined value. The remaining usable period of the microfilter 114 is calculated as follows.

  For example, the integrated value of the amount of water that can be filtered by the microfilter 114 is stored in the storage unit 133 in advance. For example, when the integrated value of the amount of water that can be filtered by the microfilter 114 is 2500 L, the integrated value of the stored flow rate is set to 2000 L, which is 80% of 2500 L. The control unit 131 calculates an integrated flow rate based on the signal received from the flow sensor 121, and compares the calculated integrated flow rate value with the integrated value stored in the storage unit 133. By comparing the calculated integrated flow rate value with the stored integrated value, the control unit 131 can determine whether the remaining usable period of the microfilter 114 is equal to or less than a predetermined value. .

  By comparing the calculated integrated flow rate value with the integrated value stored in the storage unit 133, the remaining amount of water that can be filtered by the microfilter 114 is obtained. The greater the remaining amount of water that can be filtered by the microfilter 114, the greater the remainder of the usable period of the microfilter 114. Therefore, if the remaining amount of water that can be filtered by the microfilter 114 is not more than a predetermined value, that is, if the calculated integrated flow rate is not less than the integrated value stored in the storage unit 133, the microfilter 114. It is possible to determine that the remaining usable period is equal to or less than a predetermined value.

  If the remaining usable period of the microfilter 114 is equal to or smaller than a predetermined value, the process proceeds to step S202. If the remaining usable period of the microfilter 114 is not less than the predetermined value, the process returns to step S201.

  In step S202, the control unit 131 controls the electromagnetic valve so that water is stored in the cleaning tank 301. The controller 131 controls the solenoid valve A201, the solenoid valve C203, the solenoid valve E205, and the solenoid valve F206 to open. By doing in this way, the raw | natural water which flowed in into the main water flow path 101 from the exterior of the water purifier 1 passes along the main water flow path 101 and the 1st sub water flow path 102, as shown by the arrow A in FIG. It is stored in the dedicated tank 301. Based on the water level detected by the water level sensor 303, the control unit 131 controls the solenoid valve A201, the solenoid valve C203, the solenoid valve E205, and the solenoid valve F206 to be opened until the cleaning dedicated tank 301 becomes full. Next, the process proceeds to step S203.

  In step S203, the control unit 131 performs control so that the electromagnetic valve A201, the electromagnetic valve C203, the electromagnetic valve E205, and the electromagnetic valve F206 are closed, the electromagnetic valve I209 and the electromagnetic valve D204 are opened, and the pump 150 is driven. By doing so, the water stored in the cleaning tank 301 is fully filled and flows into the microfilter 114 in the direction indicated by the arrow B in FIG.

  The water that has flowed into the microfilter 114 cleans the microfilter 114 while passing through the microfilter 114. The water that has washed the microfilter 114 is drained to the outside of the water purifier 1 through the second drainage channel 107 in which the electromagnetic valve D204 is disposed. In this way, the microfilter 114 is washed with clean water.

  As described above, in the water purifier 1, the control unit 131 calculates the remainder of the usable period of the microfilter 114, and when the remaining usable period of the microfilter 114 is equal to or less than a predetermined value, It is configured to determine that it is time to clean the filter 114.

  By doing so, the microfilter 114 can be washed when the water purification performance of the microfilter 114 is lowered and the remaining usable period of the microfilter 114 becomes a predetermined value or less.

  Next, another example of the cleaning process of the microfilter 114 of the water purifier 1 will be described.

  As shown in FIG. 5, in step S <b> 301, the control unit 131 determines whether the user has pressed the cleaning button of the operation unit 160. If the user has pressed the cleaning button of the operation unit 160, the process proceeds to step S302. If the user has not pressed the cleaning button of the operation unit 160, the process returns to step S301.

  In step S <b> 302, the control unit 131 controls the electromagnetic valve so that water is stored in the cleaning tank 301. The controller 131 controls the solenoid valve A201, the solenoid valve C203, the solenoid valve E205, and the solenoid valve F206 to open. By doing in this way, the raw | natural water which flowed in into the main water flow path 101 from the exterior of the water purifier 1 passes along the main water flow path 101 and the 1st sub water flow path 102, as shown by the arrow A in FIG. It is stored in the dedicated tank 301. Based on the water level detected by the water level sensor 303, the control unit 131 controls the solenoid valve A201, the solenoid valve C203, the solenoid valve E205, and the solenoid valve F206 to be opened until the cleaning dedicated tank 301 becomes full. Next, the process proceeds to step S303.

  In step S303, the control unit 131 performs control so that the electromagnetic valve A201, the electromagnetic valve C203, the electromagnetic valve E205, and the electromagnetic valve F206 are closed, the electromagnetic valve I209 and the electromagnetic valve D204 are opened, and the pump 150 is driven. By doing so, the water stored in the cleaning tank 301 is fully filled and flows into the microfilter 114 in the direction indicated by the arrow B in FIG.

  The water that has flowed into the microfilter 114 cleans the microfilter 114 while passing through the microfilter 114. The water that has washed the microfilter 114 is drained to the outside of the water purifier 1 through the second drainage channel 107 in which the electromagnetic valve D204 is disposed. In this way, the microfilter 114 is washed with clean water.

  As described above, the water purifier 1 includes the operation unit 160 for the user to select that the microfilter 114 is cleaned. The control unit 131 is configured to determine that it is time to clean the microfilter 114 when the user selects cleaning the microfilter 114 through the operation unit 160.

  In this way, the user can choose to clean the microfilter 114 as needed.

  Next, still another example of the cleaning process of the microfilter 114 of the water purifier 1 will be described.

  As shown in FIG. 6, in step S401, the control unit 131 determines whether or not the remaining usable period of the microfilter 114 is equal to or less than a predetermined value. The remaining usable period of the microfilter 114 is calculated in the same manner as in step S201 shown in FIG. 4, for example.

  In step S <b> 402, the control unit 131 controls the electromagnetic valve so that water is stored in the cleaning tank 301. The controller 131 controls the solenoid valve A201, the solenoid valve C203, the solenoid valve E205, and the solenoid valve F206 to open. By doing in this way, the raw | natural water which flowed in into the main water flow path 101 from the exterior of the water purifier 1 passes along the main water flow path 101 and the 1st sub water flow path 102, as shown by the arrow A in FIG. It is stored in the dedicated tank 301. Based on the water level detected by the water level sensor 303, the control unit 131 controls the solenoid valve A201, the solenoid valve C203, the solenoid valve E205, and the solenoid valve F206 to be opened until the cleaning dedicated tank 301 becomes full. Next, the process proceeds to step S403.

  In step S403, the control unit 131 controls the notification unit 170 to notify the user that the remaining usable period of the microfilter 114 is equal to or less than a predetermined value. Next, the process proceeds to step S404.

  In step S <b> 404, the control unit 131 determines whether the user has pressed the cleaning button of the operation unit 160. If the user has pressed the cleaning button of the operation unit 160, the process proceeds to step S405. If the user has not pressed the cleaning button of the operation unit 160, the process returns to step S404.

  In step S405, the control unit 131 performs control so that the electromagnetic valve A201, the electromagnetic valve C203, the electromagnetic valve E205, and the electromagnetic valve F206 are closed, the electromagnetic valve I209 and the electromagnetic valve D204 are opened, and the pump 150 is driven. By doing so, the water stored in the cleaning tank 301 is fully filled and flows into the microfilter 114 in the direction indicated by the arrow B in FIG.

  The water that has flowed into the microfilter 114 cleans the microfilter 114 while passing through the microfilter 114. The water that has washed the microfilter 114 is drained to the outside of the water purifier 1 through the second drainage channel 107 in which the electromagnetic valve D204 is disposed. In this way, the microfilter 114 is washed with clean water.

  As described above, in the water purifier 1, the control unit 131 is configured to calculate the remaining usable period of the microfilter 114, and the remaining usable period of the microfilter 114 is equal to or less than a predetermined value. It further includes a notification unit 170 for notifying the user of the presence. When the remaining usable period of the microfilter 114 is equal to or less than a predetermined value, the control unit 131 supplies the cleaning dedicated tank 301 to the cleaning dedicated tank 301 by the pump 150, the electromagnetic valve A201, the electromagnetic valve C203, the electromagnetic valve E205, and the electromagnetic valve F206. After supplying the water, the notification unit 170 controls the notification unit 170 to notify the user that the remaining usable period of the microfilter 114 is equal to or less than a predetermined value.

  In this way, the user does not have to wait while water is stored in the cleaning tank 301. In addition, after the user is notified by the notification unit 170 that the water has been stored in the cleaning tank 301, the user stores the cleaning material such as a medicine for cleaning the microfilter 114 in the cleaning tank 301. In addition, it is possible to select to clean the microfilter 114 through the operation unit 160.

  Next, an ion exchange resin regeneration process for regenerating the ion exchange resin 113 will be described.

  In the ion exchange resin regeneration process, all the solenoid valves are first closed. The user puts salt into the cleaning tank 301 through the supply unit 302. Next, the control unit 131 controls the solenoid valve A201, the solenoid valve C203, the solenoid valve E205, and the solenoid valve F206 to open. In this way, raw water that has flowed into the main water passage 101 from the outside of the water purifier 1 passes through the main water passage 101 and the first sub water passage 102 and is stored in the cleaning tank 301. Based on the water level detected by the water level sensor 303, the control unit 131 controls the solenoid valve A201, the solenoid valve C203, the solenoid valve E205, and the solenoid valve F206 to be opened until the cleaning dedicated tank 301 becomes full.

  Next, the control unit 131 performs control so that the electromagnetic valve A201, the electromagnetic valve C203, the electromagnetic valve E205, and the electromagnetic valve F206 are closed, the electromagnetic valve J210 and the electromagnetic valve B202 are opened, and the pump 150 is driven. By doing so, the saline stored in the washing tank 301 is fully filled in the ion exchange resin regeneration water passage 104 in the direction indicated by the arrow C in FIG. Then, the regeneration of the ion exchange resin 113 is started. The salt solution that has passed through the ion exchange resin 113 passes through the first drainage channel 106 and is discharged to the outside of the water purifier 1.

  Next, the control unit 131 transmits a control signal to the electromagnetic valve A201, the electromagnetic valve C203, the electromagnetic valve E205, and the electromagnetic valve G207, and controls to open these electromagnetic valves. In this way, cleaning after the regeneration of the ion exchange resin 113 is started. That is, water is supplied into the main water passage 101 from the outside of the water purifier 1. The water supplied into the main water passage 101 is discharged to the outside of the water purifier 1 through the third drainage passage 108. In this way, water that does not contain salt is supplied into the water passage through which the saline has passed, and the water passage is cleaned. The water used for the cleaning flows in the direction indicated by the arrow D in FIG. 1 and is discharged to the outside of the water purifier 1.

  After the cleaning is sufficiently performed, the control unit 131 transmits control signals to the electromagnetic valve A201, the electromagnetic valve C203, the electromagnetic valve E205, and the electromagnetic valve G207 to control these electromagnetic valves to be closed. In this way, the ion exchange resin regeneration process is completed.

  The embodiment disclosed above should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above embodiments but by the scope of claims, and includes all modifications and variations within the meaning and scope equivalent to the scope of claims.

DESCRIPTION OF SYMBOLS 1: Water purifier, 114: Micro filter, 131: Control part, 150: Pump, 160: Operation part, 170: Notification part, 201: Solenoid valve A, 203: Solenoid valve C, 204: Solenoid valve D, 205: Solenoid Valves E, 206: Solenoid valve F, 209: Solenoid valve I, 301: Dedicated tank for cleaning.

Claims (5)

A filter medium that passes the raw water and purifies it,
A water reservoir for storing water for washing the filter medium;
A first supply unit for supplying water to the water storage unit;
A second supply unit for supplying water stored in the water storage unit to the filter medium;
Determining whether it is time to wash the filter medium, and comprising a control unit for controlling the first supply unit and the second supply unit,
When the control unit determines that it is time to clean the filter medium, the control unit supplies water to the filter medium by the second supply unit after supplying water to the water storage unit by the first supply unit. When it is not determined that it is time to wash the filter medium, the first supply unit and the second supply unit are not supplied to the water storage unit by the first supply unit. A water purifier configured to control the supply section.   The control unit calculates a remaining period of the filter medium that can be used, and determines that it is time to wash the filter medium when the remaining period of the filter medium that is usable is equal to or less than a predetermined value. The water purifier according to claim 1, which is configured. A selection unit for the user to select to perform the cleaning of the filter medium;
2. The control unit according to claim 1, wherein the control unit is configured to determine that it is time to clean the filter medium when the user selects cleaning the filter medium through the selection unit. Water purifier. The controller is configured to calculate a remaining usable period of the filter medium;
Further comprising a notifying unit for notifying the user that the remainder of the usable period of the filter medium is a predetermined value or less,
The control unit is configured to supply the water to the water storage unit by the first supply unit when the remaining usable period of the filter medium is equal to or less than a predetermined value, and then to use the filter medium. The water purifier of Claim 3 which controls the said alerting | reporting part so that the said alerting | reporting part alert | reports to a user that the remainder of below is below a predetermined value. The water purifier according to any one of claims 1 to 4, wherein the first supply unit is configured to supply water that has passed through the filter medium to the water storage unit.

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