JP3846536B2 - Ion remover - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an ion removing device that removes ionic substances in water by using an electrostatic force.
[0002]
[Prior art]
Electric water such as humidifiers, washing machines, dishwashers, and water purifiers uses tap water, well water, and rainwater. These waters contain cations such as calcium ions and magnesium ions, anions such as chlorine ions, and charged silica. Thereby, in a humidifier, since a cation and a silica adhere as a scale to a water vapor generation part, the generation amount of water vapor decreases and the humidification capacity decreases. In addition, scales such as calcium and magnesium are released from the water vapor generating part and scattered in the room, causing a problem that the room is contaminated with white powder.
[0003]
In a washing machine, ionic substances in water reduce the effectiveness of detergent surfactants, thereby causing a problem that the washing efficiency of the laundry is lowered.
Furthermore, in the dishwasher, moisture adhering to the tableware after washing is dried, and the above-mentioned ionic substances and the like are fixed as scales on the surface of the tableware, which may be unsanitary. In the case of a mineral water generator, since the balance of ions affects the taste, it is desirable to provide a mechanism for controlling the amount of ionic substances.
[0004]
In order to solve the above-mentioned problems, ionic substances in water can be removed by an electrodialysis ion removal apparatus using an ion exchange membrane or an ion exchange resin. FIG. 13 is a cross-sectional view showing an ion removal apparatus for electrodialysis of an ion exchange membrane disposed in a water path of a humidifier disclosed in, for example, JP-A-7-301441.
[0005]
In FIG. 13, 1 is a rectangular parallelepiped case, 2 is a water inlet portion formed on one side of the case 1, 3 is a water outlet portion formed on the other side of the case 1, and 4 is above and below the water outlet portion 3. Each of the waste liquid outlet portions 5 is a flat negative collector disposed in the longitudinal direction of the upper portion of the case 1, 6 is a negative lead wire connected to the upper portion of the negative collector 5, 7 Is a flat positive collector disposed in the lower part of the case 1 in the longitudinal direction, 8 is a positive lead connected to the lower part of the positive collector 7, and 9 is between these collectors. A belt-like cation exchange membrane 10 provided at a position in the vicinity of the negative-side collector electrode 5 is a belt-like anion exchange membrane provided between these collector electrodes and in the vicinity of the positive-side collector electrode 7. . Both the exchange membranes are arranged so as to be parallel to the flat electrode. Reference numeral 11 denotes a support member having water permeability that is disposed on both sides in the case 1 and contacts both end portions of both exchange membranes to support the exchange membranes. A waste liquid tank 12 is connected to the ion removing apparatus having such a configuration.
[0006]
Next, the operation of the electrodialysis ion removal apparatus having such a configuration will be described with reference to FIG. A predetermined DC voltage is applied between the negative-side collector electrode 5 and the positive-side collector electrode 6 with water flowing from the water inlet 2 of the case 1. As a result, the cationic substance in water is attracted to the negative collector electrode 5 and the anionic substance is attracted to the positive collector electrode 7 by electrostatic force action. A part of the cation material flowing between the cation exchange membrane 9 having the function of allowing only the cation material to pass through and the anion exchange membrane 10 having the function of allowing only the anion material to pass through the cation exchange membrane 9 is passed. And sucked by the negative-side collector electrode 5. In addition, a part of the negative ion substance in the portion passes through the anion exchange membrane 10 and is attracted to the positive collector 6. Therefore, almost all ionic substances in the water existing between the cation exchange membrane 9 and the anion exchange membrane 10 are removed. The water from which ions have been removed by such an operation passes through the water outlet 3 and is stored in a water storage tank (not shown) of the humidifier. On the other hand, the ionic substance is present in a concentrated state in the water flowing between the collector electrode and the exchange membrane, and the concentrated ionic solution is discharged to the waste liquid tank 10 through the waste liquid outlet portion 4.
[0007]
[Problems to be solved by the invention]
As described above, the conventional electrodialysis ion removal apparatus removes impurities such as scales by attracting an ionic substance in water to a collecting electrode. However, the concentrated ionic solution flowing between the collecting electrode and the exchange membrane is stored in a waste liquid tank, and the user has a problem in that it is troublesome for the maintenance work of discarding the ionic solution stored in the tank every time.
[0008]
This invention removes ionic substances in water with an ion removing device to prevent the generation of scales, and also adds desorption means for periodically detaching ionic substances deposited on the electrodes to improve the ability to remove ions in water. The purpose is to maintain improvement. In addition, there is an advantage that the operation of discharging water containing the desorbed ionic substance is very simple.
[0009]
[Means for solving the problems]
The ion removing apparatus according to the present invention is provided so as to contact the positive and negative collector electrodes and the positive and negative collector electrodes, respectively. , Have irregularities on the surface An ion removing device provided with a positive and negative porous electrode plate and a short-circuit means for electrically short-circuiting each of the positive and negative porous electrode plates, and disposed in the middle of a water supply path, the positive and negative porous electrode One of gold, platinum, palladium, and powdered activated carbon is coated on the contact surface of the plate with the positive and negative collector electrodes.
[0010]
Also, A conductive resin was filled in a non-contact state between the positive and negative porous electrode plates and the positive and negative collector electrodes. Is.
[0011]
Also, Provided with a spring that presses the positive and negative collectors against the positive and negative porous plates, respectively. Is.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Embodiment 1 FIG.
1 and 2 are sectional views showing an embodiment of the ion removing apparatus according to the present invention. 1 and 2, the same reference numerals as those in the conventional example indicate the same or corresponding parts. Reference numeral 13 denotes a negative electrode plate provided in contact with the lower surface of the flat negative collector electrode 5 disposed in the upper portion of the case 1, and reference numeral 14 denotes a flat positive collector disposed in the lower portion of the case 1. It is a positive electrode plate provided in contact with the upper surface of the electrode 7. It is preferable that the negative electrode plate 13 and the positive electrode plate 14 have, for example, a thickness of several hundred μm and a porous shape having liquid permeability.
[0014]
The electrode material of the negative electrode plate 13 and the positive electrode plate 14 is, for example, any one of activated carbon fiber, porous metal, porous conductive polymer, activated carbon, or a member in which metal fine particles are supported on a porous support. A conductor may be used. As another electrode material, any one of a porous dielectric such as barium titanate or lead zirconate titanate, or a member in which dielectric fine particles are supported on a porous support may be used. Reference numeral 15 denotes an insulating spacer disposed in the gap between the negative electrode plate 13 and the positive electrode plate 14, and 16 denotes a switch for short-circuiting the negative electrode plate 13 and the positive electrode plate 14. When the negative electrode plate 13 and the positive electrode plate 14 are conductors, the respective collector electrodes may be removed and the negative electrode lead wire 6 and the positive electrode lead wire 8 may be directly connected to each electrode plate. Further, when both the electrode plate materials are dielectrics, the insulating spacer 15 may not be provided between the electrode plates.
[0015]
For the purpose of reducing the contact resistance between the negative-side collector electrode 5 and the negative electrode plate 13 made of, for example, activated carbon fiber as much as possible to improve the ion removal performance, as shown in the enlarged view of the main part of FIG. The surface of the activated carbon fiber of the plate 13 is preliminarily coated with any of gold, platinum, palladium, powdered activated carbon (A part in the figure), and the like. Thereby, it is estimated that the pores on the surface of the activated carbon fiber are filled with those conductive substances, and the contact resistance is reduced by the electrical bridge effect. Further, as shown in FIG. 3 (b), a conductive resin is filled in a portion where the negative side collector electrode 5 and the negative electrode plate 13 of activated carbon fiber are not in contact with each other so as to reduce the contact resistance. good. Further, as shown in FIG. 3C, when the negative electrode plate 13 is made of, for example, a porous metal, a push spring 17 is provided on the negative side collector electrode 5 and the collector electrode is poled with a predetermined spring force (load). You may devise so that it may press on the board side and contact resistance may be made small. Such a configuration is also applied to the positive side collector electrode 7 and the positive electrode plate 14 side.
[0016]
Next, the operation of the underwater ion removing apparatus having such a configuration will be described with reference to FIG. After passing through the support member 11 through the water inlet 2 provided on one side of the case 1, the water flows through the negative electrode plate 13 and the positive electrode plate 14 made of, for example, activated carbon fiber, to which a DC voltage is applied. Go. At this time, negative charges are accumulated in the negative electrode plate 13, and the cationic substance in the water is attracted and adsorbed to the negative electrode plate 13 side by the electrostatic force action of the negative charges. Furthermore, positive charges accumulate on the positive electrode plate 14, and an anionic substance in the water is attracted and adsorbed to the positive electrode plate 14 side by the electrostatic force action of this positive charge. Thereafter, the water containing almost no cationic substance or anionic substance passes through the support member 11 provided on the other side of the case 1 and is discharged from the water outlet part 3.
[0017]
Here, in addition to setting the DC voltage applied between the negative electrode plate 13 and the positive electrode plate 14 to a constant voltage in advance, an ion detector is provided at the water outlet 3 of the case 1 (not shown). And the magnitude of the DC voltage may be determined based on the detected amount. The upper limit of the DC voltage is to prevent the generation of explosive hydrogen and oxygen due to water electrolysis between the electrodes, and to prevent the generation of harmful sodium hypochlorite due to oxidation of chlorine in the water. Is preferably set to several volts.
[0018]
Next, the cleaning operation of the negative electrode plate 13 and the positive electrode plate 14, that is, the desorption operation of the ionic substance that is attracted and deposited on each electrode plate will be described with reference to the sectional view of the ion removing device shown in FIG. In this operation, the application operation for applying a DC voltage between the electrode plates is stopped, and at the same time, the switch 16 connected to the electrode plate through the collector electrode is turned on. Thereby, the electric charge (electricity) accumulated in each electrode plate is lost. In such a state, when water flows in from the water inlet portion 2 of the case 1, the ionic substance deposited on each electrode plate is easily detached due to the flow of water, and it passes through the water outlet portion 3. Flow out. At this time, since no charge is accumulated in each electrode plate, the ionic substance contained in the water used at the time of cleaning is not sucked and adsorbed to the electrode plate side.
[0019]
The timing for executing the cleaning operation of each electrode plate will be described below. An ion detector is provided at the water outlet 3 of the case 1 (not shown). When the detection amount from the detector reaches a predetermined value, the concentration of ions in the water increases and impurities such as scale increase, It is judged that the ion removal performance of the plate has deteriorated. Based on the determination result, a notification operation that prompts the user to perform a cleaning operation is executed. In addition, as the execution timing of other cleaning operations, the amount of treated water of each electrode plate with respect to the ion removal capability is estimated in advance, and after that, when the flow rate and treatment time are detected and their product reaches the treated water amount, You may comprise so that the alert | report of the cleaning operation of a board may be performed.
[0020]
Further, in order to increase the processing amount of ion removal in water, an ion removal apparatus having an electrode laminated structure as shown in FIG. 4 is proposed. In FIG. 4, a plurality of negative side collector electrodes 5 and positive side collector electrodes 7 are arranged so as to be staggered from the upper part to the lower part in the case 1. And you may comprise the negative electrode plate 13 and the positive electrode plate 14 between collector electrodes, and the electric charge accumulate | stored in those electrode plates may be laminated | stacked.
[0021]
Moreover, you may arrange | position each collector electrode and each electrode plate which comprise an ion removal apparatus so that it may oppose with respect to a water flow, as shown in FIG. In the case of such an electrode arrangement configuration, the collector electrode is formed in a mesh shape so as to have water permeability. As a result, water passes through the support member 11 from the inlet 2 of the case 1 and further passes through the negative electrode plate 13 from the negative-side collector electrode 5. Thereafter, the water passes from the insulating spacer 15 through the positive electrode plate 14 and from the positive side collector electrode 7 through the water outlet 3.
[0022]
Further, as shown in the perspective view of FIG. 6, the ion removing apparatus includes a cylindrical negative electrode plate 13 and a positive electrode plate 14, and a negative-side collector electrode 5 is provided on one side peripheral edge of the negative electrode plate 13. You may make it provide the positive side collector electrode 7 in a peripheral part. Here, the case 1 is formed in a circular shape, and water inlet portions 2 are provided on both sides thereof, and a water outlet portion 3 is provided in the lower portion thereof. Further, a sealing plate 18 is provided in the upper portion of the case 1 in order to prevent water flowing from the water inlet 2 from passing through the ion removing device and ejecting upward. Further, when each electrode plate is a conductor, an insulating spacer 15 for preventing a short circuit is provided between the electrode plates. In the ion removing apparatus configured as described above, water passes from the outer peripheral portion of each electrode plate toward the inner peripheral portion, and in this process, ionic substances in the water are removed. And the water from which the ionic substance was removed is discharged outside through the water outlet 3 of the case 1.
[0023]
As described above, by applying a DC voltage between the negative electrode plate 13 and the positive electrode plate 14 and shorting the electrode plates, the ionic substances in the water can be efficiently removed and each electrode plate can be removed. It is possible to provide an ion removing apparatus that maintains the improvement of the ion removing ability by executing the cleaning operation.
[0024]
Embodiment 2. FIG.
FIG. 7 is a cross-sectional view showing an embodiment when the ion removing apparatus of the present invention is incorporated in, for example, a steam humidifier. In FIG. 7, the same reference numerals as those in the conventional example indicate the same or corresponding parts. Reference numeral 19 denotes a humidifier body, 20 denotes a water tank disposed in the humidifier body 19, and 21 denotes a cap that is detachably attached to the lower portion of the water tank 20. The cap 21 is disclosed in the first embodiment. The cylindrical ion removing device (not shown) stored is stored. Reference numeral 22 denotes an L-shaped lead wire storage holder provided on the side surface portion of the cap 21, and a plurality of lead wires drawn from each collector electrode constituting the ion removing device are stored in the storage holder 22.
[0025]
Reference numeral 23 denotes a power supply holder that is connected to face the L-shaped lead wire storage holder 22. Reference numeral 24 denotes a water tray that receives the water in the water tank 19 through a water supply valve 25 that is fixed in a state of protruding from the bottom of the cap 21. An evaporation unit 26 introduces water in the water receiving tray 24 through a pipe 27 and heats and evaporates the water with a heater (not shown). 28 is a cooling unit that cools the water vapor generated from the evaporation unit 26, and 29 is a diffusion member that vigorously diffuses the water vapor cooled by the cooling unit 28 to the outside.
[0026]
FIG. 8 is an enlarged cross-sectional view of the vicinity of the cap 21 attached to the lower part of the water tank 20. In FIG. 8, reference numeral 30 denotes a lead wire storage holder electrode portion disposed at the distal end portion of the lead wire storage holder 22, and the storage holder electrode portion 30 has a negative electrode drawn from each collector electrode constituting the ion removing device. The lead wire 6 and the positive electrode lead wire 8 are connected. Reference numeral 31 denotes a power supply holder electrode portion disposed at the tip of the power supply holder 23, and has an arrangement configuration facing the storage holder electrode portion 30. Note that the negative power supply lead 32 and the positive power supply lead 33 are drawn from the power supply holder electrode 31.
[0027]
FIG. 9A is a view showing the internal structure in the vicinity of the electrode portion 30 for the lead wire storage holder. In FIG. 9A, reference numeral 34 denotes a first negative electrode fixed to one side of the tip of the lead wire storage holder electrode portion 30, and the negative power supply lead 6 is drawn from the negative electrode 34. Reference numeral 35 denotes a first positive electrode fixed to the other side of the distal end portion of the lead wire storage holder electrode portion 30, and the positive lead wire 8 is drawn from the positive electrode 35. Then, a gap (A portion in the figure) is formed between the first negative electrode 34 and the first positive electrode 35. Reference numeral 36 denotes a push-type switch unit that short-circuits or opens the negative electrode lead wire 6 and the positive electrode lead wire 8. The switch portion 36 includes a plate-shaped switching contact 36a, a coil spring 36b that applies a spring force to the switching contact 36a, and a stopper 36c that holds the coil spring 36b.
[0028]
FIG. 9B is a diagram showing the internal structure in the vicinity of the power supply holder electrode 31. In FIG. 9B, reference numeral 37 denotes a second negative electrode fixed to one side of the distal end portion of the power supply holder electrode portion 31, and the negative power supply lead wire 32 is drawn from the negative electrode 37. Reference numeral 38 denotes a second positive electrode fixed to the other side of the tip of the power supply holder electrode 31, and the positive power supply lead 33 is drawn from the positive electrode 38. Reference numeral 39 denotes a push rod formed in a state of protruding between the second negative electrode 37 and the second positive electrode 38. The push bar 39 has a mechanism that pushes the plate-like switching contact 36a to which the spring force of the coil spring 36b is applied through a gap formed at the tip of the lead wire storage holder electrode 30. Yes. As a result, the switching contact 36a changes from the ON state to the OFF state.
[0029]
Next, the ion removal operation in water when the cylindrical ion removing device having such a configuration is incorporated in the humidifier body will be described with reference to FIG. In FIG. 8, when the water tank 20 containing water is attached to the humidifier body, a part of the water supply valve 25 (A portion in FIG. 8) disposed at the bottom of the cap 21 is the water tray 24. Is pushed by a pushing member (B portion in FIG. 8). At this time, the water in the water tank 20 is in a stacked state constituting the ion removing device, and flows through the outer peripheral portion of each cylindrical electrode plate to the inner peripheral portion. Then, water flows into the water tray 24 through the water supply valve 25 in the open state.
[0030]
At the same time, the lead wire storage holder electrode 30 at the tip of the lead wire storage holder 22 provided on the side surface of the cap 21 and the power supply holder electrode 31 at the tip of the power supply holder 23 are connected, and The switch portion 36 provided in the lead wire storage holder 22 is turned off. Therefore, a DC voltage is applied from the power supply holder 23 to each electrode plate of the ion removing device via the lead wire storage holder 22. As a result, the ionic substance in the water that has flowed out of the water tank 20 is sucked and adsorbed to each electrode plate, and the water containing almost no ionic substance is guided to the water receiving tray 24. Then, the water in the water tray 24 is vaporized in a predetermined operation path and diffused to the outside.
[0031]
Next, the cleaning operation of each electrode plate of the ion removing apparatus will be described below. When the water tank 20 is removed from the humidifier body 19, a part of the water supply valve 25 (A part in FIG. 8) provided at the bottom of the cap 21 is a pushing member of the water tray 24 (B part in FIG. 8). Therefore, the water supply valve 25 is closed. At the same time, the lead wire storage holder 22 and the power supply holder 23 are disconnected from each other, and the switch portion 36 provided in the lead wire storage holder 21 is turned on. As a result, no DC voltage is applied to each electrode plate of the ion removing device, and the negative electrode plate 13 and the positive electrode plate 14 are short-circuited.
[0032]
Thereafter, the cap 21 is removed from the water tank 20, and the cleaning adapter 40 is mounted so as to engage with the outer peripheral portion of the water supply valve 25 provided at the bottom of the cap 21 as shown in the sectional view of FIG. The cleaning adapter 40 includes a ring-shaped support member 40a that is engaged with the outer peripheral portion of the water supply valve 25, and an L-shaped push member 40b that is formed on the inner peripheral surface of the support member 40a.
[0033]
When the cleaning adapter 40 is attached to the cap 21, a part of the water supply valve 25 (A portion in FIG. 10) is pushed by the L-shaped pushing member 40b of the adapter 40, so that the water supply valve 25 is opened. It becomes a valve state. Next, for example, tap water is allowed to flow from the outer peripheral portion of each cylindrical electrode plate to the inner peripheral portion through the inlet portion 2 of the case 1, and the water discharged from the inner peripheral portion is allowed to pass through the water supply valve 25 in a valve-opened state. To the outside. In this process, the ionic substance adsorbed on each electrode plate is easily desorbed by the flow of tap water.
[0034]
Further, the ion removing device may be provided inside the water receiving tray 24 in addition to being stored inside the cap 21, or may be provided inside the pipe 27 interposed between the water receiving tray 24 and the evaporation unit 26.
[0035]
In addition to incorporating the above-mentioned ion removing apparatus into a humidifier having a system in which water is heated and evaporated by a heater, for example, a system in which water is generated into a fine mist by an ultrasonic element and sprayed, or water is vaporized by an air flow. You may make it incorporate in the humidifier which has a system to make it.
[0036]
As described above, the ion removing device is housed in the cap 21 provided in the lower part of the water tank 20, and the water tank 20 is attached to the humidifier body, whereby the ionic substances in the water can be efficiently removed. Also, by removing the water tank 20 from the humidifier body 19 and washing the ion removing device in the cap 21 with water, the ionic substance adsorbed on each electrode plate can be easily desorbed and the cleaning operation can be executed. .
[0037]
Embodiment 3
FIG. 11 is a cross-sectional view showing an embodiment when the ion removing device of the present invention is incorporated in a mineral water generator. In FIG. 11, the same reference numerals as those in the first and second embodiments denote the same or corresponding parts. 41 is a mineral water generator main body, 42 is a pre-filter which is disposed below the mineral water generator main body 41 and captures coarse debris in the water flowing in from the inlet pipe 43. For example, activated carbon particles or hollow fibers It is composed of a film. Reference numeral 44 denotes, for example, a laminated plate-type ion removing device or a cylindrical ion removing device disclosed in the first embodiment, which is arranged in the upper part of the prefilter 42. 1, 46 is a mineral component release device disposed at the top of the ion removal device 44, 47 is a first electromagnetic valve disposed between the ion removal device 44 and the mineral component release device 46, 48 is A second pipe 49 extending from the output portion of the first electromagnetic valve 47 is a third pipe connected to the upper part of the mineral component release device 46.
[0038]
The mineral component release device 46 is filled with barleystone, and the amount of elution of ionic substances such as calcium, magnesium, and sodium increases as the amount of water increases. A voltage supply switching circuit 50 is configured to apply a DC voltage between the electrodes constituting the ion removing device 44 or to short-circuit them without applying a DC voltage between the electrodes. The operation content of the voltage supply switching circuit 50 is set by the changeover switch 51.
[0039]
Next, the operation of the mineral water generator will be described with reference to FIG. In this operation, the voltage supply switching circuit 50 is operated by setting the changeover switch 51, and a DC voltage is applied between the electrode plates of the ion removing device 44. At this time, the first electromagnetic valve 47 is in an OFF state. And water flows in from the water intake pipe 43 and passes through the pre-filter 42, whereby dust, bacteria, etc. having a size of 1 to 100 microns in water are captured. When the pre-filter 42 is made of activated carbon, it is possible to remove harmful organic substances such as trihalomethane and simazine contained in the water, and further, malodorous substances such as a chalk component. Next, the water filtered by the prefilter 42 flows into the ion removing device 44 through the first pipe 45. Then, water that contains almost no ionic substance discharged from the ion removing device 44 passes through the OUT1 side from the IN side of the first electromagnetic valve 47 and flows into the mineral component releasing device 46. Thereafter, the mineral component release device 46 adds mineral components such as calcium ions, magnesium ions, and sodium ions to the ion-removed water so that the concentration of the predetermined mineral components is obtained. And the mineral water produced | generated with the mineral component removal device 46 is discharge | released outside the water purifier main body 41 through the 3rd piping 49. FIG.
[0040]
Next, the cleaning operation of each electrode plate constituting the ion removing device 44 will be described. In this operation, the voltage supply switching circuit 50 is operated according to the setting of the changeover switch 51, and the electrode plates are short-circuited without applying a DC voltage between the electrode plates of the ion removing device 44. At this time, the first electromagnetic valve 47 is in the ON state. Then, water flows from the prefilter 42 into the ion removing device 44 through the first pipe 45. Thereafter, water containing ionic substances desorbed from each electrode plate discharged from the ion removing device 44 passes through the OUT2 side from the IN side of the first electromagnetic valve 47 and passes through the second pipe 48 to the water purifier main body 41. Is discharged outside.
[0041]
In addition, the ion removing device 44 is detachably attached to the mineral water generator main body 41, and in conjunction with this attaching / detaching operation, an operation for removing ionic substances in water and a cleaning operation for positive and negative electrodes are performed. Also good.
[0042]
As described above, the mineral water generator main body 41 is provided with the ion removing device 44 to remove ionic substances in the water, and then configured to add a predetermined amount of mineral components to the ion-removed water. We can provide water purifiers that produce delicious water. Further, by adding a cleaning means for each electrode plate constituting the ion removing device 44, the ion removing ability can be improved.
[0043]
Embodiment 4 FIG.
FIG. 12 is a cross-sectional view showing an embodiment when the ion removing device of the present invention is incorporated in a washing machine. In FIG. 12, the same reference numerals as those in the first to third embodiments denote the same or corresponding parts. 52 is a top cover of the washing machine storing the ion removing device 44 disclosed in the first embodiment, 53 is a fourth pipe connected to the lower part of the ion removing device 44 stored in the top cover 52, and 54 is an ion. The IN side of the second electromagnetic valve 55 is connected to the tip of the fifth pipe connected to the upper portion of the removing device 44. A sixth pipe 56 is connected to the OUT1 side of the second electromagnetic valve 55, and a seventh pipe 57 is connected to the OUT2 side of the electromagnetic valve 55. Here, the tip end portion of the sixth pipe 56 extends through the lower portion of the top cover 52 to the washing and dewatering tub (not shown) side. Further, the distal end portion of the seventh pipe 57 extends outside the washing machine main body (not shown).
[0044]
Next, the operation of removing ions in water when the ion removing device 44 is incorporated in a washing machine will be described with reference to FIG. A power switch (not shown) of the washing machine is turned on so that a DC voltage is applied to each electrode plate of the ion removing device 44. At this time, the second electromagnetic valve 55 is in an OFF state. And tap water flows into the ion removal apparatus 44 through the 4th piping 53 from the water supply valve for washing machines (not shown) in the valve open state. Therefore, calcium, magnesium, and the like, which are ionic substances in water, are almost removed. Thereafter, water not containing an ionic substance passes through the fifth pipe 54 from the IN side of the second electromagnetic valve 55 to the OUT1 side, and flows into the washing and dewatering tub side through the sixth pipe 56. Thereby, when the laundry is washed using the water in the washing and dewatering tank, the effectiveness of the surfactant contained in the detergent is not lowered, and the washing efficiency is improved.
[0045]
Next, the cleaning operation of each electrode plate constituting the ion removing device 44 will be described. A cleaning switch (not shown) provided on the back cover 52 is turned on, and the electrode plates are set to be short-circuited without applying a DC voltage between the electrode plates of the ion removing device 44. At this time, the second electromagnetic valve 55 is in the ON state. And tap water flows into the ion removal apparatus 44 through the 4th piping 53 from the water supply valve for washing machines in the valve open state. Thereafter, the water containing the ionic material desorbed from each electrode plate constituting the ion removing device 44 passes through the fifth pipe 54 from the IN side of the second electromagnetic valve 55 to the OUT2 side, and the seventh pipe. It is discharged to the outside of the washing machine main body through 57.
[0046]
In addition to storing the ion removing device 44 in the top cover 52 as described above, that is, in addition to performing an operation of removing tap water ion substances and cleaning of each electrode plate, the ion removing device 44 is installed. The top cover 52 may be detachably attached, and in conjunction with the attachment / detachment operation, an operation for removing ionic substances in water and a cleaning operation for positive and negative electrode plates may be executed.
[0047]
As described above, when the ion removing device 44 is incorporated in the washing machine main body to produce water containing almost no ionic substances, and the laundry is washed with the water, the effectiveness of the surfactant contained in the detergent is reduced. The washing efficiency for the laundry can be improved.
[0048]
In addition to using the ion removing apparatus disclosed in the first embodiment for the humidifier, the mineral water generator, and the electric device of the washing machine, for example, it is provided in the water supply path of a dishwasher or a water purifier, and a direct current is provided between the plates. You may comprise so that a voltage may be applied or between electrode plates may be short-circuited.
[0049]
【The invention's effect】
Since the present invention is configured as described above, the following effects can be obtained.
[0050]
The ion removing apparatus according to the present invention is provided so as to contact the positive and negative collector electrodes and the positive and negative collector electrodes, respectively. , Have irregularities on the surface An ion removing apparatus provided with a positive and negative porous electrode plate and a short-circuit means for electrically short-circuiting each of the positive and negative porous electrode plates, and disposed in the middle of a water supply path, the positive and negative porous plate Since the contact surface of the electrode plate with the positive and negative collector electrodes is coated with gold, platinum, palladium, or powdered activated carbon, the contact resistance between the negative collector electrode and the negative electrode plate and the positive electrode Ion removal performance can be improved by reducing the contact resistance between the collector electrode and the positive electrode plate as much as possible. For example, an ion removal device is housed in a cap provided in the lower part of the water tank of the humidifier, and the water tank is humidified. By attaching to the vessel body, ionic substances in water can be efficiently removed. Further, by removing the water tank from the humidifier body and washing the ion removing device in the cap with water, the ionic substance adsorbed on each electrode plate is desorbed, and the cleaning operation can be executed.
[0051]
Also, the positive and negative collector electrodes and the positive and negative collector electrodes are provided in contact with each other. , Have irregularities on the surface An ion removing apparatus provided with a positive and negative porous electrode plate and a short-circuit means for electrically short-circuiting each of the positive and negative porous electrode plates, and disposed in the middle of a water supply path, the positive and negative porous plate Since a conductive resin is filled in a portion of the electrode plate that is in a non-contact state with the positive and negative collector electrodes, the contact resistance between the negative collector electrode and the negative electrode plate, and the positive collector electrode and the positive electrode plate The ion removal performance can be improved by making the contact resistance with the smallest possible.
[0052]
Also, the positive and negative collector electrodes and the positive and negative collector electrodes are provided in contact with each other. , Have irregularities on the surface An ion removing apparatus provided with a positive and negative porous electrode plate and a short-circuit means for electrically short-circuiting between each of the positive and negative porous electrode plates, disposed in the middle of a water supply path, the positive side and the negative side Since there is a pressing spring that presses the collector electrode on each side against the positive and negative porous plates, the contact resistance between the negative collector electrode and the negative electrode plate and the contact resistance between the positive collector electrode and the positive plate are as much as possible. The ion removal performance can be enhanced by reducing the size.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing a flat plate type ion removing apparatus at the time of removing ions according to Embodiment 1. FIG.
2 is a cross-sectional view showing a flat plate type ion removing apparatus during electrode cleaning according to Embodiment 1. FIG.
FIG. 3 is a cross-sectional view of a main part of the ion removing apparatus according to Embodiment 1.
FIG. 4 is a cross-sectional view showing a flat plate type ion removing apparatus for removing ions according to the first embodiment.
5 is a cross-sectional view showing another ion removing apparatus according to Embodiment 1. FIG.
6 is a cross-sectional view showing a cylindrical ion removing device according to Embodiment 1. FIG.
FIG. 7 is a cross-sectional view showing a humidifier with an ion removing device according to a second embodiment.
FIG. 8 is a cross-sectional view of the inside of a cap of a water tank for a humidifier according to a second embodiment.
FIG. 9 is a cross-sectional view of a main part of one component provided in a cap portion of a water tank according to a second embodiment.
FIG. 10 is a cross-sectional view showing a state in which components are attached to the cap portion of the water tank according to the second embodiment.
FIG. 11 is a cross-sectional view showing a mineral water generator with an ion removing device according to a third embodiment.
12 is a block diagram showing the inside of a back panel of a washing machine with an ion removing device according to Embodiment 4. FIG.
FIG. 13 is a cross-sectional view showing a conventional ion removing apparatus.
[Explanation of symbols]
1 case, 2 water inlet, 3 water outlet, 4 waste outlet, 5 negative collector, 6 negative lead, 7 positive collector, 8 positive lead, 9 strip cation exchange membrane, 10 strip Anion exchange membrane, 11 Support member, 12 Waste liquid tank, 13 Negative electrode plate, 14 Positive electrode plate, 15 Insulating spacer, 16 Short circuit switch, 17 Push spring, 18 Sealing plate, 19 Humidifier body, 20 Water tank, 21 Cap, 22 Lead wire storage holder, 23 Power supply holder, 24 Water tray, 25 Water supply valve, 26 Evaporating section, 27 Piping, 28 Cooling section, 29 Diffusion member, 30 Lead wire storage holder electrode section, 31 Power supply holder electrode section, 34 1st negative electrode, 35 1st positive electrode, 36 Switch part, 37 2nd negative electrode, 38 2nd positive electrode, 39 Push rod, 40 Cleaning adapter, 41 Neral water generator, 42 Pre-filter, 43 Water inlet pipe, 44 Ion removal device, 45 First piping, 46 Mineral component release device, 47 First solenoid valve, 48 Second solenoid valve, 49 Third piping , 50 voltage supply switching circuit, 51 changeover switch, 52 top cover, 53 fourth piping, 54 fifth piping, 55 second solenoid valve, 56 sixth piping, 57 seventh piping.

Claims (3)

Positive and negative collector electrodes, positive and negative porous plates having uneven portions on the surface, which are provided so as to be in contact with the positive and negative collector electrodes, and the positive and negative porous electrodes A short-circuit means for electrically short-circuiting between the plates, and an ion removing device disposed in the middle of the water supply path, wherein the positive and negative porous plates are in contact with the positive and negative collector electrodes. An ion removing apparatus characterized in that the surface is coated with gold, platinum, palladium, or powdered activated carbon. Positive and negative collector electrodes, positive and negative porous plates having uneven portions on the surface, which are provided so as to be in contact with the positive and negative collector electrodes, and the positive and negative porous electrodes An ion removing device disposed in the middle of the water supply path, wherein the positive and negative porous electrode plates are not connected to the positive and negative collector electrodes. An ion removing apparatus characterized in that a conductive resin is filled in a contact state. Positive and negative collector electrodes, positive and negative porous plates having uneven portions on the surface, which are provided so as to be in contact with the positive and negative collector electrodes, and the positive and negative porous electrodes An ion removing device that is disposed in the middle of the water supply path, and that presses the positive and negative collector electrodes against the positive and negative porous plates, respectively. An ion removing apparatus comprising a pressing spring.

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