KR101212292B1 - Water softening apparatus - Google Patents

Abstract

The present invention relates to a softening device capable of further increasing the treatment flow rate.

The water softener according to the present invention includes a plate-shaped net electrode in which a plurality of through holes are formed to allow a material in an ionic state to pass therethrough, and the net electrodes are spaced apart from each other and a pair of first nets to which a positive pole power is applied. Including an electrode and a pair of second net electrodes spaced apart from each other and to which a negative pole power is applied, the substances in the anion state move into the space between the first net electrodes and are discharged with water and are in the cation state. Are moved to the space between the second net electrodes and are discharged together with water to generate soft water, so that the ions are not adsorbed on the electrode and thus do not need to be regenerated, thereby increasing the processing capacity of the softening device. It is effective.

Description

Water softener {WATER SOFTENING APPARATUS}

1 is a schematic diagram schematically showing a water softener according to a first embodiment of the present invention.

2 is a schematic view showing a water softener according to a second embodiment of the present invention.

3 is a schematic view schematically showing a softening apparatus according to a third embodiment of the present invention.

4 is a schematic view showing a water softener according to a fourth embodiment of the present invention.

5 is a view showing the operation principle of the softening apparatus according to the fourth embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

10: chamber 10a: inlet port

10b: first outlet 10c: second outlet

10d: soft water outlet 11: first net electrode

12: second net electrode 11a, 11b: through hole

The present invention relates to a softening apparatus, and more particularly, to a softening apparatus capable of increasing processing capacity.

The water softener is a device that converts the properties of water by reducing ions such as Ca ²⁺ , Mg ²⁺ , Fe ³⁺ , and Al ³⁺ , which are materials of hard water, which are contained in the water. There is a capacitive deionization method.

Capacitor deionization softening device is applied to apply a voltage to the porous electrode so that the ionized material having electrical properties to be adsorbed to the porous electrode to remove the water-based material in the ionic state contained in the water.

By the way, such a capacitive deionization type water softener is deteriorated in the ion adsorption capacity of the porous electrode after a predetermined amount of ions are adsorbed on the porous electrode. Therefore, the power supply to the porous electrode must be cut off or the reverse polarity must be applied to periodically regenerate the water to discharge the water with the water in the ionic state adsorbed on the porous electrode. There is a problem that there is no choice but to.

The present invention is to solve the above problems of the prior art, an object of the present invention to provide a softening device that can further increase the processing capacity by not undergoing a regeneration operation.

The softening apparatus according to the present invention for achieving the above object comprises a plate-shaped net electrode formed with a plurality of through holes so that the material in the ionic state can pass through, the net electrode is disposed spaced apart from each other and the positive pole power source is And a pair of first net electrodes to be applied, and a pair of second net electrodes spaced apart from each other and to which a negative pole power is applied.

The apparatus may further include a chamber in which a flow path is formed to allow water to flow from the upper side to the lower side, wherein the pair of first net electrodes are disposed on one side and the pair of second net electrodes are disposed on the other side. An inlet for introducing water is provided at an upper portion of the chamber, and a lower portion of the chamber is disposed at a lower side of the space between the first outlet and the pair of second net electrodes formed below the space between the pair of first net electrodes. And a second outlet formed therein, and a soft water outlet formed below a space between the pair of first net electrodes and the pair of second net electrodes.

In addition, a first base electrode formed in a plate shape in a space between the pair of first net electrodes and to which a positive pole power is applied is spaced apart from the first net electrodes, and the pair of second nets The second base electrode is formed in a plate shape in the space between the electrodes and the negative electrode power is applied to be spaced apart from the second net electrodes.

In addition, the first net electrode and the second net electrode is characterized in that a plurality of pairs are each arranged alternately arranged one by one.

In addition, the water softener according to the present invention is formed in a plate shape formed with a plurality of transmission holes so that the material in the ionic state can be spaced apart from each other and comprises a plurality of net electrodes, the plurality of net electrodes located on one side From the net electrode to the net electrode located on the other side it is characterized in that the application of the positive pole power sequentially, the negative pole power applied and the power is cut in turn.

In addition, the flow path is formed so that the water flows from the top to the bottom and further includes a chamber in which the plurality of net electrodes are arranged to be spaced apart from each other in the side, the upper portion of the chamber is provided with an inlet through which water is introduced And a soft water discharge port through which the softened water is discharged on one lower side of the chamber, and a first discharge port through which water containing a large amount of anion and cationic material is discharged is provided on the other lower part of the chamber. Between the outlet and the first outlet is characterized in that a second outlet for discharging water containing a small amount of anion and cationic material is provided.

Hereinafter, a softening apparatus according to a first embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the water softener according to the present invention has a chamber 10 in which water flows through the water from the top to the bottom thereof, and is formed in a plate shape extending vertically and long in an ionic state. It includes a net electrode (11, 12) is formed with a plurality of through holes (11a, 12a) to pass through the phosphorus material.

The chamber 10 is formed with an inlet 10a through which water is introduced, and outlets 10b, 10c, and 10d through which water is discharged from the lower side, and the net electrodes 11 and 12 are formed of the chamber 10. A pair of the first net electrode 11 to which the positive pole (+) power is applied and spaced apart from each other on one side of the inner side of the chamber 10 and the negative pole (-) power to the other side of the chamber 10 And a pair of second net electrodes 12. At this time, the through hole 11a provided in the first net electrode 11 is called the first through hole 11a, and the through hole 12a provided in the second net electrode 12 is referred to as the second through hole 12a. This is called.

As such, when the pair of first net electrodes 11 are disposed on one side of the chamber 10 and the pair of second net electrodes 12 are disposed on the other side of the chamber 10, the inside of the chamber 10 is disposed. The materials in the anion or cationic state passing through the spaces between the first net electrodes 11 or the second are caused by electrical attraction generated between the first net electrodes 11 or the second net electrodes 12. It moves to the space between the net electrodes 12.

Therefore, water passing through the space between the first net electrodes 11 and the space between the second net electrodes 12 passes through the space between the first net electrodes 11 and the second net electrodes 12. Soft water can be obtained by allowing the water to be discharged from the chamber 10 through different outlets 10b, 10c, and 10d.

To this end, the chamber 10 includes discharge ports 10b, 10c, and 10d, each of which includes a first discharge port 10b formed below the space between the first net electrodes 11 and a space between the second net electrodes 12. The second outlet 10c formed at the lower side and the soft water outlet 10d formed at the lower side of the space between the first net electrodes 11 and the second net electrodes 12 are included. Accordingly, the anion-like material introduced into the space between the first net electrodes 11 through the first through hole 11a is discharged through the first outlet 10b together with the water and the second through hole 12a. C) material introduced into the space between the second net electrodes 12 is discharged through the second outlet 10c together with water, and the first net electrode is removed from the anion and cation materials. 11) and the water in the space between the second net electrode 12 becomes soft water and is discharged to the soft water discharge port (10d) can be obtained soft water.

In the present embodiment, the water softener includes only a pair of first net electrodes 11 and a pair of second net electrodes 12, but the present invention is not limited thereto and is disclosed as a second embodiment of the present invention in FIG. As shown, a first base electrode 23 formed in a plate shape in a space between the pair of first net electrodes 21 and to which a positive pole power is applied is spaced apart from the first net electrodes 21. And a second base electrode 24 formed in a plate shape in a space between the pair of second net electrodes 22 and to which a negative pole power is applied, thereby providing an anion state with the first base electrode 23. Due to the electrical attractive force acting between the materials, the materials in the anion state are more easily introduced into the space between the first net electrodes 21 through the first transmission hole 21a and the second base electrode 24 and the second base electrode 24. Due to the electrical attraction between the materials in the cationic state It is also possible to allow the substances in the sea cation state to more easily flow into the space between the second net electrodes 22 through the second transmission hole 22a.

In addition, in the present embodiment, the water softener includes a pair of first net electrodes 11 and a pair of second net electrodes 12, but is not limited thereto. As shown in the figure, a plurality of pairs of first net electrodes 31 and a plurality of pairs of second net electrodes 32 may be alternately arranged one by one, thereby making it possible to soften a large amount of water.

Hereinafter, a softening apparatus according to a fourth embodiment of the present invention will be described in detail with reference to the drawings.

In the water softener according to the fourth embodiment of the present invention, as shown in FIG. 4, a plurality of nets are provided with a plurality of permeation holes 41a to allow a substance in an ionic state to pass through the chamber 40 through which water passes. The electrode 41 is arranged.

The chamber 40 is formed with an inlet 40a through which water flows in the upper side, and outlets 40b, 40c, and 40d through which water is discharged in the lower side. The plurality of net electrodes 41 are formed to extend up and down, respectively. It is arranged to be spaced apart from each other by a predetermined distance to the side to guide the water from the upper side to the lower side while the ion state material can be moved to the side through the through hole (41a).

In addition, as illustrated in FIG. 5, the net electrodes 41 are sequentially supplied with positive pole power, negative pole power, and power off as the time T1, T2, T3, T4, T5 progresses. It is to be made, in order to be made from the net electrode 41 located on one side to the net electrode 41 located on the other side. In this embodiment, the positive pole power supply, the negative pole power supply, and the power interruption are made in order from the net electrode 41 located on the left side to the net electrode 41 located on the right side based on the drawing.

As described above, when the net electrode 41 to which the positive pole power is applied, the net electrode 41 to which the negative pole power is applied, and the net electrode 41 to which the power is cut off are sequentially changed from one side to the other side, the materials are in a cation state. Since the substances in the anion state are gradually moved from one side of the inside of the chamber 40 to the other side through the through hole 41a, the water located in the lower one side of the chamber 40 is removed with most of the ionic substance. The water located at the other bottom of the chamber 40 includes a large amount of anionic and cationic materials, and the water located at the bottom central side of the chamber 40 includes a small amount of materials in anionic and cationic states.

Accordingly, the water at one lower side of the chamber 40, the water at the other lower side of the chamber 40, and the water at the lower center side of the chamber 40 are discharged through different outlets 40b, 40c, and 40d. By doing so, the number of years can be obtained.

To this end, the lower one side of the chamber 40 is provided with a soft water discharge port 40d for discharging water from the lower one side of the chamber 40, and the lower side of the chamber 40 has a large amount of positive and negative ions. A first outlet 40b through which the included water is discharged is provided, and a second outlet 40c through which water containing a small amount of a substance in a cation and anion state is discharged from the lower center side of the chamber 40 to provide a soft water outlet 40d. The soft water can be obtained by discharging the soft water collected at the lower one side of the chamber 40 through).

As described in detail above, the water softener according to the present invention includes a pair of first net electrodes to which a positive pole power is applied and a pair of second net electrodes to which a negative pole power is applied, Ion substances are adsorbed on the electrodes because they move to the spaces between the first net electrodes and are discharged together with water, and the positively charged substances are moved to the spaces between the second net electrodes and are discharged together with water to produce soft water. There is no need to perform a regeneration operation, thereby increasing the processing capacity of the water softener.

Claims (6)

It includes a plate-shaped net electrode formed with a plurality of transmission holes so that the material in the ionic state can pass through, The net electrode may include a pair of first net electrodes spaced apart from each other and to which positive pole power is applied, and a pair of second net electrodes spaced apart from each other and to which negative pole power is applied. Device. The method of claim 1, A flow path is formed to allow water to flow from the top to the bottom and further comprises a chamber in which the pair of first net electrode is disposed on one side and the pair of second net electrode is disposed on the other side, An upper portion of the chamber is provided with an inlet for inflow of water, and a lower portion of the chamber has a space between the first outlet and the pair of second net electrodes formed below the space between the pair of first net electrodes. And a soft water outlet formed in a lower portion of the space between the pair of first net electrodes and the pair of second net electrodes. The method of claim 1, A first base electrode formed in a plate shape in the space between the pair of first net electrodes and to which a plus pole power is applied is spaced apart from the first net electrodes, and the pair of second net electrodes And a second base electrode formed in a plate shape in the space therebetween and spaced apart from the second net electrodes. The method of claim 1, And a plurality of pairs of the first net electrodes and the second net electrodes, respectively. It is formed in the shape of a plate formed with a plurality of transmission holes so that the material in the ionic state can be spaced apart from each other to include a plurality of net electrodes, And a plurality of net electrodes are sequentially supplied with positive pole power, negative pole power applied, and power cut off from the net electrode located on one side to the net electrode located on the other side. The method of claim 1, A flow path is formed to allow water to flow from the top to the bottom, and a plurality of the first net electrode and the second net electrode is provided therein, And a plurality of chambers in which the plurality of first net electrodes and the plurality of second net electrodes are alternately arranged in pairs and spaced apart from each other laterally. An upper portion of the chamber is provided with an inlet through which water is introduced, and a softened water outlet for discharging the softened water is provided at one side of the lower side of the chamber. And a second outlet for discharging water containing a small amount of anion and cationic material is provided between the soft outlet and the first outlet.

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