KR20110078158A - Effective electrolysis method of seawater - Google Patents

Abstract

PURPOSE: A method for electrolyzing seawater is provided to prevent the formation of scales on electrodes by eliminating metal components forming the scales during a seawater electrolyzing process. CONSTITUTION: A reverse osmosis process and a capacitive deionizing process are successively implemented with respect to seawater in order to eliminate metal components including magnesium and calcium from the seawater before the seawater is introduced into an electrolyzing bath(20). Micro bubbles are added to the seawater through the capacitive deionizing process. A manganese oxide electrode is arranged in the electrolyzing bath.

Description

Effective Electrolysis Method of Seawater

The present invention relates to an efficient method of electrolyzing seawater in which scale formation on the electrode is prevented. More specifically, the present invention relates to an efficient electrolysis method of seawater in which the formation of scale at the electrode is prevented by removing the metal component forming the scale at the electrode during electrolysis of seawater by pretreatment.

Due to the electrolysis of seawater, oxygen and chlorine gas are generated at the anode of the electrolytic cell and hydrogen is generated at the cathode. Oxygen, chlorine and hydrogen generated at the anode and cathode are useful in various industries.

Specifically, during electrolysis of seawater, oxygen and chlorine gas are generated at the anode and hydrogen at the cathode by the following reactions at the anode and cathode. That is, in the cathode, hydrogen and OH ^- ions are generated from water, OH ^- ions pass through the diaphragm in the electrolytic cell to the anode, and water and oxygen are produced at the anode.

(anode)

2Cl ^- → Cl ₂ + 2e ^-

Cl ₂ + H ₂ O ↔ HCl + HClO

_{H 2 O → 1/2 O 2 ↑} + 2H + + 2e -

(cathode)

^{_{2H 2 O + 2e - → H}} 2 ↑ + 2OH -

Na ^{+ +} e ^- → Na

Na + H ₂ O → NaOH + 1/2 H ₂

However, seawater contains a large amount of magnesium, sulfur, calcium, etc. in addition to chlorine and sodium, and these react with the hydroxide ions generated at the cathode to form metal hydroxides. Such metal hydroxides (scales) adhere to and / or precipitate on the surface of the cathode electrode, thereby degrading the performance of the electrolytic cell. Among the metal components forming these scales, in particular, a scale containing magnesium (Mg) and calcium (Ca) is precipitated. Due to the formation of such scales, in particular, the lifetime and the electrolytic efficiency of the electrode are not only reduced, but when these scales are precipitated, the voltage for flowing a constant current in the electrolysis increases, thereby lowering the efficiency of the electrolyzer and increasing the amount of electric energy used. The stability of the electrolyzer is also a problem because it increases the weight and affects the spacing between the electrodes. Thus, the amount of gas produced at the anode and cathode is also lowered.

In addition, due to the generation of these scales, the electrolyzer is shut down and, in severe cases, expensive electrodes need to be replaced or repaired. Therefore, prior to electrolysis of seawater, it is desirable to remove scale forming substances in seawater in advance.

In one embodiment, the present invention provides a method for electrolyzing seawater, which removes metal components in seawater, which is the cause of formation of the scale in advance.

In another embodiment, the present invention provides a method of electrolyzing seawater, in which scale formation at an electrode is prevented.

In another embodiment, the present invention provides a method of electrolyzing seawater in which hydrogen, oxygen, and chlorine gas are stably and efficiently obtained.

Furthermore, in another embodiment, the present invention provides a method of electrolyzing seawater, which can be stably operated for a long time.

In addition, in another embodiment of the present invention, to provide an electrolysis method of seawater that can adjust the amount of gas generated from the electrode.

According to one aspect of the invention,

In the electrolysis method of seawater using an electrolytic cell,

Before introducing seawater into the electrolytic cell, there is provided a method of electrolyzing seawater, characterized in that a reverse osmosis process (RO) and a capacitive deionization (CDI) process are performed sequentially.

In the electrolysis method of seawater according to the present invention, the scale is formed during electrolysis of seawater by sequentially treating the seawater sequentially through reverse osmosis (RO) and capacitive deionization (CDI) before electrolyzing seawater. Metallic components such as magnesium and calcium in seawater are removed. Therefore, during electrolysis of seawater in the electrolytic cell, scale formation at the electrode is prevented. In addition, by introducing the microbubble into the CDI-processed seawater flowing into the electrolytic cell, the adsorption of scale-forming metal ions to the electrode by the microbubble is prevented, thereby further preventing the formation of scale on the electrode. Thus, the method according to the present invention can stably electrolyze seawater for a long time. In addition, the generation efficiency of hydrogen, oxygen and chlorine gas at the electrode is also improved. Furthermore, by using the selective electrode, it is possible to efficiently control the amount according to the type of gas to be obtained in the anode and cathode.

The present invention has been proposed to prevent the formation of scale at the electrode during the electrolysis of seawater, before introducing the seawater into the electrolytic cell, the seawater through a reverse osmosis (RO) and a capacitive deionization (CDI) It is a technical feature to remove metal components, such as magnesium, calcium and other impurities, which cause scale generation in seawater by sequentially treating them sequentially. In this way, before the electrolysis, the formation of scale during electrolysis is prevented by removing the metal component and impurities which cause scale generation.

Furthermore, in the electrolysis method of seawater according to the present invention, the microbubble is introduced into the CDI-processed seawater flowing into the electrolytic cell, thereby preventing the adsorption of scale-forming metal ions to the electrode by the microbubble, thereby forming scale on the electrode. It is further characterized by further prevention.

In addition, by using the selective electrode, it is characterized by controlling the amount of generation according to the type of gas generated in the anode and / or cathode.

1 shows a concept of electrolysis of conventional seawater using an electrolytic cell. As shown in FIG. 1, seawater A is introduced into the electrolytic cell 10, and the seawater is electrolyzed in the electrolytic cell 10 to generate oxygen and chlorine gas at the anode 12, and hydrogen at the cathode 13. Is generated and the electrolyzed seawater is discharged (B). On the other hand, the electrolytic cell 10 is not limited thereto, but, for example, generally, the separator 11, the anode 12, the cathode 13, the oxygen gas / chlorine gas outlet 14, and the hydrogen gas outlet 15. Etc.)

The electrolysis method of seawater according to the present invention can be applied to any seawater electrolysis method using any electrolyzer which is generally known in the art, and sequentially and sequentially before introducing the seawater into the electrolyzer. Reverse osmosis (RO) treatment and then capacitive deionization (CDI).

Reverse osmosis process (RO) is generally known as a method of obtaining high purity fresh water by removing the solute dissolved in seawater using a semi-permeable membrane and osmotic pressure, but is not limited thereto. Including basic osmosis module, high pressure pump, influent line, effluent line, permeate line and backwash line. In the electrolysis method of seawater according to the present invention, the seawater is primarily subjected to a RO process to remove metal components and impurities that cause scale formation in seawater.

In the capacitive deionization process, as the seawater passes through the capacitive deionization apparatus, the scale-forming substance and impurities in the seawater are further removed by the adsorption capacity of Mg and Ca ions of the deionization electrode. The capacitive deionization process includes a deionized electrode module and a constant voltage applying device in a basic configuration.

The reverse osmosis process apparatus and the capacitive deionization apparatus, the reverse osmosis process and the capacitive deionization process itself are common in the art and can be performed with any process apparatus and process known in the art. As such, seawater treated with RO and CDI processes may flow into the electrolytic bath.

The RO process removes a large amount of scale-forming metal components and other impurities present in the seawater, so that the metal components and impurities in the seawater remaining in the trace amount after the RO process are first removed after the RO process is first performed. do. Thus, in the method according to the present invention, the intended effect is achieved when the RO and CDI processes are performed sequentially.

In addition, by introducing microbubbles into the seawater sequentially processed in the RO and CDI processes and introduced into the electrolyzer, the adsorption of the scale to the electrode is additionally prevented during the electrolysis of the seawater. That is, in the microbubble, since the bubble outer wall is negatively charged (-), the metal component that causes scale formation in seawater is bonded to the surface of the microbubble. Thus, the amount of the metal component which causes scale formation to move to the electrode is reduced, thereby further preventing and / or reducing scale formation at the electrode. Microbubbles can be produced using any microbubble forming apparatus generally known in the art.

On the other hand, the electrode in the electrolytic cell may be an electrode of any shape, size and material conventionally known in the art, and is not particularly limited. Although not limited thereto, for example, the electrode may be a flat type, a fiber type or a mesh type having a plurality of holes formed therein. In addition, although not limited thereto, the electrode may be, for example, platinum, iridium, stainless steel, lead oxide (PbO ₂ ), platinum oxide (PtO ₂ ), palladium oxide (PdO ₂ ), iridium oxide (IrO ₂ ), Made of ruthenium oxide (RuO ₂ ), manganese oxide (MnO ₂ ), carbon steel, gold, silver, copper, graphite, glassy carbon or titanium in lead oxide (PbO ₂ ), platinum oxide (PtO ₂ ), palladium oxide (PdO ₂ ), iridium oxide (IrO ₂ ), ruthenium oxide (RuO ₂ ), or manganese oxide (MnO ₂ ) may be plated.

On the other hand, by using a specific electrode, it is possible to adjust the amount generated according to the type of gas generated in the anode and / or cathode. For example, when a manganese oxide (MnO ₂ ) electrode is used, a large amount of oxygen gas is generated at 80-90% at the anode.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Figure 2 shows a schematic view of the electrolysis method of seawater according to the present invention including a pretreatment process.

As shown in FIG. 2, in the electrolysis method of seawater according to the present invention, seawater is first introduced into the RO process apparatus 26. After that, the metal component and impurities which are the cause of scale formation in seawater are first removed by the RO process. Subsequently, the RO treated seawater is continuously and secondarily introduced into the CDI process apparatus 27 and treated, and the metal component that causes scale formation in seawater due to the adsorption capacity of the deionized electrode to the metal ions in the CDI process. This is further removed.

As such, the RO and CDI processes are sequentially performed to perform electrolysis using seawater from which the scale-forming metal component in seawater has been removed, thereby preventing scale formation on the electrode during electrolysis.

Further, after the RO and CDI processes, nanoscale microbubbles may be added to the seawater introduced into the electrolytic cell 20 using the microbubble processing apparatus 28. That is, the seawater including the microbubble flows into the electrolytic cell 20. As described above, metal ions, which cause scale formation, are attached to the microbubble of which the surface is negatively charged, and thus, precipitation of scale on the electrode can be further prevented.

In addition, in the electrolysis method of seawater according to the present invention, by using a specific electrode as the electrodes 22 and 23 in the electrolytic cell 20, the amount of gas generated in the anode 22 and the cathode 23 can be adjusted.

Hereinafter, the present invention will be described in detail through examples. However, the following Examples do not limit the present invention.

Example 1

Seawater was electrolyzed using an electrolysis system of seawater as shown in FIG. 2. First, seawater was introduced into the RO process apparatus at a rate of 15 l / min to primarily remove scale-forming metal components and impurities in seawater. Thereafter, the RO treated seawater is introduced into the CDI processing apparatus 27, where the scale forming metal component and the impurities are secondarily removed. Thereafter, CDI treated seawater was introduced into the electrolytic cell 20. In the electrolytic cell 20, a pair of flat electrodes having a size of 2 cm x 2 cm and coated with platinum oxide (PtO ₂ ) on titanium was used. The space | interval of the positive electrode 22 and the negative electrode 23 was 6 mm.

The electrolyzer was subjected to electricity at a current density of 34 A / m 2 and electrolyzed for one week using the electrolyzed seawater. As described above, in the case of electrolyzing the seawater subjected to the RO and CDI processes, it was visually confirmed that no scale was formed on the electrode even after one week of electrolysis. However, except that the RO and CDI process was not treated, it was observed visually that scale was formed on the electrode after one week when the seawater was electrolyzed under the same conditions as described above.

Example 2

Seawater was treated with RO and CDI under the same conditions as in Example 1. Thereafter, microbubbles were introduced into the CDI treated seawater introduced into the electrolytic cell 20 using the microbubble treatment apparatus 28 as shown in FIG. Thereafter, the same method as in Example 1 and the seawater with the microbubble introduced into the electrolytic cell 20 were introduced at an inflow rate of 15 l / min. The electrolytic cell 20 was decomposed by applying electricity at a current density of 34 A / m 2. In the case of the present example in which the microbubble was added, it was also visually confirmed that no scale was formed on the electrode even after one week of electrolysis.

1 is a view showing an electrolysis method of seawater using a conventional electrolytic cell,

2 is a view showing an electrolysis method according to the present invention.

Description of the Related Art [0002]

10, 20 ... electrolyzer 11, 21 ... separator

12, 22 ... anode 13, 23 ... cathode

14, 24 ... oxygen and / or chlorine outlet 15, 25 ... hydrogen gas outlet

26 ... RO process equipment 27 ... CDI process equipment

28 ... microbubble processing unit

A ... Influent B ... Electrolyzed Water

Claims (3)

In the electrolysis method of seawater using an electrolytic cell, A method of electrolysis of seawater, characterized in that a reverse osmosis step (RO) and a capacitive deionization step (CDI) are carried out sequentially before seawater is introduced into the electrolytic cell. 2. The electrolysis method of seawater according to claim 1, wherein microbubbles are added to the seawater subjected to the capacitive deionization process introduced into the electrolytic cell. The method according to claim 1 or 2, wherein the electrolytic cell is provided with a manganese oxide (MnO ₂ ) electrode.

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