KR101070710B1 - eletrolytic cell for sea water - Google Patents

Abstract

The present invention relates to a new type of electrolyzer for seawater electrolysis, which prevents the electrolyzed water flowing through the inside of the electrolyzer from leaking out through a portion where a power supply pin is formed, and enables the coupling operation between the flanges to be easily performed.

To this end, the present invention is a tubular body portion formed with an inlet pipe and an outlet pipe for outflow of seawater on one side and the other side of the circumferential surface; Two body flanges which are provided to respectively surround both end surfaces of the body portion; Two coupling flanges in close contact with outer walls of the two body flanges, respectively; A portion of the outer wall circumferential side is in close contact with the inner wall of the coupling flange in a state of being inserted into the outer wall inner portion of each of the body flanges, and each inner wall surface is inserted into the body portion through the body portion flange An electrode portion having two support plates on which plate-shaped electrodes are installed, and power supply pins protruding from the center of the outer wall surfaces of the two support plates, respectively, and penetrating through the respective coupling flanges; And, one end is formed integrally along the periphery of the portion of the outer wall surface of each of the supporting plate is formed with the power supply pin, the other end is configured to include a plurality of fastening bolts that are exposed to the outside through the respective coupling flanges: A seawater electrolytic cell is provided.

Seawater electrolyzer, fastening bolt, support plate, electrode part

Description

Electrolytic cell for sea water

The present invention relates to a seawater electrolyzer, and more particularly, to prevent the electrolyzed water flowing through the seawater electrolyzer from leaking out through a portion where a power supply pin is formed, and a new form to facilitate the coupling operation between the flanges. It relates to an electrolytic cell for seawater electrolysis.

In general, power plants use seawater as cooling water to amplify the waste steam generated during power generation.

The cooling water used in the plurality of apparatuses is treated by generating seawater sodium chlorate after electrolyzing seawater with a seawater electrolytic cell in order to sterilize eggs or spores of seaweeds, crops such as seaweeds and shellfish.

The seawater electrolyzer is a bipolar type electrolytic cell in which two poles are simultaneously present in one electrolytic plate, and a monopolar type in which one pole is alternately arranged by providing only one pole in one electrolytic plate. (monopolar type).

The structure of the seawater electrolyzer is introduced in Korea Registered Utility Model Publication No. 20-0309987 and No. 20-0441233, etc., and based on this, one side and the other side of the circumferential surface have inlets and outlets for outflow of seawater. It includes a tubular body portion, a body flange provided at both ends of the body portion, an electrode portion, and a coupling flange for coupling the electrode portion to the body flange.

Here, the electrode unit is composed of a pair of support plates, a pair of power supply pins and a plurality of plate-shaped electrodes.

At this time, each of the power supply pin is formed to protrude outward on the center side of the outer wall surface of the support plate.

 In addition, each of the plate-shaped electrode is provided on the inner wall surface of any one of the support plate and a plurality of anode-side plate-type electrode which receives power from the power supply pin of the anode, and provided in the body portion while crossing between each input side plate-shaped electrode And a plurality of negative electrode side plate electrodes provided on the inner wall surface of the other supporting plate and provided with power from the negative electrode power supply pin.

In addition, each of the supporting plates of the electrode portion is the outer wall surface is installed in the outer wall surface of the coupling flange, the coupling is fixed to the body portion by the bolt coupling between the coupling flange and the body flange.

However, the conventional seawater electrolyzer configured as described above has a problem that the fastening operation time will be relatively long because the bolt fastening holes between the flanges must be exactly matched to fasten the bolts between the coupling flange and the body flange. Have

In addition, the conventional seawater electrolyzer described above is provided with a sealing means such as a gasket between the joint surface between the flanges and the joint surface between the body flange and the body portion to prevent leakage of sea water flowing in the body portion. It is not possible to prevent the leakage of sea water through the coupling position of the support plate constituting the electrode portion.

Therefore, seawater leaks to the area where the power supply pins are located, and in particular, when the seawater in the body part contains sodium hypochlorite by electrolysis, rust occurs. have.

The present invention has been made to solve the various problems caused by the above-described conventional electrolytic cell structure, the object of the present invention is to change the coupling structure between the electrode portion and each flange so that quick and easy coupling can be made; In addition, it is to provide a new type of seawater electrolyzer to prevent the leakage of seawater in the body portion to each power supply pin is located.

According to the seawater electrolyzer of the present invention for achieving the above object, a tubular body portion formed with an inlet pipe and an outlet pipe for outflow of seawater on one side and the other side of the circumferential surface; Two body flanges which are provided to respectively surround both end surfaces of the body portion; Two coupling flanges in close contact with outer walls of the two body flanges, respectively; A portion of the outer wall circumferential side is in close contact with the inner wall of the coupling flange in a state of being inserted into the outer wall inner portion of each of the body flanges, and each inner wall surface is inserted into the body portion through the body portion flange An electrode portion having two support plates on which plate-shaped electrodes are installed, and power supply pins protruding from the center of the outer wall surfaces of the two support plates, respectively, and penetrating through the respective coupling flanges; And, one end is formed integrally along the periphery of the portion of the outer wall surface of each of the supporting plate is formed with the power supply pin, the other end is configured to include a plurality of fastening bolts that are exposed to the outside through the respective coupling flanges: It is characterized by.

Here, between the outer wall of the two support plate and the inner wall surface of the coupling flange is characterized in that it further comprises a sealing ring for preventing leakage, the sealing ring is the portion where the respective fastening bolt is formed of the outer wall surface of the two support plate It is characterized by being installed along the perimeter of the.

In addition, the body portion is characterized in that it is formed of a transparent material capable of seeing inside.

In addition, a plurality of charging electrode plates charged with the respective plate electrodes and simultaneously having a cathode and an anode are spaced apart from each other in the state adjacent to each of the plate electrodes, and the upper and lower ends of the respective charging electrode plates are disposed on the body. In addition to the mounting plate for mounting in each part, each of the charging electrode plate is fixed to the two mounting plate by a plurality of coupling pins connecting the two mounting plate vertically, the outer surface of the two mounting plate and the Both sides of each charging electrode plate is characterized in that the support plate for the insulation and support between the body portion and each of the charging electrode plate is further provided.

As described above, the seawater electrolyzer of the present invention forms a plurality of fastening bolts integrally on the outer wall surface of the support plate constituting the electrode part so that the electrode part is directly fastened and fixed to the coupling flange, thereby making stable installation of the electrode part. It has the effect that it became possible.

In particular, the operation of matching the fastening hole for the coupling between the coupling flange and the body flange is mutually made by the process of coupling the fastening bolt to the coupling flange, so that no separate work is required by the operator. Even in the process of coupling the separate bolts to the fastening hole, the fastening operation formed in the coupling flange and the fastening hole formed in the body flange do not have to be carried out so that the operation to hold the matching operation can be easily carried out with each other.

In addition, by installing a sealing ring along the circumference of the portion where the respective fastening bolt is formed of the opposing surface between the support plate and the coupling flange, it is possible to prevent the leakage of seawater to the site where the power supply pin is located, thereby It is possible to prevent the occurrence of damage, such as the occurrence of rust on the wire coupled to the supply pin.

Hereinafter, a preferred embodiment of the seawater electrolyzer of the present invention will be described with reference to FIGS. 1 to 6.

First, the seawater electrolyzer according to the preferred embodiment of the present invention includes a body part 100, a body part flange 210 and 220, a coupling flange 310 and 320, an electrode part 410 and 420, and a plurality of parts as shown in FIG. 1. It comprises a fastening bolt (510, 520).

Here, the body portion 100 is a portion that forms the appearance of the seawater electrolyzer, and is a series of configurations forming a space in which the seawater is electrolyzed to produce sodium hypochlorite.

At this time, the body portion 100 is formed in a tubular shape, the inlet pipe 110 for the inflow of sea water and the outflow pipe 120 for the outflow of sea water are formed on both side surfaces.

In particular, the embodiment of the present invention proposes that the body portion 100 is formed of a transparent material capable of seeing inside.

Next, the body flanges 210 and 220 are a series of components for installation of the electrode portions 410 and 420 which will be described later.

The body flanges 210 and 220 are configured of a cathode body flange 210 provided on the cathode side and an anode body flange 220 provided on the anode side, each of which is a portion of the body 100. It is installed to surround the peripheral surface of both ends.

At this time, the body flanges 210 and 220 are formed in a ring shape in which a central portion thereof is opened.

Next, the coupling flanges 310 and 320 are coupled to the two body flanges 210 and 220, respectively, and serve to close the space in the body part 100 while serving as the electrode parts 410 and 420. A series of configurations to perform.

The coupling flanges 310 and 320 are formed in a plate shape, and the anode side coupling flange 310 coupled to the cathode side body flange 210 and the anode side coupling flange coupled to the anode side body flange 220 ( While being configured as 320, it is installed to be in close contact with the outer wall surface of each of the body flanges (210, 220).

In addition, through holes 311 and 321 through which the power supply pins 413 and 423 of the electrode parts 410 and 420 to be described later are formed in the center of the coupling flanges 310 and 320, and a plurality of circumferential portions of the through holes 311 and 321 are formed. Bolt holes 312 and 322 are formed, respectively. This is as shown in Figure 3 attached.

Next, the electrode parts 410 and 420 are a series of components for performing electrolysis of seawater flowing in the body part 100 by receiving an external power source.

The electrode parts 410 and 420 may include a cathode side electrode part 410 and an anode side electrode part 420, and each of the electrode parts 410 and 420 may include support plates 411 and 421, plate electrodes 412 and 422, and a power supply pin ( 413,423).

The support plates 411 and 421 are fixed to the body flanges 210 and 220 and the coupling flanges 310 and 320, and the outer wall circumferential side portion is formed to be in close contact with the inner wall surfaces of the coupling flanges 310 and 320.

In addition, the plate-shaped electrodes 412 and 422 are provided in plural and fixedly installed on inner portions of inner wall surfaces of the support plates 411 and 421, respectively, and penetrate through the open central side portions of the body flanges 210 and 220. 100) configured to be inserted into.

In addition, the power supply pins 413 and 423 are a series of components that receive external power and deliver them to the plate electrodes 412 and 422.

At this time, in the case of the negative electrode side 410, the power supply pin 413 is configured to receive a negative pole of power, and in the case of the positive electrode side 420, the power supply pin 423 is a positive pole. Is configured to receive power.

In particular, the power supply pins 413 and 423 are formed to protrude through the through holes 311 and 321 formed at the center portion of the coupling flanges 310 and 320 to be exposed to the outside.

In addition, the body part 100 includes a plurality of charging electrode plates 430 and an installation plate 440 as shown in FIG. 2.

In this case, the charging electrode plate 430 is charged with each of the plate electrodes 412 and 422 to electrolyze seawater passing between each of the charging electrode plate 430 and each of the plate electrodes 412 and 422 while simultaneously having a cathode and an anode. It is a series of configurations, and is configured such that one end is positioned between each of the plate electrodes 412 and 422 or one end (or both ends) is positioned between the other charging electrode plates 430.

In addition, the mounting plate 440 is a series of components for installing the respective charging electrode plates 430 in the body portion 100, and is provided at the upper and lower ends of the respective charging electrode plates 430. In this case, each of the charging electrode plates 430 is fixed to the two mounting plates 440 by a plurality of coupling pins 441 for vertically connecting the two mounting plates 440.

Meanwhile, the electrode parts 410 and 420, the charging electrode plate 430, and the mounting plate 440 configured as described above are fixedly installed in the body part 100 by the plurality of support plates 450.

In this case, the support plate 450 is provided on the periphery of the plate-shaped electrodes 412 and 422 constituting the electrode portions 410 and 420, on the outer surface of the two mounting plates 440, and on both sides of each of the charging electrode plates 430, respectively. Is formed.

Next, the fastening bolts 510 and 520 are a series of components for fastening the support plates 411 and 421 constituting the electrode parts 410 and 420 to be easily and stably coupled to the coupling flanges 310 and 320.

The fastening bolts 510 and 520 are provided in plural, one end of which is integrally formed along a circumference of a portion where the power supply pins 413 and 423 are formed among the outer wall surfaces of the support plates 411 and 421, and the other end of the coupling flanges 310 and 320. It is formed to penetrate through each bolt hole (312,322) formed in the) to be exposed to the outside.

Meanwhile, the embodiment of the present invention suggests that the sealing rings 610 and 620 are further included between the outer walls of the support plates 411 and 421 and the inner wall surfaces of the coupling flanges 310 and 320 corresponding thereto.

At this time, the sealing rings (610, 620) is a series of configurations for preventing the leakage of sea water in the gap between the support plates (411,421) and the coupling flanges (310,320), in particular, each of the fastening bolts of the outer wall surface of the support plates (411,421) 510 and 520 are installed along the circumference of the formed portion.

In addition, a plurality of fastening holes 213, 223, 313, 323 are formed in the circumferential portions of the body flanges 210 and 220 and the coupling flanges 310 and 320, respectively, among the series of configurations according to the embodiment of the present invention. Both ends are fastened and fixed by the nuts 215 and 315 while the separate bolts 214 and 314 are penetrated, which is the same as a coupling structure between a conventional body flange and a coupling flange.

In the following, the assembly process of the seawater electrolyzer according to the embodiment of the present invention described above will be described.

First, the electrode parts 410 and 420, the charging electrode plate 430, the installation plate 440, and the support plate 450 are coupled to each other. This is as shown in Figure 4 attached.

That is, the plate-shaped electrodes 412 and 422 constituting the electrode parts 410 and 420 and the respective charging electrode plates 430 are coupled with the coupling pins 441 in a state in which the two mounting plates 440 are opposed to each other. The supporting plate 450 is provided on the outer surface of each mounting plate 440 and on both sides of each of the charging electrode plates 430, respectively.

In this case, the support plates 450 are spaced apart from each other along the longitudinal direction of the body portion 100.

Subsequently, an assembly (hereinafter, referred to as an “electrode unit assembly”) between the electrode units 410 and 420, the charging electrode plate 430, the installation plate 440, and the support plate 450 coupled as described above is referred to as the body unit 100. Inside). This is as shown in Figure 5 attached.

Then, when the operation of inserting the electrode unit assembly into the body portion 100 is completed, the body flanges 210 and 220 are coupled to both ends of the body portion 100, respectively. At this time, it is preferable that a sealing means (not shown) such as a gasket is interposed between each of the body part flanges 210 and 220 and the body part 100.

Next, the two coupling flanges 310 and 320 are coupled to both ends of the body portion 100, respectively. This is as shown in Figure 6 attached.

In this case, through holes 311 and 321 through which the power supply pins 413 and 423 of the electrode parts 410 and 420 are formed are formed in the coupling flanges 310 and 320, and a plurality of bolt holes are formed along the circumference of the through holes 311 and 321. Considering that the 312 and 322 are formed, the worker engages the coupling flange 310 and 320 through a series of processes of coupling the coupling flanges 310 and 320 in a state where the respective fastening bolts 510 and 520 are matched to the respective bolt holes 312 and 322. ) And the respective fastening holes 213 and 223 formed along the circumferential side portions of the body flanges 210 and 220 coincide with each other.

Accordingly, a separate operation of the operator is not required to match the respective fastening holes 213 and 223, and the labor of the worker for maintaining the same state of the fastening holes 213 and 223 can be omitted.

Thereafter, the fastening nuts 511 and 521 are fastened to the respective fastening bolts 510 and 520 through the bolt holes 312 and 322 of the coupling flanges 310 and 320 to be exposed to the outside, and thus, between the electrode portions 410 and 420 and the coupling flanges 310 and 320. The coupling is fixed, and the coupling holes 310, 320 and the body flanges 210, 220 of the fastening holes (213, 223, 313, 323) by using a pair of nuts (215, 225, 315, 325) through a separate bolt (214, 224, 314, 324) through the fastening Coupling of the coupling flanges 310 and 320 and the body flanges 210 and 220 is made.

As a result, the electrode parts 410 and 420 may be stably coupled in the body part 100 by the aforementioned coupling structures.

Particularly, when the sealing rings 610 and 620 are provided between the outer wall surfaces of the support plates 411 and 421 of the electrode portions 410 and 420 and the inner wall surfaces of the coupling flanges 310 and 320, the support plates 411 and 421 and the coupling flanges 310 and 320 are respectively provided. By the simple fastening force, the sealing rings 610 and 620 block the gap between the support plates 411 and 421 and the coupling flanges 310 and 320, whereby the seawater present in the body portion 100 is coupled to the support plates 411 and 421. The gap between the flanges 310 and 320 is prevented from leaking to the portion where the power supply pins 413 and 423 are located.

1 is a cross-sectional view illustrating the internal structure of a seawater electrolytic cell according to a preferred embodiment of the present invention.

2 is a cross-sectional view taken along line II of FIG. 1.

Figure 3 is a side view showing for explaining the external structure of the cathode side portion of the seawater electrolytic cell according to a preferred embodiment of the present invention

4 to 6 are cross-sectional views for explaining the coupling process between the body portion and the electrode portion and each flange of the seawater electrolytic cell according to a preferred embodiment of the present invention

Explanation of symbols for main parts of the drawings

100. Body 110. Inlet pipe

120. Outflow pipes 210,220. Body Flange

213,223,313,323. Fasteners 214,224,314,324. volt

215,225,315,325. Nut 310,320. Coupling flange

311,321. Through hole 312,322. Bolt ball

410,420. Electrode section 411,421. Support plate

412,422. Plate electrodes 413,423. Power supply pin

430. Electrode plate 440. Mounting plate

441.Binding Pins 450.Support Plates

510,520. Fastening bolts 511 521. Fastening nut

610,620. Sealing ring

Claims (5)

A tubular body portion having inlet and outlet pipes configured for inflow and outflow of seawater on one side and the other side of the circumferential surface; Two body flanges which are provided to respectively surround both end surfaces of the body portion; Two coupling flanges in close contact with outer walls of the two body flanges, respectively; A portion of the outer wall circumferential side is in close contact with the inner wall of the coupling flange in a state of being inserted into the outer wall inner portion of each of the body flanges, and each inner wall surface is inserted into the body portion through the body portion flange An electrode portion having two support plates on which plate-shaped electrodes are installed, and power supply pins protruding from the center of the outer wall surfaces of the two support plates, respectively, and penetrating through the respective coupling flanges; And, One end is formed integrally along the periphery of the portion of the outer wall of each of the supporting plate is formed with the power supply pin, the other end is configured to include a plurality of fastening bolts: through the coupling flange exposed to the outside Seawater electrolyzer. The method of claim 1, Seawater electrolyzer, characterized in that further comprising a sealing ring for preventing leakage between the outer wall of the two support plate and the inner wall surface of the coupling flange. The method of claim 2, The sealing ring is a seawater electrolytic cell, characterized in that installed along the circumference of the portion of each of the fastening bolt is formed of the outer wall surface of the two support plate. delete The method of claim 1, In the body portion, a plurality of charging electrode plates charged with each of the plate electrodes and simultaneously having a cathode and an anode are spaced apart from each other in a state adjacent to the plate electrodes. Installation plates for installation in the body portion are provided at the top and bottom of each of the charging electrode plates, respectively, and each of the charging electrode plates is formed by a plurality of coupling pins that vertically connect the two mounting plates. Is fixed to, Seawater electrolyzer, characterized in that the outer surface of the two mounting plate and the both sides of each of the charging electrode plate is further provided with a support plate for insulation and support between the body portion and each of the charging electrode plate.

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