JPH0444617Y2 - - Google Patents

Description

[Detailed description of the invention] [Industrial field of application] This invention is a method for applying galvanic current to prevent corrosion of the bottom outer surface (annual plate) of outdoor above-ground structures, especially circular outdoor above-ground structures such as outdoor above-ground tanks. This relates to an anode sheet plate.

[Conventional technology]

Conventionally, outdoor above-ground tanks have been constructed by laying an asphalt sand layer 4 serving as an insulating layer on top of the foundation sand 5, as shown in FIG. ,
Lay down the galvanic anode sheet plate 3. The galvanic anode sheet plate 3 is laid in a ring shape on the surface of the asphalt sand layer, as shown in FIG. A tank bottom plate 2 is installed on the asphalt sand layer 4 having the galvanic anode sheet plate 3 laid in a ring shape, and a tank side plate 1 is installed relative to the tank bottom plate 2.
were welded vertically. The above galvanic anode sheet plate 3
was electrically connected to the tank side plate 1 by an electric wire 6 via a joint box 9. It is preferable that the electric wire 6 is covered with a PVC tube 7.

An outdoor above-ground tank installed with such a structure may not allow rainwater or acidic water to enter between the tank bottom plate 2 and the asphalt sand layer 4 from around Inuhashiri 8, or if rainwater or acid water enters between the tank bottom plate 2 and the asphalt sand layer 4. Although dew condensation water may accumulate on the tank bottom plate 2, an anticorrosion current flows from the galvanic anode sheet plate 3 inserted between the tank bottom plate 2 and the asphalt sand layer 4 through moisture toward the tank bottom plate surface. , cathodic protection is performed to prevent corrosion of the tank bottom plate.

The galvanic anode sheet plate 3 is generally prepared as a rectangular plate made of magnesium, zinc, aluminum or their respective alloys, and a plan view of the galvanic anode sheet plate is shown in FIG. .

The rectangular galvanic anode sheet plate shown in Fig. 8 above was cut along the dotted line in Fig. 8 in order to adapt it to the outside diameter of the outdoor above-ground tank before installation, and then cut as shown in Fig. 7. It is laid out in a ring like this. The above-mentioned corrective cutting is a process of cutting along dotted lines to create a trapezoidal galvanic anode sheet plate that can be laid in a ring shape that fits the outer diameter of the tank. The work of cutting the galvanic anode sheet plate into rectangles and the work of correcting it into trapezoidal shapes are generally carried out at a factory, but the above-mentioned corrective cutting work has also been carried out at the tank installation site.

[The problem that the idea attempts to solve]

In any case, before a conventional galvanic anode sheet plate can be laid in a ring shape, a plate made of magnesium, zinc, aluminum or their respective alloys must be cut into rectangular shapes, and at least one modification cut must be made. The cutting operation had to be carried out twice, consuming a lot of labor and time.

[Means to solve the problem]

Therefore, the present inventor conducted research to obtain a galvanic anode sheet plate with a shape that does not require the above-mentioned modification cutting according to the outside diameter of an outdoor above-ground tank, and as a result, completed the galvanic anode sheet plate of this invention. That's what I came to do.

In other words, this invention consists of a circular arc with a central angle of less than 180 degrees, and a semicircle that has a different center from the circular arc, has the same radius as the circular arc, and is curved in the same direction as the circular arc. , the galvanic anode sheet plate is characterized by having a shape surrounded by two lines connecting the end of the arc and the end of the semicircle.

The two lines may be a straight line, a polygonal line, or a combination of a straight line and a curved line. Moreover, any metal plate among magnesium, magnesium alloy, zinc, zinc alloy, aluminum, and aluminum alloy may be used for this galvanic anode sheet plate.

〔Example〕

Next, the shape of the galvanic anode sheet plate of this invention will be specifically explained based on the drawings.

Figures 1 to 3 are plan views showing the specific shape of the galvanic anode sheet plate of this invention, and Figure 4 is a plan view showing the galvanic anode sheet plate of Fig. 1 arranged in a ring shape. FIG. 5 is an explanatory view showing that the galvanic anode sheet plates of this invention can be arranged to fit the outer diameter of the tank.

As shown in Figure 1, the galvanic anode sheet plate of this invention has a shape surrounded by a semicircle ab⌒, an arc de⌒ whose central angle is less than 180 degrees, and a polygonal line. . It is necessary that the semicircle ab⌒ and the arc de⌒ have the same radius and that their centers are eccentric.

The end of the semicircle ab⌒ and the end of the arc de⌒ are the second
As shown in the figure, it may be a shape connected by a line consisting of a straight line and a curve fe⌒ or a line consisting of a straight line and a curve cd⌒, or the end of a semicircle ab⌒ as shown in Figure 3. and the ends of the arc de⌒ are straight lines and straight lines
It may be in a shape tied with bd.

For example, when laying the galvanic anode sheet plate of this invention having the shape shown in FIG.
As shown in the figure, the arc portion of the galvanic anode sheet plate 10 of this invention and the semicircular portion of the galvanic anode sheet plate 11 of this invention are joined, and the galvanic anode sheet plate 11 of this invention is further bonded. The galvanic anode sheet plates 13, 14, 15, . The invented galvanic anode sheet plate can be laid out in a ring shape. In this case, since the radius of the circular arc and the radius of the semicircle are the same length, the above circular arc part and the circumferential part can be joined without creating a gap, and the length of the above circular arc is the same as the semicircular radius. Since it is shorter than the length of , it can be joined as shown by the solid line in FIG. 5, or it can be joined as shown by the dotted line. Therefore, it can be laid freely in a ring shape according to the outer diameter of the outdoor above-ground tank.

[Effect of idea]

The galvanic anode sheet plate of this invention can be adapted to any outside diameter of an outdoor above-ground circular structure without having to make corrections and cutting according to the outside diameter of the outdoor above-ground circular structure, unlike conventional galvanic anode sheet plates. Since it can be laid in a ring shape, it has the excellent effect of significantly reducing costs.

[Brief explanation of the drawing]

Figures 1 to 3 are plan views of the galvanic anode sheet plates of this invention, and Figure 4 shows the state in which the galvanic anode sheet plates of this invention shown in Figure 1 are continuously joined. A partial plan view, FIG. 5 is an explanatory diagram showing that the joining direction of the galvanic anode sheet plate of this invention can be changed, and FIG. 6 is a sectional view showing the installation structure of a conventional outdoor ground tank. Figure 7 is a plan view showing a conventional galvanic anode sheet plate laid in a ring shape on an asphalt sand layer, Figure 8 is a plan view of a conventional galvanic anode sheet plate, 1...tank side plate , 2...tank bottom plate, 3...
Galvanic anode sheet plate, 4... Asphalt sand layer, 5... Foundation sand, 6... Electric wire, 7... PVC pipe,
8... Inuhashiri, 9... Joint Box, 1
0, 11, 12, 13, 14, 15... Galvanic anode sheet plate of this invention.

Claims (1)

[Claims for Utility Model Registration] (1) A circular arc with a central angle smaller than 180 degrees, and a circular arc that has a different center from the above circular arc, has the same radius as the above circular arc, and is curved in the same direction as the above circular arc. A galvanic anode sheet plate having a shape surrounded by a semi-circumference, two lines connecting an end of the arc and an end of the semi-circumference. (2) The galvanic anode sheet plate according to claim 1, wherein the line is a straight line. (3) The galvanic anode sheet plate according to claim 1, wherein the line is a polygonal line. (4) The galvanic anode sheet plate according to claim 1, wherein the line is a combination of a straight line and a curved line.