KR20140132900A - Electric equipment with reduced damage from sea wind - Google Patents

Abstract

The present invention provides a corrosion inhibiting layer formed on a surface of a metal facility, comprising: a metal facility including a metal case having an electrical facility therein and for protecting the electrical facility from the outside; An artificial stone coating layer formed on the surface of the first adhesive layer, and a protective coating layer formed on the surface of the artificial stone coating layer. According to the present invention, it is possible to prevent the corrosion of electric facilities due to salt damage even when exposed to a long period of time in a severe wind and severe typhoon damage such as a coastal island region, and to improve the appearance by harmonizing the appearance of the electric facilities with the surrounding natural environment have.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a corrosion-

The present invention relates to a corrosion-resistant corrosion-resistant electric facility, and more particularly, to an electric facility having a corrosion resistant property against salt corrosion by forming an artificially prepared stone coating layer on the surface of a metal case.

Electrical equipment, including electrical control devices and switchgears, is usually embedded in protective means such as metal, wood, concrete, etc. in order to protect against external environment such as sudden temperature changes and wind and rain.

As an example of electric facilities, the switchboard is installed in a place such as a power plant, a substation or a building where electric facilities are installed, and arranges safeguards, instruments, indicators, relays, , Protected by a distribution box. The power distribution box is a specific area where power distribution equipment such as a transformer or system disposal for energizing or controlling electric cables installed in the ground is blocked from the outside in the form of a box, It is installed on a foundation such as a concrete structure in a place where a lot of people do not gather and in a green area, a back wall of the underpass, a slope lower part of the overpass, etc. as far as possible from a building and the like.

However, if the distribution box is installed near the islands or coasts where the damage from salt damage is constant, the surface may corrode, which may jeopardize the safety of various electric facilities inside the distribution box in the long term.

Another typical electrical facility is the distribution board, which is often seen in parks and streets. A distribution board is a collection of panels with bus, light, and temperature power circuit control switches in a fixed frame, usually stored in a metallic distribution box, for example a street light distribution box. On the other hand, street lamps in parks and roads are also filled with electric devices such as electric wires inside iron columns and exposed to external environment for a long time.

In the case of distributing boxes and street lamps, the outer case is mainly made of a metal material. Stainless steel or iron is used as the material of the case. Unlike general iron, which is easily rusted due to oxidation, stainless steel is a metal which does not cause corrosion However, stainless steel is corroded due to the destruction of the passive film which prevents corrosion due to environmental factors. Particularly, typhoons are frequent, and saltwater pollution is serious in island areas and coastal areas where sea breeze from the sea is usually severe.

FIGS. 1A and 1B show a streetlight distribution box installed near a coastal zone. As shown in FIG. 1A and FIG. 1B, the metal casing is rusted due to exposure to an external environment for a long period of time and the physical stiffness is partially weakened. If such a corrosion phenomenon is prolonged, the electric facilities inside the distribution box can not be exposed to the damage caused by the salt.

FIGS. 2A and 2B show a portion of the streetlight of a streetlight easily visible in a nearby park or a street, and the upper part of the metal cylindrical structure is severed and the upper part is already cut off. The effect of this salt corrosion is not only threatening the safety of the facility but also causing a deterioration of the aesthetics in the coastal area where there are many tourist and resting spaces.

In the coastal zone, the metal part is made of aluminum or the like to prevent the corrosion of the metal part of the structure due to the salt contained in the sea breeze, or the corrosion-resistant alloy or metal coating layer is formed. However, it is disadvantageous in that it is not only extremely expensive in the case of an alloy or a coating layer having corrosion resistance to salting, but also it is difficult to maintain a long-term protection characteristic under a severe natural environment such as an island region.

In addition, as an alternative to the corrosion problem of electric facilities, a coating material such as a polymer resin, which is not a metal material, may be coated on the surface, but it is also difficult to maintain long-term durability in coastal areas where sea breeze is high and humidity is high there is a problem.

As a result, the corrosion caused by salt corrosion in the coastal area and the island area increases the maintenance cost of the electric facilities, and it becomes a troublesome hurdle to damage the coastal landscape and the surrounding environment. However, since there is no clear solution to this problem, to be. Particularly, there is an urgent need for new technical measures to prevent the damage of seawater while maintaining the physical stability of electrical facilities for a long period of time for the effects of sea breezes, frequent rain, and typhoons as an annual event.

The present invention was made in view of the above technical background, and an object of the present invention is to prevent corrosion of electric facilities due to coastal salinity.

Another object of the present invention is to overcome the disadvantage of damaging coastal landscapes and surrounding landscapes due to corrosion of electric facilities disposed around the coast.

It is still another object of the present invention to provide a preventive measure capable of reducing facility maintenance and maintenance cost due to salt corrosion corrosion of electric facilities, and mass production for preventing corrosion of electric facilities.

Other objects and technical features of the present invention will be more specifically described in the following detailed description.

In order to achieve the above object, the present invention provides a corrosion inhibiting layer formed on a surface of a metal facility, comprising: a metal casing including a metal casing that has an electric facility inside and protects the electric facility from the outside; A first adhesive layer formed on the surface of the metal case, ii) a synthetic stone coating layer formed on the surface of the first adhesive layer, and iii) a protective coating layer formed on the surface of the artificial stone coating layer. .

The artificial stone coating layer is preferably an artificial stone obtained by mixing stone powder and cement together with water, kneading, drying and curing. In addition, it is preferable that the artificial stone coating layer is obtained by pulverizing waste stone or natural stone into at least two or more particle sizes. The artificial stone coating layer may further include a glaze.

The artificial stone coating layer is preferably formed to a thickness of 5 to 30 mm from the surface of the metal case in consideration of durability, corrosion resistance, and load side applied to the electric facility.

Meanwhile, the first adhesive layer may be mixed with the artificial stone coating layer to be integrated. Further, in the present invention, the protective coating layer may contain a dye.

According to the present invention, it is possible to prevent the corrosion of electric facilities due to salt damage even when exposed to a long period of time in a severe wind and severe typhoon damage such as a coastal island area, and to improve the appearance by harmonizing the appearance of the electric facilities with the surrounding natural environment Of course, the facilities can be utilized as various tourism resources.

In addition, it is possible to reduce the maintenance cost of damage to existing electric facilities, and to produce a large amount of artificial stone coating layer used in electric facilities, thereby preventing salt corrosion and corrosion for a long time at low cost.

Figs. 1a and 1b are photographs showing the corrosion state of a street lamp distributing box installed near a waterfront
Figs. 2a and 2b are photographs showing the corroded state of a street lamp installed in a park near the waterfront
3 is a perspective view showing a salt corrosion prevention layer of an electric facility according to the present invention.
4 is an enlarged view of a portion A in Fig. 3
5 is a flowchart showing an example of a manufacturing process of the corrosion-
6a and 6b are photographs showing a street lamp distribution box having a salt corrosion prevention layer according to an embodiment of the present invention
7 is a photograph showing a street lamp pole formed with a salt corrosion prevention layer according to an embodiment of the present invention

The present invention relates to an electrolytic corrosion resistant corrosion preventing electrical equipment, and an artificial stone coating layer is formed on the surface of a metal case to provide electrical strength and durability against long-term penetration due to wind and seawater, Facilities.

Particularly, the present invention not only transforms the artificial stone coating layer formed for the purpose of preventing the corrosion of electric facilities into an eco-friendly facility through recycling of resources, but also improves aesthetics and changes into a harmonious facility in the surrounding environment. More specifically, the present invention relates to a method of manufacturing an outdoor sculpture or an installation sculpture by making a stone frame having a natural feel to the frame or an outer frame or a protective structure, I can feel it. As a result, the electric facilities, which are merely the rigid shapes of the existing metal structures, can be sublimated into natural stone materials and images, thereby providing harmonious environmentally friendly aesthetics to the surrounding environment.

In addition, the present invention can provide an excellent effect of maintaining a long-term durability against salting in a coastal area by forming a salt corrosion-resistant and neglected layer through a simple and easy process on the surface of an electric facility.

Hereinafter, the features of the present invention will be described in more detail with reference to the drawings and preferred embodiments.

3 and 4, the corrosion-resistant corrosion-prevention electrical equipment according to the present invention includes a metal facility 100 having a built-in electrical facility therein and a metal case for protecting the electrical facility from the outside, Corrosion-preventing layer 110 formed on the surface of the substrate 1.

The corrosion-resistant corrosion-preventive layer is a surface protective layer in which a variety of materials are mixed or sequentially stacked. The first adhesive layer 120 is formed on the surface of the metal case. The artificial stone coating layer 130 is formed on the surface of the first adhesive layer. And a protective coating layer 140 formed on the surface of the artificial stone coating layer. The first adhesive layer, the artificial stone coating layer and the protective coating layer may be composed of one layer in which the respective components are mixed according to the manufacturing process needs.

The electric facilities to which the present invention is applied may include a distribution box, a distributing box, and various electric power control boxes which are exposed to the outdoor for a long period of time.

In the present invention, the first adhesive layer 120 facilitates the physical and chemical bonding between the metal case surface of the electric facility and the artificial stone coating layer, which is a key element of the salt corrosion prevention layer. The first adhesive layer may be coated beforehand with a thin film on the surface of the metal case of the electric facility before the artificial stone coating layer is formed. Alternatively, the adhesive may be mixed in the pre-mixing process of the artificial stone coating layer, Or may be left as a thin film between the coating layers.

It is preferable that the artificial stone coating layer 130 is an artificial stone in which glaze, stone powder and cement are mixed with water, kneaded, dried and cured, . Although such artificial stone is valuable in terms of natural recycling, it is advantageous in that it is light in weight compared to concrete or functional alloy layer, and hardness is not so great as to increase the physical load on electric facilities.

There are no particular restrictions on the type of glaze used in the artificial stone coating layer, and various materials capable of improving the corrosion resistance of the salt corrosion resistant layer by filling the gaps between the gypsum and the cement and filling the gaps in the mixed materials can be used, When the artificial stone coating layer has sufficient bonding force, the glaze may not be used.

The stone can be used, for example, by crushing waste stones or natural stones from the construction site. The stones can be used in various ways such as basalt, granite, concrete, etc. in consideration of the strength and color of the material. Cement serves as a kind of adhesive in the artificial stone coating layer and at the same time, it functions to increase the durability and hardness of the coating layer by filling the void of the stone. The cement may vary depending on the thickness of the coating layer, the type of the granule used, and the particle size. It is not necessary that the cement is used excessively, but a range of about 5 to 30% is preferable in terms of weight ratio for bonding strength of the coating layer and internal bonding between the granite.

In addition, it is preferable that the artificial stone coating layer is obtained by pulverizing waste stone or natural stone into at least two or more particle sizes. Such artificial stones can be used not only to reduce the cost of repairing and maintaining electrical facilities, but also to produce artificial stone coating layers used for repairing electrical facilities in large quantities by using existing abandoned resources for recycling and using them for corrosion and corrosion prevention It is also very advantageous in terms of production process. The pulverization and mixing of the waste stone or natural stone used in the artificial stone coating layer into two or more particle sizes not only makes it possible to uniformly mix the coating layer material but also has an advantage of improving the adhesion of the metal material to the case surface. In addition, it is possible to suppress the occurrence of unnecessary voids in the coating layer, thereby improving the physical stiffness of the coating layer and the long-term resistance to the external environment.

The artificial stone coating layer is preferably formed to a thickness of 5 to 30 mm from the surface of the metal case. If the thickness of the coating layer is too small, physical strength or adhesive force of the coating layer may be weakened by exposure to typhoons or frequent rain, and if the thickness of the coating layer is excessively excessive, the amount of material is increased and the production cost is increased. The long-term durability can be weakened.

Meanwhile, the first adhesive layer 120 may be formed as a layer independently of the artificial stone coating layer 130, but may be mixed with the artificial stone coating layer to be integrated. In this case, there is an advantage that both the internal bonding force of the artificial stone coating layer itself and the adhesive force to be bonded to the surface of the metal case of the electrical facilities can be achieved at the same time. If necessary, the second adhesive layer may be further mixed with the artificial stone coating layer separately from the first adhesive layer.

The materials used for the first adhesive layer and the second adhesive layer are not particularly limited, and any organic adhesive, inorganic adhesive, or natural adhesive capable of bonding metal and stone can be used.

In the present invention, the protective coating layer 140 protects the outer surface of the artificial stone coating layer 130 to improve the durability of the artificial stone coating layer, and various materials having corrosion resistance against salt water and strong adhesion Can be used. In particular, various colors or patterns may be imparted to the outside of the artificial stone coating layer by including a coloring matter in the protective coating layer or by further forming a coloring layer separately from the protective coating layer. In this case, by protecting the protection against the salinisation of the electric facilities, the beauty of the facilities can be improved, and thus the electric facilities can be changed into the environmentally friendly facilities which are in harmony with the places where the electric facilities are installed.

Further, the color layer 150 may be additionally formed as an outer coating layer separately from the protective coating layer. In this case, the protective coating layer functions as a protective layer of the artificial stone coating layer in a pure manner, thereby preventing the artificial stone coating layer from being physically damaged by temperature change, external moisture or strong wind, .

5 is a flowchart showing an example of a manufacturing process of the corrosion-resistant corrosion-prevention electrical equipment of the present invention. A structure corresponding to a frame or a skeleton of the electric facility is grounded (step S110). The base structure may be formed of, for example, a rectangular parallelepiped case, a cylindrical columnar structure, or the like through a process such as cutting, bending, and bonding. Artificial stone material is blended to prepare a coating layer to be used for preventing the corrosion of the electric facilities (step S120).

As artificial stone material, stone powder such as stone powder and other materials are mixed and prepared in a kneaded state. The artificial stone coating layer to be coated on the outline of the electric facility is coated on the surface of the electric facility with the first adhesive layer being formed in advance (Step S130) or the adhesive is mixed (Step S140). An automated spraying apparatus may be used for coating, or the coating operation may be partially performed manually if the appearance of the electric facility is complicated.

After the coating is completed, the shape of the artificial stone coating layer is completed by attaching an outer mold or a mold to fix the shape of the artificial stone coating layer (step S150). Depending on the pattern of the mold, the artificial stone of various patterns may be coated on the surface of the electric facilities.

After the curing and drying step (step S160) is performed for a predetermined period of time while the forming mold is fixed, the outer mold forming mold or the coating film is demolded, and a protective coating layer or an external shape stone image is implemented on the surface of the artificial stone coating layer, The implementing pigment is applied (step S170). According to the kind of materials used in the salt corrosion prevention layer, the drying time is controlled to final dry, and the electric structure in the form of a stone molding is completed.

Example 1

Figures 6a and 6b show the formation of artificial stone coatings for the streetlight distribution box.

The artificial stone coating layer used was manually added by using an adhesive agent, using fine granules which were firstly sieved to the elaborate parts such as handles and door seats of the distribution box metal case which is an electric facility, And water in a ratio of 6: 3: 1 was applied to the surface of the metal case, and then the surface shape was formed using a mold.

After the finished artificial stone coating layer was cured and dried, the surface was supplemented with a protective coating layer containing pigment on the surface.

The corrosion-resistant corrosion-resistant layer including the formed artificial stone coating layer was formed to have a thickness of 20 mm, and was found to be light in weight compared with concrete or other artificial stone, and excellent in corrosion resistance against salt water. In addition, it was confirmed that brine was not permeated through the artificial stone coating layer surface of 10 mm thick by holding the brine for 30 days or more under pressure.

Example 2

An artificial stone coating layer was formed on the circular column of street lamps. The coated artificial stone layer was formed by mixing a mixture of stone and cement on the outer surface of a metal cylindrical structure to a thickness of 25 mm.

The outer appearance of the artificial stone coating layer was maintained for 3 to 4 hours or more using a cylindrical forming mold so as to conform to the shape of the cylindrical structure, and the appearance was fixed by curing and drying, and the coating layer having excellent hardness and excellent corrosion resistance .

Fig. 7 shows the appearance of the corrosion-resistant corrosion-resistant layer of the completed street lamp pole. The formed barrier layer is similar to the color of basalt in Jeju area, and it is harmonized with the surrounding landscape by adding the gray - gray color.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And may be modified, changed, or improved in various forms.

100: Electric facilities 110: Salt corrosion prevention layer
120: first adhesive layer 130: artificial stone coating layer
140: protective coating layer 150: colored layer

Claims (4)

A metal facility including an electric facility inside and a metal case for protecting the electric facility from the outside,
A corrosion preventive layer formed on a surface of the metal facility,
A first adhesive layer formed on the surface of the metal case,
A synthetic stone coating layer formed on the surface of the first adhesive layer and kneaded with the water and the stone and cement, kneaded and cured,
And a protective coating layer formed on the surface of the artificial stone coating layer,
Wherein the artificial stone coating layer is formed by pulverizing waste rock or natural stone into at least two or more particle sizes, and the artificial stone coating layer is formed to a thickness of 5 to 30 mm from the surface of the metal case
Corrosion resistant electrical facilities.
The method according to claim 1,
Wherein the first adhesive layer is mixed and integrated with the artificial stone coating layer.
The corrosion-resistant corrosion-resistant electric installation according to claim 1, wherein the protective coating layer comprises a coloring matter.
The method according to claim 1,
Characterized in that the artificial stone coating layer further comprises a glaze.

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