TH166363A - Corrosion protection system for storage tank bottom - Google Patents

Abstract

Systems for the protection of the ground bottom of anticorrosive storage tanks include piping systems that Assembled with a non-perforated inlet pipe. And the perforated tube connected to that part, the casing container with the solid VCI compound in that section, was inserted into the perforated tube. The casing can penetrate Pass through to the vapor that is released by the solid VCI compound and flows through the pipe for perforation where it Is taken into the area beneath the storage tank so that it can touch the bottom of the tank. (Ground side) and protect things The same from corrosion

Claims (9)

Disclaimer (all) which will not appear on the advertisement page: Amendment 20 Mar 2020 No disclaimer -------------------------------------------------- ------------------------ 1. Anti-corrosion system storage tank, which consists of Piping systems, consisting of one or more perforated tubes, are located under at least one casing container containing at least one corrosion inhibitor compound. Volatile solids (VCI) in that area, at least one of the casings can be housed within a At least some of the perforated tubes, such casing containers, were liquid-free by default. And the perforated pipe without VCI powder was blown in. Alternatively, at least one SCI solid compound is mixed with the VCI solid compound located in the container, the casing, and the casing that is permeable to the vapor released from at least one VCI compound. Such solids, but is impermeable to the VCI compound. It can be discharged from the pipe system through the perforation of the perforated pipe. 2. Anti-Corrosive Systems Storage Tank according to claim 1, where the perforated pipe is truly curved or straight. 3. Anti-corrosion system storage tank according to claim 2, where the casing is capable of It permits air from about 1 to approximately 1,000 cubic feet per minute, per square foot, and where the casing container is located in the perforated pipe. 4. Corrosion protection storage tanks according to claim 3, where the piping system contains a number of perforated pipes and where a certain number of casings are contained in the perforated pipe and where the diameter Of the said casing Ie, from approximately 5% to approximately 95% of the diameter of The perforated pipe 5. Anti-corrosion system storage tanks according to claim 4, where only such solid VCI compounds are used; Where VCI solids are composed of inorganic nitrite salts, organic nitrite salts, sodium molybdate anhydrous, anhydrous ammonia dimolybdate or anhydrous. Drusamine Molybdate, Amine Benzoate, Amine Nitrate, Benzothiazole, Cyclohexylamine Benzoate, Ethylamine Benzoate, Disoclohexylamine Nitrate, Tolyltriazole and its salts, or C13H26O2N and any combination thereof. 6. Anti-corrosion system storage tank according to claim 4, where the pipe is made of plastic, where the perforated pipe is truly linear. And where the casing is capable Air permeability is from approximately 100 to approximately 300 cubic feet per minute per square foot, where the casing diameter is from approximately 50% to approximately 90% of the rated pipe diameter. Drill such holes; Where such casings can be connected to each other And where such solid VCI compounds are composed of sodium nitrite, amine salt, benzoate, nitrobenzoate, phosphate, carbonate, imidazoline or aggregation. Well any of it 7. Anti-corrosion system storage tanks according to claim 5, where the casing contains liquid in That section is less than 5% by weight compared to the total weight of that VCI in that section, where the casing diameter is approximately 70% to approximately 85% of the pipe diameter and where the solid VCI compound is composed Combine with sodium nitrite, amine salt, benzoate, nitrobenzoate, phosphate, carbonate, imidazoline or any combination of it. 8. Anti-corrosion system of storage tanks according to claim 4, which includes at least one such SCI compound, where the amount of such SCI compound ranges from approximately 1 to approximately 30 percent by weight compared to total weight. Of all of the SCI and VCI compounds. 9.Corrosion protection system for storage tanks according to claim 8, where such solid SCI compounds include borates, carbonates, phosphate, polyphosphates, silicates or a combination. Any of it 1 0. Anti-corrosion system storage tank according to claim 9, where the pipe is made of plastic, where the perforated pipe is truly linear. And where the casing is capable Air permeability is from approximately 100 to approximately 300 cubic feet per minute per square foot, where the casing diameter is from approximately 50% to approximately 90% of the rated pipe diameter. Drill such holes; Where the casing Can be connected to each other And where the amount of that solid SCI compound They range from approximately 15% to approximately 35% of weight. All of all SCI compounds and those of VCI compounds 1 1. A process system for providing corrosion protection to the ground bottom of storage tanks, which includes: Piping systems consisting of one or more perforated pipes located below the storage tank. The bottom section with the material area to support the tank below that section One container, casing, or more containing at least one solid VCI compound in that portion, the casing is permeable to the vapor released from at least one such solid VCI compound, but is impermeable. Also such solid VCI compound, the liquid-free casing container by default. Optionally, at least one SCI solid compound was mixed with the said solid VCI compound in the casing container. Inserting one or more of the above casing containers into the said casing system, the casing is optimized to release the said VCI vapor into the perforated tube and discharge respectively as the VCI vapor. From the perforated pipe in the tank support area 1 2. Process system of claim 11, where the diameter of the casing Is from approximately 5% to approximately 95% of the diameter of the perforated pipe.1 3.Processing system of claim 12, which includes a number of the aforementioned perforated pipes and a number of aforementioned casing containers 1. 4. Process system of claim 13, where only such solid VCI compounds are used; Where VCI solids contain inorganic nitrite salts, organic nitrite salts, sodium molybdate anhydrous, anhydrous ammonia dimolybdate or anhydrous. Drusamine Molybdate, Amine Benzoate, Amine Nitrate, Benzothiazole, Cyclohexylamine Benzoate, Ethylamine Benzoate, dicyclohexylamine nitrate, tollitriazole and its salts or C13H2502 N and any combination of it 1. 5. Process system of claim 14, where the casing diameter is approximately 70% to approximately 95% of the perforated tube diameter. And where the casing It has a permeability ranging from approximately 1 to approximately 1,000 cubic feet per minute per square foot 1. 6. Process system of claim 15, where such solid VCI compounds Contains sodium nitrite, amine salt, benzoate, nitrobenzoate, phosphate, carbonate, imidazoline or any combination of it. 7. Process system of claim 13, where such permeable pipes are distributed. Regularly in the area of the tank support material And where the perforated pipe is free of VCI blown in 1 8. Process system of claim 17, which includes the aforementioned SCI powder, where such SCI compounds include borates, carbonates, molybdate, phosphate, polyphosphate, Silicates or any combination thereof and where the amount of such solid SCI compound They range from approximately 1% to approximately 30% of the total weight of all SCI compounds and such VCI compounds 1. 9. Process system of claim 18, where the amount of powder air that is blown into It is approximately 10% less than the total weight of such VCI in one or more such casings and where the amount of liquid inside one or more casings is approximately 3% by weight or less compared to total weight. Of VCI in one container or more than 2 such casings. 0. Process system of claim 19, where the casing diameter is approximately 70% to approximately 95% of the diameter of the perforated pipe, where the casing It has an air permeability ranging from about 1 to about 1,000 cubic feet per square foot. And where the amount of that solid SCI compound They range from approximately 15% to approximately 35% of the total weight of all SCI compounds and such VCI compounds.