RU2136783C1 - Corrosion protector and method for casting thereof - Google Patents

Abstract

FIELD: corrosion protection. SUBSTANCE: magnesium- alloy corrosion protector for oil and gas constructions is made in the form of semicircle. Protector has coaxially aligned core protruding from two sides to 1/7-1/12 its total length. Height-to-length ratio equals (0.8- 1.2):(1.12-0.8). When casting protector, casting mold is warmed for more than 30 min, core is heated at temperature higher than 100 C and placed in casting mold, into which magnesium alloy is poured in with rate 1 to 3 kg/s. Protector is continuously cooled with water at 70-80 C and pressure 0.2 MPa. EFFECT: improved quality of protector due to decreased pipes, hollows, and oxide and flux inclusions. 5 cl, 1 dwg

Description

 The invention relates to non-ferrous metallurgy, in particular to methods for casting magnesium and magnesium alloys to obtain treads of a certain shape used to protect oil and gas structures from corrosion.

A known method of casting ingots and protectors (Prince. Metallurgy of magnesium and other light metals. Stefanyuk SL: Textbook for technical schools. M: Metallurgy, 1985, p.123-126). This method includes the following operations: metal or alloy is poured into molds, which are cooled by water. The molds are heated to 600-650 ^o C, the metal in it is kept at 690-700 ^o C for 30-40 minutes and then the mold is immersed in water at a speed of 1.5-2 cm / min. Due to this inclusion in the metal, the molds settle to the bottom and are separated during the machining of the ingot. The molds have a trapezoidal or semicircular cross-sectional shape, respectively, and the tread have the same shape.

 The disadvantage of this casting method is the insufficiently high quality of the resulting tread.

There is a known method of casting a tread and a tread (Art. Improving the technology of production and use of protectors from magnesium alloys for electrochemical protection. // I.P. Vyatkin, V.A. Kechin, L.F. Kirina and others / - Magnesium alloys. - M.: Science. - 1978 - p. 196-202). The method includes casting magnesium or its alloy into molds at a casting temperature of 690-700 ^o C, the temperature of the removed tread is 320-360 ^o C. When casting treads with a mass of more than 10 kg, water-cooled steel molds are used, and casting treads of lower mass use cast-iron, non-water-cooled.

 The disadvantage of this method is the low quality of the protectors.

A known method of casting protectors is a prototype (see the book. Refining and casting of primary magnesium. // Vyatkin I.P., Kechin V.A., Mushkov S.V. / Metallurgy, 1974, p. 142-176). The method includes the following operations: heating the assembled water-cooled mold, pouring metal — magnesium or its alloy — into the mold, supplying water to the mold shell, then turning off the feed, cooling the tread in the mold and removing it. Casting temperature 690-700 ^o C, water consumption, 20-30 liters per minute, or depending on the type of tread 60-90 liters per minute, the water temperature at the entrance to the mold 30-35 ^o C, at the exit from the mold - 80-85 ^o C, the duration of the tread in the mold is 3-4 minutes.

 The disadvantage of this method is the low quality of the tread due to the formation of shrinkage shells, voids and non-metallic inclusions.

 Known tread made of magnesium alloys (see GOST 26251-84 (ST SEV 4046-83). Publishing house of standards, 1987, p. 16) brand P-POM-4, P-POM-10, P-POM-30, P- POM-60 with a length of 250 mm and 600 mm and a weight of 4, 10, 30, 60 kg, made semicircular in the center of which, on one side, a round core with a diameter of 8 mm is inserted.

 A tread of this form does not adequately meet the requirements of the customer for oil and gas production facilities due to the inconvenient form of manufacture.

 The objective of the invention is to improve the quality of the tread by reducing shrinkage cavities, voids, oxide and flux inclusions during casting of the tread.

 The objective is achieved by the fact that the proposed tread of a magnesium alloy made in a semicircular shape, in which the core is placed coaxially with the tread, is new that the core is located along the entire length of the tread, and the ratio of tread height to its width is (0.8-1, 2) :( 1.12-0.8), the core protrudes on both sides of the tread at a distance of 1 / 7-1 / 12 from its length and the ratio of the radius of curvature of the core to the height of the tread is 3 / 5-1 / 3.

 The location of the core along the entire length with protrusions on both sides of the tread at a distance of 1 / 7-1 / 12 of the total length with a ratio of the radius of curvature of the core to the tread height of 3 / 5-1 / 3 creates a good contact of the core with the tread, which will reduce the formation of shrinkage shells and voids in the tread. And in addition, this form of manufacturing the tread creates a reliable working contact with the object of protection.

 The performance of the tread with a ratio of its height to width equal to (0.8-1.2): (1.12-0.8) will make it possible to obtain a tread of better quality without shrinking shells and voids.

The method of casting the tread, including heating the mold, installing the core, pouring a magnesium alloy, water supply for cooling the tread is new, that the core is preheated before installation in the mold, the magnesium alloy is fed into the mold at a speed of 1-3 kg / s, water is constantly supplied at a temperature of 70-80 ^o C and a pressure of more than 0.2 MPa, the duration of the mold heating is more than 30 minutes, and the core is heated to a temperature of more than 100 ^o C.

 The supply of magnesium alloy to the molds at a speed of 1-3 kg / s will allow for uniform crystallization of the alloy and to obtain a high-quality dense tread without shells and voids.

Heating the core to a temperature of more than 100 ^o C will eliminate the sharp cooling of the molten metal and thereby exclude the formation of oxide and flux inclusions in the tread.

A constant supply of water for cooling the mold at a temperature of 70-80 ^o C and a pressure of more than 0.2 MPa will allow rapid crystallization of the alloy and thereby reduce the formation of oxide and flux inclusions in the tread.

 The drawing shows a view of the tread, which consists of a semicircular tread - 1, a core - 2, made along the entire length of the tread and extending beyond the tread on both sides at a distance of 1 / 7-1 / 12 of its length.

 An example implementation of the method.

The finished alloy grade MP-1 (aluminum - 5.3-6.7; zinc - 2.2-3.7%; manganese 0.02-0.4%; iron - not more than 0.003%; the rest is magnesium) from the crucible of the SMT-2 furnace with the help of a bucket is poured into molds stationary installed near the furnace, made of a metal case 10-15 mm thick. The side walls of the mold are removable and fixed in the mold. A metal casing of sheet steel 3-4 mm thick is welded to the body. Steel longitudinal guides are welded on the bottom of the casing from the inside to organize the movement of water into the molds. Water supply is carried out at one point below the mold, the drain at two points on top. The temperature of the alloy during casting is 690-700 ^o C. To heat the mold use a block of gas burners, the temperature of the mold by the start of casting should be at least 100 ^o C, the heating is carried out for at least 30 minutes and is controlled by the device. Before starting casting, the working part of the mold is pretreated with boric acid, and then the rods are laid carefully rooted to a temperature of more than 100 ^o C for 1-1.5 hours in the grooves of the empty mold. A rod with a diameter of 8-10 mm is used as a rod, the surface of which should be free of corrosion. Simultaneously with the start of casting, water heated in the boiler is supplied to the mold casing at a temperature of at least 70-80 ^o C and a pressure of at least 0.2 MPa. Magnesium alloy is fed into the molds at a speed of 1-3 kg / s. After pouring without shutting off the water, the mold is cooled, after 3-4 minutes the tread is removed and stored. The obtained protectors have the following composition, wt.%: Aluminum - 5.0-7.0; zinc - 2.0-4.0, manganese - 0.02-0.50: iron - not more than 0.003; titanium - not more than 0.04; copper - not more than 0.004; nickel - not more than 0.001; silicon - not more than 0.04.

 Magnesium protectors for corrosion protection of oilfield structures in the underwater zone (type PMM-20, PMM-30, PMM-60) are made from alloys of the grade MP-2, MP-3, MP-4, MP-5, MP-6. For the manufacture of the core of the treads, a steel strip or circle made of steel grade B, Art. The core must be coated. The mass of the tread is at least 20 kg and the core is at least 2.8 kg, and the ratio of height to tread width is (0.8-1.2) :( 1.12-0.8). The tread core is made along the entire length of the tread and protrudes at a distance of 1 / 7-1 / 12 of the total length. The core is installed in the tread with a ratio of the radius of curvature to the height of the tread equal to 3 / 5-1 / 3.

 The surface of the treads does not contain flux, oxide inclusions and impurities, as well as shrinkage shells and voids and corresponds to GOST 26251-84.

Claims (5)

 1. The tread of a magnesium alloy, made of a semicircular shape, with a core located along its axis, characterized in that the core is located along the entire length of the tread, and the ratio of tread height to its width is (0.8 - 1.2): (1, 12 - 0.8).  2. The tread according to claim 1, characterized in that the core protrudes from two sides of the tread to a distance of 1/7 - 1/12 of the total length of the tread. 3. A method of casting the tread, including heating the mold, installing the core in the mold, pouring a magnesium alloy, supplying water to the tread to cool the tread, characterized in that the core is heated before being installed in the mold, the magnesium alloy is poured at a speed of 1-3 kg / s, and the water supply is carried out constantly at a temperature of 70 - 80 ^o C and a pressure of more than 0.2 MPa.  4. The method according to claim 3, characterized in that the heating time of the mold is more than 30 minutes 5. The method according to claim 1, characterized in that the heating of the core is carried out at a temperature of more than 100 ^o C.