RU2048955C1 - Method of making castings of ferrous and non-ferrous metals - Google Patents

Abstract

FIELD: casting production. SUBSTANCE: method of making castings includes steps of preparing a mold by filling a floatable self-hardening mixture into a technological fitting, to which a pattern had been placed beforehand; removing the pattern; calcining the mold, pouring the metal to the mold for crystallizing it; performing a step of calcining the mold at temperature, being no more, than 572 C; pouring the liquid metal under pressure by squeezing out way with crystallization under pressure; upon making patterns from a water soluble composition facing the patterns by wax-like composition, upon making castings of titanium and its alloys using as a floatable self-hardening material liquid aluminium and its alloys and using zinc and its alloys as material for making patterns. EFFECT: enlarged manufacturing possibilities of the method at making precision castings. 5 cl

Description

 The invention relates to foundry and can be used to produce precision castings with increased mechanical properties of the metal in one-time forms manufactured by lost wax, water soluble or burnable models.

A known method for producing precision investment castings, including manufacturing models, applying a multilayer refractory coating (usually 4 layers or more) to the model by repeatedly performing dipping operations in a refractory slurry, followed by sprinkling with dry granular refractory and drying, smelting models from a multilayer shell, molding the shell in the flask with dry granular refractory filler, laying the formed shell in the furnace at 800-1100 ^о С, gravitational pouring of the melt (with overheating above the liquidus temperature) and exposure for the solidification of the metal in the form at atmospheric pressure.

 At the same time, models in some cases are also made of a water-soluble composition, such as urea, as well as from polystyrene foam, which is burned before casting with metal during calcination of molds.

The closest technical solution is a method of manufacturing castings, including the manufacture of a mold by pouring a liquid-moving self-hardening mixture (f. S. Into technological equipment, in which the model is pre-installed, removing and calcining the mold, pouring the mold into metal and hardening, while heating forms are carried out at 200-300 ^about With in a vacuum, which is maintained at the level of (1-2) ˙ 10 ⁴ PA for 45-2 hours

The use of vacuum complicates the process of manufacturing molds. Free (gravitational) pouring into a mold at 200-300 ^о С limits the nomenclature of the obtained castings due to impenetrability of thin long walls, and heating molds to 800-900 ^о С is associated with high energy costs and cracking of molds due to transformations in quartz sand.

 The mechanical properties of the metal of the castings obtained are inferior to rolled products, which leads to an increase in the metal consumption of products with cast parts and does not allow their use in critical products. In addition, there are restrictions on the nomenclature of casting due to defects in underfilling and blockages.

The invention consists in that in the method of manufacturing castings of ferrous and non-ferrous metals and their alloys, comprising the manufacturing mold by pouring zhidkopodvizhnoy self-hardening mixture in the tooling, calcifying form is carried to a temperature not higher than 572 ^{° C,} and then molten metal under pressure method of squeezing with crystallization under pressure (LVCD).

 The proposed mode of calcination of molds and the method of pouring metal into molds simplify the technology and expand the technological capabilities of casting, and reduce the amount of scrap by underfilling.

The upper limit of the calcination temperature form 572 ^{° C} with the temperature set transformations in silica sand (at 573 ^{° C} β-quartz transforms into α -kvarts with the increase in linear dimensions by 1.4% which can lead to cracking of shapes).

 Pouring a molten metal under pressure (LVCD) provides good spillability and obtaining even in cold forms of thin-walled long castings made of steel and non-ferrous alloys, and the relatively low temperature of the molten melt in the crystallization interval, and solidification of the melt in a "cold" form under pressure allow to obtain increased mechanical properties of metal precision castings, at the rental level.

 When casting copper melts using the HDPE method in gypsum molds, high-quality, accurate castings from any bronzes are obtained by investment casting models. This is ensured by the low temperature of pouring the melt into the mold and crystallization under pressure.

 In some cases, when castings are made from aluminum and copper alloys, cast iron and steel in one workshop, and there is a need to use one type of iron. from. from. for example, gypsum, or steel castings are made in cement forms with increased requirements for the cleanliness of their surface, before pouring. from. from. 1-2 layers of refractory coating are applied to the model, it is dried, and then impregnated with water.

 The presence on the surface of the gypsum mold of the refractory coating and the pouring of the melt under pressure at low temperature provide the possibility of forming a high-quality surface of the steel casting before decomposition of the gypsum begins (in this case, the refractory coating plays the role of thermal protection).

 The use of one type of mold material in the foundry simplifies the solution of organizational issues. The refractory coating on the working surface of the cement mold or on the mold surface of liquid-bulk mixtures ensures the surface quality of the castings is the same as in the usual investment casting process, with a significant reduction in the production cycle and production areas, reducing the cost of casting.

 The next difference of the proposed method lies in the fact that in the manufacture of lost wax models from a water-soluble composition, they are faced with a waxy composition. This solution allows the use of models of water-soluble strong compounds to obtain large castings using g. from. from. containing water (as the material of the models, compositions based on urea or polyethylene glycol are used). Combined models are obtained, for example, by pouring into the mold a liquid waxy model composition and its subsequent discharge after freezing a thin crust, and then, for example, a composition based on polyethylene glycol is poured into the resulting shell. The combined model is non-hygroscopic and does not interact with the mold material.

 After pouring the combined model g. from. from. "grasping" it, first dissolve the base of the model in water, and then a thin-walled waxy shell is melted.

 Models of water-soluble compositions are not subject to warping, which is an important factor in the manufacture of large castings.

 In the manufacture of castings from titanium and alloys based on it as a material from. from. use liquid aluminum or alloys based on it. Moreover, as the material of the models, a more fusible metal is used, for example, zinc and its alloys, or water-soluble compositions, for example, salts, etc.

 After pouring the aluminum melt and solidifying it, the models are removed from the molds by smelting or dissolving in water.

 In the process of pouring the titanium melt by the HPLC method into an aluminum mold and solidifying it, the mold heats and melts. The mold material is reused and the process repeated.

 Another difference of the method lies in the fact that in the manufacture of large, long, thin-walled castings, investment models are made of polyethylene. This allows you to significantly expand the technological capabilities of foundry technology by increasing the casting range of products currently manufactured from expensive rolled products, such as steel pipes, reinforcing steel for building structures, various welded assemblies, etc. Moreover, polyethylene models of a simple configuration, for example pipes are made by extrusion.

EXAMPLE 1. A block of investment models made of paraffinostearin model mass is installed in a steel cassette with a pouring funnel down and filled in. from. from. gypsum molding sand mixture of the following composition, Gypsum 60 Quartz sand 35 Ground mica 5
The gypsum factor (the ratio of water to dry component) is 66-70%
5 minutes after pouring from. from. (setting time of gypsum 2.7 min) the model is smelted from the mold in hot water. During smelting, the model composition does not enter the pores of the mold, since they are filled with water. Drying to remove moisture and mold in the cassette calcination is carried out in a heating furnace at 450 ^C. After baking form with the cassette removed from the oven and, depending on the process requirements, produce an extract to reduce the temperature to the required limit. Then the cartridge is installed in the container of the casting machine by squeezing with crystallization under pressure, the melt of bronze is poured into the squeezing chamber, and at liquidus temperature the melt is squeezed out of the chamber into the mold by moving the chamber upward at a predetermined speed, for example, 15 mm / s (metal speed in the gate 0.7 m / s). Immediately after filling the working cavity of the mold, compressed gas is supplied to the container under a pressure of 0.5 MPa and holding is carried out until the casting solidifies completely. Due to the low melt pouring temperature (without overheating above the liquidus temperature), the mold temperature not higher than 450 ^C and high casting speeds the contact time of the liquid phase to the surface of the mold is close to zero, ie. E. Almost immediately after the mold filling is the formation of solid crusts metal on its surface and gas formation processes, for example, due to decomposition of gypsum, no longer have a negative impact on the surface quality of the casting. Crystallization of the melt under gas pressure provides a dense casting with high mechanical properties of the metal at the rental level.

 The hardened cast is removed from the mold and the process is repeated.

 PRI me R 2. The list and sequence of operations is the same as in example 1. The difference lies only in the fact that when receiving steel castings use g. from. from. from a mixture of quartz sand, cement (8-12% by weight) and water (30-40% in excess of 100%).

 PRI me R 3. The list and sequence of operations is the same as in example 1. The difference is that before filling g. from. from. from the gypsum-containing composition, one layer of refractory suspension on ethyl silicate is applied to the model, sprinkled with chamotte powder, dried and then impregnated with water.

The finished form after drying and calcining at a temperature of 500 ^about With pour cast iron.

PRI me R 4. To obtain a large casting in a metal mold is poured the model composition PS 50-50 at 70 ^about C, hold for 1-2 s and drain the liquid residue. Then the mold was molded composition based on polyethylene glycol at 47 ^C. After solidification polyethylene formed hybrid model: a thin outer layer of a waxy composition, the remainder of the water-soluble composition.

 The outer waxy layer provides non-hygroscopicity when storing models, as well as non-interaction with water-containing g. from. from. when pouring it.

 The finished model is removed from the mold and subsequent operations similar to those described in examples 1,2 and 3 are performed except for removing the model from the mold: first dissolve the model base from polyethylene glycol in cold water, and then the remaining thin shell from the waxy composition is melted in hot water .

PRI me R 5. The expanded polystyrene model is poured g. from. from. containing cement. After "setting" g. from. from. the mold is placed in an electric furnace and produce a suction holding at 170 ^{° C} for the evaporation of expanded polystyrene. The remaining operations are performed similarly to the operations in the above examples.

 PRI me R 6. A complex casting of titanium alloy VT5L receive in the following sequence.

A casting model is molded from a zinc alloy under pressure (in some cases, the model can consist of several separately cast parts, and then assembled into one unit), which is installed in a metal mold and poured under low pressure with an aluminum alloy of the following composition: Fe 2% Si 1, 5% Al the rest. The aluminum casting is removed from the metal mold and placed in a thermo model for smelting at 420 ° ^C.

The finished aluminum mold is fixed in a squeeze casting machine located together with the melting furnace in a vacuum chamber, the VT5L titanium alloy melt is poured into the squeeze chamber, and then the melt is squeezed out at a temperature t _liquor into the working cavity of the mold and mechanical pressing is performed.

 In the process of hardening and cooling of the titanium casting, the aluminum mold heats up and melts. The titanium casting is removed from the vacuum chamber, the mold material is sent for reuse and the process is repeated.

 PRI me R 7. A steel pipe with an outer diameter of 500 mm, a wall thickness of 5 mm and a length of 6000 mm is obtained as follows.

 An extruded polyethylene pipe with dimensions greater than the shrinkage of steel is installed in the cassette and poured. from. from. containing cement, with vibration. At the same time, a metal rod is placed inside the model to reduce consumption. from. from.

After pouring g. from. from. "setting" mixtures, the constant rod is removed, and the mold with the model is placed vertically in a shaft electric furnace, where it is heated to 450 ^° C and held. In the process of heating, the polyethylene melts (mp. 104-115 ^о С), overheats and flows down into the tray located under the mold.

 The finished mold is installed in a squeezing molding machine with crystallization under pressure above the squeezing chamber, steel is poured into the chamber, exposure is carried out, and at the temperature of crystallization onset, steel is squeezed into the mold by moving the chamber upward at a speed of 20 mm / s. After filling out the form, a gas pressure of 0.5 MPa is supplied to the profitable part of the casting. The hardened cast is removed from the mold and the process is repeated.

 The proposed method allows to reduce the cost of casting, to expand technological capabilities.

Claims (5)

1. METHOD FOR PRODUCING CASTINGS FROM BLACK AND NON-FERROUS METALS and alloys based on them, including the manufacture of a mold by pouring a liquid-moving self-hardening mixture into technological equipment, into which the model is pre-installed, its removal, calcination of the mold, casting of the mold with metal and its solidification, characterized in that that the calcination of the form is carried out to a temperature not higher than 572 ^o C, and pour the molten metal under pressure by squeezing with crystallization under pressure.  2. The method according to claim 1, characterized in that before pouring the liquid-moving self-hardening mixture, 1 2 layers of refractory material are applied to the model, dried, and then impregnated with water.  3. The method according to claims 1 and 2, characterized in that the models are made of a water-soluble composition and veneered with a waxy composition.  4. The method according to PP.1 to 3, characterized in that the form is made of liquid aluminum or its alloys based on it, and the model of zinc and its alloys.  5. The method according to PP. 1 and 2, characterized in that the models are made of polyethylene.