RU50890U1 - CASTING SHAPE - Google Patents

Abstract

The utility model relates to foundry. The technical task of the utility model is to obtain a dense casting without gas impurities and shrinkage holes in the recess under the flange in the third cavity. The problem is solved as follows. The mold contains a gating system. The gating system includes lateral and upper profits, three internal working cavities, two of which are located on the same axis and communicated with lateral profits, and the third cavity is located on the perpendicular axis and communicated with upper profits, each cavity having a recess under the flange. New in the utility model is that the shape is equipped with a tide located on the axis of the third cavity and communicated with this cavity and the upper profit, while the cross-sectional area of the tide in the plane perpendicular to the axis of the third cavity is not less than the minimum cross-sectional area of the flange of the third cavity, in a plane parallel to its axis.

Description

The utility model relates to foundry.

A known mold containing a gating system, which includes three lateral profits, three internal working cavity, two of them are located on the same axis, and the third on the perpendicular axis, all cavities communicated with lateral profits. All cavities are interconnected, they have a recess in the walls under the flange. (Sokolova A.N. Mechanization and automation of foundry. Lenizdat. 1957, pp. 171-172).

The disadvantage of this sprue system is that the hydrostatic pressure of the metal coming from the side profits is too small and defects appear in the form of shrink shells, both in the walls of the casting and in the flanges.

The closest analogue is the mold containing the gating system. The gating system includes lateral and upper profits, three internal working cavities, two of which are located on the same axis and communicated with lateral profits, and the third cavity is located on the perpendicular axis and communicated with both upper and lateral profits, with each cavity recess under the flange. (Sokolova A.N. Mechanization and automation of foundry. Lenizdat. 1957, p. 176. Fig.)

The main disadvantage of the mold with this arrangement of the gating system is the insufficient spillability of the upper part of the recess under the third flange

cavity due to the fact that the upper profit is not involved in the filling of the recess under the flange, but only in the filling of the walls. The recess under the flange is poured with the help of massive lateral profit communicated with the third cavity, which does not result in complete crystallization, since the metal goes from bottom to top and it has too little hydrostatic pressure, which is not enough for the metal to rise. As a result, defects in the form of a shrink shell appear in the upper part of the recess under the flange, as well as gas impurities.

The utility model aims to overcome this drawback.

The technical task of the utility model is to obtain a dense casting without gas impurities and shrinkage holes in the recess under the flange in the third cavity.

The problem is solved as follows.

The mold contains a gating system. The gating system includes lateral and upper profits, three internal working cavities, two of which are located on the same axis and communicated with lateral profits, and the third cavity is located on the perpendicular axis and communicated with upper profits, each cavity having a recess under the flange.

New in the utility model is that the form is equipped with a tide located on the axis of the third cavity and communicated with this cavity and the upper profit, while the cross-sectional area of the tide in a plane perpendicular to the axis of the third cavity is not

less than the minimum cross-sectional area of the flange of the third cavity, in a plane parallel to its axis.

The utility model is implemented as follows.

The mold contains a gating system. The gating system includes side profits 1 and top profit 2, three internal working cavities 3, 4, 5, two of which 3, 4 are located on the same axis 6 and communicated with side profits 1, and the third cavity 5 is located on the perpendicular axis 7 and communicated with an upper profit 2. Each cavity has a recess under the flange 8. The mold is provided with a tide 9 located on the axis 7 of the third cavity 5 and communicated with this cavity 5 and the upper profit 2. The cross-sectional area 10 of the tide 9 in the plane perpendicular to the axis 7 is not less than the minimum cross-sectional area 11 flange and 8 of the third cavity 5, in a plane parallel to its axis 7.

The utility model works as follows. When casting, the metal is poured into the side profits 1, through which it enters the internal cavities 3, 4, filling them through the recesses under the flanges 8, then the metal fills the tide 9 and the upper profit 2.

Then begins the crystallization of the metal, as a result of which the upper profit 2 through the tide 9 feeds the recess under the flange 8 in the third cavity 5 until complete crystallization.

With the help of the tide, the upper profit is involved in the fill, since it communicates with a recess under the flange. The metal that flows from it has more hydrostatic pressure, it

denser fills the recess under the flange, which is in the third cavity, since the metal goes from top to bottom, while it has no impurities, they remain in profit. In order to fulfill the directed crystallization condition, that is, so that when modeling crystallization it is possible to roll out a thermal unit (ball) from the recess under the flange into the tide, the tide cross-sectional area in the plane perpendicular to the axis of the third cavity should be no less than the minimum cross-sectional area of the third cavity in a plane parallel to its axis. Thus, the tide serves as a channel for directional crystallization, where normal crystal growth occurs from the upper profit through the tide to the recess under the flange in the third cavity.

Claims (1)

A mold containing a gating system including lateral and upper profits, three internal working cavities, two of which are located on the same axis and communicated with lateral profits, and the third cavity is located on the perpendicular axis and communicated with upper profits, each cavity having a recess under the flange, characterized in that the mold is equipped with a tide located on the axis of the third cavity and communicated with this cavity and the upper profit, while the cross-sectional area of the tide in a plane perpendicular to the axis of the third cavity, no less than the minimum cross-sectional area of the flange of the third cavity, in a plane parallel to its axis.