RU2063836C1 - Method of internal-combustion engine pistons production - Google Patents

Abstract

FIELD: mechanical engineering, production of internal-combustion engines pistons. SUBSTANCE: heated blank is preliminary stamped in stamp, punch of which has ring-type bulge directed to lower half of stamp. After preliminary stamping semi-finished product of VV₁ is produced. Semi-finished product has ring type bulge, due to which during final deformation filling of stamp lower half cavity is exercised by reverse stamping. Diameter DD₁ of stamp lower half cavity after preliminary stamping is equal to 0.97 - 1.0 of diameter D D₂ of stamp cavity after final stamping. Semi-finished product produced after preliminary stamping has volume equal to 1.0 - 1.07 of piston volume produced after final stamping. After preliminary stamping fin cutting-off is exercised during final stamping process. EFFECT: improved process. 4 dwg, 1 tbl

Description

 The invention relates to the processing of metals by pressure and can be used in mechanical engineering in the manufacture of pistons of internal combustion engines.

 Closest to the invention in technical essence and the achieved result is a method in which the stamping of the pistons of internal combustion engines is carried out in a stamp, the punch of which corresponds to the internal configuration of the piston, and the lower half is provided with a cavity, the side surface of which is formed by two consecutive surfaces, one of which the bottom of the cavity is made in the form of a cylinder, and the cylindrical and bottom surfaces are interconnected by an annular ditch 1.

 The disadvantage of this method is that when stamping pistons from a cylindrical billet on the annular surface of the extruded metal, significant tensile tangential stresses arise, the direction of which coincides with the directions of the tangents to the concentric circles of the ring. Due to the fact that high-silicon alloys with low technological ductility are used for the manufacture of pistons, stamping may destroy the wrought metal due to high stresses.

 The technical problem, the solution of which the present invention is directed, is to eliminate the destruction of the wrought metal.

 The problem is solved in that in a method for manufacturing pistons of internal combustion engines, including the preparation of a workpiece and final stamping in a stamp, the punch of which corresponds to the internal configuration of the piston and the lower half is provided with a cavity, additionally stamping is carried out in the stamp, the punch of which is equipped with a conical protrusion directed towards the lower half of the stamp, made with a conical cavity, the diameter of which at the intersection with the plane facing the punch, was it is from 0.97 to 1.0 on the diameter of the cavity of the lower half of the final stamping stamp at its intersection with the plane facing the corresponding punch, after preliminary stamping a semi-finished product is obtained, the volume of which is from 1.0 to 1.7 of the volume of the finished piston , and in the process of final stamping, the trim obtained from preliminary stamping is trimmed.

 The supply of the stamp of pre-stamping with a punch with a conical protrusion directed towards the lower half of the stamp, contributes to the fact that in the process of pre-stamping in the workpiece an annular protrusion is formed. At the final deformation, due to the presence of an annular protrusion, the cavity of the lower half of the die is filled by reverse pressing, in which there are practically no tangential stresses in the deformable metal, which prevents the destruction of the metal.

 The supply of the lower half of the pre-stamping die with a conical cavity, the diameter D1 of which is from 0.97 to 1.0 from the diameter D2 of the cavity of the final stamping stamp, helps to reduce tensile stresses in the conical billet during deformation in the final stamping stamp due to the insignificant difference in their diameters in the preliminary and final stamps.

 When the value of the diameter D1 of the cavity of the stamp of the preliminary stamping is greater than the diameter D2 of the cavity of the stamp of the final stamping, the semifinished products will not be placed in diameter in the final stamp, which will make it difficult to separate the flake, which will be stamped as a defect.

 When the value of the diameter D1 of the cavity of the stamp of the preliminary stamping is less than 0.97 of the diameter D2 of the cavity of the stamp of the final stamping (D1 <0.97 D2), it is difficult to chip the flake because it can be pulled into the cavity of the stamp and stamped in the form of a defect. In addition, with this ratio, significant tangential stresses arise, which can lead to the destruction of the workpiece.

 Obtaining after pre-stamping of the workpiece with a volume equal to from 1.0 to 1.07 of the piston volume after the final stamping, contributes to the complete filling of the stamp volume of the final stamping with metal. And when the metal comes into contact with the end face of the punch, the excess metal goes into the burr of the final stamping stamp.

 Obtaining a semi-finished product with a volume of more than 1.07 from the volume of the finished piston leads to an overspending of metal due to the increased volume.

 The operation of trimming the flake after preliminary stamping in the process of final stamping helps to reduce the complexity of manufacturing products, does not require tools and equipment for the operation to remove the flake.

 In FIG. 1 shows a general view of a pre-stamping stamp; in FIG. 2 general view of the stamp of the final stamping; in FIG. 3 is a general view of the semi-finished product after preliminary stamping, as in FIG. 4 General view of the piston after final stamping.

 The punch 1 of the pre-stamping die is equipped with a conical protrusion 2, and the lower half 3 is provided with a conical cavity 4, the diameter D1 of which is from 0.97 to 1.0 from the diameter D2 of the cavity 5 of the lower half 6 of the final stamping die. Position 7 denotes the punch of the stamp of the final stamping. The semi-finished product obtained after preliminary stamping has an annular protrusion 8, and its volume is from 1.0 to 1.07 of the volume of the finished piston obtained after final stamping. The lower half 6 of the stamp of the final stamping is provided with a sharp working edge.

 The method is as follows.

 After heating, the cylindrical billet is placed in a pre-stamping stamp, the stroke of the upper crosshead of the press is turned on, and preliminary stamping is performed until the lower and upper halves of the stamp are closed. In the process of stamping, an annular protrusion is formed 8. After preliminary stamping, a blank with a volume of V1 is obtained. At the final stamping, also after heating, the semi-finished product is placed in the lower cavity 5 of the final stamping stamp. At the first moment, when the upper press beam moves down, the punch 7 presses on the surface of the semi-finished product. As a result of this, the flashing is cut off, which remains in the circumferential groove of the final stamping stamp, and the semi-finished product sinks to the bottom of the stamp cavity 5. With further movement of the punch 7, metal is extruded, which fills the entire lower die cavity, fitting the shape of the punch 7. In this case, the cavity 5 is filled by back pressing, and due to the presence of an annular protrusion, there are practically no tangential stresses in the deformable metal, which prevents its destruction. After the deformation is completed, the press traverse is turned on, the traverse with the upper half of the stamp rises. After that, the stamped piston with a volume of V2 is removed from the final stamp.

 An example of a specific implementation.

We stamped the pistons of the internal combustion engines of the IKARUS bus from AK18DP aluminum alloy. Stamping was carried out on a vertical hydraulic press with a force of 2500 tf, the metal heating temperature was 420 - 460 ^° C, the temperature of the dies was in the range of 250 - 400 ^° C. Cylindrical billets of size ⌀ 120 • 160 mm were heated in a resistance furnace, and then stamped in a preliminary stamped. The pre-stamped molds were also heated to the indicated temperatures and final stamping was performed. In this case, the dimensions of the preliminary stamp and the volume of its cavity were equal to the limiting, average, and transcendental declared sizes and volumes.

 To compare the claimed method with the closest analogue, the blank was stamped o 120 • 160 mm in a stamp made according to / 1 /.

 The results of the experiment are summarized in table.

 As can be seen from the table, when stamping by the method performed according to paragraphs 1.2, 1.3, 1.4 and 1.7, 1.8, 1.9, the semi-finished products had a full design, surface defects were absent. Details are fully consistent with the specified parameters and specifications.

 When stamping the semi-finished product according to Clause 1.1, tightening and stamping of the coating were observed, which caused the parts to become defective. The defect is caused by a significant difference between the die (final stamp) and the diameter of the part (pre-stamped semi-finished product).

 When stamping a semi-finished product according to Clause 1.5, a stamping of the shell was also observed, which displays the details in the marriage. The defect is caused by the excess of the diameter of the part over the matrix, leading to its tightening and stamping into the body of the part.

 When stamping a semi-finished product according to Clause 1.6, a non-filling of the cavity of the final stamp was observed due to the insufficient volume of the preliminary semi-finished product. In addition, cracks were found on the annular surface of the part due to the absence of impact from the end surface of the final stamp on the deformable metal.

 When stamping a semi-finished product according to Clause 1.10, the metal consumption increased by 3% due to a significant increase in the volume of the pre-die cavity.

 In all semi-finished products obtained prior to the method known from / 1 /, cracks were observed on the end surface of the parts.

As a result of the experiment, we can conclude that this method in comparison with the closest analogue has the following advantages:
due to preliminary deformation, semi-finished products of a given volume are obtained;
by supplying the pre-stamp punch with a conical protrusion, semi-finished products with an annular protrusion are obtained;
due to the receipt of the semi-finished product with the given dimensions, trimming of the flake after preliminary stamping is carried out in the process of final stamping.

 The advantages of this method compared to the closest analogue are due to the expansion of technological capabilities in the production of pistons from high-silicon aluminum alloys with high performance. YYY2 TTT1 TTT2

Claims (1)

 A method of manufacturing pistons of internal combustion engines, including obtaining a workpiece and final stamping in a stamp containing a punch corresponding in shape to the configuration of the piston cavity and the lower half with a cavity, characterized in that prior to final stamping, the blank is pre-stamped in a stamp containing the lower half and punch with a conical protrusion facing the lower half having a conical cavity, the diameter of which is at the intersection with a plane located on the side of the punch it is from 0.97 to 1.0 from the diameter of the cavity of the lower half of the stamp of the final stamping at the point of its intersection with the plane facing the corresponding punch, after preliminary stamping a semi-finished product is obtained, the volume of which is from 1.0 to 1.7 from the volume the finished piston, and in the process of final stamping, the trim obtained as a result of preliminary stamping is trimmed.

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