RU2352431C2 - Punching method of welding neck flange forging - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: preliminarily swaged blank is pressed out into tapered part of matrix and it is received preliminary forging with flange of required dimensions, conical flange part and preliminary outline for reach-through hole. Preliminary outline allows forming angle at the side surface. Tapering of flange part of preliminary forging exceeds tapering of flange part of final forging. Then it is implemented punching of final forging with shaping of conical flange part, allowing undeviating reach-through hole. Mentioned shaping is implemented by means of cut off of forming slope and crosspiece broaching. These operations are implemented simultaneously with distribution and elongation of flange part and calibration of reach-through hole.

EFFECT: reduction of metal consumption and reduction of straining effort while punching.

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Description

The invention relates to the processing of metals by pressure and can be used in forging and stamping in the manufacture of forgings of standard parts collar flange (GOST 12821-80) on stamping hammers.

A known method of stamping forgings such as flanges on hammers (II group 1 subgroup) and presses (I group 2 subgroup) (Forging and stamping: Handbook. In 4 volumes / Ed. Advice: E.I. Semenov and others. - M : Engineering, 1986 - T. 2. Hot stamping / Under the editorship of EI Semenov, 1986. - 592 p.). Stamping at the end face is usually carried out in two transitions: the draft and the final shaping with the outline of the central hole. Finishing operation: trim flashing and flashing holes. The disadvantage of this method is the availability of allowances and inlets (stamping slopes) on the wall of the stitched hole, which determine the increased complexity of the subsequent mechanical processing of forgings.

A known method of removing stamping slopes by calibrating holes (A.S. Konkov. Cleaning and finishing forgings. Popular science library of a blacksmith worker. Issue 16. M. - Sverdlovsk: Mashgiz, 1960. - 70 p.). Calibration is performed after combined trimming and firmware in a special stamp. The stamping slope is cut off by a punch with a cutting edge.

Also known is the design of a combined stamp for simultaneous trimming, punching, removing slopes and dressing (Forging and stamping: Handbook. In 4 volumes / Ed. Advice: EI Semenov et al. - M: Mechanical Engineering, 1986. - T .2. Hot stamping / Under the editorship of EI Semenov, 1986. - 592 p.). A punch punch at the same time punches the jumper and cuts off the internal slopes in the central hole of the forging. The disadvantage of this method and the stamp is the preservation of the allowance for machining the hole.

There is a method of low-waste, steady stamping of axisymmetric forgings (Intensification of metal forming processes / O.G. Vlasov, V.I.Kazachenok, I.B.Pokras and others. - Izhevsk: Udmurtia, 1989. - 112 pp .; patent No. 2159690 " A method of manufacturing annular forgings without stamping slopes "). In case of low-waste stamping of circular forgings round in plan without admission to internal slopes, sequential or combined dies are used to trim the flake, punch the jumper and distribute the hole with a punch through the remainder of the technological jumper (Forging and stamping: Handbook. In 4 volumes / Editorial tip: EI Semenov et al. - M: Mechanical Engineering, 1986 - T. 2. Hot stamping / Edited by EI Semenov, 1986. - 592 p.). The disadvantage of these technical solutions is the preservation of the allowance for machining the hole.

Known methods for the manufacture of hollow flange forgings (RF patent No. 1552460 "Method for the manufacture of hollow flange forgings", No. 2217262 of the Russian Federation "Method for the manufacture of hollow flange forgings", No. 2169632 of the Russian Federation "Method for the manufacture of hollow flange forgings"). A common drawback of these technical solutions is the preservation of the allowance for the machining of the hole, multi-transition stamping and marketability only on crank hot stamping presses.

A known method of manufacturing a hollow axisymmetric products (patent No. 1807914 "Method for the manufacture of hollow products"). A specially prepared blank is placed in the upper part of the matrix and shaping (piercing) is carried out with a punch, the larger diameter of which is equal to the smaller diameter of the matrix or less than it. When this occurs, the process of combined extrusion by shear (PIC) of the metal under the punch and its displacement into the lower part of the matrix cavity. The deformation diagram and examples of technological transitions of stamping axisymmetric products using FAC, including collar flanges, are given in the work of Yu.P. Katrich. Combined extrusion by shear / Forging and stamping, 2005 - No. 3, p.22-28. The disadvantages of this method are:

- the need for preliminary preparation of the initial billet by calibration in the container, curly draft, closed stamping with calibration;

- obtaining high-quality forgings with a hollow hub is possible only with a narrow range of ratios of the firmware coefficient (the ratio of the cavity area and the larger base of the workpiece) and the area of the side supporting surface of the workpiece.

Combined shear extrusion is implemented in the method of stamping a conical sleeve with a flange (AS No. 532444 "Method of stamping in the matrix of a conical sleeve with a flange"). The method involves extrusion with backpressure of a pre-deposited preform to obtain a flange of the required size, and then the resulting preform is flashed with a flange, filling the free part of the cone matrix with metal. A pre-deposited preform is laid in the matrix, and under the influence of the punch, the metal of the preform is extruded into the conical part of the matrix, having a slope equal to the stamping slope, until a flange of the required size is obtained. For a clear design of the angle of the lower end and to prevent bulge at the end, a counter-pressure pusher is used. After extrusion, the workpiece is placed in a matrix having a slope equal to the stamping slope, where it is stitched with a punch, filling the free part of the conical matrix. The excess volume of the workpiece is then removed in the form of a “notch” of variable height. The specified method is selected by the applicant as a prototype.

The disadvantage of the prototype is the possibility of warping at the second stamping transition of the flange part of the forging, non-filling of the corners of the cavity of the matrix of this transition, the presence of a stamping slope and allowance for the machining of the hole, great effort and deformation.

The technical task of the invention is to increase the manufacturing efficiency of forgings collar flanges by reducing the volume of subsequent machining, reducing metal consumption, reducing forces and work of deformation.

To achieve the task in a method of stamping forgings of collar flanges, including stamping a preliminary forging by extruding a pre-deposited blank into a conical part of the matrix with the formation of the flange of the required size and conical collar part and stamping the final forgings with the formation of a conical collar part having a steady through hole, according to the invention stamping of the preliminary forging is carried out to obtain a tapered collar with a taper exceeding the taper of the collar part of the final forging, and basting through the hole with a stamping slope on the side surface, and the formation of the conical collar part with a steady through hole when stamping the final forging is performed by cutting the specified stamping slope on the side surface of the basting and flashing the jumper, which is carried out simultaneously with the distribution and extension of the collar part and the calibration of the through hole.

Performing stamping of the preliminary forging with obtaining a conical collar part with a taper greater than the taper of the collar part of the final forging allows for the collar part to be distributed by stamping the final forgings, which helps to reduce the forces and work of deformation, in addition, it allows to compensate for the thickening of the collar wall due to more intense wear of the preliminary stream and thereby ensure its stable placement in the cavity of the piercing matrix.

The shaping of the conical collar part with a steady through hole during stamping of the final forgings reduces the amount of subsequent machining, that is, to obtain the final hole size by eliminating the internal stamping slopes and machining allowance.

Basting under the through hole having a stamping slope on the side surface and shaping the conical collar of the forgings by cutting off the specified stamping slope on the side surface of the basting and flashing the jumpers, which are carried out simultaneously with the distribution and extension of the collar part and calibration of the through hole, helps to reduce metal consumption due to the use of part of the metal stamping slopes, and also helps to reduce the forces and work of deformation.

Patent studies have not identified methods characterized by the claimed combination of features, therefore, we can assume that this method meets the criterion of "novelty."

The use of a combination of distinctive features is also not known, which indicates compliance with the criterion of "inventive step".

In addition, the proposed method can be used on an industrial scale and will find application, in particular, in forging and stamping in the manufacture of forgings of standard parts - collar flange, i.e. characterized by the criterion of "industrial applicability".

The essence of the claimed technical solution is illustrated by diagrams and photographs, where Fig. 1 shows the stages of shaping upon receipt of preliminary forging, Fig. 2 shows the stages of shaping upon receipt of final forgings, in Fig. 1 - experimental forging "collar flange" Ru16Du50, in Fig. 2 - experimental batch of forgings "collar flange".

The inventive method is as follows.

A piece billet heated to forging temperature is upset, then the preliminary forging is stamped in an open stream to obtain a flange of the required size and two-sided basting under the hole (Fig. 1), while the taper of the collar part of the preliminary forging is larger than the final one, and the height is less. Then trim the flap and stamp the final forging (Fig. 2), while forming the collar part of the forgings with a steady through hole by cutting the stamping slope and flashing the jumper, accompanied by the distribution and extension of the collar part while calibrating the hole.

The process of flashing and calibration is as follows. The firmware is embedded in the slope on the lateral surface of the main (upper) basting and begins to cut it (figa). At the same time, the calibrating belt enters the basting cavity, distributing it and moving the slope metal along the direction of the combined piercing. In this case, the metal is redistributed with thinning of the wall and lengthening of the collar part. After full contact on the conical surface of the matrix, an angular turn of the collar part occurs (Fig.2b), lying below the piercing before contact with the cylindrical part of the matrix, and the piercing reaches the body of the jumper. Next, the firmware rests against the jumper (figv-d), and the cylindrical section of the collar wall is drawn and the jumper is cut. At the same time, a calibrating belt passing through the cavity of the conical section of the matrix performs an axial shift of the metal. Depending on the geometrical features of preliminary forging at this stage, shaping options are possible in which either the drawing effect may prevail, accompanied by a thinning of the formed cylindrical section of the collar wall, or an extrusion pattern due to the advance movement of the metal with a calibrating punch belt.

Next, the final cut of the jumper occurs, while the calibrating girdle is located at the exit from the conical zone of the matrix (fig.2d). With further advancement, the calibrating girdle distributes and calibrates the cylindrical portion of the collar (Fig. 2e).

Thus, hot stamped forgings of collar flanges without allowances and stamping slopes in the central hole are obtained in two forming operations. Pre-stamping has all the stamping biases necessary to remove the forgings from the stream, the final geometric parameters are given only to the flange part of the preliminary forging, the collar part is pre-formed. Giving this part of the forgings the final shape and size is carried out when performing finishing operations on the edging press. Here, in a specialized stamp, an overlay is successively cut off and a collar forging a flange with a steady hole is formed. The deformation scheme used combines the elements of the slope of the stamping slope and the firmware of the jumper, accompanied by the distribution and extraction of the collar part while calibrating the hole.

The development and justification of the proposed stamping transitions was carried out on the basis of the results of mathematical modeling of plastic forming.

For these purposes, we used the object-oriented software package RAPID-2D. As a result of a series of computational experiments, the influence of the following structural and technological factors on the character of the shape formation of forgings of flanges of various sizes was established:

- designs and sizes of the working elements of the combined (firmware-calibrating) punch and die for final shaping;

- the shape and size of the collar of the preliminary forging;

- speed and temperature of deformation, contact friction.

The simulation results made it possible to develop the design and technological documentation for the pilot industrial testing of the technology for stamping the forgings of the Ru16Du50 flange (photo 1). An experimental stamping, carried out using KGShP 25MN, a 4MN edging press with a special stamp, showed the attainability of the predicted shape and size of the final forging with the required surface roughness of the central hole.

As a result of summarizing the results of computer simulation of deformations, laboratory and factory experiments, a methodology has been developed for the design and technological design of stamping transitions and tools for the created technology.

The final forging is designed according to the final drawing of the flange in accordance with GOST 7505-89. Forging parameters: M1 (M2, M3), T4, C4. Allowances are assigned only to end surfaces, the central hole has no stamping slopes, and its diameter corresponds to the final size. The radii of rounding of the outer and inner corners of the forgings are prescribed from the condition of smooth conjugation of surfaces and the underestimation of metal consumption.

The preliminary forging is designed according to the drawing of the final forging and differs from the final one only in the shape and size of the collar section. Its flange part is finally formed in the preliminary stamping operation. When using a PVShM for this purpose, it is advisable to place the cavity under the collar in the upper part of the stamp, and when stamping on the KGShP, in the lower part. The outer surface of the die connector is assigned to the forging flange. The collar contour is formed by two smoothly mating conical surfaces with an inclination angle of 26 ° and 7 °. In preliminary forging, two-sided basting is performed for flashing the central hole. The main part of the hole marking has a stamping slope of 5 °, the height of the collar part of the preliminary forging is determined from the condition that the volumes of preliminary and final forgings are constant minus the volume of the jumper.

The specified design methodology was tested during the technological preparation for the production of forgings of collar flanges at the Forge Plant of OJSC “Kurganmashzavod” (photo 2). With its application, new stamping technologies of the following flange nomenclature have been developed and tested: Ru16Du40, Ru16Du50, Ru25Du50, Ru40Du50, Ru16Du80, Ru40Du80, Ru64Du80, Ru16Du100, Ru40Du100, Ru64Du100, Ru16Du150, Ru40Du150.

The main provisions of technological design will ensure the production of a range of high-quality forgings of small and medium collar flanges:

- with a central hole without stamping slopes and machining allowances;

- with an allowable deviation from flatness of the flange part of the forging;

- in the absence of gaps and clamps on the surfaces of the forgings;

- with reduced metal consumption.

The achieved accuracy of the diametrical size and surface quality of the central hole made it possible to eliminate the operation of its boring. Along with the effect of eliminating machining, a reduction in metal consumption by 8-10% is achieved due to the organization of a rational flow pattern at the preliminary and final stamping transitions.

Claims (1)

A method of stamping forgings of collar flanges, including stamping a preliminary forgings by extruding a pre-deposited blank into a cone part of the matrix with shaping a flange of the required size and cone collar part and stamping the final forging with shaping a cone collar part having a steadless through hole, characterized in that the stamping is preliminarily carried out to obtain a conical collar with a taper greater than the taper of the collar parts of the final forging, and basting for a through hole having a stamping slope on the side surface, and the formation of a conical collar part with a steady through hole when stamping the final forging is performed by cutting the specified stamping slope on the side surface of the basting and flashing the jumper, which are carried out simultaneously with the distribution and extension of the collar and calibration of the through hole.

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