CN113059011A

CN113059011A - Extrusion and stretching composite forming equipment for forming large conical cylinder

Info

Publication number: CN113059011A
Application number: CN202110285897.7A
Authority: CN
Inventors: 张治民; 李国俊; 白雪智
Original assignee: North University of China
Current assignee: North University of China
Priority date: 2021-03-17
Filing date: 2021-03-17
Publication date: 2021-07-02
Anticipated expiration: 2041-03-17
Also published as: CN113059011B

Abstract

The invention discloses an extrusion and stretching composite forming device for forming a large-scale conical cylinder, which comprises a die female die, a middle shaft pressure cylinder, an annular pressure cylinder and a middle shaft plunger, the middle part of the die female die is a through forming channel, the diameter of the forming channel is gradually folded from top to bottom to allow a blank to deform, the middle shaft pressure cylinder and the annular pressure cylinder are coaxially arranged and are respectively erected on the forming channel up and down, the lower parts of the middle shaft pressure cylinder and the annular pressure cylinder are respectively connected with the middle shaft plunger and the annular plunger, the middle part of the annular pressure cylinder is a through plunger channel, the middle shaft plunger penetrates through the plunger channel, the die male die, the annular pressure ring and the die female die form a closed space at the upper part of the blank, the die male die and the annular pressure ring drive the blank to be extruded downwards from the forming channel, the shape of the die male die is consistent with the inner cavity of the conical cylinder, and the gap between the die male die and the forming. The invention can manufacture the high-performance thin-wall cylinder by one-step forming.

Description

Extrusion and stretching composite forming equipment for forming large conical cylinder

Technical Field

The invention relates to the technical field of large-scale component forming, in particular to extrusion and stretching composite forming equipment for forming a large-scale conical cylinder.

Background

The large cone-shaped component (see fig. 1(a)) is used as a common bearing component and is applied to equipment in a large amount. At present, the traditional forming process for preparing the large-scale cone-shaped component is a stamping method, a spinning method, a casting method and an extrusion method.

As shown in fig. 1(b), the stamping method is to process the component in sections, the straight wall part is welded after being rolled up by a plate material, the conical head part is stretched by the plate material, and then the straight wall and the conical head are welded, but the process flow is more, the welding seam strength is low, and the requirement of high mechanical property of a large pressure container is difficult to meet.

As shown in fig. 1(c), the multi-pass spinning forming process adopts a tubular member as a blank, the tubular member is heated and insulated while rotating, and the tube body is spun for multiple times by a spinning wheel, so that the process time is long and the efficiency is low.

Referring to fig. 2, the ironing method performs multiple times of wall thickness ironing after the bar stock is reversely extruded to perform the thick-walled cylinder, so that the number of die sets is large, the cost is high, the number of times of the ironing is large, the material is heated for multiple times, the crystal grains are large, the member performance is low, the production efficiency is low, and the method cannot be used for mass production.

The problems of low strength and low efficiency exist in the processing process of the large conical barrel-shaped component.

Disclosure of Invention

The invention aims to provide extrusion and stretching composite forming equipment for forming a large-sized cone cylinder, overcomes the defects and develops equipment for forming a high-performance thin-walled cylinder by a one-step forming method.

In order to achieve the above purpose, the solution of the invention is: an extrusion and stretching composite forming device for forming a large-scale conical barrel comprises a die female die, a middle shaft pressure cylinder, an annular pressure cylinder, a middle shaft plunger piston, an annular plunger piston, a die male die and an annular pressing ring, wherein a through forming channel is arranged in the middle of the die female die, the diameter of the forming channel is gradually reduced from top to bottom so as to deform a blank, the middle shaft pressure cylinder and the annular pressure cylinder are coaxially arranged and are respectively erected on the forming channel from top to bottom, the lower parts of the middle shaft pressure cylinder and the annular pressure cylinder are respectively connected with the middle shaft plunger piston and the annular plunger piston, the middle shaft pressure cylinder and the annular pressure cylinder respectively control the pressing speed of the middle shaft plunger piston and the annular plunger piston, the middle part,

the lower ends of the central shaft plunger and the annular plunger are respectively connected and drive the die male die and the annular pressing ring to move downwards and extrude the blank to form, the die male die, the annular pressing ring and the die female die form a closed space at the upper part of the blank, the annular pressing ring is sleeved outside the die male die,

the die punch and the annular pressing ring drive the blank to be extruded downwards from the forming channel, the shape of the die punch is consistent with that of the inner cavity of the conical cylinder, and the gap between the die punch and the forming channel is the wall thickness of the blank forming conical cylinder.

Preferably, the die is arranged on the first base, an opening is formed in the first base corresponding to the forming channel, a discharging ring is arranged on the lower portion of the first base, the discharging ring and the forming channel are coaxially arranged, the discharging ring is externally connected with a reciprocating mechanism, and the discharging ring is radially expanded and contracted in the forming channel through the reciprocating mechanism.

Preferably, the die cavity is suspended on the second base, the second base is provided with an ejection cylinder, and the ejection cylinder ejects out of the axis of the forming channel.

Preferably, the cross sections of the plunger channel and the middle shaft plunger are square.

Preferably, the middle shaft pressure cylinder and the annular pressure cylinder are respectively suspended on the forming channel through a first suspension and a second suspension.

Preferably, the upper part and the lower part of the forming channel are cylindrical cavities, the diameter of the cylindrical cavity at the upper part of the forming channel is larger than that of the cylindrical cavity at the lower part of the forming channel, the middle part of the forming channel is a circular truncated cone cavity which shrinks from top to bottom, and the thickness of the blank forming cone is the gap between the cylindrical cavity at the lower part of the forming channel and the male die of the die.

Preferably, the annular pressing ring is a circular ring with a bottom protruding circular truncated cone ring, the annular pressing ring is sleeved in the cylindrical cavity at the upper part of the forming channel, the annular surface of the circular truncated cone ring is parallel to the annular surface of the circular truncated cone cavity at the middle part of the forming channel, and a gap is formed between the annular surface of the circular truncated cone ring and the annular surface of the circular truncated cone cavity at the middle part of the forming channel.

After the scheme is adopted, the invention has the beneficial effects that:

the forming equipment provided by the invention only needs to carry out heating deformation twice, so that the fine grain structure of the material is kept, the mechanical property of the material is greatly improved, cracking is avoided, the inner cavity of the formed conical cylinder does not need to be processed, and the formed conical cylinder meets the mechanical property requirements of high strength and high toughness required by the product.

The blank flows out from a gap between the male die of the die and the forming channel, the lower ends of the middle shaft plunger and the annular plunger are respectively connected and drive the male die of the die and the annular pressing ring to press down at different pressing speeds to form differential extrusion, and the wall thickness is extruded once to form a thin wall of the product. The invention greatly shortens the manufacturing process of the large conical cylindrical component, reduces the production cost, has simple equipment and convenient operation, and the forming channel designed by the invention refines the metal microstructure and improves the performance.

Drawings

FIGS. 1(a) to 1(c) are schematic views of a cone and its processing in the background of the invention;

FIG. 2(d) -FIG. 2(g) are schematic diagrams of the present invention related to the background art using multiple ironing process to process cone;

FIGS. 3(h) -3 (j) are schematic illustrations of the shape of the blank of the present invention;

FIG. 4 is a schematic structural view of the present invention;

FIG. 5 is a first schematic view of a machined blank of the present invention;

FIG. 6 is a second schematic view of the machined blank of the present invention;

FIG. 7 is a third schematic view of a machined blank of the present invention;

FIG. 8 is a fourth schematic view of the machined blank of the present invention;

FIG. 9 is a fifth schematic view of the machined blank of the present invention;

fig. 10(k) -fig. 10(l) are internal deformation diagrams of the blank of the present invention.

Description of reference numerals: the device comprises a die female die (1), a middle shaft pressure cylinder (2), an annular pressure cylinder (3), a middle shaft plunger (4), an annular plunger (5), a die male die (6), an annular pressing ring (7), a forming channel (10), a plunger channel (30), a first base (11), a discharging ring (8), a second base (12), an ejection cylinder (9), a first suspension (21), a second suspension (31) and a blank (100).

Detailed Description

The invention is described in detail below with reference to the accompanying drawings and specific embodiments.

As shown in FIGS. 1-10, the invention provides an extrusion-stretch composite forming apparatus for forming a large-sized cone, comprising a die cavity 1, a middle shaft pressure cylinder 2, an annular pressure cylinder 3, a middle shaft plunger 4, an annular plunger 5, a die male die 6 and an annular pressing ring 7, wherein the middle part of the die cavity 1 is a through forming channel 10, the diameter of the forming channel 10 is gradually reduced from top to bottom to deform a blank, the middle shaft pressure cylinder 2 and the annular pressure cylinder 3 are coaxially arranged and respectively erected on the forming channel 10 from top to bottom, the lower parts of the middle shaft pressure cylinder 2 and the annular pressure cylinder 3 are respectively connected with the middle shaft plunger 4 and the annular plunger 5, the middle shaft pressure cylinder 2 and the annular pressure cylinder 3 respectively control the pressing speed of the middle shaft plunger 4 and the annular plunger 5, the middle part of the annular pressure cylinder 3 is a through plunger channel 30, the,

the lower ends of the middle shaft plunger 4 and the annular plunger 5 are respectively connected and drive the die male die 6 and the annular pressing ring 7 to move downwards and extrude the blank to form, the die male die 6, the annular pressing ring 7 and the die female die 1 form a closed space at the upper part of the blank, the annular pressing ring 7 is sleeved outside the die male die 6,

the die convex die 6 and the annular pressing ring 7 drive the blank to be extruded downwards from the forming channel 10, the shape of the die convex die 6 is consistent with that of the inner cavity of the conical cylinder, and the gap between the die convex die 6 and the forming channel 10 is the wall thickness of the blank forming conical cylinder. The material flows out from the gap between the die male die 6 and the forming channel 10, the lower ends of the middle shaft plunger 4 and the annular plunger 5 are respectively connected and drive the die male die 6 and the annular pressing ring 7 to press down at different pressing speeds to form differential extrusion, and the wall thickness is formed into a thin wall of the product through one-time extrusion. The male die 6 of the die stretches the middle part of the blank and keeps the shape of the inner cavity, and the blank is taken out from the female die 1 of the die after being formed. The invention greatly shortens the manufacturing process of the large conical cylindrical component, reduces the production cost, has simple equipment and convenient operation, and the forming channel 10 designed by the invention refines the metal microstructure and improves the performance.

The method of forming the cone can be referred to as reverse extrusion-extrusion stretch forming.

The die cavity die 1 is arranged on a first base 11, an opening is formed in the position, corresponding to a forming channel 10, of the first base 11, a discharging ring 8 is arranged on the lower portion of the first base 11, the discharging ring 8 and the forming channel 10 are coaxially arranged, a reciprocating mechanism is connected to the outer portion of the discharging ring 8, and the discharging ring 8 is radially expanded and contracted through the reciprocating mechanism in the forming channel 10. More specifically, the present disclosure uses an elastic pull ring as a reciprocating mechanism. Through setting up discharge ring 8, can realize automatic discharge.

The die concave die 1 is suspended on a second base 12, an ejection cylinder 9 is arranged on the second base 12, and the ejection cylinder 9 ejects out of the axis of the forming channel 10. The ejection cylinder 9 is designed in order to eject the blank from the forming channel using an ejection bar in special cases.

The sections of the plunger channel 30 and the middle shaft plunger 4 are both square. The maximum stroke of the middle shaft plunger 4 is 2-5m, and the maximum load is 1000T. The plunger channel 30 and the middle shaft plunger 4 are designed to be square to prevent the middle shaft plunger 4 from rotating.

The middle shaft pressure cylinder 2 and the annular pressure cylinder 3 are respectively suspended on the forming channel 10 through a first suspension 21 and a second suspension 31. In this case, the first suspension 21 and the second suspension 31 are mounted on two vertical frames.

The upper portion and the lower portion of the forming channel 10 are cylindrical cavities, the diameter of the cylindrical cavity at the upper portion of the forming channel 10 is larger than that of the cylindrical cavity at the lower portion of the forming channel 10, the middle portion of the forming channel 10 is a circular truncated cone cavity which shrinks from top to bottom, and a gap between the cylindrical cavity at the lower portion of the forming channel 10 and the male die 6 of the die is the wall thickness of a blank forming conical cylinder. The circular truncated cone cavity in the middle of the forming channel 10 can realize three-way (upward along the circular truncated cone inclined plane, downward along the circular truncated cone inclined plane and outward vertical to the circular truncated cone inclined plane) compressive stress state forming, so that material cracking is avoided, and the yield of large conical barrel-shaped components is improved.

The annular pressing ring 7 is a circular ring with a circular table ring protruding from the bottom, the annular pressing ring 7 is sleeved in a cylindrical cavity in the upper portion of the forming channel 10, the annular surface of the circular table ring is parallel to the annular surface of the circular table cavity in the middle of the forming channel 10, and a gap is formed between the annular surface of the circular table ring and the annular surface of the circular table cavity in the middle of the forming channel 10. The annular pressing ring 7 is matched with a circular truncated cone cavity in the middle of the forming channel 10, so that the blank is promoted to flow in the circular truncated cone cavity, and the strength of the formed conical cylinder is improved.

The working steps are as follows:

step one, blank entering into a die: putting a preformed cup-shaped blank on a forming channel 10, wherein the middle part of a male die 6 of the die is abutted against a cup-shaped central concave part of the blank, and an annular pressing ring 7 is abutted against a cup-shaped edge convex part of the blank;

step two, extruding and stretching: the die male die 6 and the annular pressing ring 7 are driven by the middle shaft plunger 4 and the annular plunger 5 respectively and are pressed downwards, and the pressing speeds of the die male die 6 and the annular pressing ring 7 are independently controlled by the middle shaft pressure cylinder 2 and the annular pressure cylinder 3;

firstly, the male die 6 of the die is pressed downwards, the annular pressing ring 7 only abuts against the convex part of the cup-shaped edge of the blank, and the bottom of the male die 6 of the die downwards extrudes the concave part of the cup-shaped center of the blank to be thinned and formed into a conical part of a conical cylinder in advance;

secondly, after the cone part of the cone barrel starts to be formed, the annular pressing ring 7 starts to press downwards and drives the blank to deform downwards, the pressing speed of the annular pressing ring 7 is slower than that of the male die 6 of the die, and the blank is pressed downwards to form the side wall of the cone barrel under the extrusion of the side wall of the male die 6 of the die and the inner wall of the female die 1 of the die because the male die 6 of the die, the annular pressing ring 7 and the female die 1 of the die form a closed space at the upper part of the blank;

step three, finishing stretching: after the side wall of the cone cylinder is formed, the annular pressure cylinder 3 stops pressing down and retracts to reset, the annular pressure cylinder 3 drives the annular pressing ring 7 to retract through the annular plunger 5, the middle shaft pressure cylinder 2 continues to push the die male die 6 to move downwards through the middle shaft plunger 4, the middle shaft plunger 4 stops moving after the die male die 6 drives the blank to penetrate out of the forming channel 10, the blank is stretched and deformed, and the formed blank automatically falls out of the discharging ring 8;

step four, unloading and core pulling: the male die 6 of the die is separated from the blank, and the middle shaft pressure cylinder 2 resets the middle shaft plunger 4 through the annular plunger 5.

Principle explanation:

in the invention, when the cone part of the cone barrel is deformed, the die convex die 6, the annular pressing ring 7 and the die concave die 1 form a closed space at the upper part of a blank, in addition, the middle part of the forming channel 10 of the die is designed to be a circular truncated cone cavity which shrinks from top to bottom, when the cavity of the circular truncated cone is put into a blank for extrusion forming, the blank is formed under a three-dimensional compressive stress state, namely upward along the inclined plane of the circular truncated cone, downward along the inclined plane of the circular truncated cone and outward vertical to the inclined plane of the circular truncated cone, wherein, the stress upward along the inclined surface of the circular truncated cone is less than the stress downward along the inclined surface of the circular truncated cone, the stress downward along the inclined surface of the circular truncated cone at the lower part of the blank is transformed into a conical cylinder, and after the upper part of the blank deforms to the annular pressing ring 7 along the upward stress of the inclined surface of the circular truncated cone, the blank flows on the bottom surface of the annular pressing ring 7 and turns over towards the inner ring of the annular pressing ring 7, crystal grains in the metal can be refined through the turning, and the strength of the formed conical cylinder is improved.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the design of the present invention, and all equivalent changes made in the design key point of the present invention fall within the protection scope of the present invention.

Claims

1. The utility model provides an extrusion drawing composite forming equipment of shaping large-scale awl section of thick bamboo which characterized in that: the die comprises a die female die (1), a middle shaft pressure cylinder (2), an annular pressure cylinder (3), a middle shaft plunger (4), an annular plunger (5), a die male die (6) and an annular pressing ring (7), wherein a through forming channel (10) is arranged in the middle of the die female die (1), the diameter of the forming channel (10) is gradually reduced from top to bottom so as to deform a blank, the middle shaft pressure cylinder (2) and the annular pressure cylinder (3) are coaxially arranged and are respectively erected on the forming channel (10) from top to bottom, the lower parts of the middle shaft pressure cylinder (2) and the annular pressure cylinder (3) are respectively connected with the middle shaft plunger (4) and the annular plunger (5), the middle shaft pressure cylinder (2) and the annular pressure cylinder (3) respectively control the pressing speed of the middle shaft plunger (4) and the annular plunger (5), the middle part of the annular pressure cylinder (3) is a through plunger channel (30), and,

the lower ends of the middle shaft plunger (4) and the annular plunger (5) are respectively connected and drive the die male die (6) and the annular pressing ring (7) to move downwards and extrude the blank to form, the die male die (6), the annular pressing ring (7) and the die female die (1) form a closed space at the upper part of the blank, the annular pressing ring (7) is sleeved outside the die male die (6),

the die punch (6) and the annular pressing ring (7) drive the blank to be extruded downwards from the forming channel (10), the shape of the die punch (6) is consistent with that of the inner cavity of the conical cylinder, and the gap between the die punch (6) and the forming channel (10) is the wall thickness of the blank forming conical cylinder.

2. The extrusion-stretch composite forming equipment for forming the large-sized cone cylinder as claimed in claim 1, wherein: the die is characterized in that the die female die (1) is arranged on a first base (11), an opening is formed in the position, corresponding to the forming channel (10), of the first base (11), a discharging ring (8) is arranged on the lower portion of the first base (11), the discharging ring (8) and the forming channel (10) are coaxially arranged, the discharging ring (8) is externally connected with a reciprocating mechanism, and the discharging ring (8) is radially expanded and contracted through the reciprocating mechanism on the forming channel (10).

3. The extrusion-stretch composite forming equipment for forming the large-sized cone cylinder as claimed in claim 1, wherein: the die concave die (1) is arranged on the second base (12) in a suspending mode, the second base (12) is provided with the ejection cylinder (9), and the ejection cylinder (9) ejects out of the axis of the forming channel (10).

4. The extrusion-stretch composite forming equipment for forming the large-sized cone cylinder as claimed in claim 1, wherein: the sections of the plunger piston channel (30) and the middle shaft plunger piston (4) are square.

5. The extrusion-stretch composite forming equipment for forming the large-sized cone cylinder as claimed in claim 1, wherein: the middle shaft pressure cylinder (2) and the annular pressure cylinder (3) are respectively suspended on the forming channel (10) through a first suspension (21) and a second suspension (31).

6. The extrusion-stretch composite forming equipment for forming the large-sized cone cylinder as claimed in claim 1, wherein: the upper portion and the lower portion of the forming channel (10) are cylindrical cavities, the diameter of the cylindrical cavity at the upper portion of the forming channel (10) is larger than that of the cylindrical cavity at the lower portion of the forming channel (10), the middle portion of the forming channel (10) is a circular truncated cone cavity which shrinks from top to bottom, and a gap between the cylindrical cavity at the lower portion of the forming channel (10) and the male die (6) of the die is the wall thickness of a blank forming conical cylinder.

7. The extrusion-stretch composite forming equipment for forming the large-sized cone cylinder as claimed in claim 6, wherein: the annular pressing ring (7) is a circular ring with a circular table ring protruding from the bottom, the annular pressing ring (7) is sleeved in a cylindrical cavity in the upper portion of the forming channel (10), the ring surface of the circular table ring is parallel to the ring surface of the circular table cavity in the middle of the forming channel (10), and a gap is formed between the ring surface of the circular table ring and the ring surface of the circular table cavity in the middle of the forming channel (10).