CN112246906A

CN112246906A - Ultrathin strip extrusion die

Info

Publication number: CN112246906A
Application number: CN202011141365.8A
Authority: CN
Inventors: 张宇杰; 许四妹
Original assignee: Guangzhou Solderwell Advanced Materials Co ltd
Current assignee: Guangzhou Solderwell Advanced Materials Co ltd
Priority date: 2020-10-22
Filing date: 2020-10-22
Publication date: 2021-01-22

Abstract

The invention provides an ultrathin strip extrusion die, and belongs to the technical field of extrusion dies. The extrusion die comprises a die head, a die core and a die holder, wherein the die core is fixed in the die holder, the die head is fixed with the die holder, a die head extrusion cavity, a die core extrusion cavity and a blanking hole are respectively formed in the die head, the die core and the die holder, the die head extrusion cavity is opposite to the die core extrusion cavity, and the die core extrusion cavity is opposite to the blanking hole. The extrusion die extrudes the strip for multiple times, gradually extrudes the required shape, does not concentrate the stress borne by the extruded strip acutely, avoids the strip cracking, can extrude the ultrathin strip and process a qualified product, and fills the blank in the technical field of extruding the tin alloy ultrathin strip.

Description

Ultrathin strip extrusion die

Technical Field

The invention belongs to the technical field of extrusion dies, and relates to an ultrathin strip extrusion die.

Background

The tin alloy is used as a large class of nonferrous metals, has low melting point, strength and hardness, excellent plastic processing performance and excellent antifriction performance, and is widely applied to various industries such as industry, agriculture, national defense science and technology, medicine and the like. With the development of electronic manufacturing industry, especially electronic solder soldering flakes, the demand of ultrathin (commonly used thickness is 0.08mm, 0.1mm, 0.2mm and the like) tin alloy strips is increasing day by day, but at present, the extrusion thickness of domestic tin alloy strips is obviously thicker (2-5mm), the dies are generally single-hole extrusion dies, the workload of the later-stage strip (especially tin bismuth alloy with poor plasticity) rolling process is seriously increased, the production cost is very high, and therefore the problems need to be solved from the aspect of die design, and the dies are designed so that ultrathin strips meeting the quality requirements can be extruded.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides an ultrathin strip extrusion die, which aims to solve the technical problems that: how to extrude ultrathin strips meeting the quality requirement and improving the productivity of the extrusion process.

The purpose of the invention can be realized by the following technical scheme:

the ultra-thin strip extrusion die is characterized by comprising a die head, a die core and a die holder, wherein the die core is fixed in the die holder, the die head is fixed with the die holder, a die head extrusion cavity, a die core extrusion cavity and a blanking cavity are respectively formed in the die head, the die core and the die holder, the die head extrusion cavity is opposite to the die core extrusion cavity, and the die core extrusion cavity is opposite to the blanking cavity.

The working principle is as follows: in the extrusion die, the die head is used for matching with the extrusion cylinder, the die holder is used for connecting the die head, the extrusion cavity of the die head performs one-time or multiple-time extrusion deformation on the bar, the die core is assembled on the die holder, the die holder provides supporting force for the die core, the extrusion cavity of the die core performs the final-time extrusion deformation on the bar, after the extrusion is completed, the bar is formed by an extrusion piece, and the bar comes out from a blanking hole of the die holder. The extrusion die is not formed at one time, but extruded for multiple times to gradually extrude a required shape, so that the stress borne by an extruded strip cannot be concentrated violently, the strip can be prevented from cracking, an ultra-thin strip (such as tin alloy) with excellent quality can be extruded and processed, the thickness of the strip can be designed to be 0.3-2mm, and the blank in the technical field of tin alloy ultra-thin strip extrusion is filled.

One or more progressive die head extrusion cavities can be formed in the die head, namely a first die head extrusion cavity, a second die head extrusion cavity and the like, so that classified extrusion is realized, a plurality of parallel die core extrusion cavities can be formed in the die core so as to realize porous extrusion, and a plurality of parallel blanking cavities can also be formed in the die holder.

Three or more threaded holes which are uniformly distributed can be formed in the die head, the die head and the die holder are fixed by connecting locking screws on the threaded holes in a threaded manner, and the aperture size and the number of the threaded holes are determined according to actual use requirements.

In foretell ultra-thin strip extrusion die, mold core extrusion chamber includes mold core pan feeding hole, sizing zone and mold core discharge opening, the mold core pan feeding hole is frustum form and its width from last to reducing gradually down, the mold core discharge opening is frustum form and its width from last to increasing gradually down. The specific structure and shape of the die core extrusion cavity are determined according to the shape of the product.

In the mold core, the mold angle of the mold core feeding hole can be designed to be 0-90 degrees, and when the mold angle (the included angle between the inclined plane of the mold core feeding hole and the central axis) is 0-90 degrees, a flat mold is formed. In order to ensure smooth tin feeding, the die angle of the feeding hole of the die core cannot be too small, and is generally 30-75 degrees.

In the ultrathin strip extrusion die, the die head extrusion cavity comprises a die head feeding hole and a die head discharging hole, and the joint of the inner walls of the die head feeding hole and the die head discharging hole is provided with more than one inclined wall.

The inclined wall can be one or a plurality of inclined walls, and each progressive inclined wall sequentially forms a first extrusion cavity of the die head, a second extrusion cavity of the die head and the like, so that the step extrusion of the bar stock on the die head is realized. At this time, the die extrusion cavity comprises a plurality of extrusion cavities such as a first extrusion cavity of the die, a second extrusion cavity of the die and the like.

The inclined wall is a transition area, and the peripheral size of strip diminishes gradually when the strip is in the extrusion deformation in-process, through this transition area, and this structure can be fine prevents that the strip from ftractureing in the extrusion process, brings better extrusion effect.

In foretell ultra-thin strip extrusion die, die head pan feeding hole and die head discharge opening are cylindric or square body form, the tilt wall is the annular, and the tilt wall is close to the middle part in the first extrusion chamber of die head from last to lower gradually, the junction of tilt wall and die head pan feeding hole has first circular arc chamfer, and the junction of tilt wall and die head discharge opening has second circular arc chamfer, has the non-deformation zone along vertical direction between tilt wall and the tilt wall, and the junction all has the circular arc chamfer.

The die head feed hole and the die head discharge hole can be cylindrical or square or in other shapes, the die head feed hole is designed according to the actual shape of a bar, and the die head discharge hole is designed into a circular shape, a square shape or other shapes according to the specific structure of the die core extrusion cavity.

The junction of communications between the inclined wall and die head pan feeding hole passes through first circular arc chamfer, the transition of second circular arc chamfer is passed through with first non-deformation zone junction to the inclined wall, first non-deformation zone passes through third circular arc chamfer with second inclined wall junction to analogize, the junction of last inclined wall and die head discharge opening passes through last circular arc chamfer and passes through, hierarchical extrusion can be realized to this structure, reduce bar peripheral dimension gradually, further prevent that the strip from ftracturing at extrusion in-process.

In the ultrathin strip extrusion die, the included angle between the inclined wall and the vertical direction is 0-90 degrees. When the angle is 0 degrees, the material rod can not deform in the die head area.

In the ultrathin strip extrusion die, the die core feeding hole and the die core discharging hole are annular, the connecting part of the die core feeding hole and the die core discharging hole is provided with an annular connecting straight wall, and the connecting straight wall extends along the vertical direction. In the structure, the width of each part of the connecting straight wall is the same, the connecting straight wall is a calibrating strap, and the calibrating strap is used for stabilizing the thickness of the strip. Preferably, the die core feeding hole and the die core discharging hole are in circular arc transition with the bearing belt.

In the above ultra-thin strip extrusion die, the connecting straight walls are enclosed to form a strip-shaped groove, and the strip-shaped groove has two semicircular arc-shaped end parts. The two ends of the sizing belt are in transition through the semicircular arcs, so that stress concentration at the two ends of the mold core can be reduced, and the edge of the belt material is prevented from cracking during discharging.

In the above ultra-thin strip extrusion die, the length of the strip-shaped groove is 1mm to 8 mm.

In the ultrathin strip extrusion die, the end parts of the die core feeding hole and the die core discharging hole are arc-shaped. And both ends of the die core feeding hole are in semicircular arc transition, so that the tin feeding amount can be increased.

In the ultrathin strip extrusion die, more than two parallel die core extrusion cavities are formed in the die core, and the distance between the central lines between the adjacent die core extrusion cavities is greater than or equal to 10 mm.

The number of the die core extrusion cavities can be two or more, the multi-hole extrusion can be realized by the plurality of die core extrusion cavities, the distance between the central lines between the die core extrusion cavities is more than 10mm, and the strength of the die core can be well ensured.

In addition, a technical difficulty of ultra-thin strip extrusion is that the extrusion ratio is too large, the friction between the bar and the die is severe, the service life of the die is reduced, the load of the extruder is too large, meanwhile, the die core bearing belt is seriously damaged, the thickness of the strip can become uneven, scratches, black spots, pits and the like are easily generated on the surface, and more seriously, the bar cannot be extruded and the die is scrapped due to the too large extrusion ratio. The design of the porous structure can reduce the extrusion ratio by times, prolong the service life of the die, reduce the load of the extruder by times and improve the surface quality of the strip.

In the ultrathin strip extrusion die, the die holder is provided with a groove, and the die core is embedded and fixed in the groove. The assembling mode of the die holder and the die core can be interference assembling, pin assembling and the like.

Compared with the prior art, the invention has the following advantages:

1. the extrusion die extrudes the strip for multiple times, gradually extrudes the required shape, the stress borne by the extruded strip cannot be concentrated violently, the strip is prevented from cracking, the ultrathin strip (such as tin alloy) can be extruded, qualified products can be processed, the thickness of the strip can be designed to be 0.3-2mm, and the blank of the technical field of tin alloy ultrathin strip extrusion is filled.

2. The extrusion die is simple in structure, easy to process and low in die processing cost, and achieves the best using effect through simple design.

3. The mold core of the extrusion mold adopts a porous structure design, so that the extrusion ratio can be reduced, the service life of the mold is prolonged, the load of an extruder is reduced, and the surface quality of a strip is improved.

Drawings

FIG. 1 is a schematic diagram of the structure of a die;

FIG. 2 is a cross-sectional view A-A of FIG. 1;

FIG. 3 is a schematic view of a die holder;

FIG. 4 is a cross-sectional view B-B of FIG. 3;

FIG. 5 is a schematic structural view of a mold core;

FIG. 6 is a cross-sectional view C-C of FIG. 5;

FIG. 7 is an assembly view of the present extrusion die;

FIG. 8 is a cross-sectional view taken along line D-D of FIG. 7;

FIG. 9 is a top view of the thinnest tin-bismuth alloy strip on the market;

FIG. 10 is a side view of the thinnest commercially available tin-bismuth alloy strip;

FIG. 11 is an enlarged view of a portion of the red frame area with material in FIG. 9;

fig. 12 is a top view of a strip extruded with a 1 x 43 gauge extrusion die of the present invention;

fig. 13 is a side view of a strip extruded with a 1 x 43 gauge extrusion die of the present invention;

fig. 14 is an enlarged view of a portion of the red frame area with material in fig. 12.

In the figure, 1 die; 2, a mold core; 3, a die holder; 4, a first extrusion cavity of the die head; 5, a mold core extrusion cavity; 6 a blanking cavity; 7 an inclined wall; 8, chamfering a first arc; 9, chamfering a second circular arc; 10 connecting the straight walls; 11, grooves; 12 a threaded hole; 13 die head feed holes; 14 die head discharge holes; 15 mold core feed holes; and 16 mold core discharge holes.

Detailed Description

The following is a specific embodiment of the present invention, in which the extruded bar is a cylinder, the die head is designed with only one inclined wall, the die head inlet and outlet are both circular, forming a first extrusion cavity of the die head, in which the bar is extruded and deformed for the first time. The mould core is provided with two parallel mould cores, and the bar stock is extruded and deformed for the second time in the cavity. The technical solutions of the present invention will now be further described with reference to the accompanying drawings, but the present invention is not limited to these embodiments.

As shown in fig. 1-8, the extrusion die comprises a die head 1, a die core 2 and a die holder 3, wherein the die core 2 is fixed in the die holder 3, the die head 1 is fixed with the die holder 3, a first die head extrusion cavity 4, a first die core extrusion cavity 5 and a blanking cavity 6 are respectively arranged on the die head 1, the die core 2 and the die holder 3, the first die head extrusion cavity 4 is opposite to the first die core extrusion cavity 5, and the first die core extrusion cavity 5 is opposite to the blanking cavity 6.

In the extrusion die, the die head 1 is used for being matched with an extrusion cylinder, the die holder 3 is used for being connected with the die head 1, the extrusion cylinder and a first extrusion cavity 4 of the die head 1 perform primary extrusion deformation on a strip, the die core 2 is assembled on the die holder 3, the die holder 3 provides supporting force for the die core 2, the extrusion cylinder and a die core extrusion cavity 5 on the die core 2 perform secondary extrusion deformation on the strip, after the extrusion is completed, the extruded part becomes a formed product, and the product is discharged from a blanking cavity 6 of the die holder 3.

Three or more threaded holes 12 which are uniformly distributed can be formed in the die head 1, locking screws are connected to the threaded holes 12 in a threaded mode, the die head 1 and the die holder 3 are fixed, and the aperture size and the number of the threaded holes 12 are determined according to actual use requirements.

As shown in fig. 6, in this embodiment, the mold core extrusion cavity 5 includes a mold core feeding hole 15 and a mold core discharging hole 16, the mold core discharging hole 16 is frustum-shaped and the width thereof gradually decreases from top to bottom, and the mold core discharging hole 16 is frustum-shaped and the width thereof gradually increases from top to bottom. The specific configuration and shape of the core extrusion cavity 5 will depend on the shape of the product.

In the mold core 2, the mold angle of the mold core feeding hole 15 can be designed to be 0-90 degrees, and when the mold angle (the included angle between the inclined plane of the mold core feeding hole 15 and the central axis) is 0-90 degrees, a flat mold is formed. In order to ensure smooth tin feeding, the die angle of the die core feeding hole 15 cannot be too small, and is generally 30-75 degrees.

In the present embodiment, as shown in fig. 2, the first extrusion cavity 4 of the die comprises a die inlet 13 and a die outlet 14, and the connection between the inner walls of the die inlet 13 and the die outlet 14 has an inclined wall 7.

The inclined wall 7 is a transition area, the peripheral size of the strip material is gradually reduced when the strip material passes through the transition area in the first extrusion deformation process, and the structure can well prevent the strip material from cracking in the extrusion process, so that a better extrusion effect is brought.

As shown in fig. 2, in this embodiment, the die head feeding hole 13 and the die head discharging hole 14 are cylindrical, the inclined wall 7 is annular, the inclined wall 7 gradually approaches to the middle of the die head first extrusion cavity 4 from top to bottom, a first arc chamfer 8 is provided at a joint of the inclined wall 7 and the die head feeding hole 13, and a second arc chamfer 9 is provided at a joint of the inclined wall 7 and the die head discharging hole 14.

The connection of the inclined wall 7 and the die head feed hole 13 is transited through a first arc chamfer 8, the connection of the inclined wall 7 and the die head discharge hole 14 is transited through a second arc chamfer 9, and the structure can further prevent the cracking of the strip in the extrusion process.

The inclined wall 7 and the vertical included angle of 0 ~ 90. When the angle is 0 degrees, the material rod can not deform in the area of the die head 1.

In the present embodiment, as shown in fig. 6, the mold core inlet 15 and the mold core outlet 16 are annular, and the junction between the two has an annular connecting straight wall 10, and the connecting straight wall 10 extends in the vertical direction. In this structure, the width of each of the connecting straight walls 10 is the same, and the connecting straight walls 10 are the calibration bands for stabilizing the thickness of the strip. Preferably, the die core inlet hole 15 and the die core outlet hole 16 are in circular arc transition with the bearing belt.

Preferably, the connecting straight walls 10 enclose a strip-shaped groove having two semicircular arc-shaped ends. The two ends of the sizing belt are in transition through the semicircular arcs, so that the stress concentration at the two ends of the mold core 2 can be reduced, and the edge of the belt material is prevented from cracking during discharging.

Preferably, the length of the strip-shaped groove is 1mm to 8 mm.

As shown in fig. 5, in the present embodiment, the ends of the core inlet hole 15 and the core outlet hole 16 are curved. And the two ends of the die core feeding hole 15 are in semicircular arc transition, so that the tin feeding amount can be increased.

Preferably, more than two die core extrusion cavities 5 are formed in the die core 2, and the distance between the central lines of the adjacent die core extrusion cavities 5 is greater than or equal to 10 mm.

The number of the die core extrusion cavities 5 can be two or more than two, the plurality of die core extrusion cavities 5 can realize multi-hole extrusion, the distance between the central lines between the die core extrusion cavities 5 is more than 10mm, and the strength of the die core 2 can be well ensured.

One technical difficulty of ultra-thin strip extrusion is that the extrusion ratio is too large, the friction between the bar and the die is severe, the service life of the die is reduced, the load of the extruder is too large, the bearing belt of the die core 2 is seriously damaged, the thickness of the strip can become uneven, scratches, black spots, pits and the like are easily generated on the surface, and more seriously, the bar cannot be extruded and the die is scrapped due to the too large extrusion ratio. The design of the porous structure can reduce the extrusion ratio by times, prolong the service life of the die, reduce the load of the extruder by times and improve the surface quality of the strip.

As shown in fig. 4 and 8, in the present embodiment, the mold base 3 is provided with a groove 11, and the mold core 2 is embedded and fixed in the groove 11. The die holder 3 and the die core 2 can be assembled in a manner of interference fit, pin fit and the like.

To more clearly illustrate the benefits of the embodiments of the present invention, the following description will be made in comparison with the conventional die extruded strip currently used for production.

The extruded tin rod material used in the comparative example is a tin-bismuth alloy, the shape is a cylinder, the diameter of an extrusion cylinder is 80mm, and the preparation conditions are the same except that the used dies are different.

Fig. 9 and 10 are top and side views, respectively, of the thinnest commercially available tin-bismuth alloy strip extruded from a 3 x 45 gauge conventional extrusion die;

FIG. 11 is an enlarged partial view (31.6 times magnification) of the red frame region of the strip of FIG. 9;

fig. 12 and 13 are top and side views, respectively, of a strip extruded with a 1 x 43 gauge extrusion die of the present invention;

fig. 14 is an enlarged partial view (31.6 x magnification) of the red box area of the tape of fig. 12.

As can be seen from fig. 9-14, the surface of the strip produced by the 3 x 45 standard conventional extrusion die was low (fig. 9 and 10), and had a lot of deep scratches, scattered black spots and pits (fig. 11), while the surface of the strip extruded by the 1 x 43 extrusion die of the present invention was high (fig. 12 and 13), and had no black spots and pits (fig. 14), and the surface quality of the strip produced by the present invention was significantly improved compared to the conventional extrusion die.

Meanwhile, because the tin bismuth alloy has larger brittleness, the deformation rate of single rolling cannot be too high, if a strip with the thickness of 3mm is rolled to the thickness of 1mm by 10 percent deformation rate each time, 10 times of rolling are needed, and the problems of low production efficiency and high cost exist.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the spirit or ambit of the invention as defined in the appended claims.

Claims

1. The utility model provides an ultra-thin strip extrusion die, its characterized in that, extrusion die includes die head (1), mold core (2) and die holder (3), mold core (2) are fixed in die holder (3), die head (1) are fixed mutually with die holder (3), die head extrusion chamber (4), mold core extrusion chamber (5) and blanking chamber (6) have been seted up on die head (1), mold core (2) and die holder (3) respectively, die head extrusion chamber (4) and mold core extrusion chamber (5) are relative, die core extrusion chamber (5) are relative with blanking chamber (6).

2. The ultra-thin strip extrusion die of claim 1, wherein the die core extrusion cavity (5) comprises a die core feeding hole (15), a sizing belt and a die core discharging hole (16), the die core feeding hole (15) is frustum-shaped and the width of the die core discharging hole is gradually reduced from top to bottom, and the die core discharging hole (16) is frustum-shaped and the width of the die core discharging hole is gradually increased from top to bottom.

3. The ultra-thin strip extrusion die of claim 1, wherein the die extrusion cavity comprises a die inlet (13) and a die outlet (14), and the junction of the inner walls of the die inlet (13) and the die outlet (14) has more than one inclined wall (7).

4. The ultra-thin strip extrusion die of claim 3, wherein the die head inlet hole (13) and the die head outlet hole (14) are cylindrical or cubic, the inclined wall (7) is annular, the inclined wall (7) is gradually close to the middle of the die head extrusion cavity (4) from top to bottom, a first arc chamfer (8) is arranged at the joint of the inclined wall (7) and the die head inlet hole (13), and a second arc chamfer (9) is arranged at the joint of the inclined wall (7) and the die head outlet hole (14).

5. An ultra-thin strip extrusion die as claimed in claim 3, wherein the angle between the inclined wall (7) and the vertical is 0-90 °.

6. The ultra-thin strip extrusion die of claim 2, wherein the die core inlet hole (15) and the die core outlet hole (16) are annular, and the junction of the two holes has an annular connecting straight wall (10), and the connecting straight wall (10) extends along the vertical direction.

7. The ultra-thin strip extrusion die of claim 6, wherein the connecting straight walls (10) enclose a strip-shaped groove, the strip-shaped groove has two semi-circular arc-shaped end portions, and the length of the strip-shaped groove is 1 mm-8 mm.

8. The ultra-thin strip extrusion die of claim 2, wherein the ends of the core inlet hole (15) and the core outlet hole (16) are curved.

9. The ultra-thin strip extrusion die of claim 1, wherein the die core (2) is provided with more than two die core extrusion cavities (5) which are arranged in parallel, and the distance between the central lines of the adjacent die core extrusion cavities (5) is greater than or equal to 10 mm.

10. The ultra-thin strip extrusion die of claim 1, wherein the die holder (3) is provided with a groove (11), and the die core (2) is embedded and fixed in the groove (11).