TWM605134U - Forging die set and the forging punch thereof - Google Patents

Abstract

A forging die set includes a plurality of die cavities and a plurality of forging punches, and the plurality of die cavities are used for containing the metal blank. The plurality of forging punches are used to respectively form a forging hole on the metal blank. The forging punch includes a columnar body and a first receding gap. The columnar body has a head, a forging end, a lateral surface and an imaginary longitudinal axis. The two ends of the lateral surface are respectively connected with the head and the forging end, and the lateral surface surrounds the longitudinal axis. The first receding gap is separated from the forging end by a first distance, the first receding gap has a first surface, and the first surface is recessed on the lateral surface of the columnar body around the longitudinal axis. The metal blank is sequentially placed in the plurality of cavities, and is punched by the plurality of forging punches in sequence to form the hole with a Length-to-diameter ratio greater than 2.2.

Description

Forging die set and forging punch

This creation is about a forging die set, especially a forging die set that can form a deep hole on a blank in multiple passes.

Forging is a processing technology that applies pressure to a metal blank to cause plastic deformation. Cold forging (Cold forging) is a forging process performed below 30% of the recrystallization temperature (generally at room temperature). It has the following advantages: it can improve the mechanical strength and dimensional accuracy of the forging; the material removal rate is extremely high Low, no material waste problem; and high production efficiency.

Although cold forging has the above advantages, it is still quite difficult to form a deep hole (for example, the ratio of length to diameter greater than 5) of a blank in a single pass. For steel blanks, the length-to-diameter ratio (Length-to-diameter ratio) of the holes that can be formed in a single pass should be less than 2.2, preferably less than 2, otherwise it is easy to cause punches during the forging process Buckled and fractured.

In addition, when the punch punches the blank to form a hole, the blank will cover the side peripheral surface of the punch due to plastic flow and form a compressive stress on the side peripheral surface. When the punch rises, it will be separated from the blank. During the process, the punch is often pulled off due to the friction formed by the bonding of the blank material. This phenomenon becomes more serious as the length of the hole is longer. To solve this problem, the industry usually designs the punch with a pullout angle (for example, 3°) to reduce the time for the friction force. However, when the hole is not suitable for taper, additional processing and removal are needed, which leads to a decrease in material utilization and an increase in process time and cost.

According to the cold room forging technology, it is difficult to directly forge deep holes on the metal blank with the existing die and punch. Therefore, it is necessary to provide a new forging die to solve the aforementioned problems.

One of the purposes of this creation is to provide a forging die set whose punch is not provided with a draft angle, so that non-tapered holes can be forged on the blank without additional processing and removal, which improves material utilization and reduces process time and cost .

Another purpose of this creation is to provide a forging die set that can form a hole with a length-to-diameter ratio greater than 2.2 on a metal blank by punching the forging die set in multiple passes.

According to the above purpose, this creation provides a forging punch for forming a forging hole on a metal blank. The forging punch includes: a columnar body with a head, a punching end, and a side circumference. Surface and an imaginary longitudinal axis, the two ends of the lateral peripheral surface respectively connect the head and the forging end, the lateral peripheral surface surrounds the longitudinal axis; and a first escape clearance, which is away from the forging end A first distance, the first escape gap has a first surface, and the first surface is recessed around the longitudinal axis on the side peripheral surface of the cylindrical body; when the forging punch forms the forging metal blank In the case of a hole, the first escape gap reduces the contact area between the forging punch and the hole wall of the forging hole.

According to the above-mentioned purpose, this creation further provides a forging die set for forming a hole with an aspect ratio greater than 2.2 on a metal blank in multiple passes. The forging die set includes: a plurality of cavities for accommodating the aforementioned metal Blanks; and plural forged punches, each of the plural forged punches includes: a cylindrical body having a head, a punching end, a side surface, and an imaginary longitudinal axis, two of the aforementioned side surface The ends are respectively connected to the aforementioned head and the aforementioned punching end, and the aforementioned lateral peripheral surface surrounds the aforementioned longitudinal axis; and a first escape gap which is connected to the aforementioned punching The ends are separated by a first distance, the first escape gap has a first surface, and the first surface is recessed on the lateral surface of the cylindrical body around the longitudinal axis; when the forging punch forms the metal blank During the forging hole, the first clearance reduces the contact area between the forging punch and the hole wall of the forging hole; the plurality of forging punches are individually used to form the forging hole on the metal blank; wherein, the metal blank The material system is sequentially placed in the aforementioned plurality of die cavities, and sequentially punched by the aforementioned plurality of forging punches, and finally the aforementioned hole with the aspect ratio greater than 2.2 is formed.

An escape gap is formed on the side surface of the forging punch of this creation, which can reduce the contact area between the forging punch and the formed forging hole wall, thus reducing the positive pressure of the metal blank on the side surface of the forging punch (That is to reduce the friction between the metal blank and the forging punch). Therefore, the punch does not need a draft angle, can punch out holes without taper, and does not require additional processing and removal, which improves material utilization and reduces process time and cost. In addition, this creation uses a forging die set with multiple forging punches and multiple cavities to forge a metal blank in multiple passes to form a hole with an aspect ratio greater than 2.2, which overcomes the difficulty in forming deep with conventional technology. Technical problems with holes.

10: Mechanical parts

11: blind hole

200,210,220,230,240: metal blank

211,221,231,241: Forging holes

1000: Forging die set

1100, 1200, 1300, 1400: Forging die

1110,1210,1310,1410: lower die

1111, 1211, 1311, 1411: mold cavity

1120, 1220, 1320, 1420: upper die

3100, 3200, 3300, 3400: Forged punch

3110, 3210: cylindrical body

3111: head

3112, 3212: Forging end

3113, 3213: side surface

3114, 3214: longitudinal axis

3120, 3220: The first escape

3230: second escape

d1: first distance

d2: second distance

R1: first ridge

R2: second ridge

S1: First surface

S2: second surface

T1: First promotion

T2: Second promotion

θ1: first cone angle

θ2: second cone angle

Figure 1 is a schematic cross-sectional view of a mechanical part.

Figure 2 is a schematic cross-sectional view of an embodiment of the creative forging die set.

3A to 3E are schematic cross-sectional views of metal blanks formed by cold forging in an embodiment of the forging die set created by this invention.

Figure 4 is a schematic diagram of a forging punch of one embodiment of the creative forging die set.

5A to 5C are schematic diagrams of the implementation of a forging punch with a plurality of first clearances in an embodiment of the creative forging die set.

Figure 6 is a schematic diagram of another forging punch in an embodiment of the creative forging die set.

In order to make the above or other purposes, features and characteristics of this creation more obvious and understandable, the relevant embodiments of this creation are described in detail as follows in conjunction with the diagrams:

Fig. 1 is a schematic cross-sectional view of a mechanical part, Fig. 2 is a schematic cross-sectional view of an embodiment of the creative forging die set, and Figs. 3A to 3E are schematic cross-sectional views of a metal blank formed by cold forging through an embodiment of the creative forging die set. 4 is a schematic diagram of a forging punch of one embodiment of the creative forging die set. Please refer to Figure 1. The mechanical part 10 is made of steel and is roughly cup-shaped, with an outer diameter of 20mm and a length of 100mm. It has a blind hole 11 with an aperture of 10mm, a length (depth) of 70mm, and an aspect ratio ( Length-to-diameter ratio, L/D) is 7. Limited by the strength of the die material, it is still quite difficult for the forging die made of general tool steel to cold forge the steel blank in a single pass to form a hole with an aspect ratio greater than 2.2. In order to solve this problem, this creation will cold-forge the steel blank with multiple forging dies to form a mechanical part 10 with a blind hole 11 in multiple passes.

In order to avoid punch buckling and fracture, the number of forging dies will depend on the aspect ratio of the hole to be formed by cold forging of the metal blank. For steel blanks, each forging die can perform a single pass. The aspect ratio of the formed forging hole is preferably less than 2.2, preferably less than 2. Based on this principle, the number of forging dies included in the forging die set can be estimated. In this embodiment, the aspect ratio of the forging hole that can be formed in a single pass performed by each forging die is selected to be 2. Therefore, the blind hole 11 (L/D=7) with a length (depth) of 70mm and a diameter of 10mm requires 4 passes to complete. For other metal blanks with lower strength (such as aluminum alloy blanks), the aspect ratio of the forging holes that can be formed in a single pass of the forging die will be greater than 2.2. Those familiar with this technical field should be able to disclose The technical documents can obtain reasonable data, and can be easily applied to the implementation of other materials according to the content disclosed in this manual.

Please refer to Fig. 1, Fig. 2 and Fig. 3A~3E at the same time, for cold forging forming the mechanical part 10 shown in Fig. 1. The forging die set 1000 of this creation contains 4 sets The forging dies 1100, 1200, 1300, and 1400 are cold-forged with metal blanks (the material of which is steel in this embodiment) 200, 210, 220, and 230 through 4 passes to form holes with an aspect ratio equal to 7. Each forging die 1100, 1200, 1300, 1400 includes a lower die 1110, 1210, 1310, 1410 and an upper die 1120, 1220, 1320, 1420. The lower dies 1110, 1210, 1310, and 1410 are set on a bed (not shown) of a punching machine (not shown), and the upper dies 1120, 1220, 1320, and 1420 are fixed on the slide of the punching machine. Seat (not shown), and moves back and forth with the slide seat. The lower molds 1110, 1210, 1310, and 1410 each have a mold cavity 1111, 1211, 1311, 1411 for accommodating and forming metal blanks 200, 210, 220, 230, and the upper molds 1120, 1220, 1320, and 1420 each hold A forged punch 3100, 3200, 3300, 3400. The simple appearance of the mechanical part 10 shown in this embodiment is for the convenience of explanation, and is not used to limit the creation. Those familiar with this technical field should understand that more complicated appearances may still pass through a reasonable cavity The design is completed by cold forging technology.

4 is a schematic diagram of a forging punch of an embodiment of the creative forging die set. Please refer to FIGS. 2 and 4 together. The forging punch 3100 includes a cylindrical body 3110 and a first escape gap 3120. The cylindrical body 3110 has a head 3111, a punching end 3112, a side surface 3113, and an imaginary longitudinal axis 3114. The head 3111 is for inserting and fixing to the upper die 1120, and the punching end 3112 is for extending into The die cavity 1111 punches and forges the metal blank 200. The two ends of the side surface 3113 respectively connect the head 3111 and the forging end 3112. The imaginary longitudinal axis 3114 extends along the longitudinal axis of the cylindrical body 3110, and the side surface 3113 surrounds the longitudinal axis 3114. The cross section of the cylindrical body 3110 shown in this embodiment is a circle, but the implementation should not be limited to this.

The cylindrical body 3110 is recessed with a first escape gap 3120, the first escape gap 3120 and the forging end 3112 are separated by a first distance d1, the first escape gap 3120 has a first surface S1, the first surface S1 surrounds the longitudinal axis 3114 is recessed on the side surface 3113 of the cylindrical body 3110. Please refer to the A-A sectional view of Figure 4, The first surface S1 of this embodiment is a circumferential surface with a radius slightly smaller than that of the side circumferential surface 3113, and the side circumferential surface 3113 and the first surface S1 have a common axis line. When the forging punch 3100 forms the forging hole 211 on the metal blank 200, the first clearance 3120 reduces the contact area between the forging punch 3100 and the hole wall of the forging hole 211. Preferably, along the direction of the longitudinal axis 3114, the length ratio of the first escape gap 3120 (first surface S1) to the first distance d1 is 8-12. In an example, the first distance d1 is 2mm, the difference in radius between the lateral peripheral surface 3113 and the first surface S1 is 0.03mm, along the longitudinal axis 3114, the length of the first clearance 3120 (first surface S1) is 16mm .

Please refer to Figure 2, Figure 3A, Figure 3B and Figure 4 together. When the forging punch 3100 punches the metal blank 200 to form the forging hole 211, the blank 200 is subjected to the die cavity 1111 and the forging punch 3100. It is plastically deformed by the extrusion, and flows upward along the space between the die cavity 1111 and the forging punch 3100 to gradually cover a part of the forging punch 3100. In order to prevent the metal blank 200 from filling the first escape gap 3120 and causing the forging punch 3100 to be stuck and unable to escape from the forging hole 211, preferably, the first surface S1 is close to the side of the forging end 3112 and the side peripheral surface 3113 A first push T1 is formed at the joint of the first surface S1, and a second push T2 is formed at the joint of the side of the first surface S1 close to the head 3111 and the lateral surface 3113. The first push T1 and the second push T2 have a first taper angle θ1 and a second taper angle θ2 respectively. The angle of the first taper angle θ1 and the second taper angle θ2 can be selected to be greater than or equal to 10° and less than or equal to 15°. In an example, the first taper angle θ1 and the second taper angle θ2 of the first escape gap 3120 are both selected to be 10°.

5A to 5C show a schematic diagram of an embodiment of the forging punch with plural first escape gaps in an embodiment of the creative forging die set. Please refer to FIGS. 4 and 5A together. In other applications, the forging punch 3100 may include a plurality of first escape gaps 3120, which are all separated from the forging end 3112 by a first distance d1, and each of the plurality of first escape gaps 3120 has one The first surface S1 and the plurality of first surfaces S1 are recessed on the lateral surface 3113 of the cylindrical body 3110 at intervals around the longitudinal axis 3114. The section shown in Figure 5A The number of 3120 escapes is three, but not limited to this.

Please refer to FIG. 5B. The plurality of first escape gaps 3120 shown in FIG. 5B each have a first surface S1, two adjacent first surfaces S1 are connected, and the plurality of first surfaces S1 are recessed in the column around the longitudinal axis 3114 The side surface 3113 of the shaped body 3110. The number of the first escape gap 3120 shown in FIG. 5B is four, but it is not limited to this. The four first surfaces S1 form a square, and the connecting line between two adjacent first surfaces S1 is located on the side peripheral surface 3113 , And become the inscribed square of the side peripheral surface 3113.

Please refer to FIG. 5C. Each of the plurality of first escape gaps 3120 shown in FIG. 5C has a first surface S1, two adjacent first surfaces S1 are connected, and the plurality of first surfaces S1 are recessed on the column around the longitudinal axis 3114 The side surface 3113 of the shaped body 3110. The number of first escape gaps 3120 shown in FIG. 5C is six, but it is not limited to this. The six first surfaces S1 form a hexagon, and the connecting line between two adjacent first surfaces S1 is located on the side circumference. Inside surface 3113. Of course, the entire hexagon surrounded by the six first surfaces S1 can also be regarded as a first surface S1.

In this creation, a long hole is formed by multiple forging dies for multiple passes. Therefore, the forging punches 3100, 3200, 3300, and 3400 are slightly different in length and diameter. The aforementioned technical features are all present in each The forging punches 3100, 3200, 3300, and 3400 are now only described with the forging punch 3100. Those familiar with this technical field should be able to understand the implementation of the other forging punches 3200, 3300, and 3400 through the foregoing description.

Figure 6 is a schematic diagram of another forging punch of the creative forging die set embodiment. As the number of forging passes increases, the depth of the forging hole will be deeper, and the length of the forging punch covered by the blank will increase, which increases the friction area. Please refer to FIG. 6, in addition to a first escape gap 3220, the forged punch 3200 also includes a second escape gap 3230. The second escape gap 3230 and the forging end 3212 are separated by a second distance d2. The second escape gap 3230 has a second surface S2. The second surface S2 is recessed on the side surface 3213 of the cylindrical body 3210 around the longitudinal axis 3214. . When forging When the punch 3200 forms the forging hole 221 on the metal blank 210, the second escape gap 3220 reduces the contact area between the forging punch 3200 and the hole wall of the forging hole 221. In an example, the second distance d2 is 20mm, the difference in radius between the lateral peripheral surface 3213 and the second surface S2 is 0.03mm, and along the longitudinal axis 3214, the length of the second clearance 3220 (second surface S2) is 16mm .

Similarly, the junction of the side of the second surface S2 close to the forging end 3212 and the side peripheral surface 3213 can also form a first push T1. The second surface S2 is close to the side of the head 3211 and the side peripheral surface 3213. The junction forms a second push T2. The first push T1 and the second push T2 have a first taper angle θ1 and a second taper angle θ2 respectively. The angle of the first taper angle θ1 and the second taper angle θ2 can be selected to be greater than or equal to 10° and less than or equal to 15°. The embodiment with multiple first escape gaps shown in FIGS. 5A to 5C can also be applied to the second escape gap 3220. In an example, the first cone angle θ1 and the second cone angle θ2 of the second escape gap 3220 are both selected to be 10°.

Please refer to FIG. 6 again, since the first escape gap 3220 and the second escape gap 3230 are both recessed on the side peripheral surface 3213, a first ridge R1 is formed between the first escape gap 3220 and the forging end 3212. A second ridge R2 is formed between an escape gap 3220 and a second escape gap 3230. Along the longitudinal axis 3214, the length ratio of the first escape gap 3220 to the first ridge R1 is 8-12, and the length ratio of the first escape gap 3220 or the second escape gap 3230 to the second ridge R2 is 8 ~12. The junction of the first surface S1 and the first ridge R1 forms a first push T1, the junction of the first surface S1 and the second ridge R2 forms a second push T2, the first push T1 and the second push T2 has a first taper angle θ1 and a second taper angle θ2, respectively. The angles of the first taper angle θ1 and the second taper angle θ2 can be selected to be greater than or equal to 10° and less than or equal to 15°.

When the depth of the forging hole gradually increases, in order to further reduce the contact area between the forging punch and the wall of the forging hole, the forging punch may be provided with a third escape clearance, a fourth escape clearance, etc. according to actual needs. This is done by those skilled in the art. The above description is understandable.

The forging die set of this embodiment is composed of four sets of forging dies, each of the upper die and the lower die has a forging punch and a cavity. In other applications, multiple forging punches can be set in a single upper die, and multiple cavities can be set in a single lower die to form the forging die set of this creation, which can also achieve the effect of cost creation.

Please refer to Fig. 2, Figs. 3A to 3E and Fig. 4. When the forging die set 1000 of the present embodiment is used to perform 4 passes of cold forging on the metal blank 200 to form the mechanical part 10, the steps are as follows:

First, the metal blank 200 (FIG. 3A) is placed in the cavity 1111 of the forging die 1100, and the sliding seat of a forging tool drives the upper die 1120 to move down, and the forging punch 3100 held on the upper die 1120 extends into the die cavity. 1111 performs the first pass of forging the metal blank 200 to form a metal blank 210 with forging holes 211 (FIG. 3B ). When the forging punch 3100 punches the metal blank 200 to form the forging hole 211, the blank 200 is plastically deformed by the extrusion of the die cavity 1111 and the forging punch 3100, and follows the die cavity 1111 and the forging punch The space between 3100 flows upward and gradually covers a part of the side peripheral surface 3113 of the forging punch 3100. Since the side peripheral surface 3113 is recessed with the first escape gap 3120, the contact area between the forging punch 3100 and the wall of the forging hole 211 can be reduced. When the upper die 1120 moves upward, the forging punch 3100 can smoothly interact with the forging hole 211. Break away. After the forging punch 3100 leaves the die cavity 1111, the metal blank 210 is ejected and can leave the die cavity 1111. In this embodiment, the outer diameter of the metal blank 210 is 20 mm, the length is about 87.58 mm, the diameter of the forging hole 211 is about 10 mm, and the hole depth is 20 mm.

Please refer to Figure 2, Figures 3A to 3E and Figure 6. Next, the metal blank 210 is placed in the cavity 1211 of the forging die 1200, and the sliding seat of the forging tool drives the upper die 1220 to move downward and is held in the upper die 1220. The forging punch 3200 extends into the die cavity 1211 to perform a second pass of forging the metal blank 210 to form a metal blank 220 with a forging hole 221 (FIG. 3C ). Similarly, the side peripheral surface 3213 of the forging punch 3200 is recessed with a first escape gap 3220 and a second escape gap 3230, which can make The contact area between the forging punch 3200 and the wall of the forging hole 221 is reduced. When the upper die 1220 moves upward, the forging punch 3200 can be separated from the forging hole 221 smoothly. After the forging punch 3200 leaves the die cavity 1211, the metal blank 220 is ejected and can leave the die cavity 1211. In this example, the outer diameter of the metal blank 220 is 20 mm, the length is about 92.58 mm, the hole diameter of the forging hole 221 is about 10 mm, and the hole depth is 40 mm.

In the third and fourth pass forging, the forging punch 3300 forms a metal blank 230 with a forging hole 231 (Figure 3D). The metal blank 230 is then placed into the die cavity 1411 and formed by the forging punch 3400 A metal blank 240 with forged holes 241 (Figure 3E). The metal blank 240 is generally cup-shaped, with an outer diameter of 20mm and a length of about 100.2mm. It has a forging hole 241 with a diameter of 10mm and a hole depth of about 70.2mm. Cut off the excess part (0.2mm) of the cup mouth. The mechanical parts 10 shown in Figure 1 can be obtained.

This creation has the following functions: 1. Metal blanks are placed in multiple die cavities in sequence, and forged by multiple forging punches in multiple passes to form holes with an aspect ratio greater than 2.2; and 2. Due to forging The side peripheral surface of the punch is concavely provided with at least one first escape gap, which can reduce the contact area between the forging punch and the forging hole wall, and the forging punch can be easily separated from the forging hole, and the forging punch is not provided with a draft angle Therefore, holes without taper can be forged without additional processing and removal, which improves material utilization and reduces process time and cost.

To sum up, it only records the preferred implementations or examples of the technical means used in this creation to solve the problem, and is not intended to limit the scope of implementation of this creation patent. That is to say, all the equivalent changes and modifications made in accordance with the scope of the creation patent application or made in accordance with the scope of the creation patent are covered by the scope of the creation patent.

3100: Forged punch

3110: cylindrical body

3111: head

3112: Forging end

3113: side surface

3114: longitudinal axis

3120: first escape

d1: first distance

S1: First surface

T1: First promotion

T2: Second promotion

θ1: first cone angle

θ2: second cone angle

Claims (10)

A forging punch is used to form a forging hole on a metal blank. The forging punch includes: A cylindrical body having a head, a punched end, a side peripheral surface, and an imaginary longitudinal axis. The two ends of the side peripheral surface are respectively connected to the head and the punched end, and the side peripheral surface is Around the aforementioned longitudinal axis; and A first escape gap, which is a first distance away from the forging end, the first escape gap has a first surface, and the first surface is recessed on the lateral surface of the cylindrical body around the longitudinal axis; When the forging punch forms the forging hole on the metal blank, the first clearance reduces the contact area between the forging punch and the hole wall of the forging hole. The forging punch according to claim 1, wherein the forging punch includes a plurality of first escape gaps, and is separated from the forging end by the first distance, and each of the plurality of first escape gaps has a first surface The plurality of first surfaces are recessed on the side peripheral surface of the cylindrical body at intervals around the longitudinal axis. The forging punch according to claim 1, wherein the forging punch includes a plurality of first escape gaps, and is separated from the forging end by the first distance, and each of the plurality of first escape gaps has a first surface Two adjacent first surfaces are connected, and the plurality of first surfaces are recessed on the side circumferential surface of the cylindrical body around the longitudinal axis. As the forged punch mentioned in claim 1, the aforementioned forged punch further includes: A second escape gap, which is a second distance away from the forging end, the second escape gap has a second surface, and the second surface is recessed on the lateral surface of the cylindrical body around the longitudinal axis; When the forging punch forms the forging hole on the metal blank, the second escape allows the forging punch to contact the hole wall of the forging hole The area is reduced. The forging punch according to claim 4, wherein the forging punch includes a plurality of second escape gaps, which are all separated from the forging end by the second distance, and each of the plurality of second escape gaps has a second surface The plurality of second surfaces are recessed on the side peripheral surface of the cylindrical body at intervals around the longitudinal axis. The forging punch according to claim 4, wherein the forging punch includes a plurality of second escape gaps, which are all separated from the forging end by the second distance, and each of the plurality of second escape gaps has a second surface Two adjacent second surfaces are connected, and the plurality of second surfaces are recessed on the side circumferential surface of the cylindrical body around the longitudinal axis. The forging punch according to claim 4, wherein a first ridge is formed between the first escape gap and the forging end, and a second ridge is formed between the first escape gap and the second escape gap. Ridge. The forging punch according to claim 7, wherein in the direction of the longitudinal axis, the ratio of the length of the first clearance to the first ridge is 8-12, and the first clearance or the second The length ratio between the escape gap and the aforementioned second ridge is 8-12. The forged punch according to claim 7, wherein the connection between the first surface and the first ridge forms a first push, and the connection between the first surface and the second ridge forms a first Two pushes, the first push and the second push have a first taper angle and a second taper angle respectively, and the angles of the first taper angle and the second taper angle are selected to be greater than or equal to 10° and less than Equal to 15°. A forging die set is used to form a hole with an aspect ratio greater than 2.2 on a metal blank in multiple passes. The aforementioned forging die set includes: Multiple mold cavities for containing the aforementioned metal blanks; and Plural such as the forged punch of any one of items 1 to 9 of the request, The aforementioned plural forging punches are individually used to form the aforementioned forging holes on the aforementioned metal blank; Wherein, the aforementioned metal blanks are sequentially placed in the aforementioned plurality of die cavities, and are sequentially punched by the aforementioned plurality of forging punches, and finally the aforementioned holes with an aspect ratio greater than 2.2 are formed.

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