JP2006312979A - Con'rod manufacturing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a con'rod manufacturing method capable of obtaining a con'rod having superior symmetric property of cross-sectional shape of a column portion and high buckling strength. <P>SOLUTION: In a hot forging process, the hot forging is performed so that burr 2 is formed on a position offset from a center "a" in the thickness direction of the con'rod 1, and in a trimming process, the con'rod is inserted into a trimming hole of a trimming die at a thicker side from the burr 2, the burr 2 is brought into contact with a burr cutting blade, and the con'rod 1 is pressed to press the burr 2 to the burr cutting blade so that the burr 2 is cut. The offset quantity A from the central position "a" in the thickness direction of the con'rod 1, of the burr 2 preferably satisfies 0<A≤D/4+B/2-C/2 when C<B/4, and B/4≤A≤D/4+B/2-C/2 when C≥B/4 in the relationship with a thickness B of a central portion in the width direction of the column portion 13, a height D of a rib, and a thickness C of the burr 2. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a connecting rod manufacturing method capable of suppressing a decrease in buckling strength.

A connecting rod, which is one of the parts of an engine used in automobiles, is often manufactured by hot forging. As a general manufacturing method, there is a method of performing a hot forging process, a deburring process, and a cold coining process (for example, Patent Document 1).
By the way, the connecting rod has a large end portion, a small end portion, and a column portion connecting them, as is well known, and the column portion includes ribs arranged on both sides and a trunk portion connecting them. Usually, the cross section is substantially H-shaped. And the connecting rod needs to withstand the compressive force when the explosive force in the cylinder is received by the piston fixed to the small end side of the connecting rod, so increasing the buckling strength of the column can reduce the weight To become indispensable. Therefore, research for improving the buckling strength has been actively promoted.

In addition, while researches for increasing the buckling strength have been actively conducted, there remains a problem that causes a reduction in the buckling strength in manufacturing. In other words, in actual manufacturing, it is difficult to manufacture a connecting rod in which the cross-sectional shape of the column portion is completely symmetric.
When the cross-sectional shape of the column part is not symmetrical, for example, when the ribs on both sides of the H-shaped are not parallel but inclined, there is a difference in resistance to compressive force between the upper and lower parts of the H-section. Anyway, bending distortion will occur in the column part. Therefore, if this bending strain increases beyond a certain amount, a buckling phenomenon will naturally occur, and the buckling strength will be greatly reduced by the amount of bending strain compared to the case of perfect symmetry. It becomes. The connecting rod manufactured in the above general manufacturing method often undergoes deformation as described above in the column part, and accordingly, measures such as increasing the wall thickness are necessary to improve the overall rigidity. It is one of the obstacles.

JP 2003-147434 A

  The present invention has been made in view of such conventional problems, and an object of the present invention is to provide a manufacturing method capable of obtaining a connecting rod having excellent symmetry of the cross-sectional shape of the column portion and high buckling strength.

The present invention provides a hot forging process in which a hot forging process is performed on a material to form a connecting rod having a large end portion, a small end portion, and a column portion having a substantially H-shaped cross section connecting the large end portion and a burr on the outer peripheral portion. And a deburring step for removing the burrs generated on the outer periphery of the connecting rod, and a cold coining step for performing cold coining on the large end portion, the small end portion and the column portion. In
In the hot forging step, hot forging is performed so as to generate the burr at a position offset from the thickness direction center of the connecting rod,
In the deburring step, a die having a hole and a burr cutting blade around the hole is used, and the thicker side of the connecting rod from the burr is inserted into the hole, and the burr cutting blade The burr is removed by pressing the burr against the burr cutting blade by pressing the burr against the burr and pressing the burr against the burr cutting blade (Claim 1). ).

  It should be noted in the present invention that in the hot forging step, burrs generated on the outer peripheral portion of the connecting rod are positively offset from the center in the thickness direction. Thereby, finally, a connecting rod having excellent symmetry of the cross-sectional shape of the column portion and high buckling strength can be obtained.

  That is, in the conventional method of providing the burr at the center position in the thickness direction of the connecting rod in the hot forging step, when the burr removing step is performed, stress is applied to the column portion due to shear stress at the time of burr cutting. The ribs are deformed so that they open in a “C” shape. When this deformation occurs, the larger the deformation, the more the compressive force in the subsequent cold coining process works in the direction of increasing the deformation, causing a larger deformation.

  On the other hand, in the present invention, as described above, burrs generated in the outer peripheral portion of the connecting rod in the hot forging process are positively offset from the center in the thickness direction. In the subsequent deburring step, the thicker side of the connecting rod from the burr is inserted into the hole and the burr is brought into contact with the burr cutting blade. Then, in this state, the connecting rod is pressed by a pressure die to perform burr cutting.

Thereby, since the force generated when the burr is cut is generated at a position offset from the center of the column portion in the thickness direction, the force acting in the direction of opening in the “C” shape can be suppressed. And the deformation | transformation in a subsequent cold coining process can also be suppressed according to the deformation | transformation suppression effect in this deburring process.
Therefore, if the manufacturing method of the present invention is used, a connecting rod having excellent symmetry of the cross-sectional shape of the column portion and high buckling strength can be obtained.

In the present invention, it is considered that the appropriate range of the offset amount of the burr is different in the shape, dimension, etc. of the connecting rod. That is, the offset amount A from the center position in the thickness direction of the connecting rod at the center position in the thickness direction of the burr is the thickness B of the center section (stem section) in the width direction of the column section, the height D of the rib, and the burr. In relation to the thickness C of
In the case of C <B / 4, 0 <A ≦ D / 4 + B / 2−C / 2 is satisfied,
In the case of C ≧ B / 4, it is preferable that B / 4 ≦ A ≦ D / 4 + B / 2−C / 2 is satisfied (Claim 2).

  First, in the case of C <B / 4, since the thickness of the burr is small, the influence on the deformation of the rib at the time of cutting is relatively small. Therefore, if the lower limit value of the offset amount A is larger than 0, no particular problem occurs. On the other hand, when the offset amount A exceeds D / 4 + B / 2−C / 2, the rib on the side where the rib is offset, that is, the rib located on the opposite side to the side through which the punching hole is inserted is inside. There is a risk of deformation to approach.

  In addition, when C ≧ B / 4, the influence on rib deformation at the time of burr cutting is very large. Therefore, the offset amount A is set to B / 4 or more. When the offset amount A is less than B / 4, it is difficult to prevent the rib on the side inserted into the punching hole of the punching die from being deformed so as to open in a “C” shape. Further, when the offset amount A exceeds D / 4 + B / 2−C / 2, the rib on the offset side, that is, the rib located on the opposite side to the side inserted through the punching hole of the punching die is shifted to the inside. There is a risk of deformation.

Example 1
A method for manufacturing a connecting rod according to an embodiment of the present invention will be described with reference to FIGS.
In this example, as shown in FIG. 1, a connecting rod 1 having a large end portion 11, a small end portion 12, and a column portion 13 having a substantially H-shaped cross section connecting them is manufactured. As shown in the figure, the column portion 13 has a substantially H-shaped cross section composed of ribs 131 arranged on both sides and a trunk portion 130 connecting them.
As shown in FIG. 2, the manufacturing method of this example includes a hot forging step S1, a deburring step S2, a shot blasting step S3, and a cold coining step S4. Note that the shot blasting step S3 can be omitted. Further, as shown in the figure, after the cold coining step S4, a shot peening step S5 and a machining step S6 may be added as necessary.

First, as shown in FIG. 3, the hot forging step S <b> 1 includes a large end portion 11, a small end portion 12, and a column portion 13 having a substantially H-shaped cross section connecting the large end portion 11 and the small end portion 12. This is a step of forming a connecting rod 1 having burrs 2 on the outer periphery.
Here, in this example, as shown in FIGS. 4B and 4C, in the hot forging step S1, the burrs 2 are formed so as to be generated at positions offset from the center a in the thickness direction of the connecting rod 1. Forging.

  Next, as shown in FIG. 4, a deburring process S <b> 2 for removing the burrs 2 generated on the outer peripheral portion of the connecting rod 1 is performed. In this example, as shown in FIG. 4A, a punching die 5 having a punching hole 50 and having a burr cutting blade 51 around it is used. Then, the side of the connecting rod 1 that is thicker from the burr 2 (lower half 101) is inserted into the punch hole 50 and the burr 2 is brought into contact with the burr cutting blade 51. Next, the connecting rod 1 is pressed by the pressing die 4 and the burr 2 is pressed against the burr cutting blade 51 to cut off the burr 2. Note that the pressing die 4 has a burr pressing portion 41 for pressing the burr 2 via a spring 42.

After performing this deburring step S2, in this example, a shot blasting step S3 for removing oxide scale is performed, and then a cold coining step S4 is performed.
In the cold coining step S4, as shown in FIGS. 5 and 6, a compression load is applied by sandwiching the column portion 13 of the connecting rod 1 by a pair of upper and lower coining dies 71 or 72. As the coining type, as shown in FIG. 5, with respect to the column portion 13, a coining die 71 that applies a compressive load only to the central portion in the longitudinal direction, and a compressive load applied to the entire length in the longitudinal direction of the column portion 13 as shown in FIG. 6. There is a coining mold 72.

By adopting such a manufacturing method, the connecting rod 1 obtained in this example has less deformation of the column portion 13 than the conventional one, and the buckling strength is improved as compared with the conventional one.
That is, in this example, the burr 2 formed in the hot forging step S1 is positively formed at a position offset from the center a in the thickness direction of the connecting rod 1 as described above. Due to this offset effect, in the deburring step S2, it is possible to suppress the ribs 131 on both sides of the column portion 13 from being deformed so as to be opened in a “C” shape.
Then, by suppressing the deformation in the deburring step S2, it is possible to suppress the increase in deformation due to the compressive force in the subsequent cold coining step S4.
Therefore, in the manufacturing method of this example, it is possible to obtain the connecting rod 1 having excellent symmetry of the cross-sectional shape of the column portion 13 and high buckling strength.

(Example 2)
In this example, in order to clarify the operational effects of Example 1, connecting rods were produced under a plurality of types of conditions (test Nos. 1 to 18), and the deformation state and buckling strength were evaluated.
In this example, S55C (0.55% C-0.25% Si-0.75% Mn) steel was used as a material, and the same manufacturing process as that of Example 1 described above was performed (FIG. 2). ).

  Hot forging process S1 heated the said raw material to 1250 degreeC, gave hot end forging, and formed the large end part 11, the small end part 12, and the column part 13. As shown in FIG. At this time, the positions, dimensions, and the like of the burrs 2 formed on the outer periphery of the connecting rod 1 were set as shown in Table 1 described later. Specifically, Test No. 1 to 3 and 7 to 12 are examples in which the thickness C of the burr 2 is 1 mm, and other tests are examples in which the thickness C of the burr 2 is 4 mm. And test no. 1 to 6 are examples in which the offset amount A of the burr 2 (see FIG. 3C) is appropriate. 7 to 18 are examples where the offset amount A is 0 or inappropriate.

  The deburring step S2 was performed under the same conditions. The mold structure used is as shown in Example 1 (FIG. 4). The conventional deburring step S2 when the offset amount A is 0 is shown in FIG. The types used basically are the same as in the example of the present invention (FIG. 4).

  After the deburring step S2, a shot blasting step S3 was performed, followed by a cold coining step S4. In this cold coining step S4, three kinds of conditions were adopted. The first condition is a condition in which the machining rate is set to 5% using the coining die 71 (FIG. 5) (Test Nos. 1, 4, 7, 10, 13, 16). Since this condition is a normal coining method, the processing type is indicated as “normal” in Table 1 described later. The second condition is a condition in which the coining die 72 (FIG. 6) is used and the processing rate is 15% (Test Nos. 2, 5, 8, 11, 14, 17). The third condition is a condition in which the machining rate is set to 25% using the coining die 72 (FIG. 6) (Test Nos. 3, 6, 9, 12, 15, 18). In the second condition and the third condition, the strength of the column portion can be increased by coining, so in Table 1 described later, the processing type is indicated as “column strengthening”. The processing rate can be determined by the rib height reduction rate, that is, (1-coined rib height / coining rib height) × 100 (%).

About 18 types of obtained connecting rods, the deformation | transformation state was evaluated first. As shown in FIG. 8, the deformed state was evaluated based on the angle α formed by the center line 139 indicating the inclination of the ribs 131 on both sides of the rib 131 in a “C” shape. The deformation of the rib 131 may be different between the upper half 102 and the lower half 101 with the trunk 130 as a boundary. In this case, the deformation of the rib 131 on the greatly deformed side is used as a reference. A tilt centerline 139 was created. This evaluation was performed before and after the cold coining step S4.
Moreover, about 18 obtained connecting rods, the buckling test (compression test) was done and 0.2% yield strength was measured.
These results are shown in Table 1.

The obtained results can be evaluated for each thickness of the burr 2 and for each condition of cold coining. That is, as known from Table 1, when the thickness of the burr 2 is 1 mm and the cold working rate is 5% (test Nos. 1, 7, and 10), the offset amount A of the burr 2 is set to 1 mm. The thing (Test No. 1) had the smallest deformation (C-shaped angle) before and after coining and the highest 0.2% proof stress. In contrast, test no. 7 and 10, the deformation amount (C-shaped angle) is Test No. It was larger than 1 and 0.2% yield strength was low.
Moreover, this tendency is the case where the thickness of the burr 2 is 1 mm and the cold working rate is 15% (test No. 2, 8, 11), and the thickness of the burr 2 is 1 mm and the cold working rate. The same was true in the case of 25% (Test Nos. 3, 9, and 12).

Next, when the thickness of the burr 2 is 4 mm and the cold working rate is 5% (test Nos. 4, 13, and 16), the offset amount A of the burr 2 is set to 1.5 mm (test No. .4), however, had the smallest deformation (C-shaped angle) before and after coining and the highest 0.2% proof stress. In contrast, test no. In the case of Nos. 13 and 16, the deformation amount (C-shaped angle) is Test No. It was larger than 4, and 0.2% yield strength was low.
Moreover, this tendency is the case where the thickness of the burr 2 is 4 mm and the cold working rate is 15% (test No. 5, 14, 17), and the thickness of the burr 2 is 4 mm and the cold working rate. The same was true in the case of 25% (Test Nos. 6, 15, and 18).

From the above results, compared with the conventional manufacturing method (test Nos. 7 to 9 and 16 to 18) in which the offset amount A of the burr 2 is set to 0, the manufacturing method of the present invention in which an appropriate offset amount A is set ( Test Nos. 1 to 6) show that the amount of deformation can be suppressed as compared with the conventional case, and the buckling strength can be improved.
In addition, Test No. 1-6 and test no. From 10 to 15, it can be seen that the offset amount A has an appropriate range. The appropriate range is considered to vary depending on the connecting rod shape, dimensions, etc., but as a result of examination by the inventor based on a large amount of data such as the data of this embodiment, the thickness of the central portion in the width direction of the column portion is considered. In relation to B, rib height D, and burr thickness C, at least when C <B / 4, 0 <A ≦ D / 4 + B / 2−C / 2 is satisfied, and C ≧ B In the case of / 4, it was confirmed that it was preferable to satisfy B / 4 ≦ A ≦ D / 4 + B / 2−C / 2.

The (a) top view which shows the shape of the connecting rod as a final product in Example 1, (b) Side view, (c) AA AA arrow expanded sectional view. Explanatory drawing which shows the manufacturing process in Example 1. FIG. The (a) top view which shows the shape of the connecting rod in Example 1 immediately after a hot forging process, (b) Side view, (c) BB arrow directional cross-sectional enlarged view. (A) Explanatory drawing which shows the state which set the connecting rod to the die | dye in the burr | flash removal process in Example 1, (b) Explanatory drawing which shows the state immediately after excising a burr | flash. (A) In the cold coining process in Example 1, (a) An explanatory diagram of a state where the connecting rod is set in a coining die for light processing, (b) An explanatory diagram of a state in which the column portion of the connecting rod is clamped by the coining die, (c) FIG. (A) In the cold coining process in Example 1, (a) An explanatory diagram of a state where the connecting rod is set in a coining die for heavy machining, (b) An explanatory diagram of a state in which the column portion of the connecting rod is clamped by the coining die, (c) FIG. The deburring process when the offset amount A is 0 as a conventional example in Example 2 is shown. (A) An explanatory diagram showing a state in which the connecting rod is set in a die, and (b) a state immediately after cutting the burr. Illustration. Explanatory drawing which shows the evaluation method of a deformation | transformation state in Example 2. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Connecting rod 11 Large end part 12 Small end part 13 Column part 131 Rib 2 Burr 4 Pressurization type 5 Punching die 50 Punching hole 51 Burr cutting blade 6 Restraint type 61 Housing recessed part

Claims (2)

A hot forging step in which a hot forging process is performed to form a connecting rod having a large end portion, a small end portion, and a column section having a substantially H-shaped cross section connecting the large end portion and a burr on the outer peripheral portion, and the above connecting rod. In a method for manufacturing a connecting rod, including a deburring process for removing the burr generated on the outer peripheral part of the sheet, and a cold coining process for performing cold coining on the large end part, the small end part and the column part,
In the hot forging step, hot forging is performed so as to generate the burr at a position offset from the thickness direction center of the connecting rod,
In the deburring step, a die having a hole and a burr cutting blade around the hole is used, and the thicker side of the connecting rod from the burr is inserted into the hole, and the burr cutting blade The burr is cut off by bringing the burr into contact, pressing the connecting rod with a pressure die, and pressing the burr against the burr cutting blade. The offset amount A from the central position in the thickness direction of the connecting rod at the central position in the thickness direction of the burr according to claim 1, the thickness B of the central portion in the width direction of the column section, the height D of the rib, and the burrs. In relation to the thickness C of
In the case of C <B / 4, 0 <A ≦ D / 4 + B / 2−C / 2 is satisfied,
In the case of C ≧ B / 4, the manufacturing method of the connecting rod characterized by satisfying B / 4 ≦ A ≦ D / 4 + B / 2−C / 2.

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