JP3657474B2 - Crankshaft of internal combustion engine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention mainly relates to a crankshaft of an internal combustion engine mounted on a vehicle.
[0002]
[Prior art]
Conventionally, a crankshaft of an internal combustion engine has a function of converting a vertical movement of a piston transmitted via a connecting rod into a rotational motion. Such a crankshaft includes a crankpin that is a rotating shaft of the connecting rod, a pair of crank arms that sandwich the crankpin, and a crank journal that is coupled to the outer surface of the crank arm at a position different from the axis of the crankpin. And a counterweight formed integrally with the crank arm. In such a crankshaft, bending stress and shear stress are applied to each part according to the vertical movement of the piston, but in order to reduce the weight of the internal combustion engine, it is necessary to reduce the weight while maintaining rigidity and strength. Has been tried. For example, Japanese Patent Laid-Open No. 9-317750 describes a crankshaft in which a counterweight is thinned to reduce weight while maintaining strength and durability.
[0003]
[Problems to be solved by the invention]
In a crankshaft with a hollow portion in the counterweight described above, it is known that downward bending stress is concentrated on the so-called danger cross section of the crank arm due to, for example, the downward movement of the piston after the explosion stroke. Yes. That is, in a normal crankshaft, a groove is formed around the entire circumference with a small curvature in relation to the bearing at the end of the crank journal, and a groove is also formed around the entire circumference with a small curvature at the end of the crankpin. When the crankshaft receives downward force after the explosion process, these grooves are corners where stress is concentrated by trying to distort the crank arm so that it is pulled by the crankpin and crank journal. The dangerous section is formed between the corners.
[0004]
That is, for example, as apparent from the stress distribution diagram shown in FIG. 7, bending stress concentrates around the corner Gp on the crankpin side and the corner Gj on the crank journal side (region Ra), and the inside of the crank arm Although the magnitude of the bending stress decreases toward, the stress stress region Rd is generated in a narrow range, and the bending stress is concentrated on the critical section Sd during that period. As described above, stress is easily generated in the groove portion having a small curvature, and as a result, if bending stress is concentrated on the dangerous section, a problem may occur in the crankshaft.
[0005]
The object of the present invention is to eliminate such problems.
[0006]
[Means for Solving the Problems]
In order to achieve such an object, the present invention takes the following measures. That is, the crankshaft of the internal combustion engine according to the present invention distributes the bending stress concentrated on the dangerous cross section of the crank arm to a plurality of cross sections based on the shape of the meat stealing portion provided on the counterweight, thereby reducing the weight. It is the structure which prevents concentrating on one cross section.
[0007]
DETAILED DESCRIPTION OF THE INVENTION
The present invention has a meat stealing portion on at least one of opposing surfaces of a counterweight continuous with a pair of crank arms connected by a crankpin, and is bent by a force applied perpendicularly to the crankpin. It is applied to each cross-section where bending stress is concentrated between the crank journal side corner where the stress is concentrated and the crank pin side corner and between the crank journal side corner and the meat stealing side corner. The respective distances in the axial direction from the midpoint in the axial direction of the crank journal adjacent to the meat stealing portion to the midpoint in the respective cross sections and the thicknesses of the respective cross sections so that the bending stresses are substantially equal. but setting the thinned-out part shape counterweight to maintain the thickness is increased relationship of the respective cross section with the distance of the respective increases A crank shaft of the internal combustion engine, characterized.
[0008]
With such a configuration, if a force is applied perpendicularly to the crank pin in the explosion process, the bending stress generated by the force is generated between the crank journal side corner and the crank pin side corner and the crank journal side. It is distributed in the respective cross sections between the corner and the meat stealer side corner, and becomes substantially equal. In other words, the stress generated in the crank arm is also applied to the cross section formed by forming the meat stealing portion, and is concentrated only on the cross section existing between the crank journal side corner and the crank pin side corner. There is no longer to do. Therefore, it is possible to prevent the bending stress from concentrating on one cross section, and to prevent the crankshaft from being defective.
[0009]
In order to maintain the strength without reducing the rigidity, it is preferable that the respective cross sections have substantially the same cross sectional area.
[0010]
【Example】
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
A crankshaft 100 shown in FIG. 1 is a forged three-cylinder engine, for example, a crank arm 1 paired for each cylinder, a counterweight 2 formed integrally with each crank arm 1, and a crank arm 1 And a crank journal 4 for connecting adjacent crank arms 1 to each other. In this embodiment, the surface of the second counterweight 22 that is continuous with the second crankarm 12 of the crank arm 1 for the first cylinder in the three-cylinder engine is opposed to the first counterweight 21 that is continuous with the first crank arm 11. Meat stealing portions 6 are provided around the axis of the crank journal 4 on the opposing surfaces 25a and 26a of the counterweight 2 for the 22a and the third cylinder. The internal lubricating oil path P for circulating the lubricating oil may be the same as a configuration widely known in this field.
[0011]
The meat stealing portion 6 has a small thickness in the direction of the crank journal 4 connected in the thickness direction of the crank arm 1 and, as shown in FIG. The crank arm 1 is formed symmetrically so that the width of the crank arm 1 is narrowed about the axis 4. That is, the shape of the meat stealing portion 6 is formed between the crank journal side corner portion 4a and the crank pin side corner portion 3a where stress is concentrated when bent by the force applied to the crank pin 3 and the crank journal side corner portion. The bending stress applied to each cross section where the bending stress generated in the crank arm 1 between 4a and the meat stealing portion side corner 6a is concentrated is set to be substantially equal. In FIG. 2, the crank arm 1 and the counterweight 2 for the second and third cylinders are not shown.
[0012]
By forming the meat stealing portion 6 as described above, as shown in FIG. 3, the first cross section 7 is formed on the second crank arm 12 between the crank journal side corner portion 4a and the crank pin side corner portion 3a. Moreover, the 2nd cross section 8 is assumed to the 2nd crank arm 12 between the crank journal side corner part 4a and the meat stealing part side corner part 6a, respectively. The first cross section 7 has the shape shown in FIG. 4, and the cross sectional area is determined by the width and thickness of the second crank arm 12 in this cross section. Further, the second cross section 8 has the shape shown in FIG. 5 and is different in shape from the first cross section 7, but is similarly determined by the width and thickness of the second crank arm 12 in this cross section. The cross-sectional area is approximately equal to the cross-sectional area of the cross-section 7. In FIG. 5, the thickness of the portion corresponding to the axial center of the crank journal 4 is the same when compared with the cross-sectional shape at the same position of the crank arm of the conventional crankshaft as shown by the imaginary line, but in the other portions The thickness of the second counterweight 22 is reduced by the meat stealing portion 6.
[0013]
The first and second cross sections 7 and 8 have the width of the first cross section 7 as U ₁ , the thickness of the first cross section 7 as h ₁ , the width of the second cross section 8 as U ₂ , and the second cross section 8, respectively. When the thickness of h is set to h ₂ , the section coefficients Z ₁ and Z ₂ represented by the following formulas are provided.
_{Z 1 = U 1 × h 1} 2/6 (1)
_{Z 2 = U 2 × h 2} 2/6 (2)
[0014]
When the external force F is applied to the crankpin 3 from above in the state shown in FIG. 1, bending stresses σ ₁ and σ ₂ according to the following equations are applied to the first and second cross sections 7 and 8.
M ₁ = F × a ₁ (3)
M ₂ = F × a ₂ (4)
σ ₁ = M ₁ / Z ₁ = F × a ₁ / Z ₁ (5)
σ ₂ = M ₂ / Z ₂ = F × a ₂ / Z ₂ (6)
Where M ₁ and M ₂ are bending moments, a ₁ is the distance from the midpoint in the axial direction of the adjacent crank journal 4 to the midpoint of the first cross section 7, and a ₂ is the distance between the adjacent crank journals 4. This is the distance from the midpoint in the axial direction to the midpoint of the second cross section 8.
[0015]
As described above, the shape of the meat stealing portion 6 is set so that the bending stresses σ ₁ and σ ₂ applied to the first and second cross sections 7 and 8 are substantially equal. In this case, since the width U ₁ of the first section 7 and the width U ₂ of the second section 8 equal, equation (1), (2), (5) and (6), the thickness of the first section 7 h ₁ , the thickness h ₂ of the second cross section 8, the distance a _1, and the distance a ₂ are set so as to satisfy the following relationship.
σ ₁ ≈σ ₂
F × a ₁ / Z ₁ ≒ F × a ₂ / Z ₂
a ₁ / Z ₁ ≒ a ₂ / Z ₂
a ₁ × 6 / U ₁ × h ₁ ² ≒ a ₂ × 6 / U ₂ × h ₂ ²
a ₁ / h ₁ ² ≒ a ₂ / h ₂ ² (7)
[0016]
Thus, the distance a ₁ from the midpoint of the adjacent crank journal 4 in the axial direction to the midpoint of the first cross section 7 and the midpoint of the adjacent crank journal 4 in the axial direction from the midpoint of the second cross section 8. Adjusting the distance a ₂ , the thickness h ₁ of the first cross section 7, and the thickness h ₂ of the second cross section 8, and setting the shape of the meat stealing portion 6 so that the above formula (7) is satisfied. Accordingly, the bending stresses σ ₁ and σ ₂ applied to the first cross section 7 and the second cross section 8 can be made equal. As a result, as shown in FIG. 6, the stress distribution in the second crank arm 12 is widely dispersed without concentrating on the first cross section 7 around the crankpin side corner 3a and the meat stealer side corner 6a. Thus, the first cross section 7 and the second cross section 8 are widely dispersed. That is, although the stress distribution is concentrated at the crankpin side corner 3a and the meat stealing side corner 6a, there is a region R1 having a small stress concentration so as to surround the corners 3a and 6a. In this way, by forming the meat stealing portion 6 in a predetermined shape based on a predetermined condition, bending stress is not concentrated on either the first cross section 7 or the second cross section 8.
[0017]
Therefore, since the bending stress concentrated on the first cross section 7 when there is no meat stealing portion 6 can be distributed to the second cross section 8, the bending stress is concentrated on the first cross section 7 which is a so-called dangerous cross section. It is possible to prevent the crankshaft 100 from malfunctioning. Further, by forming the meat stealing portion 6, the weight can be reduced, the strength can be increased without lowering the rigidity, and various performances required for the crankshaft 100 can be improved.
[0018]
In addition, this invention is not limited to the Example demonstrated above.
In the above embodiment, the counterweight for the first cylinder and the third cylinder is provided with the meat stealing portion. However, the present invention is not limited to this, and the counterweight for each cylinder is appropriately provided in consideration of balance. It may be a thing.
In addition, the structure of each part is not limited to the illustrated example, and various modifications can be made without departing from the spirit of the present invention.
[0019]
【The invention's effect】
As described above, according to the present invention, the axial distance from the midpoint of the crank journal adjacent to the meat stealing portion to the midpoint of each cross section and the thickness of each cross section are determined. By maintaining the relationship that the thickness of each cross-section increases as each distance increases and the meat stealing portion is formed in the counterweight, if the force is applied perpendicularly to the crankpin in the explosion process, the force The bending stress generated by the above is distributed to the respective sections between the crank journal side corner and the crank pin side corner and between the crank journal side corner and the meat stealer side corner so as to be applied substantially equally. Can be. Thus, if the stress generated in the crank arm is also applied to the cross section formed by forming the meat stealing portion, it is concentrated only on the cross section existing between the crank journal side corner and the crank pin side corner. Therefore, it is possible to prevent the bending stress from concentrating on one cross section. Therefore, the weight can be reduced by the meat stealing portion, and the strength can be maintained without reducing the rigidity.
[Brief description of the drawings]
FIG. 1 is a front view showing an embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along line AA in FIG.
FIG. 3 is an essential part front view showing an enlarged second counterweight portion of the embodiment;
FIG. 4 is an end view showing the shape of a first cross section of the embodiment.
FIG. 5 is an end view showing a shape of a second cross section of the embodiment.
FIG. 6 is a stress distribution diagram showing a distribution state of bending stress in the embodiment.
FIG. 7 is a stress distribution diagram showing a bending stress distribution state of a conventional example.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Crank arm 2 ... Counterweight 3 ... Crank pin 3a ... Crank pin side corner 4 ... Crank journal 4a ... Crank journal side corner 6 ... Meat stealing part 6a ... Meat stealing part side corner 7 ... 1st cross section 8 ... Second section

Claims (2)

At least one of the opposing surfaces of the counterweight connected to the pair of crank arms connected by the crankpin has a meat stealer, and stress is concentrated when it is bent by the force applied perpendicular to the crankpin. The bending stress applied to each cross section where the bending stress generated on the crank arm between the crank journal side corner and the crank pin side corner and between the crank journal side corner and the meat stealing side corner is concentrated is approximately The respective distances in the axial direction from the midpoints in the axial direction of the crank journal adjacent to the meat stealing portion to the midpoints in the respective cross sections and the thicknesses of the respective cross sections are It is characterized in that the distance of setting the thinned-out part shape counterweight to maintain the thickness is increased relationship of the respective cross-section with the larger The crankshaft of the internal combustion engine. 2. A crankshaft for an internal combustion engine according to claim 1, wherein each of the cross sections has substantially the same cross sectional area.

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