RU2435974C2 - Design for erection of disc of pulse generator - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: design for erection of disc of pulse generator includes the following: key groove (14), key part (16) and fastener (18). Key groove (14) is made in end surface (10) of rotating wall (9). Key part (16) is provided on disc of pulse generator (P). Disc of pulse generator (P) is attached to rotating wall (9) by means of fastener (18). Key part (16) is made of arc-shaped band-like part (16a) and pair of connecting parts (16b). Arc-shaped band-like part (16a) protrudes in the bent shape from end surface of disc of pulse generator (P). Arc-shaped band-like part (16a) is engaged with key groove (14). Connecting parts (16b) provide connection between the disc of pulse generator (P) and opposite ends of arc-shaped band-like part (16a). Longitudinal directions of key groove (14) and arc-shaped band-like part (16a) are located along radius of disc of pulse generator (P).

EFFECT: development of design for erection of disc of pulse generator, at which high positioning accuracy and manufacturability is provided.

13 cl, 17 dwg

Description

FIELD OF TECHNOLOGY

The present invention relates to an improvement in the construction for mounting a pulse generator disk, in which a keyway is formed on the end surface of the rotating wall, consisting of the crank arm and the counterweight of the crankshaft of the internal combustion engine, and a keyway is formed on the pulse generator disk, which is superimposed on said end surface. a part for engagement with a keyway, and this pulse generator disk is attached to said rotating wall by means of a fastener.

BACKGROUND

Such a design for mounting a pulse generator disk is already known, as disclosed in Patent Publication 1.

Patent Publication 1: Japanese Patent Application Laid-Open No. 10-331681

SUMMARY OF THE INVENTION

PROBLEMS THAT SHOULD BE SOLVED BY THIS INVENTION

In the previously described traditional construction for mounting the pulse generator disk, the key part is made of an L-shaped curved element that extends upward from the pulse generator disk on one side of its end surface; since the key part made in this way is fixed to the pulse generator disk in a cantilever manner, it has low rigidity and it is difficult to ensure high accuracy of mounting of the pulse generator disk relative to the crankshaft. In addition, since it is necessary to treat the sharp edge of the key part, which is cut off from the pulse generator disk during such finishing operations as chamfering, the number of machining steps will be large and it cannot be said that productivity will be good.

The present invention has been carried out in the context of these circumstances, and the purpose of this invention is to provide a structure for mounting a pulse generator disk of the type mentioned above, which ensures high accuracy in positioning the pulse generator disk relative to the crankshaft, and the pulse generator disk manufacturing capacity is good.

WAYS TO SOLVE THESE PROBLEMS

To achieve the above objective, in accordance with a first aspect of the present invention, there is provided a structure for mounting a pulse generator disk in which a keyway is formed on the end surface of a rotating wall, consisting of a crank arm and a counterweight of the crankshaft of an internal combustion engine, on a pulse generator disk, which superimposed on this end surface, a key part is formed for engagement with a key groove, and said pulse generator disk is attached to a fastening wall by means of a fastening element, and characterized in that said key part is made of an arc-shaped ribbon-like part protruding in an arc-shaped form from a pulse generator disk on one side of its end surface and engaged with said key groove, and a pair of connecting parts that provide an integral connection between the drive of the pulse generator and the opposite ends of the arcuate ribbon-like part.

The end surface of said rotating wall corresponds to the seating surface 10 of one embodiment of the present invention, which will be described later, the fastener corresponds to the bolt 18, and the fastener corresponds to the recess 12 and the boss 15.

According to a second aspect of the present invention, in addition to the first aspect, said arcuate ribbon-like part is arranged so that its longitudinal direction extends along the radius of said pulse generator disk.

According to a third aspect of the present invention, in addition to the first aspect, said keyway and said arcuate ribbon-like part that are engaged with each other are arranged so that their longitudinal directions extend along the radius of said pulse generator disk.

According to a fourth aspect of the present invention, in addition to the first aspect, elongated holes are drilled in said pulse generator disk, the opposite ends of said arcuate ribbon-like part facing these elongated holes.

According to a fifth aspect of the present invention, in addition to the first aspect, there are a large number of positions on which fasteners are mounted for connecting said pulse generator disk to said rotating wall by fasteners, wherein said positions are located in the peripheral direction of said pulse generator disk, and gaps in the peripheral direction between at least one position of the fasteners and other positions of the fasteners adjacent to to the opposite sides of said one position of the fasteners, are made such that they differ from each other.

In accordance with the sixth feature of the present invention, in addition to the first feature, a large number of grooves are formed on the end surface of the rotating wall so that they are located in its peripheral direction, a large number of bosses with a tubular base are formed on the disk of the pulse generator, placed in a large number of said grooves moreover, these bosses are attached to the pulse generator disk by fasteners, and the tubular part of said boss has a complex cylindrical configuration such that о its small axis is directed in the peripheral direction of the pulse generator disk, and its major axis is directed in the radial direction of the pulse generator disk.

According to a seventh aspect of the present invention, in addition to the sixth aspect, the tubular portion of said boss has an elliptical tubular shape.

According to an eighth aspect of the present invention, in addition to the sixth aspect, the curvature of the curved part connected to the opposite ends of the tubular portion of the boss is made such that it is smaller from the minor axis than from the major axis.

According to a ninth aspect of the present invention, in addition to the first aspect, a rib is formed on the pulse generator disk, said rib protruding from one side of its end surface and extending in the peripheral direction.

According to a tenth aspect of the present invention, in addition to the ninth aspect, said rib extends from an end surface of said pulse generator disk towards said rotating wall, and a groove is formed in said rotating wall to accommodate a rib in which said rib is located.

According to an eleventh aspect of the present invention, in addition to the ninth aspect, said rib has an annular shape such that it extends along the entire periphery of said pulse generator disk.

According to a twelfth feature of the present invention, in addition to the ninth feature, a large number of grooves are formed on the end surface of said rotating wall, such that they are located in its peripheral direction, a large number of bosses with a tubular base are formed on the pulse generator disk, said bosses being placed inside a large number of said grooves and attached to the pulse generator disk by fasteners, said bosses are interconnected by means of a rib-like rib protruding from the end surface of the pulse generator disk from the side of the rotating wall, and a groove is provided on the end surface of the rotating wall to accommodate the rib to accommodate the ring-shaped rib.

According to a thirteenth aspect of the present invention, in addition to the ninth aspect, the height of said rib is made to be less than the height of the boss, and the depth of said groove accommodating the rib is made to be less than the depth of said undercut to accommodate mentioned boss.

In accordance with the fourteenth feature of the present invention, in addition to the ninth feature, a through hole is drilled in half of said pulse generator disk from the side of said crank arm.

SUMMARY OF THE INVENTION

In accordance with a first feature of the present invention, since the key part is formed of an arc-shaped ribbon-like part protruding in an arc-shaped form from a pulse generator disk on one side of its end surface and engaging with a keyway, and from a pair of connecting parts providing an integral connection between the pulse generator disk and opposite ends of the arcuate ribbon-like part, the key part is mounted on both sides of the pulse generator disk and therefore has a high th rigidity and, consequently, in conjunction with the key groove can be enhanced accuracy with which the pulser disk positioned relative to the crankshaft. Moreover, the key part, supported on both sides, does not have a pointed edge, and after stamping it is not necessary to carry out finishing such as chamfering, and thereby the manufacturing capacity of the pulse generator disk can be improved.

In accordance with a second feature of the present invention, the end surfaces of the keyway and the arcuate ribbon-like part extending in the radial direction of the pulse generator disk abut against each other in a wide area, thereby providing more accurate preservation of the predetermined peripheral position of the pulse generator disk relative to the crankshaft.

According to a third aspect of the present invention, since the counterweight has a wide end surface that overlaps the pulse generator disk, a keyway can be easily formed without thickening its end surface. Therefore, when designing, a large degree of freedom is ensured, productivity is good, and loss of weight alignment due to thickening of the crankshaft can be prevented.

In accordance with a fourth aspect of the present invention, stamping of an arcuate ribbon-like part of a key part can be easily performed without counteracting it from the main body of the pulse generator disk.

According to a fifth aspect of the present invention, the position in which the pulse generator disk is mounted on the rotating wall of the crankshaft is limited to one position, which prevents erroneous installation, and thereby prevents damage to the key part due to improper installation.

According to a sixth aspect of the present invention, since the tubular part of the boss of the pulse generator disk has a complex cylindrical configuration in which the minor axis is directed in the peripheral direction of the pulse generator disk and its major axis is directed in the radial direction of the pulse generator disk, if during engine operation vibrations in the dish-shaped part between adjacent bosses of the pulse generator disk, the said vibrations are transmitted to the peripheral edge part of the complex cylinder part of the entire configuration along its major axis; therefore, mechanical stresses arising due to vibration are dispersed along the peripheral edge of a part of a complex cylindrical configuration along its entire major axis, and thus the wear resistance of the area around each boss can be improved.

According to a seventh aspect of the present invention, since the change in curvature of the elliptical tubular portion of the boss of the pulse generator disk is very smooth, the dispersion of mechanical stresses is ideal, and thus the wear resistance of the area around each boss can be effectively increased.

According to an eighth aspect of the present invention, since the curvature of the curved portion connected to the opposite ends of the tubular portion of the boss of the pulse generator disk is such that it is smaller along the minor axis than along the major axis, when vibrations occur in the poppet portion between adjacent bosses pulse generator disk, mechanical stresses concentrated mainly from the minor axis of the boss, that is, along the peripheral edge part in the peripheral direction of the pulse generator disk owls, can be dispersed more widely and thus can be even more increased durability of the area around each boss.

According to a ninth aspect of the present invention, since the rib is formed on the pulse generator disk so that it protrudes from one side of its end surface and extends in the peripheral direction, the stiffness of the pulse generator disk can be increased with this edge, and disk vibrations can be effectively suppressed. pulse generator. Moreover, since there is no need to specifically increase the thickness of the pulse generator disk, this contributes to a decrease in the weight of the crankshaft system, and when the pulse generator disk is attached to a rotating wall, there is no need to specifically increase the number of mounting positions, and therefore the degree of freedom in design is high.

According to a tenth aspect of the present invention, since the rib protrudes from the end surface of the pulse generator disk from the side of the rotating wall, and a groove is formed in the rotating wall to accommodate the rib to accommodate the rib, the rib does not protrude from the outer end surface of the pulse generator disk and therefore, it is possible to install the pulse generator disk near the inner wall of the crankcase.

According to an eleventh aspect of the present invention, since the rib has an annular shape such that it extends along the entire periphery of the pulse generator disk, the stiffness of the pulse generator disk can be uniformly increased along its entire peripheral region, and the vibration of the pulse generator disk can be effectively suppressed .

According to a twelfth aspect of the present invention, since the rib is ring-shaped and provides a connection between a large number of bosses of high stiffness, the stiffness of the pulse generator disk can be even more effectively increased due to the presence of a ring-shaped rib and a large number of bosses, and therefore the vibration of the pulse generator disk can be suppressed more effectively.

According to a thirteenth aspect of the present invention, since the height of the rib is made to be less than the height of the boss, the rigidity of the connecting part between the rib and the boss can be increased, and the rigidity of the pulse generator disk can be further improved. At the same time, since the depth of the groove accommodating the rib is made so that it is less than the recess under the boss, the groove that locates the rib and this groove can be easily cut into the seating surface of the rotating wall without affecting each other, which facilitates machining.

According to a fourteenth aspect of the present invention, since through holes are drilled in the half of the pulse generator disk from the side of the crank, the weight of said half of the pulse generator disk from the side of the crank can be reduced by these holes, the counterweight can be made thinner by an appropriate amount , and the weight of the entire crankshaft system can be reduced.

The above objectives, other objectives, features and advantages of the present invention will become apparent from the explanation of the preferred embodiments of the invention, described in detail below with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 is a side sectional view of an essential part of the crankshaft of an internal combustion engine equipped with a structure for mounting a pulse generator disk related to the first embodiment of the present invention (first embodiment).

Figure 2 - image along arrow 2 in Figure 1 (first embodiment).

Figure 3 is an enlarged sectional view taken along line 3-3 of Figure 2 (first embodiment).

4 is a side sectional view of an essential part of the crankshaft of an internal combustion engine equipped with a structure for mounting a pulse generator disk related to the second embodiment of the present invention (second embodiment).

Figure 5 - image along arrow 5 in Figure 4. (second embodiment).

FIG. 6 is an enlarged sectional view taken along line 6-6 of FIG. 5 (second embodiment).

FIG. 7 is an enlarged sectional view taken along line 7-7 of FIG. 5 (second embodiment).

Fig. 8 is an enlarged view corresponding to an essential part of Fig. 5 showing a third embodiment of the present invention (third embodiment).

FIG. 9 is a view corresponding to FIG. 3 showing a fourth embodiment of the present invention (fourth embodiment).

10 is a side sectional view of an essential part of the crankshaft of an internal combustion engine equipped with a structure for mounting a pulse generator disk related to a fifth embodiment of the present invention (fifth embodiment).

11 is an image along arrow 11 in FIG. 10 (fifth embodiment).

12 is an enlarged sectional view taken along line 12-12 of FIG. 11 (fifth embodiment).

Fig. 13 is an enlarged sectional view taken along line 13-13 of Fig. 11 (fifth embodiment).

Fig. 14 is an enlarged sectional view taken along line 14-14 of Fig. 11 (fifth embodiment).

Fig. 15 is an enlarged sectional view taken along line 15-15 of Fig. 11 (fifth embodiment).

Fig. 16 is a view corresponding to Fig. 11 showing a sixth embodiment of the present invention (sixth embodiment).

Fig. 17 is a sectional view taken along line 17-17 of Fig. 16 (sixth embodiment).

EXPLANATION OF REFERENCE NUMBERS AND SYMBOLS

A - peripheral direction of the pulse generator disk

In - the radial direction of the pulse generator disk

C - crankshaft

D1 - minor axis

D2 - major axis

H1 - rib height

H2 - boss height

h1 is the depth of the groove accommodating the rib

h2 - recess depth

P - pulse generator disk

S1, S2 - the gap in the peripheral direction between the fastening parts

3 - crank arm

4 - counterweight

9 - rotating wall

10 - end surface

12, 15 - fasteners (recess, boss)

14 - keyway

15a - tubular part

16 - key part

16a - arch-shaped ribbon-like detail

16b - connecting part

18 - fastener (bolt)

19 - elongated hole

25 - rib

26 - groove accommodating the rib

27 - through hole

BEST MODE FOR CARRYING OUT THE INVENTION

Below, with reference to the accompanying drawings, preferred embodiments of the present invention are explained.

FIRST EXAMPLE OF IMPLEMENTATION

An explanation will now be given of the first embodiment shown in FIG. 1 to FIG. 3. In Fig.1 and Fig.2 there is a crankshaft C of a multi-cylinder internal combustion engine containing several pins 1, fixed by several main bearings of the crankcase, several connecting rods 2, to which the lower connecting rod heads of several connecting rods are connected, and several crank arms 3, providing integral connection between adjacent trunnions 1 and connecting rod journals 2, with each arm of the crank 3 is connected as a single counterweight 4, while the counterweight 4 extends in the direction opposite to each arm of the curve stud 3, and between them passes the central axis of the pin 1. In addition, a flange 5 is formed at one end of the crankshaft C, while a driving element, such as a crank pulley or a flywheel, is bolted to the flange 5.

As shown in FIG. 2, the shoulder of the crank 3 is shaped so that it is narrow in the peripheral direction, the counterweight 4 is shaped so that it is wide in the peripheral direction, and the shoulder of the crank 3 and the counterweight 4 form a rotating wall 9. On the rotating wall 9, on the very extreme side of the flange 5 is installed the pulse generator disk P, made by stamping from a sheet of magnetic metal. Said pulse generator disk P has a large number of protrusions 7, arbitrarily placed on its outer peripheral side, and a rotation sensor (not shown) mounted in the main motor housing and positioned so that it faces the outer peripheral surface.

The rotation sensor contains a Hall element, as a sensitive element, and a magnet; when the pulse generator disk P rotates together with the crankshaft C, the change in the magnetic field in the rotation sensor is converted by the Hall element into an electric signal, which after processing allows you to determine the rotation angle, rotation speed, acceleration of rotation and other characteristics of the crankshaft C.

Now, with reference to FIGS. 1-3, a construction will be explained in which the drive of the pulse generator P is mounted on the rotating wall 9 of the crankshaft C.

As shown in FIG. 1, on the outer end surface of the rotating wall 9, on its extreme side, there is an annular positioning step 8, the diameter of which is larger than the diameter of the flange 5, and which is mounted concentrically with the pin 1, and also has a seating surface 10 , which extends radially from the base of the annular positioning step 8 towards the crank arm 3 and the counterweight 4. On opposite sides of the outer end surface of the crank arm 3, in the direction of its rotation which had formed the inclined surface 3a, that leads to the crank arm 3 thinner, and therefore seating surface 10 will on the part of the crank arm 3 is even more narrow than the part of the counterweight 4.

As shown in FIGS. 1 and 2, a large number (four — in the illustrated example) having the same shape (circle shape — in the illustrated example) of the grooves 12 that extend in the peripheral direction are located on the seating surface 10. With this design, four recesses 12 are arranged so that the gaps S1 and S2 in the peripheral direction between at least one recess 12 and other recesses 12 on opposite sides of said one recess 12 are different from each other. In the case of the illustrated example, four recesses 12 are arranged so that all the gaps in the peripheral direction between adjacent recesses 12 on an imaginary circle 20, concentric with the pin 1, are different from each other. Through holes 13 are formed in the central part of each of these four recesses 12. In addition, a keyway 14 is formed at the predetermined position of the seating surface 10 on the counterweight side 4. With this design, the keyway 14 is positioned so that its longitudinal direction runs along the radius of the disk pulse generator R.

A positioning hole 11 is formed in the central part of the pulse generator disk P, while an annular positioning step 8 is precisely installed inside the mounting hole 11, and four cylindrical bosses 15 with a tubular base are formed on the disk of the pulse generator P so that they are located around the positioning hole 11, with this boss 15 are precisely installed inside the four recesses 12. At the base of each boss 15 there is a bolt hole 17 corresponding to the through hole 13 of each recess and 12.

In addition, a key part 16 is formed integrally with the disk of the pulse generator P, which is engaged with the key groove 14. This key part 16 is formed from an arc-shaped ribbon-like part 1 b which protrudes in a curved shape from the disk of the pulse generator P on one side of its end surface, and a pair of connecting parts 16b, providing a connection into a single unit of the disk of the pulse generator P and the opposite ends of the arcuate ribbon-like parts 16a. The arcuate ribbon-like part 16a is positioned so that its longitudinal direction, in the same way as the keyway 14, extends along the radial direction of the pulse generator disk P and is precisely positioned between the opposite inner end surfaces of the keyway 14 (see FIG. 3) . When this arch-shaped ribbon-like part 16a is tightly mounted inside the keyway 14, all the bosses 15 of the pulse generator disk P are freely installed in the corresponding recesses 12 of the seating surface 10.

When forming the key part 16, the pulse generator disk P is stamped so that a pair of elongated holes 19 is formed on it (see Figure 2) so that they face the opposite end surfaces of the key part 16, after which an arc-shaped ribbon-like part is formed by stamping 16a, located between two elongated holes 19, the arcuate shape of which extends in the direction in which the boss 15 protrudes, and thereby the formation of an arcuate ribbon-like part 16a can be easily performed without resistance from the main body of the pulse generator disk.

Now, the operation of this embodiment of the invention will be explained. When installing the pulse generator disk P on the seating surface 10 of the rotating wall 9, the positioning hole 11 of the pulse generator disk P is first accurately installed on the ring-shaped positioning step 8 of the rotating wall 9 from the side of the crankshaft flange C. In this process, when the keying part 16 of the pulse generator disk is engaged P with a keyway 14 of the seating surface 10 and the precise installation of each boss 15 of the pulse generator disk P into the corresponding recess 12 of the seating surface 10 of the gene the pulse generator P is superimposed on the seating surface 10. Then, by tightening and tightening the bolt 18 inserted through each bolt hole 17 into the through hole 13, the disk of the pulse generator P is precisely mounted at a specific location on the seating surface 10. With this design, the head 18a of each bolt 18 placed inside the corresponding boss 15 and does not protrude from the outer end surface of the pulse generator disk P, which makes it possible to install the pulse generator disk P near and from the inner wall of the crankcase.

Since the key part 16 of the pulse generator disk P is formed of an arc-shaped ribbon-like part 16a, which protrudes in an arcuate shape from the pulse generator disk P on one side of its end surface and engages with the key groove 14, and a pair of connecting parts 16b that provide a complete connection between the disk pulse generator P and opposite ends of the arc-shaped ribbon-like part, then it is fixed on both sides to the disk of the pulse generator P, thereby providing high rigidity s. Therefore, it is possible, when used together with the keyway, to increase the accuracy with which the drive of the pulse generator P is positioned in the peripheral direction relative to the seating surface 10, i.e. the crankshaft C. Moreover, the keyed part 16 fixed on both sides does not have a pointed edge, and after it forming by stamping, there is no need to carry out finishing such as chamfering, and the production capacity of the pulse generator disk P can be improved.

In particular, since the keyway 14 and the arcuate ribbon-like part 16a, which are precisely aligned together, are located along the radial direction of the pulse generator disk P, the end surfaces of the keyway 14 and the arcuate ribbon-like part 16a, extending in the radial direction of the pulse generator disk P, are adjacent to each other to a friend in a wide area, thereby providing more accurate maintenance of a predetermined peripheral position of the disk of the pulse generator P relative to the crankshaft C.

In addition, with regard to the seating surface 10, as described above, its width on the counterweight side 4 is wider than on the shoulder side of the crank 3, therefore, when forming the keyway 14 on the seating surface 10 on the counterweight side 4, the position at which said the groove can be selected in a wide area, the degree of freedom in the design will be high and this is convenient when positioning the pulse generator disk P. Moreover, when forming the keyway 14 there is no need to make a thinner fit surface 10, so a good performance and can prevent the loss of weight centering, since the crankshaft C is thin.

In addition, since the parts fastening the disk of the pulse generator P and the rotating wall 9 with bolts 18, that is, the recesses 12 and the boss 15, are in a large number of positions located in the peripheral direction of the disk of the pulse generator P, and at least one position of the fasteners 12 and 15 and other positions of the fasteners 12 and 15, which are adjacent to opposite sides of the same mounting position of the fasteners 12 and 15, are located so that the gaps S1 and S2 differ from each other in the peripheral direction, then the position of the the pulse generator disc Novki P on the rotating wall 9 only limited to this position, incorrect installation can be prevented, and thus can prevent damage to parts keyway 16 because of improper installation.

As described previously, the connection of the disk of the pulse generator P and the rotating wall 9 with bolts 18 can be made in at least two positions, and if such a connection is made only in these two positions, then the gaps in the peripheral direction on opposite sides between these two positions can be changed fasteners prevent improper installation.

SECOND EXAMPLE OF IMPLEMENTATION

An explanation will now be given of a second embodiment of the present invention shown in FIGS. 4-7.

Each boss 15 of the pulse generator disk P has a tubular elliptical shape at the base, and its elliptical tube portion 15a is positioned so that its small axis D1 is directed in the peripheral direction A of the pulse generator disk P, and its large axis D2 is directed in the radial direction B of the generator disk pulses R.

Since the pulse generator disk P made by stamping is relatively thin, when the moment of the crankshaft C changes during engine operation, intense vibrations sometimes occur in its plate-shaped part between adjacent bosses 15, and these plate-shaped vibrations create mechanical stresses concentrated in the peripheral edge part of the tubular parts 15a of each boss 15; however, in the second embodiment, since the tubular part 15a of each boss 15 is made in the form of an elliptical tubular part 15a, the small axis D1 of which is directed in the peripheral direction A of the pulse generator disk P, and the large axis D2 is directed in the radial direction B of the pulse generator disk P, then the vibration of the disk-shaped part between the bosses 15 of the pulse generator disk P is transmitted to the peripheral edge part of the elliptical tubular part 15a in the region of the major axis D2, and for this reason, mechanical stresses due to vibration widely dispersed in the peripheral edge part of the elliptical tubular part 15a in the region of the major axis D2, thereby increasing the wear resistance of the region around each boss 15. In particular, since the change in the curvature of the ellipse of the elliptical tubular part 15a is very smooth, the dispersion of mechanical stresses will be ideal, and the wear resistance the area around each boss 15 can be effectively increased.

In addition, this second embodiment also has a structure that allows to obtain the same operational effects as the first embodiment; the parts of FIGS. 4-7 corresponding to those in the first embodiment are denoted by the same reference numerals and symbols, and duplication of explanation is omitted.

THIRD EXAMPLE OF IMPLEMENTATION

An explanation will now be given of a third embodiment of the present invention shown in FIG.

In the third embodiment, the tubular part 15a of the boss 15 of the pulse generator disk P is formed so that it has an oval cross-section in which a pair of arcuate walls 22 are inextricably connected, facing each other through a gap corresponding to the major axis D2, and a pair of rectilinear walls 23, facing each other through the gap corresponding to the minor axis D1. In this design, the tubular part 15a of the boss 15 is positioned in the same manner as in the previous embodiment, so that the small axis D1 is directed in the peripheral direction A of the pulse generator disk P and the large axis D2 is directed in the radial direction B of the pulse generator disk P In all other respects, this construction is the same as the construction of the second embodiment described above; parts in FIG. 8 corresponding to parts in the second embodiment are denoted by the same reference numerals and symbols, and duplication of explanation is omitted.

In accordance with this third embodiment, the same operational effects as the effects of the second embodiment may occur.

FOURTH EXAMPLE OF IMPLEMENTATION

An explanation will now be given of a fourth embodiment of the present invention shown in FIG. 9.

In the fourth embodiment, the curved portion connected to the opposite ends of the elliptical tubular portion 15 a of the boss 15 of the pulse generator disk P is formed so that its curvature is less on the minor axis D1 than on the major axis D2 (see FIG. 7). In all other respects, this construction is the same as the construction of the second embodiment described above; the parts of FIG. 9 corresponding to the parts in the second embodiment are denoted by the same reference numerals and symbols, and duplication of explanation is omitted.

According to a fourth embodiment, when intense vibration occurs in the disk portion between adjacent bosses 15 of the pulse generator disk P, mechanical stresses are concentrated mainly from the minor axis D1 of the boss 15, that is, on the peripheral edge part in the peripheral direction B the pulse generator disk P can be dispersed more widely, and the wear resistance of the area around each boss 15 can be further enhanced.

FIFTH EXAMPLE OF IMPLEMENTATION

An explanation of a fifth embodiment of the present invention shown in FIGS. 10-15.

Similarly, as in the first embodiment, on the outer end surface of the rotating wall 9, on the outermost side of the crankshaft C, an annular positioning step 8 is formed, the diameter of which is larger than the diameter of the flange 5, and which is concentric with the journal 1, and the seating surface 10, which extends radially from the base of the ring-shaped positioning step 8 to the crank arm 3 and the counterweight 4. A large number is formed on this landing surface 10 (four in the shown example ery) recesses 12 having an identical shape (round shape in the example shown) and placed so that they extend in the peripheral direction. In such a design, four recesses 12 are arranged so that the gaps S1 and S2 in the peripheral direction between at least one recess 12 and other recesses 12 on opposite sides of said one recess 12 are different from each other. Four recesses 12 are arranged so that all the gaps in the peripheral direction between adjacent recesses 12 on an imaginary circle 20 concentric with the pin 1 are different from each other.

A ring-shaped rib 25 is formed on the disk of the pulse generator P, which extends along an imaginary circle 20 and protrudes on one side of the end surface of the disk of the pulse generator P. Thus, the four bosses 15 located along the imaginary circle 20 are connected by means of the rib 25. In this design, the height HI the ribs 25 are made so that it is less than the height H2 of the boss 15, which results in the presence of a step e between the rib 25 and the boss 15. Accordingly, the depth of the groove accommodating the rib 26 ited 10 is set such that it was less than the depth of the undercut 12 to accommodate the lug 15.

The rib 25 protrudes from the end surface of the pulse generator disk P from the side of the seating surface 10 of the rotating wall 9, and a groove is formed on the seating surface 10 to accommodate the rib 26 to accommodate the rib 25.

As shown in FIGS. 13 and 14, the width of the groove accommodating the rib 26 is set to be less than the length of the key groove 14 in the seating surface 10, thereby the groove accommodating the rib 26 intersects the key groove 14. This ensures that the keyway 14 and the key part 16 of the pulse generator disk P will be reliably connected to each other regardless of the presence of the groove accommodating the rib 26, and the positioning function relative to the pulse generator disk P will be realized.

In addition, as shown in FIG. 11 and FIG. 15, a large number of through holes 27 are drilled only in half of the pulse generator disk P from the side of the crank arm 3 so that they are located in the peripheral direction.

Additionally, this fifth exemplary embodiment also has a structure that allows to obtain the same operational effects as in the first embodiment; the parts of FIGS. 10 to 15 corresponding to those of the first embodiment are denoted by the same reference numerals and symbols, and duplication of explanation is omitted.

Since the pulse generator P disk made by stamping is relatively thin, intense vibration tends to occur between the adjacent bosses 15 when the crankshaft moment C changes during engine operation between the adjacent bosses 15, but in accordance with this fifth embodiment, a rib 25 is formed on the disk of the pulse generator P so that it protrudes from one end surface of the disk and extends in its peripheral direction, and therefore, the stiffness of the pulse generator disk can be increased by rib 25 P. In particular, since the rib 25 has an annular shape and extends along the entire periphery of the pulse generator disk P, the stiffness of the pulse generator disk P can be uniformly increased along its entire periphery, and the vibration of the pulse generator disk P can be effectively suppressed. Moreover, since there is no need to specifically increase the thickness of the pulse generator disk P, this contributes to lowering the weight of the crankshaft system C, and when the pulse generator disk P is attached to the rotating wall 9 by bolt 18, this can be done with a small number of positions fastening, for example with one single position from the side of the crank arm 3, where the area for installation is limited. In other words, the degree of freedom in the design will be high, since there is no need to specifically increase the number of mounting positions.

Since the rib 25 protrudes from the end surface of the pulse generator disk P from the side of the rotating wall 9, and a groove is formed in the seating surface 10 of the rotating wall 9 to accommodate the rib 26 to accommodate the rib 25, the rib 25 does not protrude from the outer end surface of the generator disk pulses P, and therefore, you can install the disk of the pulse generator P near the inner wall of the crankcase.

In addition, the head 18a of each bolt 18, placed in the recess 12, is placed inside the corresponding boss 15 and does not protrude from the outer end surface of the pulse generator disk P, and therefore, the pulse generator disk P can be installed near the inner wall of the crankcase.

Moreover, since the rib 25 is ring-shaped and provides a connection between a large number of bosses of high rigidity 15, the stiffness of the disk of the pulse generator P can be increased even more efficiently due to the interaction between the ring-shaped rib 25 and a large number of bosses 15. In this design, the formation of a step e between the rib 25 and the boss 15 by setting the height H1 of the rib 25 so that this height is less than the height H2 of the boss 15 is an effective means of increasing the rigidity of the connecting part between the rib 25 and the boss 15. Simultaneously with this task, the depth of the groove accommodating the rib 26 such that it is less than the depth of the recess 12 to accommodate the boss 15 is an effective means of ensuring that the groove accommodating the rib 26 and the recess 12 are cut into the seating surface 10 of the rotating wall 9 without affecting each other.

That is, when milling the grooves accommodating the rib 26 and the recess 12, they will not affect each other regardless of which of these elements will be cut first. If the groove accommodating the rib 26 is deeper than the recess 12, then the groove hosting the rib 26 cannot be cut in one pass due to an obstacle from the base of the groove 12. Furthermore, since the groove accommodating the rib 26 corresponds to an annular rib 25, the machining of these elements can be easily performed by rotating the crankshaft around the journal 1.

Moreover, due to the fact that the stiffness of the pulse generator disk P will be increased by an annular rib 25, it becomes possible to drill a large number of through holes 27 in the pulse generator disk P to reduce the weight of this disk. Having formed in this process a large number of through holes 27 in only half the disk of the pulse generator P from the side of the crank arm 3 and reducing due to these through holes 27 the weight of this half from the side of the crank arm 3, can be made thinner by the corresponding amount of the counterweight 4, and thereby, the weight of the crankshaft system C can be reduced.

SIXTH EXAMPLE OF IMPLEMENTATION

An explanation of a sixth embodiment of the present invention shown in FIG. 16 and FIG.

In this sixth embodiment, a large number of ribs 28 are formed in the portion of the disk of the pulse generator P protruding from the seating surface 10 from the side of the crank arm 3, extending radially from the annular rib 25. In all other respects, the construction is the same as in the fifth embodiment, except that the pulse generator disk P does not have through holes 27, as in the previous embodiment; the parts in FIG. 16 and FIG. 17 corresponding to the parts in the fifth embodiment are denoted by the same reference numerals and symbols, and duplication of explanation is omitted.

According to a sixth embodiment, due to the interaction between the ring-shaped rib 25 and the radial ribs 28, the rigidity, in particular, of the part of the disk of the pulse generator P protruding from the seating surface 10 from the side of the crank arm 3 is increased, thereby effectively preventing vibration of this part of the disk .

The present invention is not limited to the above examples of implementation and can be modified in various ways, unless these modifications deviate from the inherent features and essence of the invention. For example, in the above-described embodiments, the parts for fastening the pulse generator disk P to the rotating wall 9 with bolts 18 can be in at least two positions, and when there are only two seating positions, improper assembly can be prevented by the presence of different gaps in the peripheral direction on opposite sides of two mounting positions of fasteners. In addition, in the fifth and sixth embodiment, the annular rib 25 can be formed of two or more concentric ribs, and they can be located in the radial direction inside and outside a large number of organized in a ring of bosses 15. Moreover, the key part 16 can be located on the inner or outer side of the annular rib 25 so as not to intersect the annular rib 25, and this effectively enhances the reinforcing function of the rib 25.

Claims (13)

1. Design for mounting the pulse generator disk, in which a keyway (14) is formed in the end surface (10) of the rotating wall (9), formed from the crank arm (3) and the counterweight (4) of the crankshaft (C) of the internal combustion engine, a key part (16) for engaging with said key groove (14) is formed on the pulse generator disk (P), which is superimposed on said end surface (10), and this pulse generator disk (P) is attached to said rotating wall (9) by fastener (18),
characterized in that said key part (16) is formed of an arc-shaped ribbon-like part (16a) protruding in a curved form from said pulse generator disk (P) on one side of its end surface and engaged with said key groove (14), and a pair of connecting parts (16b) providing an integral connection between said pulse generator disk (P) and opposite ends of said arcuate ribbon-like part (16a), and said keyway (14) and said arcuate ribbon-like the second part (16a), which are coupled to each other, are arranged in such a way that their longitudinal directions extend along the radius of said pulse generator disk (P). 2. The design for mounting the pulse generator disk according to claim 1,
characterized in that said keyway (14) is formed on the end surface (10) of said counterweight (4). 3. The design for mounting the pulse generator disk according to claim 1,
characterized in that elongated holes (19) are drilled in said pulse generator disk (P), while opposite end surfaces of said arcuate ribbon-like part (16a) face elongated holes (19). 4. The design for mounting the pulse generator disk according to claim 1,
characterized in that there are a large number of positions on which fasteners (12, 15) are available for attaching said pulse generator disk (P) to said rotating wall (9) by said fixing element (18), wherein the positions are located in the peripheral direction of the disk pulse generator (P), and the gaps (S1, S2) in the peripheral direction between at least one position of the fasteners (12, 15) and other positions of the fasteners (12, 15) adjacent to opposite sides of the said one position of the fasteners s (12, 15) are arranged so that they differ from each other. 5. The design for mounting the pulse generator disk according to claim 1,
characterized in that a large number of grooves (12) are formed in the end surface (10) of said rotating wall (9) so that they are located in its peripheral direction, and a large number of bosses (15) are formed on said disk of a pulse generator (P) a tubular base located in a large number of said grooves (12), said bosses (15) being attached to said pulse generator disk (P) by fasteners (18), and the tubular part (15a) of said boss (15) has a complex cylindrical configuration such , what scarlet axis (D1) is directed in the circumferential direction (A) of said pulser disc (P), and the major axis (D2) is directed in a radial direction (B) of said pulser disc (P). 6. The design for mounting the pulse generator disk according to claim 5,
characterized in that said tubular part (15a) of the boss (15) has an elliptical tubular shape. 7. The design for mounting the pulse generator disk according to claim 5,
characterized in that the curvature of the curved part connected to the opposite ends of said tubular part (15 a) of said boss (15) is made so that it is less from the minor axis (D1) than from the major axis (D2). 8. The design for mounting the pulse generator disk according to claim 1,
characterized in that a rib (25) is formed on said pulse generator disk (P), said rib (25) protruding on one side of its end surface and extending in a peripheral direction. 9. The design for mounting the pulse generator disk of claim 8,
characterized in that said rib (25) protrudes from the end surface of said pulse generator disk (P) on the side of said rotating wall (9), and a groove is arranged in said rotary wall (9) to accommodate the rib (26) for placement therein ribs (25). 10. The design for mounting the pulse generator disk according to claim 8,
characterized in that said rib (25) has an annular shape such that it extends along the entire periphery of said pulse generator disk (P). 11. The design for mounting the pulse generator disk of claim 8,
characterized in that a large number of grooves (12) are formed on the end surface (10) of said rotating wall (9) so that they are located in its peripheral direction, a large number of bosses (15) with a tubular are formed on said disk of the pulse generator (P) the base, and said bosses (15) are located in a large number of said grooves (12) and are attached to said pulse generator disk (P) by said fasteners (18), said bosses (15) are connected to each other via said ring-shaped a rib (25) protruding from the end surface of said pulse generator disk (P) from the side of said rotating wall (9), and a groove is placed in said said end surface (10) of said rotating wall (9) (26) for placing an annular rib (25). 12. The design for mounting the pulse generator disk of claim 8,
characterized in that the height (H1) of said rib (25) is made such that it is less than the height (H2) of said boss (15), and the depth (h1) of said groove accommodating the rib (26) is made so that it was less than the depth (h2) of said recess (12) to accommodate the boss (15). 13. The design for mounting the pulse generator disk of claim 8,
characterized in that in half of said pulse generator disk (P), a through hole (27) is drilled from the side of said crank arm (3).

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