JPH0689784B2 - Drive shaft - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a drive shaft which is particularly suitable for driving a shaft of a working machine, for example, which is used at an output end of a tractor.

(Prior Art) A shaft for transmitting rotational power is used in various machines, but the connecting portion is generally narrow and a cover is often provided to prevent it from getting dirty, which makes connecting operation difficult and dangerous. Often accompanied. In order to solve such a problem, various devices have been proposed for performing safe and reliable connection.

The present applicant has proposed an advantageous drive shaft that can be easily operated only by sliding the slide collar when inserting and removing the shaft first (Japanese Patent Laid-Open Nos. 61-84410 and 61-278621).
No.). However, the Applicant has continued to research to obtain a drive shaft that is simple in structure, compact, inexpensive, and easy to operate.

(Problems to be Solved by the Invention) An object of the present invention is to simply slide the set ring when inserting the shaft, and to further freely insert the shaft even if the hand is released from the set ring during the insertion. By simply sliding the set ring when pulling out the shaft, you can freely pull out the shaft even if you release your hand from the set ring while pulling it out and securely hold the set ring in the set ring holding position. Therefore, it is possible to obtain a drive shaft which is easy and reliable and can be inexpensively operated so as to prevent the shaft from accidentally coming off.

(Means for Solving the Problems) In order to achieve the above-mentioned object, the drive shaft of the present invention comprises a shaft and a boss member which can slide in the axial direction but are fitted so as not to rotate relative to each other. A drive shaft having a set ball housed in a member and partially protruding into a ball set groove of the shaft to prevent the shaft from coming out of the boss member, wherein the set partially protrudes into the ball set groove. A set ring slidable on the boss member at a position for holding the ball from the outside and a position at which the set ball can move outward from the ball set groove; and the set ring in the axial direction of the boss member. A pair of compression coil springs that compress from both sides, an annular recess provided between a part of the boss member and the set ring part facing this part, and a radial direction in the annular recess. And a set ring holding means for surely holding the set ring in the holding position when the set ball is held by the set ring.

(Operation) When inserting or removing the shaft, the shaft can be inserted or removed by sliding the set ring in a movement that allows the set ball to move outward. Also, since the set ball that has moved outwardly due to the shaft that has moved slightly for insertion and removal prevents the set ring from returning, even if you release your hand from the set ring during insertion and removal, the compression coil spring may cause compression. The shaft can be freely inserted and removed very easily without continuing to apply a force that opposes the restoring force. Further, when the set ball and the ball set groove provided on the shaft are trying to align with each other, the restoring force due to the compression of the compression coil spring and the component force exerted by the spring means of the set ring holding means on the tapered surface of the annular recess are Performs the action of returning the set ring to the neutral holding position. Also, the frictional engagement between the spring means of the set ring holding means and the bottom of the annular recess reliably holds the set ring in the holding position when the set ring holds the set ball.

(Example) A case where the drive shaft of the present invention is applied to a yoke and a spline shaft of a universal joint will be described with reference to the drawings.

1 to 10 show a first embodiment of the drive shaft according to the present invention. A shaft or spline shaft 6 is inserted into the spline hole 4 of the boss member or yoke 2, and the set ball 8 accommodated in the hole 7 formed in the boss portion of the yoke is the ball set groove of the spline shaft 6.
The spline shaft 6 is engaged with 10 to prevent the spline shaft 6 from coming out of the yoke 2. At the boss portion of the yoke 2, the set ring 12 is axially (first) above the boss portion of the yoke.
(Indicated by arrow p in the figure). A compression coil spring 16 is arranged between the annular groove 14 formed in the yoke and the set ring 12 and is held by a stop ring 18 near the tip of the boss of the yoke so as not to come off the boss. Coil spring between the and set ring 12
Place 22. The spring forces of the compression coil springs 16 and 22 are substantially equal, and the set ring 12 is held in the position shown in FIG. A spring ring 24 having a spring force that expands outwards to help hold the set ring 12 in this position is placed in a groove 26 on the outer circumference of the yoke, while the inner surface of the set ring 12 has a gently tapered recess. Location 28 will be established. The recess 28 is an annular recess having a concave taper as shown in FIG. 1 so as to stabilize the position of the set ring 12 when the set ball 8 is held by the set ring 12.

The state of FIG. 1 is a state before the spline shaft 6 is still inserted into the yoke 2. In this state, in order to prevent the set ball 8 from falling into the spline hole 4 of the yoke 2,
The inner end of the hole 7 for accommodating the set ball 8 has an inner surface of 60 ° as shown in FIG. 1, for example.

To insert the spline shaft 6 into the yoke 2, the set ring 12 is moved to the spline shaft side, that is, to the right in FIG. 3, against the force of the compression coil spring 22, as shown in FIG. In this position, the ball holding flange 30 of the set ring 12 is located away from the set ball 8, so that the set ball 8 can move outward. In this state, the spline shaft 6 is inserted. A chamfer is provided at the tip of the spline shaft 6.
Since 32 is provided, since the set ball 8 is pushed outward by the cam action of this chamfered portion, the spline shaft 6
Can be inserted. Therefore, the spline shaft 6 can be inserted deeper as shown in FIG. In this state, when the set ring 12 is released, the set ring 12 returns slightly to the left as seen in FIG. 4 due to the restoring force of the compression coil spring 22, but as is clear from FIG. In addition, since the ball holding flange 30 of the set ring 12 engages with the set ball 8 pushed outward by the spline shaft 6, the set ring 12 cannot move to the left any more even if the hand is released. Therefore, after this, the spline shaft 6 can be easily inserted into the yoke 2 without having to continue to apply a force that overcomes the restoring force of the compressed compression coil spring 22.

FIG. 5 shows a state in which the spline shaft is further inserted and the set ball 8 is about to fall into the ball set groove 10 of the spline shaft 6. That is, as described above, the ball holding flange 30 of the set ring 12 is engaged with the spherical surface of the set ball 8 and is pushed leftward by the compression coil spring 22 as seen in FIG. The set ring 12 acts so as to be pushed inward.

When the spline shaft 6 is further inserted from this state and the end surface of the yoke 2 engages with the stop ring 32 provided on the spline shaft 6, the set ball 8 completely enters the ball set groove 10 of the spline shaft 6 (6th See figure). Since the set ball 8 has moved inward in this way, the blocking force for preventing the set ring 12 from returning is eliminated, and the ring of the spring ring 24 is directed in the direction of the restoring force of the compressed compression coil spring 22. Due to the component force acting on the tapered surface of the recess 28 and the restoring force of the compression coil spring 22, the set ring 12
Returns to its original position. And at this time the spring ring
24 is located at the bottom of the recess 28 and can stably hold the position of the set ring 12. The ball holding flange 30 of the set ring 12 is placed on the outside of the set ball 8 to prevent the set ball 8 from coming out of the ball set groove 10 of the spline shaft 6, so that the spline shaft 6 does not come out of the yoke.

Next, when pulling out the spline shaft 6 from the yoke 2, the set ring 12 is moved to the left as viewed in FIG. 6 against the spring force of the compression coil spring 16 to reach the position shown in FIG. When the set ring 12 is moved to the position shown in FIG. 7, the ball retaining flange of the set ring 12 that was holding the set ball 8
Since 30 is located away from the set ball, the set ball 8 can move outward. In this state, the spline shaft 6 is pulled out. The spline shaft 6 in FIG. 7 is in a state of slightly moving in the spline hole of the yoke while pushing the set ball 8 outward by the concave surface of the ball set groove 10.

By further removing the spline shaft 6, the set ball 8
Moves out of the ball set groove 10 of the spline shaft 6 and reaches the state shown in FIG. In this state, the spherical surface of the set ball 8 protruding outward engages with the ball pressing flange 30 of the set ring 12, so that the set ring 12 will move to the position shown in FIG. 8 even if the hand holding the set ring 12 is released. Retained. Therefore, after this, the spline shaft 6 can be easily pulled out from the yoke 2 without continuing to apply a force that overcomes the restoring force of the compressed compression coil spring 16.

If the spline shaft 6 is further pulled out from this state, the tip of the spline shaft 6 moves away from the position of the set ball 8 so that the set ball 8 can freely move inward of the spline hole 4 of the yoke 2. The blocking force that tries to prevent the return of the set ring 12 disappears, and the spring ring is oriented in the direction of the restoring force of the compressed compression coil spring 16.
As shown in FIG. 1, the ball pressing flange 30 of the set ring 12 presses the set ball 8 inward by the restoring force of the compression coil spring 16 together with the component force acting on the tapered surface of the annular recess 28 of 24. Return to position.

9 (a) and 9 (b) show the details of the set ring 12, and FIGS. 10 (a) and 10 (b) show the spring bearing 20. As shown in FIG. These pieces can be manufactured by press molding a steel plate, but may be made of plastic.

The set ball may be a steel ball, but may be made of a plastic that does not easily wear. The number of set balls 8 is 1
The number may be two or three, but it is better to provide three as in the embodiment of FIG. As the stop ring 18, a commercially available snap ring can be used. Further, a shaft stop ring 32 is also provided on the spline shaft 6 to define the insertion depth of the spline shaft 6.

A more preferable embodiment is shown in FIG. 11, and parts having the same functions as those of the above-mentioned embodiment are designated by the same reference numerals. In this embodiment, the boss member, that is, the portion of the yoke 2 to be machined is made as small as possible, and an annular groove provided in the yoke 2 for accommodating one end of the compression coil spring 16 in the above embodiment.
14 was abolished and a spring receiving ring 34 was provided instead. In addition, a groove on the outer periphery provided in the yoke 2 for accommodating the spring ring 24.
26 is provided on the set ring 12. As a result, the recess 28 for receiving the spring ring 24 is provided on the inner surface of the spring bearing 20 by extending the spring bearing 20 in the axial direction of the yoke. The other structure and operation are the same as those of the first embodiment, and the description thereof will be omitted.

The embodiment shown in FIG. 12 is substantially similar to the first embodiment, but a groove 26 is provided inside the set ring 12 in place of the outer peripheral groove 26 for accommodating the spring ring 24 in the first embodiment. The recess 28 for receiving the spring ring 24 is provided on the yoke 2 side, and the spring force of the spring ring 24 has a spring force of contracting inward.

The set ring 12 may be formed integrally with the main body of the cylindrical portion and the ball pressing flange 30 or may be formed separately.

The embodiment of FIG. 13 is a compression coil spring in the above embodiment.
16 and 22 are omitted, and a set housing 36 having a ball pressing flange 30 is provided as the set ring 12. For example, three balls 38 are housed in the set housing 36 so as to be movable in the radial direction, and the spring bearing 40 and the balls are
A compression spring 42 is disposed between the compression spring 42 and 38. A gentle recess 44 is provided on the outer circumference of the yoke 2. With this structure, the ball 38 tends to be located at the deepest portion of the recess 44 by the action of the compression spring 42, so that unless the set ring 12 is pressed by hand, the set housing 36 moves to the 13th position. Occupying the position shown in the figure, the ball pressing flange 30 is located outside the set ball 8. Therefore, the same function as that of the above-described embodiment can be achieved.

The embodiment shown in FIG. 14 is a modification of the embodiment shown in FIG. 13, and an annular spring 46 having a spring force that contracts inward is used as a spring that elastically holds the ball 38. A ball receiving seat 48 is provided to facilitate the processing of the yoke 2.
Incidentally, the compression coil springs 16 and 22 are provided in order to further ensure the operation of the set housing 36.

(Effect of the Invention) When the shaft is inserted into the boss member or when the shaft is removed from the boss member, if the set ring is held only for the first time, the set ball that has climbed onto the outer surface of the shaft and moved radially outward is set. Since the ring can be held in the shifted state, thereafter, even if the set ring is released from the hand, the insertion and removal of the shaft can be performed very easily without the need to continue to apply a force that opposes the resistance force due to the compression of the spring. Further, when the set ball and the ball set groove provided on the shaft are trying to align with each other, the restoring force due to the compression of the compression coil spring and the component force exerted by the spring means of the set ring holding means on the tapered surface of the annular recess are Performs the action of returning the set ring to the neutral holding position, and when the set ring is held by the set ring, the set ring holding means can hold the set ring securely in the holding position, and prevent accidental removal of the shaft. And it has excellent operability. There is also an advantage that the price is low.

[Brief description of drawings]

1 is a sectional view of the drive shaft of the present invention, FIG. 2 is a sectional view of the drive shaft of FIG. 1 taken along the line II-II, and FIGS. 3, 4, 5 and 6 are respectively the drive shafts of FIG. 7A and 7B are sectional views showing the sequential steps of releasing the drive shaft of FIG. 1, and FIGS. 9A and 9B are the drive shafts of FIG. 10 is a sectional view and a front view of a set ring used in FIG. 10, FIGS. 10 (a) and 10 (b) are sectional views and a front view of a spring bearing used for the drive shaft of FIG. 1, and FIG. Sectional views of other preferred embodiments, and Figures 12, 13 and 14 are sectional views showing other embodiments of the drive shaft of the present invention. 2 ... Boss member or yoke 4 ... Spline hole, 6 ... Spline shaft 7 ... Hole, 8 ... Set ball 10 ... Ball set groove, 12 ... Set ring 14 ... Annular groove, 16 ... Compression coil spring 18 ... Stop ring, 20 … Spring bearing 22… Compression coil spring, 24… Spring ring 26… Outer circumferential groove, 28… Concave 30… Ball retainer flange 32… Axis stop ring 34… Spring bearing ring, 36… Set housing 38… Ball, 40… Spring bearing 42 ... Compression spring, 44 ... Recess 46 ... Annular spring, 48 ... Ball receiving seat

Claims (6)

[Claims] 1. A shaft and a boss member which are slidable in the axial direction but are fitted so as not to rotate relative to each other, and a part of which is housed in the boss member and protrudes into a ball set groove of the shaft. A drive shaft having a set ball for preventing the shaft from slipping out of the boss member, and a position for holding the set ball (8) partially protruding into the ball set groove (10) from the outside and the set ball. A set ring (12:36) slidable on the boss member (2) to a position where the ball (8) can be moved out of the ball set groove (10), and the set ring (12). A pair of compression coil springs (16, 22) that compress from both sides in the axial direction of the boss member (2)
And an annular recess (28; 48) consisting of a tapered surface provided between a part of the boss member (2) and the set ring part (12; 36) facing this part, and the annular recess (28). ; 48)
A set ring (24; 46) for pressing the set ball (8) in the radial direction to the set ring (12) and holding the set ring (12) securely in the holding position when holding the set ball (8) by the set ring (12). Holding means (24,28; 38,46,4
8), and a drive shaft comprising. 2. An annular recess (2) of the set ring holding means.
8) is formed on the inner surface of the set ring (12), and the spring means (24) of the set ring holding means is arranged in an annular groove (26) formed on the outer periphery of the boss member (2), A first ring constituted by a spring ring (24) having a spring force that expands radially outward so as to be crimped to the annular recess (28) on the inner surface of the set ring (12).
The drive shaft according to item. 3. An annular recess (2) of the set ring holding means.
8) is formed on the outer periphery of the boss member (2), and the spring means (24) of the set ring holding means is arranged in an annular groove (26) formed on the inner surface of the set ring (12), The drive according to claim 1, comprising a spring ring (24) having a spring force that contracts radially inward so as to be crimped to the annular recess (28) on the outer periphery of the boss member (2). axis. 4. An annular recess (2) of the set ring holding means.
8) is formed on the inner circumference of the spring bearing (20) of the compression coil spring, and is used as the spring means (24) of the set ring holding means.
Is arranged in an annular groove (26) formed on the outer periphery of the set ring (12), and is provided with a spring bearing (20) of the compression coil spring.
The drive shaft according to claim 1, wherein the drive shaft comprises a spring ring (24) that expands radially inward so as to be crimped to the annular recess (28) on the inner periphery of the drive shaft. 5. An annular recess (4) of the set ring holding means.
8) is formed on the outer periphery of the boss member (2), and the spring means (46) of the set ring holding means is a ball (38) housed in the set ring (12) and the ball is the boss member. The drive shaft according to claim 1, comprising an annular spring (46) having a spring force that contracts radially inward so as to be pressed against the recess (48) of (2). 6. An annular recess (4) of the set ring holding means.
4) is formed on the outer periphery of the boss member (2), and the spring means (42) of the set ring holding means includes a ball (38) housed in the set ring (12) and the ball (38). A compression spring (42) for pressing in a radial direction toward the recess (44) of (2).
The drive shaft according to item.