NL8301611A - UNIVERSAL COUPLING. - Google Patents

Description

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Short Designation: Universal coupling.

The invention relates to a universal coupling and more particularly to a ball joint-type universal coupling adapted to connect two shafts together such that the centerline and at least substantially align in order to produce a rotary movement. was able to transfer efficiently from one of the two shafts to the other of the two shafts.

In order to connect two shafts together, universal couplings of the cross type and yoke type are known and used in practice.

Ball joint type universal couplings are also known and widely used as couplings for transmitting motion between two shafts to be joined together in a more efficient manner than universal cross and yoke type couplings do.

Examples of known ball joint fittings are disclosed in US patents 2,289,154, 208,050,788,035, 1,086,375, 2,149 * 763, 2,503,373, 2,687 * 024, and 3,196,463 and in Japanese Utility Model Applications 51300/75 and 20049 / 75. These ball joint type universal couplings comprise a recessed housing, a ball portion received in the spherical recess at one end of the housing and provided with a slot or groove and a pin mounted in the housing and extending through the housing. slot or groove formed in the ball portion.

In any of the known universal couplings, however, the ball portion is directly received in the spherical recess and movement of the ball portion out of the recess is prevented by converting the end of the housing where the recess is formed or by the pin and thus, the relative sliding movement between the ball portion and the spherical recess is not uniform and the pin is directly and forcefully applied thereto in a direction which urges the ball portion 30 out of the spherical recess, resulting in premature failure of the pin .

Furthermore, the universal couplings shown in the above-mentioned US patents 2,289-154, 208,050, 788,035,1,086,375 and 2,149-763 are not so-called multi-directional universal couplings. In other words, the known universal couplings according to these US patents tumble in only one direction.

8301611

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Moreover, the known universal couplings mentioned above are relatively complicated in construction and difficult to assemble. Furthermore, in order to obtain an even movement of the moving parts of the universal coupling, the parts must be manufactured with great precision, resulting in an expensive universal coupling.

Accordingly, an important object of the present invention is to obtain a universal coupling which is easy to assemble, which shows great mechanical efficiency and which effectively eliminates the disadvantages associated with known universal couplings indicated above.

A further object of the present invention is to obtain a universal coupling which can not only transmit constant speed rotational motion from one shaft to the other shaft, but also allows multi-directional tumbling.

A further object of the invention is to provide a universal coupling in which the pin is not directly applied to it with any bending stress other than that in a direction of rotation and thus remains free from premature failure.

A further object of the present invention is to obtain a universal coupling, which requires a relatively small number of parts and is able to move evenly, even if the parts are not manufactured with great precision, so that the coupling will be cheaper.

Yet a further object of the present invention is to obtain a universal coupling, which is particularly suitable for use in conjunction with the drive shaft mechanism of an engine or the steering shaft mechanism of a vehicle.

In order to achieve the aforementioned objects according to the present invention, a universal coupling is provided, which comprises at least substantially a recessed housing adapted to be connected to one of two axially aligned with their axes shafts, a ball section adapted to be connected to the other shaft and to be received in the recessed housing, a housing attached closure member for supporting the ball section and a pin attached to the 8301611 * r 4 - 3-23200 / CV / tl housing for free rotation and extending through a slot in the ball section. The closure member contacts the ball section with suitable spring force. In an exemplary embodiment of the invention, a substantial portion of the ball portion is supported in a spherical cavity formed in the recess housing, and a small portion of the ball portion is supported by the closure member.

In another exemplary embodiment of the invention, the ball section is supported by a spherical recess in the recessed housing and a spherical recess in the closure member. In a further embodiment of the invention, the ball section is supported by inserting the ball section into a spherical recess in an army. In such a case, the bearing is arranged in the spherical recess in the recessed housing and movement out of the spherical recess in the housing is prevented by means of the closure member and the pin extending through the housing and the ball section at least substantially perpendicular to the axes of the shafts to be joined together if they are in line with each other. The pin is included in the recessed housing for free rotation and the portion of the pin included in the slot of the ball portion is square-shaped with the square portion of the pin slidably received in the slot of the ball section. Thus, the ball portion cannot move relative to the recessed housing when the shafts to be joined rotate about the axes of the shafts, but the pin rotates together with the housing, allowing rotary movement to be transmitted from one of the shafts. two shafts on the other of the two shafts. Also, the ball portion is not allowed to move relative to the pin if the ball portion rotates in a direction perpendicular to the axis of the pin in one direction, but rotates together with the pin about the axis of the latter. Furthermore, the ball portion can rotate a predetermined angular distance independently of the pin, which angular distance corresponds to the movement area of the pin within the slot in the ball portion when the ball portion rotates in a direction perpendicular to the first direction or in a second direction . In this way, rotational movement from one axis can be transferred to the other axis and the consequences of the rotation in the first direction and that in the second direction provides universal movement.

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The invention will be explained in more detail below with reference to the accompanying figures, in which embodiments of the construction according to the invention are shown.

Fig. 1 shows a side view of an application of two at least nearly equal universal couplings made in accordance with the present invention in the drive shaft mechanism of a small-sized engine.

Fig. 2 schematically shows a longitudinal section through a first exemplary embodiment of a universal coupling according to the invention.

FIG. 3 shows the ball section with a cross section over the pin of the universal coupling according to FIG. 2.

Fig. 4 shows a longitudinal section through a further embodiment of a universal coupling according to the invention.

Fig. 5 shows in perspective a closing member as used in the exemplary embodiment according to FIG. 4.

Fig. 6 shows a longitudinal section through a further embodiment of a coupling according to the invention.

Fig. 7 shows a longitudinal section through a further embodiment of a coupling according to the invention.

FIG. 8 shows a graph plotted versus time in coupling reliability tests of the invention.

Fig. 1 shows two substantially equal universal clutches made in accordance with the present invention and used in the drive shaft mechanism of, for example, a small engine size in a mower. In the application as shown in Fig. 1, the two substantially equal universal couplings 10 and 10 'according to the invention are connected to each other by means of an intermediate shaft 11. One of the two universal couplings 10 'is thereby connected to the drive shaft 12 of, for example, a small-sized motor (not shown in more detail), while the other universal coupling 10 is connected to the shaft 13 of, for example, a drive wheel (not shown in more detail). If the shafts 12 and 13 are connected together by the two universal couplings 10 and 10 ', as indicated above, constant speed rotational movement can be evenly transferred from the shaft 35 to the shaft 13, even if the centerline extensions X and Y of the two axes 12 and 13 intersect over a wide angle range 8301611 * · ♦ -5- 23200 / CV / tl, as will be further described below.

Typically, the yoke or cross type clutches or clutches are used in the drive shaft mechanism of such a small engine.

The advantages of the universal couplings of the present invention over the known couplings will become more clear from the description below.

Fig. 2 now shows a first embodiment of a universal coupling according to the invention in more detail. The universal coupling 10 has a housing 20 with a spherical cavity or recess 21 formed at one or the inner end, while a cavity 22 is formed at the other or outer end. In the spherical recess 21, a ball portion 23 is slidably received, this ball portion being formed at the adjacent end of a shaft 24. The ball portion will preferably be received in the spherical recess 21 with an appropriate lubricant interposed. The shaft 24 of the universal coupling 10 is considerably shorter than the shaft 24 of the universal coupling 10 '.

The shafts 24 of the two universal couplings 10 and 10 'are connected to each other by means of a sleeve 25, as shown in Fig. 1, in order to obtain the above-mentioned intermediate shaft 11. In such a case, the 20 shafts 24 of the couplings 10 and 10 'equipped with serrations 26 and when the sleeve 25 is applied to the two serrated shafts 24 and force applied to the opposite ends thereof by some suitable external force application means, the inner surface of the sleeve 25 is formed with translations complementary to the serrations 26 on the sleeves 25, whereby the shafts 24 and the sleeve 25 are joined together in such a way that the shafts and the sleeve can no longer rotate relative to each other, but only at least can move in the axial direction.

The recess 22 at the outer end of the coupling 10 * receives one end of the shaft 12 and the recess 22 at the other end of the universal coupling 10 receives one end of the shaft 13 (see Figure 1).

The shafts 12 and 13 are then attached to the housings 20 of the universal couplings 10 and 10 'using shear pins (not shown) which extend through transverse holes 27 in the housings and are in line 35 therewith through the shafts 12 and 13 extending holes.

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As shown more clearly in FIG. 2, at the open end of the spherical cavity 21 in the universal coupling 10 or 101 is arranged a sealing member 30 which is in the form of a ring formed of synthetic resin or rubber with a suitable resilience in the first embodiment of FIGS. 1 and 2. The inner surface of the closure member 30 is spherical in order to contact evenly with a portion of the relevant ball portion 23 and the closure member 30 is on the recessed housing 20 attached by the open edge 20a of the spherical cavity 21 using suitable means within it to operate.

When the closure member 30 is properly positioned in the respective housing 20 in the manner described above, a portion of the ball portion 23 is supported by the closure member 30 with appropriate resilience provided by the closure member, which is made of rubber or synthetic resin, with the ball portion is prevented from moving out of the spherical cavity 21. Supporting the ball portion 23 by means of a high resilience closure member allows the ball portion to move fairly evenly in any direction within the spherical cavity 21.

The rotation of the ball portion 23 about its axis Z in the convex cavity 21 is prevented by a pin 24, which is rotatably received in a transverse through hole 41, which is formed in the relevant housing 20, at least the pin extending extends substantially perpendicular to the centerline Z of the ball portion 23 through a slot 42 in the ball portion. The pin 40 has a head 43 at one end and a resilient lock washer 44 attached at the other end to prevent the pin can move out of the housing 20. The pin 40 is mounted on the housing 20 by passing the pin through the aligned holes 41 and the slot 42 in the housing 20 and the ball section 23, respectively, until the head 43 on the pin 40 rests against the housing then the retaining ring 44 is applied to the end of the pin remote from the head.

As shown particularly clearly in Fig. 3, the slot 42 is in the form of a rectangular notch of constant width, while the portion of the pin 40 where the pin engages in the slot 42 is square as shown at 45, wherein the square portion 45 of the pin slides easily into slot 42, 8301611 t -7-23200 / CV / tl. Thus, there is no relative rotation between the pin and the ball portion. More specifically, when the ball portion 23 is rotated about its axis Z, the housing 20 rotates together with the ball portion. When the ball portion 23 is rotated about the axis of the pin 40 (this rotation will be referred to hereinafter as "the rotation in the first direction"), the ball portion may rotate together with the pin 42 about the axis of the pin over a predetermined angular distance If the ball portion 23 is rotated in a direction perpendicular to the first direction of rotation (the right angle rotation 10 will hereinafter be referred to as "the rotation in the second direction"), the ball portion may rotate a given angle distance independently of the pin 42 by the shape of the slot 42. The angular spacing area covered by the rotation of the ball portion 23 in the second direction of rotation is bounded by an inclined plane 46 formed on the inner wall 15 of the slot 42.

As described above, torque is transferred from the ball portion 23 to the housing and vice versa, but the effects of the turns in the first and second directions provide a universal motion. As a result, constant angular velocity rotation of the shaft 20 12 is transmitted to the shaft 13 by the two universal couplings 10, 10 * and intermediate shaft 11. As a result of the universal couplings, the constant angular velocity rotation is not adversely affected even if the axes of the shafts 12 and 13 are out of alignment or eccentric to each other. As shown in FIG. 2, a cover 25 50 extends astride housing 20 and shaft 24 of ball section 23. Cover 50 is made of rubber or the like and primarily serves to seal the opening of the spherical cavity 21 in the housing 20 against the ingress of dust and the like into the recess.

Fig. 4 shows a further exemplary embodiment of a universal coupling according to the invention. In this exemplary embodiment, the ball part 23 is supported by a shut-off member 60, which is constructed differently. As shown more particularly in Fig. 5, the modified shut-off member 60 a flange 61 and an annular spherical-shaped portion 62 extending from the flange radially inward.

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The spherical portion 62 evenly contacts a portion of the ball portion 23, and the portion 62 is provided in its inner circumference with a plurality of circumferentially spaced resilient pieces 63. When the flange 61 of the closure member 60 is turned at the edge of the opening in the housing 20, the resilient pieces 63 of the closing member support the ball portion 23 under suitable pressure (fig. 4). The closing member 60 is preferably made of, for example, synthetic resin. However, it is also contemplated that the closure member 60 may be manufactured! made of metal, the part of the spherical; portion 62, where this spherical-shaped portion comes into contact with the ball portion 23, may be covered with a suitable synthetic resin.

In the exemplary embodiment shown in Figure 6, the ball portion 23 is secured to the recessed housing 20 by means of a pin 70, which is different from the pin 40 shown in Figure 2.

The deviation between the pin 70 and the pin 40 is in particular that the square part of the pin 70 is formed by a separate member. In the exemplary embodiment according to Fig. 6, the pin 70 consists of a shaft 71 and a sleeve 72 arranged on the shaft 71.

For example, the sleeve 72 is made of synthetic resin, and the outer periphery of the sleeve 72 is square so that it evenly fits into the slot 42 in the ball portion 23. The pin 70 in the exemplary embodiment of FIG. 6 is in a simpler manner. than the pin 40 in the exemplary embodiment of FIG. 2.

Fig. 7 shows a further embodiment of the universal coupling according to the invention. In the exemplary embodiment of this figure, the ball portion 23 is supported by a bearing 80, which is, for example, made of synthetic resin or rubber, and is provided with a spherical recess 81 for enclosing a substantial part of the outer circumference of the ball portion 23 for free rotation. The bearing 80 is received in the complementary cavity 82 of the housing at the respective end of the housing 20 and held in position by means of a closure member 83 surrounding the ball portion 23. As in the previous embodiments, the closure member 83 is attached to the housing 20 by bending inward or boiling down the peripheral edge of the opening in the housing.

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The ball portion, recessed housing, and other parts in each of the above embodiments are formed by cold rolling steel material in the form of a rod, and consequently the parts of the universal coupling can be manufactured inexpensively and in a simple manner. To give an example, the ball portion has an outside diameter of 14mm, the recessed housing an outside diameter of 25mm and the pin a diameter of 5mm.

According to the invention, the components of each of the foregoing the embodiments of / universal coupling are, for example, assembled as follows:

First, the ball portion is placed in the spherical recess in the housing on which the pin is passed through the holes provided for this purpose in the housing and the ball portion, after which the locking ring is fitted on the end of the pin. The closure member is placed about the ball portion in a predetermined position within the recessed housing and the peripheral edge of the opening in the housing is turned inward. Thus, in comparison with the conventional universal couplings of the cross and yoke type, the universal coupling according to the present invention can be manufactured in a simpler manner. Furthermore, the universal coupling according to the invention requires a relatively small number of parts and this coupling is therefore cheaper.

Furthermore, according to the present invention, since the ball section is supported by a closing member with an appropriate spring force, the movement of the ball section in the spherical cavity or recess in the housing is smooth.

Fig. 8 shows the results of endurance tests performed on universal couplings as shown and described above and the conditions applied during these tests are as follows: 1. Revolutions: 615 rpm.

2. Swivel angle between two axes: 9 °.

3. Test cycle: 100,000 cycles (4 sec. Per cycle) 4. Load on coupling: 0.9 kg (max) for 0.2 seconds 0.1 kg (min) for 2.8 seconds 35 No load for 1 second.

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The test results show that proven universal couplings meet all endurance test conditions, chosen for the universal couplings.

From the above, it will be appreciated that the present invention can overcome the drawbacks associated with the known universal clutches. Although the description has been made in connection with the use of the invention for the drive shaft mechanism of a small-sized engine the invention can equally well be applied to, for example, the steering axle mechanism of a vehicle.

Although presently preferred embodiments of the invention have been depicted and described, it will be understood that many modifications and / or additions may be made thereto within the spirit and scope of the invention.

8301611

Claims (14)

1. Universal coupling for connecting two shafts for tumbling about the axes of these shafts provided with a recess housing adapted to be connected to one of the shafts, a housed ball portion for multi-turn the further directions and adapted to be connected to the other of the two shafts, a closure member attached to the recessed housing for supporting at least a portion of the ball portion and a pin disposed substantially perpendicular to the axis of the shaft, which extends through the housing and the ball portion, the pin being inserted into the housing for free rotation and in the ball portion such that the ball portion is not allowed to rotate relative to the pin, but relative to the pin in a direction can tumble. 2. Coupling according to claim 1, characterized in that a substantial part of the ball part is received in a spherical recess in the recessed housing and a small part of the ball part is resiliently supported by the closing member. Coupling according to claim 2, characterized in that about half of the ball-shaped portion is received in the spherical recess, while the other half of the ball-shaped portion is received in a spherical cavity in the closure member. 4. Coupling according to any one of the preceding claims, characterized in that the ball portion in the spherical recess is supported in an bearing arranged in the recess in the housing, which prevents the bearing from emerging from the recess in the housing. moves in the desired position is retained using a cover plate attached to the housing. Coupling according to any one of the preceding claims, characterized in that the closing member is provided with a flange adapted to be fixed to the housing and a spherical surface extending from the flange for uniform contact with part of the bullet section. Coupling according to any one of the preceding claims, characterized in that the closing member is attached to the housing by converting the peripheral edge 35 of the opening into the housing. 8301611 .- V -12- 23200 / CV / tl Coupling according to any one of the preceding claims, characterized in that the part of the spherical surface of the closing member which comes into contact with the spherical part is covered with a lubricant. 8. Coupling according to any one of the preceding claims, characterized in that the closing member is made of a resilient synthetic resin. Coupling according to any one of the preceding claims, characterized in that it. closing member is made of metal. 10. Coupling according to any one of the preceding claims, characterized in that the ball part is provided with a slot for receiving a square part of the pin, 11. Coupling according to any one of the preceding claims, characterized in that the square part of the pin is integrally formed around the outer circumference of the pin, 12. Coupling according to claim 10, characterized in that the square section is in the form of a sleeve which is arranged on the pin. Coupling according to claim 12, characterized in that the sleeve is made of synthetic resin. 14. Universal coupling assembly for joining together two axles of tumbling motion about the axes of the axles provided with a first universal coupling adapted to be connected to one of the axles, a second universal coupling adapted to the other of both axles to be connected and an intermediate shaft connecting the first and second universal couplings, each of the 25 universal couplings comprising a recess housing, a ball portion received in a recess housing, a closure member attached to the housing and a pin extending through the housing and the ball portion, which runs at right angles to the axes of the two shafts to be joined together, the pin being freely rotatably received in the recessed housing and further such a slot in the ball-shaped part, the pin is secured against rotation relative to this ball-shaped part r may tumble in a direction relative to this ball-shaped portion. 35 8301611