CH687581A5 - differential gearbox. - Google Patents

Description

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CH 687 581 A5

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Description

The invention relates to a differential speed reducer comprising an input shaft and an output shaft aligned with the input shaft.

In the field of mechanics, in particular, in the field of precision mechanics, it is often necessary to use a speed reducer in order to obtain, with the same type of motor, output speeds adapted to requirements.

In the field of dentistry, for example, use is made of drive motors whose rotation speed varies between 4000 and 40,000 rpm while certain works require a rotation of the tool of the order of 600 at 100 rpm only, or even 100 to 10 rpm for certain very precise special works.

Many speed reduction devices have already been envisaged. Known, for example, according to patent FR-2 383 361, a differential reduction gear with planetary gears, in which the input shaft carries a toothed pinion engaged with three planet gears, themselves engaged with a toothed crown fixed surrounding the assembly, the satellite pinion carrier being integral with the output shaft. This device is however relatively complicated due to the number of parts which have to turn and it makes it possible to obtain reduction ratios only of the order of 10: 1. By mounting several planetary gears of this type one behind the other, it is possible to obtain greater reduction ratios. However, the value of the reduction ratio is a function of the number of planetary gears used, it is therefore not possible to obtain very large reduction ratios in a reduced volume.

According to another patent FR-2 572 645, in order to reduce the space requirement, a reduction or multiplier module is used comprising an intermediate shaft oblique to the input and output shafts and provided with pinions at each end meshing respectively with the input gear and output gear. However, the reduction ratio obtained by this device is limited to the ratio of the teeth of the various cooperating pinions and therefore cannot be very high.

The object of the present invention is to produce a differential reducer allowing a great reduction in speed of a determined ratio, which can go up to approximately 2000: 1, while limiting as much as possible its size and being of a simple construction.

To this end, the differential speed reducer according to the invention is characterized by the characterizing clause of claim 1.

They can be toothed gears, therefore toothed pinions. In the description which follows, we refer only, for simplicity, to cogwheels and to their number of teeth.

With this new type of reducer, of a very simple new design, the large reduction results from the simple fact that by a tumbling movement of the intermediate wheel during a rotation of one revolution of the input shaft, this intermediate wheel rotates only by a distance which corresponds to the difference in the number of teeth of the two cooperating gears of this wheel and of the fixed wheel. A similar effect occurs with respect to the relative speed between the intermediate wheel and the output wheel, if the two cooperating gears have different numbers of teeth. If the ratios of the numbers of cooperating teeth are chosen so that the intermediate wheel and the output wheel, with respect to this intermediate wheel, rotate in opposite directions, we arrive at a difference in slow speeds very similar and therefore easily gear ratios very large, for example, 1000: 1, or even 2000: 1, as will be explained in the description, while also making it possible to obtain a whole intermediate range of other reduction ratios.

This new device has many advantages. We arrive at very large gears in a small volume. The number of moving parts is reduced compared to conventional reducers, which reduces the angular play. We can consider that the wheels are practically aligned, the oblique axis and therefore the axis of the intermediate wheel, being very slightly inclined relative to the axis of the fixed wheel and the output wheel, this allows the set to fit in the very common shape of a cylinder. The speed of the intermediate wheel is low, it will even be zero if the numbers of teeth of the fixed wheel and that of the cooperating face of the intermediate wheel are equal. There is a torque limitation by the link of mechanical reactions between the input shaft and the output shaft; with conventional reduction systems with very large gears, this torque is often too large and troublesome; it is possible to adjust this torque by construction by varying the pressure angles of the toothing and the dimension, on the design of the bearings some of which can be formed, for example, by ball bearings.

The reduction gear according to the invention is well applicable to dental instruments requiring a very slow speed, such as, for example, drills, tappers, low-speed milling machines, and can be incorporated in the handpiece or in the dental motor which is hung on a handpiece.

Preferred embodiments result from the dependent claims.

Two preferred embodiments of the reduction device will now be described below with the aid of the description which follows and of the appended drawing in which:

Fig. 1 is a schematic view, in longitudinal section, of a first embodiment of the reduction gear according to the invention.

Fig. 2 shows an exploded view of the elements of FIG. 1.

According to fig. 1 and 2, the reducer comprises an input shaft 1 extended by a cylindrical axis 2, oblique with respect to the input shaft 1, and integral with it. On this oblique axis 2 is freely mounted in rotation an intermediate wheel 3 provided on the

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two faces of annular gear zones formed by front teeth. On its face directed towards the input shaft 1 the front toothing 4 has a number of teeth Z2 and, on the other face, the front toothing 5 has a number of teeth Z3. The intermediate wheel 3 cooperates by its front toothing 4 with the toothing 6, having a number of teeth Zi, of a fixed wheel 7 disposed concentrically with the input shaft 1; the front toothing 5 of its other face cooperates with the front toothing 8, having a number of teeth Z4, of an output wheel 9 secured to the output shaft 10 and concentric with it.

In the example considered, the connection point of the oblique axis 2 to the input shaft 1 is off-center with respect to the longitudinal axis of this input shaft 1. The oblique axis 2 extends from this connection point towards the extension of said longitudinal axis and cuts it, the center of the intermediate wheel 3 being located approximately at the point of this intersection. Therefore, during the rotation of the oblique axis 2, it describes in space a double cone whose common apex is located at the intersection between the oblique axis and the extension of the longitudinal axis of the input shaft 1. Thanks to this measurement, the oblique axis 2 and the intermediate wheel 3 are roughly balanced with respect to the center of the tumbling movement and therefore offset during rotation of the oblique axis 2.

For the constructive embodiment, the oblique axis 2 is integral with the input shaft 1 by means of a collar 2a whose diameter is larger than that of the input shaft 1 and whose directed face towards the oblique axis 2 has an inclination corresponding to the obliquity of said oblique axis. Preferably, the three parts of the input shaft 1, the collar 2a and the oblique axis 2 are in one piece.

The inclination between the oblique axis 2 and the input shaft 1 is very small. In most practical cases, the angle of inclination for toothed gears is preferably between 5 ° and 15 °. However, the exact value of this angle is not essential; the minimum value of this angle which can in principle be chosen, depends on the difference in the numbers of teeth of the cooperating wheels as well as on the profile and type of the toothing; it could be, theoretically or in special cases, for a difference of a single tooth, less than 5 °, naturally respecting the condition that the engagement of the two gears is done without jamming.

The oblique axis 2 is extended by a small axis 11 aligned with the input shaft 1 and which is housed in a hole 13 in the output wheel 9 in order to ensure the centering of the input shaft 1 However, such an extension of the oblique axis is not necessary, one could also provide an attached bearing or a rolling bearing.

A bearing 12, forming the bottom of a cylindrical sleeve 12a, supports the output shaft 10 and its output wheel 9. Said sleeve 12a forms part of a housing intended to contain the entire device, the second part this housing being constituted by the fixed wheel 7, designed to fit into the end of the bush 12a and the central hub 7a of which forms a bearing for the input shaft 1. The reduction gear thus forms a compact modular unit, small footprint which can be mounted in any suitable device between two axial stops 14 for adjusting the axial play and which can be constituted by driven rings, "Circlips" (registered trademark), etc. In the example considered, said module is cylindrical, but it could have a completely different shape, for example polygonal, in particular square.

To carry out the movements of the wheels, we first observe according to FIG. 1, that the toothing 4 of the intermediate wheel 3 engages the toothing 6 of the fixed wheel 7 only over an area limited to a few teeth while the other toothing 5 of the intermediate wheel 3 engages the toothing 8 of the output wheel 9 only on an area, also limited to a few teeth, diametrically opposite.

If the input shaft 1 and therefore the oblique axis 2 make a complete rotation, the latter describes in space, as mentioned, two cones opposite by their vertex, and drives in this movement the intermediate wheel 3, which is freely mounted on this oblique axis 2. During this movement, the contact zones between the intermediate wheel 3 and the fixed wheel 7 on the one hand, as well as the output wheel 9 on the other hand, circulate along the corresponding teeth . This movement of the intermediate wheel 3 will hereinafter be called the tumbling movement.

To arrive at the reduction ratio, let us first consider that during a complete rotation of the input shaft 1, during a tumbling movement, said intermediate wheel 3 rotates by an angle which corresponds to the difference of number of teeth between the teeth Z2 of the intermediate wheel 3 and those Zi of the fixed wheel 7, therefore at Z2-Z1. If we call n1 the speed of rotation of the input shaft 1 and n3 that of the intermediate wheel 3, we have the ratio:

n3 / n1 = (Z2-Zi) / Z2 = I-Z1 / Z2 (1)

It can be seen that this ratio is all the smaller as Z1 / Z2 is closer to 1. This formula also makes it possible to predict the direction of rotation of the wheels: if Zi <Z2 the ratio is positive, therefore the input shaft 1 and the intermediate wheel 3 rotate in the same direction. If h = Z2 the intermediate wheel 3 does not rotate, but only makes a tumbling movement. If Zi> Z2 the ratio is negative, then the two wheels turn in opposite directions.

The speed of rotation of the output wheel 9 is a function of the relative speeds between the intermediate wheel 3 and the input shaft 1 on the one hand, and between the intermediate wheel 3 and the output wheel 9 on the other hand. The speed n9 of the output wheel 9 is therefore formed of two components n9 = n9A + n9ß, here n9A denotes the speed relative to the intermediate wheel 3 due to tumbling and n9ß denotes the speed due to the rotation of the intermediate wheel itself 3.

Considering first the particular case where the intermediate wheel 3 does not rotate (so if Zi = Z2), it is easily realized that the output wheel 9, during a revolution of the input shaft 1, therefore of a tumbling movement of the intermediate wheel 3, turns to cau5

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se of this tumbling of an angle which corresponds to the difference between the numbers of cooperating teeth, therefore to Z4-Z3. The speed of rotation of the output wheel 9 caused by the tumbling is therefore:

n9A = (1-Z3 / Z4) .n1 (2)

We see that if Z3 <Z4 the output wheel 9 turns in the direction of the input shaft 1, if Z3 = Z4 the output wheel 9 does not rotate and if Z3> Z4 the output wheel 9 turns in the direction reverse of input shaft 1.

Considering the effect of a rotation of the intermediate wheel 3, this rotation is transferred to the output wheel 9 in the ratio of the numbers of teeth Z3 / Z4. Indeed, if we consider a rotation of the intermediate wheel, without tumbling, it is clear that the speed ratio of this wheel relative to the speed of the output wheel is equal to the ratio of the teeth. So we have, using formula (1)

n9B = (Z3 / Z4). (1-Zi / Z2) .n1 (3)

By adding these speeds, according to (2) and (3), we thus arrive at the formula:

n9 / n1 = (n9A + n9B) / n1 = I-Z1Z3 / Z2Z4 (4)

From this formula, it clearly follows that the fraction must not be equal to 1, therefore the ratio Z3 / Z4 must not be the inverse of the ratio Z1 / Z2, because in this case, the output wheel 9 remains stationary . By formula (4), we also see the direction of rotation of the wheels, namely if the ratio ZiZ3 / Z2Z4 is less than 1, the output wheel 9 rotates in the same direction as the input shaft 1; if this ratio is greater than 1, its direction of rotation is opposite to that of the input shaft 1.

It also follows from this formula (4) that to arrive at a very large reduction, it is necessary to choose the ratio Z1 / Z2 very slightly less than 1 and the ratio Z3 / Z4 very slightly greater than 1 (or vice versa), but a little bit different.

To make optimum use of the design of the invention with a view to achieving a very large reduction, the numbers of teeth are preferably chosen as follows: Z2 = Z4 = N, Zi = N-1, Z3 = N + 1. This gives according to the formula (4) n9 / n1 = 1 / N2, the direction of rotation of the output shaft 10 is the same as that of the input shaft 1. By choosing, for example, as number N = 30, we arrive at a gear ratio n9 / n1 = 1/900. By choosing the number N = 40, the reduction ratio is 1/1600.

To achieve a large reduction with the direction of rotation of the output wheel 9 inverted compared to that of the input shaft 1, one can choose Zi = Z3 = N, Z2 = N + 1, Z4 = N- 1, this gives according to the formula (4) n9 / n1 = 1 / (N2—1). For N = 30, we have a ratio of -1/899.

In the examples described, it is understood that the intermediate wheel 3 rotates slowly in the same direction of rotation as the input shaft 1 while the output wheel 9 rotates relative to this intermediate wheel 3 with an inverse slow relative speed, but a little lower or higher than the relative speed of the intermediate wheel 3 compared to the input shaft 1, and that it is this difference which results in the very slow speed (in one direction or the other) ) of the output wheel 9.

By choosing the teeth ratios adequately, with a sufficient tooth engagement, one can arrive at reduction ratios chosen within a very large margin. For example, if Z4 = 31, Z3 = 32, Z2 = 20, and Zi = 19, we arrive at a reduction ratio of 1:51 2/3.

A single effect design can be obtained if Z3 = Z4, the final ratio will be I-Z1 / Z2, or if Zi = Z2 the ratio will be I-Z3 / Z4.

The advantage of this device is that there is only a slow rotation of the intermediate wheel 3 and that the number of moving parts is very small compared to the numbers of parts making up the reducers known hitherto. In addition, because the oblique axis 2 is very slightly inclined relative to the input shaft 1, it can be considered that the intermediate wheel 3 occupies a limited space, almost aligned with the space occupied by the fixed wheels and mobile, the three wheels can be easily inserted into a cylindrical volume. Thanks to the connection of mechanical reactions between the input shaft and the output shaft, there is a significant limitation of the torque.

Because of its small size and its presentation in the form of a compact module, the reduction gear which has just been described can advantageously be used in dental instruments requiring a large reduction, the cylindrical module which can easily be inserted into the gripping sleeve d '' a right handpiece, or in a contra-angle or also in the motor. One can in particular use such a reducer, for example, in a drill, in a tapping screw, only in a low speed milling machine. Of course, other applications could be envisaged without departing from the scope of the invention.

Claims (11)

Claims 1. Differential reduction device comprising an input shaft and an output shaft aligned with the input shaft, characterized in that the input shaft (1) is extended by a cylindrical axis (2) which is oblique to this input shaft (1) and on which is mounted freely in rotation an intermediate wheel (3) provided on each of its faces with annular gear zones (4, 5), this intermediate wheel (3 ) cooperating by its annular gear zone (4) from its face directed towards the input shaft (1) with an annular gear zone (6) combined with a fixed wheel (7) disposed concentrically with the input shaft (1), and by its annular gear zone (5) on its other face with an annular gear zone (8) combined with an output wheel (9) integral with and concentric with the output shaft (10), the ratio between the pitch diameters of the annular gear zones (4, 6; 5, 8) of one of the faces of the intermediate wheel (3) and the wheel (7 or 9) with which it cooperates being 5 10 15 20 25 30 35 40 45 50 55 60 65 4 7 CH 687 581 A5 8 unequal to one and different from the ratio between the original diameters of the annular gear zones of the other face of the intermediate wheel (3) and of the other wheel (9 or 7), so that the rotation of the axis oblique (2) causes the intermediate wheel (3) to tumble and thus gives a multiplied rotation to the output wheel (9). 2. Device according to claim 1, characterized in that the connection point of the oblique axis (2) to the input shaft (1) is off-center with respect to the longitudinal axis of the latter, said oblique axis (2) being oriented so as to cut the extension of said longitudinal axis, and that the center of the intermediate wheel (3) is located at least approximately at the intersection of the oblique axis (2) and said extension of the longitudinal axis of the input shaft (1). 3. Device according to one of claims 1 or 2, characterized in that the oblique axis (2) is connected to the input shaft (1) via a collar (2a) having a diameter greater than that of the input shaft (1) and whose face directed towards the oblique axis (2) is inclined at an angle corresponding to the obliquity thereof, preferably the shaft inlet (1), the collar (2a) and the oblique axis (2) forming a single piece. 4. Device according to one of claims 1 to 3, characterized in that the pitch diameter of the fixed wheel 17) is a few percent less than that of the annular cooperating gear zone (4) of the intermediate wheel ( 3), that the pitch diameter of the output wheel (9) is a few percent less than that of the other annular gear zone (5) of the intermediate wheel (3) and itself differs by a few percent from the pitch diameter of the fixed wheel (7), and the pitch diameters of the two annular gear zones (4, 5) of the intermediate wheel (3) are different from a few percent. 5. Device according to one of claims 1 to 4, characterized in that the annular gear zones are constituted by front teeth (4, 6; 5, 8), the numbers of teeth of the teeth of one of the faces of the intermediate wheel (3) and of the wheel (7 or 9) with which it cooperates being different. 6. Device according to claim 5, characterized in that the numbers of teeth of the teeth of the intermediate wheel (3) on the two sides are different, and each being greater by one tooth than the number of teeth of the wheel (7, 9) with which it cooperates on each side. 7. Device according to one of claims 5 or 6, characterized in that the inclination of the oblique axis (2) relative to the input shaft (1) is between 5 ° and 15 °. 8. Device according to one of claims 1 to 7, characterized in that the oblique axis (2) is extended by an axis (11) aligned with the input shaft (1) and which is housed in a hole (13) in the wheel (9) for centering said input shaft (1). 9. Device according to one of claims 1 to 8, characterized in that the fixed wheel (7) serves as a bearing for the input shaft (1) and is formed as part of a housing and that it constitutes with a socket (12, 12a) itself serving as a bearing for the output shaft (10), a closed housing. 10. Device according to one of claims 1 to 9, characterized in that it is in the form of an interchangeable module. 11. Dental handpiece comprising a device according to one of the preceding claims. 5 10 15 20 25 30 35 40 45 50 55 60 65 5