The present invention relates to a method for designing tooth profiles of a rigid internally toothed gear and a flexible externally toothed gear in a strain wave gearing.
JP 2055418 B2 proposes a means for increasing rotational accuracy and load capacity in a strain wave gearing. The means is a tooth profile with which a locus over which an externally toothed gear moves with respect to an internally toothed gear is utilized, whereby the gears can mesh in a wide range in the circumferential direction. By increasing the number of teeth in mesh at the same time, tooth profile errors are averaged to increase precision, and the load is distributed whereby the stress on each tooth decreases, thereby realizing a higher load capacity. In the strain wave gearing of the present specification, the tooth profile obtained by a technique of using the locus over which the externally toothed gear moves with respect to the internally toothed gear as the tooth profile is referred to as an IH tooth profile.
Patents for various tooth profiles have been granted on the basis of the aforementioned technique of using the moving locus for the tooth profile. For example, in JP 2055418 B2, which was mentioned above, ½ of the moving locus was used for the tooth profile, whereas in JP 2675853 B2, λ times (λ being a positive value less than 1) of the moving locus is used for the tooth profile, which is more generalized. In addition, there are many patents such as JP 2612585 B2, JP 3230595 B2, and JP 3942249 B2 in which λ times of the moving locus is used.
In a strain wave gearing, reduction of stress in the dedendum of the externally toothed gear is required in order to further increase the load capacity of the internally toothed gear and the externally toothed gear. The dedendum stress is mainly divided into tensile stress due to torque and bending stress due to elliptical deformation. In load distribution achieved using an IH tooth profile, the tensile load due to torque is dispersed and the value is reduced. Widening the root portion is effective in reducing bending stress.
To widen the root in an IH tooth profile for the purpose of reducing bending stress, the value of A must be increased, the tip portions of the external teeth of the externally toothed gear used in meshing must be made smaller, and the shape of the teeth on the dedendum side must be made thinner. Once such measures have been adopted, only a narrow range of the tips of the external teeth can be used; therefore, wear and pitching of the external teeth may occur. In addition, since the meshing point is only on the tip side, the stress in the direction in which the external teeth fall may increase.
In view of these matters, it is an object of the present invention to provide a tooth profile designing method for a strain wave gearing for obtaining a tooth profile with which the roots of the external teeth of the externally toothed gear can be widened and a larger portion of each tooth face can be used for meshing while improving the IH tooth profile technique and maintaining a wide-range mesh.
According to the present invention, there is provided a tooth profile designing method for a strain wave gearing comprising a rigid internally toothed gear, a flexible externally toothed gear, and a wave generator that causes the externally toothed gear to flex into an ellipsoidal shape and mesh with the internally toothed gear at locations including positions on a major axis of the ellipsoidal shape, and causes the positions where the externally toothed gear meshes with the internally toothed gear to move in a circumferential direction, said tooth profile designing method characterized in that:
According to the method of present invention, it is possible to obtain a tooth profile with which the roots of the external teeth can be widened and a larger portion of each face of the external teeth can be used in meshing while maintaining a wide-range mesh provided by a tooth profile designing technique of using a moving locus.
A strain wave gearing 1 has a rigid internally toothed gear 2, a flexible externally toothed gear 3 disposed coaxially inside the internally toothed gear, and an ellipsoidally contoured wave generator 4 fitted inside the externally toothed gear 3. The externally toothed gear 3 is caused to flex in an ellipsoidal shape by the wave generator 4, and external teeth 30 of the externally toothed gear 3 mesh with internal teeth 20 of the internally toothed gear 2 at the positions of both ends of the major axis L of the ellipsoidal shape. The number of teeth of the internally toothed gear 2 is 2n (n being a positive integer) greater than the number of teeth of the externally toothed gear 3. When the wave generator 4 rotates, relative rotation corresponding to the difference in the number of teeth occurs between the internally toothed gear 2 and the externally toothed gear 3. When the internally toothed gear 2 is fixed in a state of not rotating, reduced rotation is extracted from the externally toothed gear 3 to a load side (not shown). The internally toothed gear 2 and the externally toothed gear 3 are both spur gears of module m. The amount of radial flexure of the externally toothed gear 3 is 2 kmn. k is a deviation coefficient, and is in the range of, for example, 0.6<k<1.4 in practical use.
First, the IH tooth profile technique upon which the present invention is premised shall be described.
The rotation angle of the wave generator in the strain wave gearing is φ. The description below shall be focused on the internal teeth of the internally toothed gear and the external teeth of the externally toothed gear on the major axis when φ=0. The locus over which the external teeth move with respect to the internal teeth, which is obtained when the wave generator is caused to rotate between 0 and π/2, is designated as curve I (formula 1). In the IH tooth profile technique, a curved portion of part of the moving locus may be used, in which case the range of φ would be narrower than the range 0 to π/2.
The endpoint of curve I when φ=0 is designated as point A and the endpoint of curve I when φ=π/2 is designated as point B. The midpoint between point A and point B is designated as point C. Using a similarity curve obtained by multiplying curve I by λ (0<λ<1) using point B as a center of similarity, an addendum profile of the internal teeth of the internally toothed gear is defined (formula 2). A parameter representing the tooth profile shape is designated as θ.
Using point B as the center of similarity, curve I is multiplied by (1−λ) to determine a similarity curve. This similarity curve is rotated 180 degrees about point C, and the resulting curve is used to define an addendum profile of the external teeth of the externally toothed gear (formula 3).
A dedendum profile of the internal teeth and a dedendum profile of the external teeth are set to a shape that does not interfere with the counterpart addendum profile.
Since the internally toothed gear and the externally toothed gear of the strain wave gearing have a large number of teeth, the meshing of the teeth of both gears can be approximated to the meshing of a rack, assuming that the number of teeth is infinite. Using rack approximation eliminates the factor of tooth inclination, so when the apex of the addendum profile of the external teeth (formula 3) moves along the moving locus (formula 1), an external tooth addendum profile group can be expressed as formula 4.
Envelope points of the external tooth addendum profile group are meshing points. A condition for the envelope of the external tooth addendum profile group is that the Jacobian for formula 4 is zero, which is shown by formula 5.
Calculating formula 5 yields formula 6.
Formula 6 always holds when φ=θ. The shape obtained when φ=θ in formula 4 is an envelope curve of the external tooth addendum profile group. Setting φ to θ in formula 4 yields formula 7.
Comparing formula 7 with formula 2, the envelope curve of the addendum profile of the external teeth is congruent with the addendum profile of the internal teeth, proving that if the addendum profiles of the internal teeth and the external teeth are set as shown in formulas 2 and 3, a wide range of continuous contact is possible between the internal teeth and the external teeth.
In the tooth profile designing technique of the present invention, the tooth profiles are set as follows.
As with the IH tooth profile technique described above, the rotation angle of the wave generator 4 of the strain wave gearing 1 is designated as φ, and the description below shall be focused on the internal teeth 20 of the internally toothed gear 2 and the external teeth 30 of the externally toothed gear 3 on the major axis when φ=0. The locus over which the external teeth 30 move with respect to the internal teeth 20, which is obtained when the wave generator is caused to rotate between 0 and π/2, is designated as curve I (first curve) (formula 1 remains unchanged).
The endpoint of curve I when φ=0 is designated as point A, the endpoint when φ=π/2 is designated as point B, and the midpoint between point A and point B is designated as point C. Thus far, the present technique is the same as the IH tooth profile technique.
Using point B as the center of similarity, curve I is multiplied by (1−λ) to obtain a similarity curve. The similarity curve is rotated 180 degrees about point C to determine a second curve.
Only the x coordinate of the second curve is multiplied by a to obtain a third curve (formula 8). The third curve is used to define the addendum profile of the external teeth 30. In formula 8, θ is a parameter representing the tooth profile shape.
The addendum profile of the external teeth 30 can also be defined using the fourth curve determined as follows, instead of the third curve. Specifically, curve I is multiplied by (1−λ) using point B as the center of similarity to determine a similarity curve, the similarity curve is rotated 180 degrees about point C to determine the second curve, and then only the y coordinate of the second curve is multiplied by β to obtain a fourth curve (formula 9). The fourth curve is used to define the addendum profile of the external teeth 30.
The addendum profile of the internal teeth 20 is a tooth profile obtained by enveloping the set addendum profile of the external teeth 30.
When the addendum profile of the external teeth 30 is set as shown in formula 8, the addendum profile group of the external teeth 30 when rack approximation is performed is given by formula 10.
The envelope condition in this case is given by formula 11.
Since a solution to formula 11 cannot be obtained analytically, the relationship between φ and θ is determined by numerical calculation. By substituting the result into formula 10, the addendum profile of the internal teeth 20 can be obtained.
In addition, when the addendum profile of the external teeth 30 is set as shown in formula 9, the addendum profile group of the external teeth 30 in rack approximation is given by formula 12, and the envelope condition is given by formula 13.
The addendum profile of the internal teeth 20 is obtained by solving formula 13 by numerical calculation and substituting the result into formula 12.
As with the IH tooth profile, the dedendum profiles of the internal teeth 20 and the external teeth 30 are set so as not to interfere with the counterpart addendum profiles.
In the case of formula 8, if α<1, the tooth thickness of the external teeth 30 of the externally toothed gear 3 is less than in the IH tooth profile when λ is the same value, and the roots can be widened. Alternatively, when each λ is adjusted so that the tooth thickness is the same, the tooth surfaces used for meshing of the external teeth 30 become wider than in the IH tooth profile. This means that the range over which the teeth are subjected to the energy of friction will be widely distributed. Furthermore, since the radius of curvature of the tooth surfaces of the external teeth 30 also increases, contact stress on the tooth surfaces decreases. These effects combine to make the tooth surfaces resistant to damage such as wear and pitting.
In the case of formula 9, when λ=λ0 in formula 8, β is greater than 1, and when λ=1−λ0/β, the same effect as in formula 8 is obtained.
When the ellipsoidal form of the externally toothed gear 3 is given by formula 14 in tangential polar coordinates, the moving locus when the meshing of the externally toothed gear 3 with the internally toothed gear 2 is regarded as rack meshing is represented by formula 15.
An example is given in which the tooth profile is calculated with respect to the moving locus of formula 15, where m=1, n=1 (difference in the number of teeth is 2), and k=1.
1−0.65(=1−λ)=0.5×0.7(=λ·α)=0.35
Filing Document | Filing Date | Country | Kind |
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PCT/JP2021/020902 | 6/1/2021 | WO |