The present invention relates to a traction drive mechanism that uses a planetary roller mechanism.
Related art examples of a traction drive mechanism that uses a planetary roller mechanism are disclosed in Patent documents 1 and 2 below. In the traction drive mechanisms according to Patent documents 1 and 2, a ring roller of a first planetary roller mechanism and a ring roller of a second planetary roller mechanism are fixed, and a carrier of the first planetary roller mechanism is coupled to a sun roller of the second planetary roller mechanism such that the first planetary roller mechanism and the second planetary roller mechanism are connected in series. The traction drive mechanisms according to Patent documents 1 and 2 function as speed reducing mechanisms. Power input to a sun roller of the first planetary roller mechanism is reduced in speed by the first planetary roller mechanism, and then transmitted to the sun roller of the second planetary roller mechanism from the carrier of the first planetary roller mechanism, and further reduced in speed by the second planetary roller mechanism and output from a carrier of the second planetary roller mechanism. Nonpatent document 1 below also discloses a planetary roller mechanism in which four pinion rollers (planetary rollers) are arranged along the circumferential direction of a ring roller.
Patent Literatures
[Patent Document 1] JP 61-74952 A
[Patent Document 2] JP 7-54946 A
[Patent Document 3] JP 5-332413 A
[Patent Document 4] JP 7-21303 A
Nonpatent Document
[Nonpatent Document 1] Akihiko Kano, “Regarding planetary roller type traction drive speed reducing unit for printing machine”, Koyo Engineering Journal No. 165, 2004, p. 60-64
In order to transmit torque in a planetary roller mechanism, press force (normal force) required for the torque transmission needs to be applied to a contact portion between a sun roller and a pinion roller (planetary roller) and to a contact portion between the pinion roller and a ring roller so that no excessive slip (gross slip) is generated at these contact portions. When the press force is applied to each contact portion, the ring roller is elastically deformed diametrically outward in response to reaction force from the pinion roller. The amount of the diametrically outward deformation of the ring roller varies with circumferential position, and is maximal at the circumferential position of the portion to contact the pinion roller and is smaller with greater distance from the portion to contact the pinion roller. If the pinion roller relatively revolves around the ring roller, the circumferential position of the contact portion between the pinion roller and the ring roller periodically changes. Therefore, the ring roller is repeatedly diametrically deformed by the periodic changes of the circumferential position at which the amount of the diametrically outward deformation of the ring roller is maximal. The repeated deformation of the ring roller causes vibrations and noise, and the levels of the vibrations and noise resulting from the repeated deformation of the ring roller are higher when the amount of the diametrical deformation of the ring roller is greater.
In the planetary roller mechanism, the ratio between the inner diameter of the ring roller and the outer diameter of the sun roller need to be designed so that the pinion rollers arranged along the circumferential direction do not interfere with one another. Therefore, a speed change ratio (reduction ratio) obtainable by the planetary roller mechanism is also limited to a range lower than an upper limit value corresponding to the number of pinion rollers. For example, according to Nonpatent Document 1 in which four pinion rollers are arranged along the circumferential direction, the ratio between the inner diameter of the ring roller and the outer diameter of the sun roller at which the four pinion rollers do not interfere with one another is limited to a range lower than an upper limit value (3+2×20.5)≈5.83. Thus, when the ring roller is fixed, the reduction ratio ranging from the sun roller to the carrier is limited to a range lower than an upper limit value (4+2×20.5)≈6.83, and a reduction ratio equal to or greater than this upper limit value (4+2×20.5) cannot be obtained. Even if the first planetary roller mechanism and the second planetary roller mechanism are connected in series in two stages as in Patent Documents 1 and 2 to further increase the reduction ratio, the reduction ratio ranging from the sun roller of the first planetary roller mechanism to the carrier of the second planetary roller mechanism is limited to a range lower than an upper limit value (4+2×20.5)2=(24+16×20.5)≈46.6, and a reduction ratio equal to or greater than this upper limit value (24+16×20.5) cannot be obtained. If the planetary roller mechanisms are connected in series in three or more stages to further increase the reduction ratio, the structure of the traction drive mechanism is increased in size.
In order to further increase the reduction ratio without the increase in size of the structure of the traction drive mechanism, it is possible to reduce the number of pinion rollers arranged along the circumferential direction and thus increase the reduction ratio obtainable by the planetary roller mechanism per stage. However, if the number of pinion rollers arranged along the circumferential direction is reduced, the number of the contact portions between the sun roller and the pinion roller and the number of the contact portions between the pinion roller and the ring roller are also reduced, and the capacity of transmission torque is also reduced accordingly. Therefore, the press force applied to each contact portion needs to be increased to compensate for the reduction of the transmission torque capacity. However, if the press force applied to each contact portion is increased, the amount of the diametrical deformation of the ring roller is also increased, and the levels of the vibrations and noise resulting from the repeated deformation of the ring roller also rise accordingly. If two or fewer pinion rollers are arranged along the circumferential direction, the position of the sun roller pressed to the pinion roller is not stable, and stable application of press force to each contact portion is difficult.
An advantage of the present invention is to provide a traction drive mechanism which can reduce vibrations and noise resulting from the repeated diametrical deformation of a ring roller and to also increase the reduction ratio without the increase in size of the structure.
A traction drive mechanism according to the present invention comprises a first planetary roller mechanism and a second planetary roller mechanism that are connected in series. The first planetary roller mechanism includes a plurality of first planetary rollers rotatably supported by a first carrier. The first planetary rollers are held in contact between a first sun roller and a first ring roller. The second planetary roller mechanism includes a plurality of second planetary rollers rotatably supported by a second carrier. The second planetary rollers are held in contact between a second sun roller and a second ring roller. In the traction drive mechanism,
N1=3, N2=3, 4, 5, or 6, and
(ρ1+1)×(ρ2+1)≧24 +16×20.5
where N1 is the number of the first planetary rollers, N2 is the number of the second planetary rollers, ρ1 is the ratio between the inner diameter of first ring roller and the outer diameter of the first sun roller, and ρ2 is the ratio between the inner diameter of the second ring roller and the outer diameter of the second sun roller.
In the traction drive mechanism according to the present invention, provided that N2=3,
ρ1≧0.102×(ρ1+1)×(ρ2+1)+1.196, and
ρ1≦min[0.204×(ρ1+1)×(ρ2+1)+3.123, 7+4×30.5]
when the value of a smaller one of (0.204×(ρ1+1)×(ρ2+1)+3.123) and (7+4×30.5) is min[0.204×(ρ1+1)×(ρ2+1)+3.123, 7+4×30.5].
In the traction drive mechanism according to the present invention, provided that N2=4,
ρ1≧(2−20.5)×(ρ1+1)×(ρ2+1)/4−1, and
ρ1≦min[0.185×(ρ1+1)×(ρ2+1)+1.320, 7+4×30.5]
when the value of a smaller one of (0.185×(ρ1+1)×(ρ2+1)+1.320) and (7+4×30.5) is min[0.185×(ρ1+1)×(ρ2+1)+1.320, 7+4×30.5].
In the traction drive mechanism according to the present invention, provided that N2=5,
ρ1≧0.206×(ρ1+1)×(ρ2+1)−1, and
ρ1≦min[0.234×(ρ1+1)×(ρ2+1)−0.480, 7+4×30.5]
when the value of a smaller one of (0.234×(ρ1+1)×(ρ2+1)−0.480) and (7+4×30.5) is min[0.234×(ρ1+1)×(ρ2+1)−0.480, 7+4×30.5].
In the traction drive mechanism according to the present invention, provided that N2=6,
ρ1≧0.25×(ρ1+1)×(ρ2+1)−1, and
ρ1≦min[0.278×(ρ1+1)×(ρ2+1)−0.603, 7+4×30.5]
when the value of a smaller one of (0.278×(ρ1+1)×(ρ2+1)−0.603) and (7+4×30.5) is min[0.278×(ρ1+1)×(ρ2+1)−0.603, 7+4×30.5].
In one aspect of the present invention, it is preferable that the second sun roller is coupled to the first carrier and that the rotations of the first and second ring rollers are constrained.
According to the present invention, it is possible to reduce vibrations and noise resulting from the repeated diametrical deformation of the first and second ring rollers, and also increase the speed change ratio of the whole traction drive mechanism without the increase in size of the structure of the traction drive mechanism.
Hereinafter, a mode for carrying out the present invention (hereinafter referred to as an embodiment) will be described with reference to the drawings.
The planetary roller mechanism (first planetary roller mechanism) 12 has the ring roller (first ring roller) 22 in which an inner peripheral surface (first inner peripheral surface) 32 is formed, a sun roller (first sun roller) 21 disposed on the inner side (diametrically inner side) of the inner peripheral surface 32 of the ring roller 22, a plurality of pinion rollers (first planetary rollers) 23 which are arranged at intervals along the circumferential direction of the inner peripheral surface 32 of the ring roller 22 and which are each held (press-held) in contact between an outer peripheral surface 31 of the sun roller 21 and an inner peripheral surface 32 of the ring roller 22, and a carrier (first carrier) 24 which rotatably supports each of the pinion rollers 23. The pinion rollers 23 are arranged at equal intervals (or at substantially equal intervals) in the circumferential direction of the inner peripheral surface 32 of the ring roller 22. The central axes (axis lines) of the sun roller 21, the ring roller 22, and the carrier 24 correspond to one another. The rotation central axis (axis line) of each of the pinion rollers 23 when rotating on its axis is parallel to the central axis of the ring roller 22.
The planetary roller mechanism (second planetary roller mechanism) 52 has the ring roller (second ring roller) 62 which is disposed at a distance in its axis line direction from the ring roller 22 and in which an inner peripheral surface (second inner peripheral surface) 72 is formed, a sun roller (second sun roller) 61 disposed on the inner side (diametrically inner side) of the inner peripheral surface 72 of the ring roller 62, a plurality of pinion rollers (second planetary rollers) 63 which are arranged at intervals along the circumferential direction of the inner peripheral surface 72 of the ring roller 62 and which are each held (press-held) in contact between an outer peripheral surface 71 of the sun roller 61 and the inner peripheral surface 72 of the ring roller 62, and a carrier (second carrier) 64 which rotatably supports each of the pinion rollers 63. The pinion rollers 63 are arranged at equal intervals (or at substantially equal intervals) in the circumferential direction of the inner peripheral surface 72 of the ring roller 62. The central axes (axis lines) of the sun roller 61, the ring roller 62, and the carrier 64 correspond to one another, and also correspond to the central axes (axis lines) of the sun roller 21, the ring roller 22, and the carrier 24. The rotation central axis (axis line) of each of the pinion rollers 63 when rotating on its axis is parallel to the central axis of the ring roller 62. In the example shown in
In the planetary roller mechanisms 12 and 52 (the traction drive mechanism 10), torque can be transmitted by the shearing force (tangential traction force) of oil films of the rollers generated by the application of press force (normal force) to a contact portion via the oil films. In the meantime, in torque transmission, it is necessary to apply press force (normal force) required for the torque transmission to each contact portion so that no excessive slip (gross slip) is generated in each contact portion. In the planetary roller mechanism 12, in order to apply press force (normal force) to a contact portion 27 between the outer peripheral surface 31 of the sun roller 21 and the outer peripheral surface 33 of each of the pinion rollers 23 and to a contact portion 28 between the outer peripheral surface 33 of each of the pinion rollers 23 and the inner peripheral surface 32 of the ring roller 22, the sun roller 21 and each of the pinion rollers 23 are fitted into the ring roller 22, for example, by shrinkage fitting or tight fitting, and an interference is generated in the planetary roller mechanism 12. The ring roller 22 is elastically deformed diametrically outward by the interference, and diametrical inward (toward the pinion rollers 23) elastic force (restoring force) is thereby generated. The ring roller 22 presses each of the pinion rollers 23 toward the sun roller 21 by the elastic force, and can thereby apply normal force to the contact portions 27 and 28. Similarly, in the planetary roller mechanism 52, the sun roller 61 and each of the pinion rollers 63 are fitted into the ring roller 62, for example, by shrinkage fitting or tight fitting, and an interference is generated in the planetary roller mechanism 52. Thereby, press force can be applied to a contact portion 67 between the outer peripheral surface 71 of the sun roller 61 and the outer peripheral surface 73 of each of the pinion rollers 63 and to a contact portion 68 between the outer peripheral surface 73 of each of the pinion rollers 63 and the inner peripheral surface 72 of the ring roller 62. It is also possible to provide a known press force applying mechanism to apply press force to the contact portions 27, 28, 67, and 68. The normal force is thus applied to the contact portions 27, 28, 67, and 68. Consequently, tangential traction force can be generated in the contact portions 27, 28, 67, and 68, and torque can be transmitted between the sun roller 21 and each of the pinion rollers 23, between each of the pinion rollers 23 and the ring roller 22, between the sun roller 61 and the pinion rollers 63, and between the pinion rollers 63 and the ring roller 62.
An interference a1 generated in the planetary roller mechanism 12 is represented by Equation (1) below in which ds1 is the outer diameter of the sun roller 21 (the outer peripheral surface 31), dp1 is the outer diameter of the pinion roller 23 (the outer peripheral surface 33), and dr1 is the inner diameter of the ring roller 22 (the inner peripheral surface 32). Similarly, an interference a2 generated in the planetary roller mechanism 52 is represented by Equation (2) below in which ds2 is the outer diameter of the sun roller 61 (the outer peripheral surface 71), dp2 is the outer diameter of the pinion roller 63 (the outer peripheral surface 73), and dr2 is the inner diameter of the ring roller 62 (the inner peripheral surface 72).
a1=(ds1+2×dp1−dr1)/2 (1)
a2=(ds2+2×dp2−dr2)/2 (2)
The traction drive mechanism 10 according to the present embodiment can be used as a speed changing mechanism. In the example shown in
In the traction drive mechanism 10 functioning as the speed reducing mechanism, a theoretical speed change ratio (reduction ratio) e1 of the planetary roller mechanism 12 from the sun roller 21 to the carrier 24 when no slip is assumed to be generated in the contact portions 27 and 28 is represented by Equation (3) below that uses the outer diameter ds1 of the sun roller 21 (the outer peripheral surface 31) and the inner diameter dr1 of the ring roller 22 (the inner peripheral surface 32). A theoretical speed change ratio (reduction ratio) e2 of the planetary roller mechanism 52 from the sun roller 61 to the carrier 64 when no slip is assumed to be generated in the contact portions 67 and 68 is represented by Equation (4) below that uses the outer diameter ds2 of the sun roller 61 (the outer peripheral surface 71) and the inner diameter dr2 of the ring roller 62 (the inner peripheral surface 72). A theoretical total speed change ratio (total reduction ratio) e0 of the traction drive mechanism 10 from the sun roller 21 to the carrier 64 when no slip is assumed to be generated in the contact portions 27, 28, 67, and 68 is represented by Equation (5) below. However, slight slip is generated in the contact portions 27, 28, 67, and 68 during torque transmission. Therefore, strictly speaking, there is a small difference of the slight slipping between an actual speed change ratio (reduction ratio) and the theoretical speed change ratio (total reduction ratio).
e1=dr1/ds1+1 (3)
e2=dr2/ds2+1 (4)
e0=e1×e2=(dr1/ds1+1)×(dr2/ds2+1) (5)
In the planetary roller mechanism 12, when press force is applied to the contact portions 27 and 28, the ring roller 22 is subjected to the reaction force from each of the pinion rollers 23, for example, as shown in
A diametrical vibration displacement r1 at a circumferential position θ of the ring roller 22 and a diametrical vibration displacement r2 at a circumferential position θ of the ring roller 62 are both represented by sinusoidal waves, and are respectively represented by Equations (6) and (7) below. In Equations (6) and (7), a1 is an interference (see Equation (1)) in the planetary roller mechanism 12, a2 is an interference (see Equation (2)) in the planetary roller mechanism 52, ω1 is the rotation speed of the carrier 24, ω2 is the rotation speed of the carrier 64, and t is time.
r1=a1×cos (ω1×t+θ) (6)
r2=a2×cos (ω2×t+θ) (7)
The rotation speed ω1 of the carrier 24 and the rotation speed ω2 of the carrier 64 are respectively represented by Equations (8) and (9) below. In Equations (8) and (9), ωin is the rotation speed (input rotation speed) of the sun roller 21, N1 is the number of the pinion rollers 23 arranged along the circumferential direction, N2 is the number of the pinion rollers 63 arranged along the circumferential direction, e1 is the speed change ratio (see Equation (3)) of the planetary roller mechanism 12 from the sun roller 21 to the carrier 24, and e2 is the speed change ratio (see Equation (4)) of the planetary roller mechanism 52 from the sun roller 61 to the carrier 64.
ω1=ωin×N1/e1 (8)
ω2=ωin×N2/(e1×e2) (9)
A diametrical vibration speed v1 at a circumferential position θ of the ring roller 22 and a diametrical vibration speed v2 at a circumferential position θ of the ring roller 62 are respectively represented by Equations (10) and (11) below in accordance with the time derivative of Equations (6) and (7).
v1=−a1×ω1×sin (ω1×t+θ) (10)
v2=−a2×ω2×sin (ω2×t+θ) (11)
Vibration power P0 of the ring rollers 22 and 62 is calculated by integrating, over the circumferences of the ring rollers 22 and 62, the sum (m1×v1+m2×v2) of the product m1×v1 of a mass m1 and a speed v1 per unit θ at a circumferential position θ of the ring roller 22 and the product m2×v2 of a mass m2 and a speed v2 per unit θ at a circumferential position θ of the ring roller 62. The vibration power P0 is represented by Equation (12) below. In Equation (12), M1 is the mass of the ring roller 22, and M2 is the mass of the ring roller 62. As represented by Equation (12), the vibration power P0 of the ring rollers 22 and 62 varies with a reduction ratio e1 of the planetary roller mechanism 12 (the ratio ρ1 between the inner diameter dr1 of the ring roller 22 and the outer diameter ds1 of the sun roller 21), the masses M1 and M2 of the ring rollers 22 and 62, the interferences a1 and a2 in the planetary roller mechanisms 12 and 52, and the numbers N1 and N2 of the pinion rollers 23 and 63. In order to lower the levels of vibration and noise resulting from the repeated deformation of the ring rollers 22 and 62, it is preferable to reduce the vibration power P0 represented by Equation (12).
[Expression 1]
An example of a method of designing the planetary roller mechanisms 12 and 52 (the masses M1 and M2 of the ring rollers 22 and 62, and the interferences a1 and a2 in the planetary roller mechanisms 12 and 52) is shown in a flowchart in
Fs1=Ts1/(μ×ds1×N1) (13)
Fs2=Ts2/(μ×ds2×N2) (14)
In step S103, the axial lengths (the lengths of the contact portions 27, 28, 67, and 68 in the axis line direction) of the sun rollers 21 and 61, the pinion rollers 23 and 63, and the ring rollers 22 and 62 are then calculated relative to the surface pressures Ps1 and Ps2 (constant values) in the given contact portions 27 and 67, and the masses M1 and M2 of the ring rollers 22 and 62 are calculated. In the example shown in
However, the reduction ratio e1 obtainable in the planetary roller mechanism 12 is limited to a range lower than an upper limit value corresponding to the number N1 of the pinion rollers 23 so that the pinion rollers 23 arranged along the circumferential direction do not interfere with one another. This also holds true with the planetary roller mechanism 52. More specifically, the reduction ratio e2 obtainable in the planetary roller mechanism 52 is limited to a range lower than an upper limit value λN2 represented by Equation (15) below. That is, the ratio ρ2 (=dr2/ds2) between the inner diameter dr2 of the ring roller 62 and the outer diameter ds2 of the sun roller 61 is limited to a range lower than an upper limit value (λN2−1). For example, λN2=8+4×30.5≈14.93 when N2=3, λN2=4+2×20.5≈6.83 when N2=4, λN2=4.85 when N2=5, and λN2=4.0 when N2=6.
λN2=(1+sin (π/N2))/(1−sin (π/N2))+1 (15)
According to Nonpatent document 1 in which four pinion rollers are arranged along the circumferential direction, the reduction ratio ranging from the sun roller to the carrier when the ring roller is fixed is limited to a range lower than the upper limit value (4+2×20.5)≈6.83 in accordance with Equation (15), and a reduction ratio equal to or greater than the upper limit value (4+2×20.5) cannot be obtained. Even when the first planetary roller mechanism and the second planetary roller mechanism are connected in series in two stages as in Patent documents 1 and 2 to further increase the reduction ratio, the reduction ratio ranging from the sun roller of the first planetary roller mechanism to the carrier of the second planetary roller mechanism is limited to a range lower than the upper limit value (4+2×20.5)2=(24+16×20.5)≈46.6, and a reduction ratio equal to or greater than this upper limit value (24+16×20.5) cannot be obtained. In the traction drive mechanism 10 according to the present embodiment, the carrier 24 of the planetary roller mechanism 12 is coupled to the sun roller 61 of the planetary roller mechanism 52, and the planetary roller mechanisms 12 and 52 are connected in series in two stages to increase the total reduction ratio e0. Meanwhile, in order to obtain a high total reduction ratio e0 greater than (24+16×20.5) which cannot be obtained by N1=N2=4, it is necessary to reduce one or more of the numbers N1 and N2 of the pinion rollers 23 and 63 to three or less. However, if the number of the pinion rollers is reduced to three or less, the vibration power P0 represented by Equation (12) is easily increased by the increase of the product of the interference of the planetary roller mechanism and the number of the pinion rollers, as shown in
As shown in
As shown in
As shown in
Accordingly, even when one or more of the products a1×N1 and a2×N2 that have an influence on the vibration power P0 are increased by decreasing one of more of the numbers N1 and N2 of the pinion rollers 23 and 63 to three in order to obtain a high total reduction ratio e0 greater than (24+16×20.5) which cannot be obtained by N1=N2=4, the noise level (vibration power P0) can be reduced by adjusting the reduction ratio e1 of the planetary roller mechanism 12. Moreover, the minimal value of the noise level can be lower when at least the number N1 of the pinion rollers 23 of the planetary roller mechanism 12 is reduced to three than when the number N2 of the pinion rollers 63 of the planetary roller mechanism 52 is reduced to three. In addition, if the number N2 of the pinion rollers 63 of the planetary roller mechanism 52 is increased to reduce the interference a2, the minimal value of the noise level can be further reduced. However, if the number N2 of the pinion rollers 63 is increased to seven or more, the decrease rate of the interference a2 is lower than the increase rate of the number N2 of the pinion rollers 63. As a result, the product a2×N2 that has an influence on the vibration power P0 is increased, and the reduction effect of the vibration power P0 resulting from the increase of the number N2 of the pinion rollers 63 cannot be obtained. Thus, according to the present embodiment, the number N1 of the pinion rollers 23 arranged along the circumferential direction is set to three, and the number N2 of the pinion rollers 63 arranged along the circumferential direction is set to three or more and six or fewer.
A human being can hardly perceive a change in noise level of about 1 dB. Thus, according to the present embodiment, the reduction ratio e1 of the planetary roller mechanism 12 is set to a range in which the noise level (vibration power P0) varies from the minimal value to +1 dB, relative to the set numbers N1 and N2 of the pinion rollers 23 and 63. The range of the reduction ratio e1 of the planetary roller mechanism 12 is described below.
In the case shown in.
In the case shown in
When N1=3 and N2=5, the range of the first-stage reduction ratio e1 in which the noise level varies from the minimal value to +1 dB or less has a lower limit value of 10.31 and an upper limit value of 12.26 provided that e0=50 as shown in
When N1=3 and N2=6, the range of the first-stage reduction ratio e1 in which the noise level varies from the minimal value to +1 dB or less has a lower limit value of 12.50 and an upper limit value of 14.19 provided that e0=50 as shown in
When N1=3 and N2=3, the range of the shaded portion in
e0≧24+16×20.5 (16)
e1≧0.102×e0+2.196 (17)
e1≦min[0.204×e0+4.123, 8+4×30.5] (18)
Equations (16) to (18) can be transformed into Equations (19) to (21) below by using the ratio ρ1 (=dr1/ds1) between the inner diameter dr1 of the ring roller 22 and the outer diameter ds1 of the sun roller 21 and the ratio ρ2 (=dr2/ds2) between the inner diameter dr2 of the ring roller 62 and the outer diameter ds2 of the sun roller 61. However, in Equation (21), min[0.204×(ρ1+1)×(ρ2+1)+3.123, 7+4×30.5] indicates the value of a smaller one of (0.204×(ρ1+1)×(ρ2+1)+3.123) and (7+4×30.5). If (ρ1+1)×(ρ2+1)≦53.0, then ρ1≦0.204×(ρ1+1)×(ρ2+1)+3.123. If (ρ1+1)×(ρ2+1)>53.0, then ρ1≦7+4×30.5.
(ρ1+1)×(ρ2+1)≧24+16×20.5 (19)
ρ1≧0.102×(ρ1+1)×(ρ2+1)+1.196 (20)
ρ1≦min[0.204×(ρ1+1)×(ρ2+1)+3:123, 7+4×30.5] (21)
In the traction drive mechanism 10 according to the present embodiment, when N1=3 and N2=3, ρ1 and ρ2 (e1 and e2) are set to ranges that satisfy Equations (19) to (21) (Equations (16) to (18)) so that the noise level varies from the minimal value to +1 dB or less. This makes it possible to reduce the noise level (vibration power P0), and also obtain a high total reduction ratio e0 greater than (24+16×20.5) which cannot be obtained by N1=N2=4. When N1=3 and N2=3, the maximal value of the total reduction ratio e0 is 124.8.
A broken line in
e1=0.146×e0+2.890 (22)
ρ1=0.146×(ρ1+1)×(ρ2+1)+1.890 (23)
When N1=3 and N2=4, the range of the shaded portion in
e1≧(2−20.5)×e0/4 (24)
e1≦min[0.185×e0+2.320, 8+4×30.5] (25)
Equations (24) and (25) can be transformed into Equations (26) and (27) below. However, in Equation (27), min[0.185×(ρ1+1)×(ρ2+1)+1.320, 7+4×30.5] indicates the value of a smaller one of (0.185×(ρ1+1)×(ρ2+1)+1.320) and (7+4×30.5). If (ρ1+1)×(ρ2+1)≦68.2, then ρ1≦0.185×(ρ1+1)×(ρ2+1)+1.320. If (ρ1+1)×(ρ2+1)>68.2, then ρ1≦7+4×30.5.
ρ1≧(2−20.5)×(ρ1+1)×(ρ2+1)/4−1 (26)
ρ1≦min[0.185×(ρ1+1)×(ρ2+1)+1.320, 7+4×30.5] (27)
In the traction drive mechanism 10 according to the present embodiment, when N1=3 and N2=4, ρ1 and ρ2 (e1 and e2) are set to ranges that satisfy Equations (19), (26), and (27) (Equations (16), (24), and (25)). This again makes it possible to reduce the noise level (vibration power P0), and also obtain a high total reduction ratio e0 greater than (24+16×20.5) which cannot be obtained by N1=N2=4. When N1=3 and N2=4, the maximal value of the total reduction ratio e0 is 101.9.
A broken line in
e1=0.122×e0+2.488 (28)
ρ1=0.122×(ρ1+1)×(ρ2+1)+1.488 (29)
When N1=3 and N2=5, the range of the shaded portion in
e1≧0.206×e0 (30)
e1≦min[0.234×e0+0.520, 8+4×30.5] (31)
Equations (30) and (31) can be transformed into Equations (32) and (33) below. However, in Equation (33), min[0.234×(ρ1+1)×(ρ2+1)−0.480, 7+4×30.5] indicates the value of a smaller one of (0.234×(ρ1+1)×(ρ2+1)−0.480) and (7+4×30.5). If (ρ1+1)×(ρ2+1)>61.6, then ρ1≦0.234×(ρ1+1)×(ρ2+1)−0.480. If (ρ1+1)×(ρ21+1)>61.6, then ρ1≦7+4×30.5.
ρ1≧0.206×(ρ1+1)×(ρ2+1)−1 (32)
ρ1≦min[0.234×(ρ1+1)×(ρ2+1)−0.480, 7+4×30.5] (33)
In the traction drive mechanism 10 according to the present embodiment, when N1=3 and N2=5, ρ1 and ρ2 (e1 and e2) are set to ranges that satisfy Equations (19), (32), and (33) (Equations (16), (30), and (31)). This again makes it possible to reduce the noise level (vibration power P0), and also obtain a high total reduction ratio e0 greater than (24+16×20.5) which cannot be obtained by N1=N2=4. When N1=3 and N2=5, the maximal value of the total reduction ratio e0 is 72.4.
Furthermore, when N1=3 and N2=5, the noise level decreases from the upper limit to the lower limit of the shaded portion in
When N1=3 and N2=6, the range of the shaded portion in
e1≧0.25×e0 (34)
e1≦min[0.278×e0+0.397, 8+4×30.5] (35)
Equations (34) and (35) can be transformed into Equations (36) and (37) below. However, in Equation (37), min[0.278×(ρ1+1)×(ρ2+1)−0.603, 7+4×30.5] indicates the value of a smaller one of (0.278×(ρ1+1)×(ρ2+1)−0.603) and (7+4×30.5). If (ρ1+1)×(ρ2+1)≦52.3, then ρ1≦0.278×(ρ1+1)×(p2+1)−0.603. If (ρ1+1)×(ρ2+1)>52.3, then ρ1≦7+4×30.5.
ρ1≧0.25×(ρ1+1)×(ρ2+1)−1 (36)
ρ1≦min[0.278×(ρ1+1)×(ρ2+1)−0.603, 7+4×30.5] (37)
In the traction drive mechanism 10 according to the present embodiment, when N1=3 and N2=6, ρ1 and ρ2 (e1 and e2) are set to ranges that satisfy Equations (19), (36), and (37) (Equations (16), (34), and (35)). This again makes it possible to reduce the noise level (vibration power P0), and also obtain a high total reduction ratio e0 greater than (24+16×20.5) which cannot be obtained by N1=N2=4. When N1=3 and N2=6, the maximal value of the total reduction ratio e0 is 59.7.
Furthermore, when N1=3 and N2=6, the noise level decreases from the upper limit to the lower limit of the shaded portion in
As described above, according to the present embodiment, it is possible to reduce vibrations and noise resulting from the repeated diametrical deformation of the ring rollers 22 and 62, and also increase the total reduction ratio e0 of the whole traction drive mechanism 10 without an increase in size of the structure of the traction drive mechanism 10.
According to the present embodiment, it is also possible to fix the carrier 24 and the ring roller 62 to the casing 20 to constrain their rotations, and mechanically couple the ring roller 22 to the sun roller 61 to transmit power between the sun roller 21 and the carrier 64 with reduced speed (transmit power from the sun roller 21 to the carrier 64 with reduced speed). It is also possible to fix the ring roller 22 and the carrier 64 to the casing 20 to constrain their rotations, and mechanically couple the carrier 24 to the sun roller 61 to transmit power between the sun roller 21 and the ring roller 62 with reduced speed (transmit power from the sun roller 21 to the ring roller 62 with reduced speed). It is also possible to fix the carriers 24 and 64 to the casing 20 to constrain their rotations, and mechanically couple the ring roller 22 to the sun roller 61 to transmit power between the sun roller 21 and the ring roller 62 with reduced speed (transmit power from the sun roller 21 to the ring roller 62 with reduced speed).
While the mode for carrying out the present invention has been described above, the present invention is not in the least limited to such a mode. It should be understood that various modes can be carried out without departing from the spirit of the present invention.
[Description of Reference Numbers]
10: traction drive mechanism, 12 and 52: planetary roller mechanisms, casing 21 and 61: sun rollers, 22 and 62: ring rollers, 23 and 63: pinion rollers, 24 and 64: carriers, 27, 28, 67, and 68: contact portions.
Number | Date | Country | Kind |
---|---|---|---|
2010-167150 | Jul 2010 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2011/064649 | 6/27/2011 | WO | 00 | 1/18/2013 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2012/014611 | 2/2/2012 | WO | A |
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5435794 | Mori et al. | Jul 1995 | A |
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6461265 | Graham et al. | Oct 2002 | B1 |
20120196720 | Miyawaki et al. | Aug 2012 | A1 |
Number | Date | Country |
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A-50-22970 | Mar 1975 | JP |
58099549 | Jun 1983 | JP |
A-61-74952 | Apr 1986 | JP |
U-61-96040 | Jun 1986 | JP |
A-5-332413 | Dec 1993 | JP |
A-7-54946 | Feb 1995 | JP |
B-7-21303 | Mar 1995 | JP |
A-9-42398 | Feb 1997 | JP |
A-2007-71248 | Mar 2007 | JP |
Entry |
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Kawano, “Planetary Roller Type Traction Drive Unit for Printing Machine,” Koyo Engineering Journal, 2004, pp. 60-64, No. 165. |
International Search Report issued in International Application No. PCT/JP2011/064649 dated Aug. 23, 2011 (w/translation). |
Japanese Office Action issued in Japanese Patent Application No. 2010-167150 on Mar. 12, 2013 (with translation). |
Number | Date | Country | |
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20130123059 A1 | May 2013 | US |