1. Field of the Invention
The field of the invention relates generally to transmissions, and more particularly to methods, assemblies, and components for continuously variable transmissions (CVTs).
2. Description of the Related Art
There are well-known ways to achieve continuously variable ratios of input speed to output speed. Typically, a mechanism for adjusting the speed ratio of an output speed to an input speed in a CVT is known as a variator. In a belt-type CVT, the variator consists of two adjustable pulleys coupled by a belt. The variator in a single cavity toroidal-type CVT usually has two partially toroidal transmission discs rotating about a shaft and two or more disc-shaped power rollers rotating on respective axes that are perpendicular to the shaft and clamped between the input and output transmission discs. It is generally necessary to have a control system for the variator so that the desired speed ratio can be achieved in operation.
Embodiments of the variator disclosed herein include spherical-type variators utilizing spherical speed adjusters (also known as power adjusters, balls, planets, sphere gears or rollers) that each has a tiltable axis of rotation adapted to be adjusted to achieve a desired ratio of output speed to input speed during operation. The speed adjusters are angularly distributed in a plane perpendicular to a longitudinal axis of a CVT. The speed adjusters are contacted on one side by an input disc and on the other side by an output disc, one or both of which apply a clamping contact force to the rollers for transmission of torque. The input disc applies input torque at an input rotational speed to the speed adjusters. As the speed adjusters rotate about their own axes, the speed adjusters transmit the torque to the output disc. The output speed to input speed ratio is a function of the radii of the contact points of the input and output discs to the axes of the speed adjusters. Tilting the axes of the speed adjusters with respect to the axis of the variator adjusts the speed ratio.
There is a continuing need in the industry for variators and control systems therefor that provide improved performance and operational control. Embodiments of the systems and methods disclosed here address said need.
The systems and methods herein described have several features, no single one of which is solely responsible for its desirable attributes. Without limiting the scope as expressed by the claims that follow, its more prominent features will now be discussed briefly. After considering this discussion, and particularly after reading the section entitled “Detailed Description of Certain Inventive Embodiments” one will understand how the features of the system and methods provide several advantages over traditional systems and methods.
One aspect of the invention relates to a method of controlling a transmission having a group of traction planets. The method includes the steps of providing each traction planet with a planet axle and imparting a skew angle to each planet axle. In one embodiment, the method can also include the step of tilting each planet axle.
Another aspect of the invention concerns a method of facilitating control of the speed ratio of a continuously variable transmission (CVT). The method can include the steps of providing a group of traction planets and providing each of the traction planets with a planet axle. Each traction planet can be configured to rotate about a respective planet axle. In one embodiment, the method includes providing a first carrier plate configured to engage a first end of each of the planet axles. The first carrier plate can be mounted along a longitudinal axis of the CVT. The method can include the step of providing a second carrier plate configured to engage a second end of each of the planet axles. The second carrier plate can be mounted coaxially with the first carrier plate. The method can also include the step of arranging the first carrier plate relative to the second carrier plate such that during operation of the CVT the first carrier plate can be rotated, about the longitudinal axis, relative to the second carrier plate.
Yet another aspect of the invention concerns a transmission having a set of traction planets arranged angularly about a longitudinal axis of the transmission. In one embodiment, the transmission has a set of planet axles. Each planet axle can be operably coupled to each traction planet. Each planet axle can define a tiltable axis of rotation for each traction planet. Each planet axle can be configured for angular displacement in first and second planes. The transmission can have a first carrier plate operably coupled to a first end of each planet axle. The first carrier plate can be mounted about the longitudinal axis. The transmission can also have a second carrier plate operably coupled to a second end of each planet axle. The second carrier plate can be mounted about the longitudinal axis. The first and second carrier plates are configured to rotate, about the longitudinal axis, relative to each other.
One aspect of the invention concerns a control system for a continuously variable transmission (CVT) having a set of traction planets with tiltable axes of rotation. The control system includes a control reference source configured to provide a control reference indicative of a desired operating condition of the CVT. In one embodiment, the control system also includes a skew dynamics module operably coupled to the control reference source. The skew dynamics module can be configured to determine an adjustment in the tiltable axes of rotation based at least in part on a skew angle value.
Another aspect of the invention concerns a method of controlling a continuously variable transmission (CVT) having a group of traction planets. Each traction planet having a planet axle about which the traction planet rotates. The method includes the steps of providing a control reference indicative of a desired operating condition of the CVT and determining a skew angle based at least in part on the desired operating condition of the CVT. In one embodiment, the method includes the step of applying the skew angle to each of the planet axles.
Yet one more aspect of the invention addresses a method of controlling a continuously variable transmission (CVT) having a group of traction planets with tiltable axes of rotation. The method includes the steps of providing a control reference indicative of a desired operating condition of the CVT and sensing a current operating condition of the CVT. In one embodiment, the method includes the step of comparing the desired operating condition with the current operating condition thereby generating a control error. The method also includes the step of imparting a skew angle to each of the tiltable axes. The skew angle is based at least in part on the control error.
In another aspect, the invention concerns a method of controlling a continuously variable transmission (CVT) having a group of traction planets arranged angularly about a longitudinal axis of the CVT, each traction planet mounted on a planet axle that defines a tiltable axis of rotation. The CVT can have a traction sun in contact with each of the traction planets. The traction sun can be configured to translate axially. The method includes the step of coupling the traction sun to a sun position locker. The sun position locker can be configured to retain the traction sun at an axial position. In one embodiment, the method includes the step of providing a skew angle coordinator that can be operably coupled to the traction planets and to the traction sun. The skew angle coordinator can be configured to adjust a tilt angle of the planet axles.
Another aspect of the invention relates to a control system for a transmission having a traction sun and a set of traction planets each having a tiltable axis of rotation. The control system has a control reference source configured to provide a control reference indicative of a desired operating condition of the transmission. In one embodiment, the control system has a feedback source configured to provide a feedback indicative of a current operating condition of the transmission. The control system can have a sun position locker operably coupled to the traction sun. The sun position locker can be configured to selectively hold an axial position of the traction sun. The control system can have a skew angle coordinator operably coupled to the traction planets. The control system can also have a decision process module configured to compare the control reference to the feedback. The decision process module can be configured to generate a signal based at least in part on the comparison. The signal is configured to be passed to the sun position locker and to the skew angle coordinator.
One aspect of the invention relates to a control system for a transmission having a traction sun and a group of traction planets operably coupled to a carrier plate and to the traction sun. The control system includes a control reference nut mounted coaxially with a longitudinal axis of the CVT. In one embodiment, the control system includes a feedback cam operably coupled to the control reference nut and to the traction sun. The feedback cam can be positioned coaxially with the control reference nut. The carrier plate is positioned coaxially with the feedback cam. The control system also includes a skew cam coupled to the feedback cam and to the carrier plate. The skew cam can be configured to rotate the carrier plate about the longitudinal axis.
Another aspect of the invention concerns a method for controlling a continuously variable transmission (CVT). The method includes the steps of providing a skew-based control system and operably coupling a neutralizer assembly to the skew-based control system. The neutralizer assembly can be configured to balance a group axial forces that are generated in the CVT during operation.
Yet another aspect of the invention involves a method of controlling a continuously variable transmission (CVT) having a traction sun and a group of traction planets each having a tiltable axis of rotation. The method includes the step of sensing an axial force imparted on the traction sun during operation of the CVT. In on embodiment, the method also includes the step of supplying a force of equal magnitude and of opposite direction of the axial force. The force can be configured to be operably applied to the traction sun.
One aspect of the invention concerns a neutralizer assembly for a continuously variable transmission having a skew-based control system. The neutralizer assembly can have a first resistance member configured to generate a force in a first axial direction. In one embodiment, the neutralizer assembly has a second resistance member configured to generate a force in a second axial direction. The neutralizer assembly can also have a translating resistance cap operably coupled to the skew-based control system. The translating resistance cap can be configured to separately engage each of the first and the second resistance members.
Another aspect of the invention relates to a feedback cam for a skew-based control system. The feedback cam has a generally elongated cylindrical body having a first end and a second end. In one embodiment, the feedback cam has a bearing race located on the first end. The feedback cam can have a threaded portion located on the first end. The feedback cam can also have a splined portion located on the second end.
Yet one more aspect of the invention addresses a skew cam for a continuously variable transmission (CVT) having a skew-based control system. The skew cam has a generally elongated cylindrical body having a first end and a second end. In one embodiment, the skew cam has a first threaded portion located in proximity to the first end. The skew cam can have a second threaded portion located in proximity to the second end. The first threaded portion has a lead that is smaller than a lead of the second threaded portion.
In another aspect, the invention concerns a carrier plate for a continuously variable transmission (CVT) having a skew-based control system and a group of traction planets. The carrier plate includes a generally cylindrical plate and a set of concave surfaces formed on a face of the cylindrical plate. The concave surfaces are adapted to operably couple to each of the traction planets. In one embodiment, the carrier plate includes a threaded central bore configured to operably couple to the skew-based control system. The carrier plate can also have a reaction face coaxial with the central bore. The reaction face can be configured to operably couple to the skew-based control system.
Another aspect of the invention relates to a leg assembly for a continuously variable transmission (CVT) having a skew-based control system. The leg assembly includes a leg having an elongated body with a first end and a second end. The leg has a first bore formed on the first end and a second bore formed in proximity to the first end. The second bore can have first and second clearance bores. The second bore can be substantially perpendicular to the first bore. The leg assembly can also include a shift guide roller axle operably coupled to the second bore. The shift guide roller axle can be adapted to pivot in the second bore.
One aspect of the invention relates to a leg for a continuously variable transmission (CVT) having a skew-based control system. The leg has an elongated body having a first end and a second end. In one embodiment, the leg has a first bore formed on the first end and a second bore formed in proximity to the first end. The second bore can have first and second clearance bores. The second bore can be substantially perpendicular to the first bore. The leg can also have a third clearance bore formed between the first and second clearance bores. The third clearance bore can be configured to provide a pivot location for a shift guide roller axle of the CVT.
Another aspect of the invention concerns a transmission having a longitudinal axis. In one embodiment, the transmission includes a traction sun that is coaxial with the longitudinal axis. The traction sun can be configured to translate axially. The transmission can have first and second carrier plates that are coaxial with the longitudinal axis. The traction sun is positioned between the first and second carrier plates. The transmission can have a planetary gear set operably coupled to a control reference input source. In one embodiment, the transmission has a feedback cam operably coupled to the planetary gear set and to the traction sun. The transmission can have a skew cam operably coupled to the planetary gear set and to the first carrier plate. The transmission can also have first and second resistance members operably coupled to the skew cam. The first carrier is configured to be rotatable with respect to the second carrier plate.
Yet another aspect of the invention involves a control reference assembly for a continuously variable transmission (CVT) having a skew-based control system. The control reference assembly includes a control reference nut. The control reference assembly can include first and second resistance members coupled to the control reference nut. In one embodiment, the control reference assembly includes an intermediate reaction member coupled to the first and second resistance members. The intermediate reaction member can be located coaxially with, and radially inward of, the control reference nut. A rotation of the control reference nut in a first direction energizes the first resistance member. A rotation of the control reference nut in a second direction energizes the second resistance member.
One aspect of the invention concerns a control reference assembly for a continuously variable transmission (CVT) having a skew-based control system. The control reference assembly has a control reference nut. The control reference assembly can have first and second resistance members coupled to the control reference nut. In one embodiment, the control reference assembly includes a pulley operably coupled to the control reference nut. The control reference assembly can have first and second cables each coupled to the control reference nut and to the pulley. The control reference assembly can also have a spring retention member coupled to the pulley and to the first and second resistance members. A rotation of the control reference nut in a first direction unwinds the first cable from the pulley. A rotation of the control reference nut in a second direction unwinds the second cable from the pulley.
Another aspect of the invention relates to a transmission having a carrier plate mounted coaxial with a longitudinal axis of the transmission. In one embodiment, the transmission includes a group of traction planets arranged angularly about the longitudinal axis. The transmission can include a planet axle operably coupled to each traction planet. The planet axle defines a tiltable axis of rotation. The transmission can include a planet support trunnion coupled to a respective planet axle. The planet support trunnion can have an eccentric skew cam configured to couple to the carrier plate. The transmission can also include a sleeve coupled to each planet support trunnion. The sleeve can be configured to axially translate. The sleeve can be configured to rotate. A rotation of the sleeve imparts a skew angle to each of the planet axles.
Yet one more aspect of the invention addresses a torque governor for a continuously variable transmission (CVT) having a set of traction planets with tiltable axes of rotation. The torque governor includes a carrier plate mounted coaxial with a longitudinal axis of the CVT. In one embodiment, the torque governor includes a shift cam operably coupled to the carrier plate. The shift cam can have a threaded extension. The torque governor includes a first reaction arm coupled to the shift cam. The first reaction arm can be operably coupled to the carrier plate. The first reaction arm is coaxial with the longitudinal axis. The torque governor also includes a second reaction arm operably coupled to the first reaction arm. The first and second reaction arms are configured to rotate the carrier plate during operation of the CVT.
In another aspect, the invention concerns a method of adjusting a speed ratio of a continuously variable transmission (CVT) having a group of traction planets configured angularly about a longitudinal axis of the CVT. Each traction planet is mounted on a planet axle that defines a tiltable axis of rotation for a respective traction planet. The method includes the step of imparting a skew angle to each planet axle.
Another aspect of the invention relates to a method of adjusting a speed ratio of a continuously variable transmission (CVT) having a group of traction planet configured angularly about a longitudinal axis of the CVT. Each traction planet has a tiltable axis of rotation. The method includes the step of imparting a skew angle to each tiltable axis of rotation.
The preferred embodiments will be described now with reference to the accompanying figures, wherein like numerals refer to like elements throughout. The terminology used in the descriptions below is not to be interpreted in any limited or restrictive manner simply because it is used in conjunction with detailed descriptions of certain specific embodiments of the invention. Furthermore, embodiments of the invention can include several novel features, no single one of which is solely responsible for its desirable attributes or which is essential to practicing the inventions described. Certain CVT embodiments described here are generally related to the type disclosed in U.S. Pat. Nos. 6,241,636; 6,419,608; 6,689,012; 7,011,600; 7,166,052; U.S. patent application Ser. Nos. 11/243,484 and 11/543,311; and Patent Cooperation Treaty patent application PCT/IB2006/054911 filed Dec. 18, 2006. The entire disclosure of each of these patents and patent applications is hereby incorporated herein by reference.
As used here, the terms “operationally connected,” “operationally coupled”, “operationally linked”, “operably connected”, “operably coupled”, “operably linked,” and like terms, refer to a relationship (mechanical, linkage, coupling, etc.) between elements whereby operation of one element results in a corresponding, following, or simultaneous operation or actuation of a second element. It is noted that in using said terms to describe inventive embodiments, specific structures or mechanisms that link or couple the elements are typically described. However, unless otherwise specifically stated, when one of said terms is used, the term indicates that the actual linkage or coupling may take a variety of forms, which in certain instances will be readily apparent to a person of ordinary skill in the relevant technology.
For description purposes, the term “radial” is used here to indicate a direction or position that is perpendicular relative to a longitudinal axis of a transmission or variator. The term “axial” as used here refers to a direction or position along an axis that is parallel to a main or longitudinal axis of a transmission or variator. For clarity and conciseness, at times similar components labeled similarly (for example, control piston 582A and control piston 582B) will be referred to collectively by a single label (for example, control pistons 582).
It should be noted that reference herein to “traction” does not exclude applications where the dominant or exclusive mode of power transfer is through “friction.” Without attempting to establish a categorical difference between traction and friction drives here, generally these may be understood as different regimes of power transfer. Traction drives usually involve the transfer of power between two elements by shear forces in a thin fluid layer trapped between the elements. The fluids used in these applications usually exhibit traction coefficients greater than conventional mineral oils. The traction coefficient (μ) represents the maximum available traction forces which would be available at the interfaces of the contacting components and is a measure of the maximum available drive torque. Typically, friction drives generally relate to transferring power between two elements by frictional forces between the elements. For the purposes of this disclosure, it should be understood that the CVTs described here may operate in both tractive and frictional applications. For example, in the embodiment where a CVT is used for a bicycle application, the CVT can operate at times as a friction drive and at other times as a traction drive, depending on the torque and speed conditions present during operation.
Embodiments of the invention disclosed here are related to the control of a variator and/or a CVT using generally spherical planets each having a tiltable axis of rotation that can be adjusted to achieve a desired ratio of input speed to output speed during operation. In some embodiments, adjustment of said axis of rotation involves angular misalignment of the planet axis in one plane in order to achieve an angular adjustment of the planet axis in a second plane, thereby adjusting the speed ratio of the variator. The angular misalignment in the first plane is referred to here as “skew” or “skew angle”. In one embodiment, a control system coordinates the use of a skew angle to generate forces between certain contacting components in the variator that will tilt the planet axis of rotation. The tilting of the planet axis of rotation adjusts the speed ratio of the variator. In the description that follows, a coordinate system is established with respect to the traction planet, followed by a discussion of certain kinematic relationships between contacting components that generate forces which tend to cause the planet axis to tilt in the presence of a skew angle. Embodiments of skew control systems for attaining a desired speed ratio of a variator will be discussed.
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Referring now to contact area 1 in
The kinematic relationships discussed above tend to generate forces at the contacting components.
As already mentioned, spin-induced forces can be generated at the contacting areas. The spin-induced forces tend to resist the skew-induced forces. During operation of a CVT, the spin-induced forces and the skew-induced forces can be reacted axially through the traction sun 110, and are sometimes referred to here as axial forces or side forces. Embodiments of the CVT 100 can be configured such that the planet axis 106 tilts when the skew-induced forces are larger than the spin-induced forces. In one embodiment of a CVT, under a steady state operating condition, the skew-induced forces and the spin-induced forces can balance each other, resulting in the CVT operating under a skew condition. To operate the CVT under a substantially zero skew angle, therefore, it is preferable to provide an auxiliary side force reaction acting on the traction sun 110; that is, in some embodiments of the CVT, the axial position of the traction sun 110 is constrained axially by a mechanism other than the skew-induced forces.
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For some applications, a linear relation between an axial translation of the traction sun 310 and the tilt angle 118 can be expressed as follows. Axial translation of the traction sun 310 is the mathematical product of the radius of the traction planets 308, the tilt angle 18 and a RSF (that is, axial translation of the traction sun 310=planet radius*tilt angle 118*RSF), where RSF is a roll-slide factor. RSF describes the transverse creep rate between the traction planet 308 and the traction sun 310. As used here, “creep” is the discrete local motion of a body relative to another and is exemplified by the relative velocities of rolling contact components as previously discussed. In traction drives, the transfer of power from a driving element to a driven element via a traction interface requires creep. Usually, creep in the direction of power transfer is referred to as “creep in the rolling direction.” Sometimes the driving and driven elements experience creep in a direction orthogonal to the power transfer direction, in such a case this component of creep is referred to as “transverse creep.” During operation of the CVT 301, the traction planet 308 and the traction sun 310 roll on each other. When the traction sun 310 is translated axially (that is, orthogonal to the rolling direction), transverse creep is imposed between the traction sun 310 and the traction planet 308. An RSF equal to 1.0 indicates pure rolling. At RSF values less than 1.0, the traction sun 310 translates slower than the traction planet 308 rotates. At RSF values greater than 1.0, the traction sun 310 translates faster than the traction planet 308 rotates.
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In this embodiment, a skew algorithm 400 includes a function 203 coupled to the skew dynamics module 202. The function 203 is configured to convert the carrier plate angle β into a skew angle ζ. The skew algorithm 400 receives the carrier plate angle β as input and returns a rate of change in tilt angle γ′. In one embodiment, an integrator 410 can be applied to the result of the skew dynamics module 202 to derive a tilt angle γ, which determines a speed ratio of a CVT. A speed ratio (SR) 420 can be derived from γ by a function 418 having as inputs the normal force FN and the rotational speed of the traction planet 108. The tilt angle γ can also be transformed into a feedback 404 by applying a gain (K4) 402. In some embodiments, the gain 402 is equal to the planet radius multiplied by the RSF (that is, K4=R*RSF). In one embodiment, the skew algorithm 400 is a transfer function based on the specific operating conditions of a CVT. In some applications, the skew algorithm 400 can take the form of a look up table that can be created by empirically determining γ′ for a given carrier plate angle β and operating conditions of a CVT. For example, tests can be performed on a specific CVT where the input operating condition is held at discrete speeds and loads appropriate for the intended application, while discrete steps in the carrier plate angle β can be applied to the system so that the speed ratio change of the CVT can be measured and used to calculate the resultant γ′. The resultant data characterizes the dynamic response of the system and can be formulated into a look-up table or function used for the skew algorithm 400.
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In one embodiment, the skew control system 207 includes two summing junctions 501 and 503. The first summing junction 501 produces the control error 408 based on a control reference 208 and two sources of feedback. A first feedback source can be the axial position of the traction sun 110, and the other feedback source can be the axial position of the skew cam 1068 (see
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The axial force 518 on the traction sun is reacted on the skew cam 1068 in some embodiments. In one embodiment, the axial force 518 is generated by spin-induced and skew-induced side forces at the contact area 3. The force 518 can be determined by the traction sun force algorithm 519 that is a function of, among other things, the normal force at contact 3 and the rotational speed ω of the traction planet 108, 308, or 1022. The forces just described are combined at the summing junction 503 and are used in the skew control system 207 for feedback to account for the steady state operating error that can exist in the skew angle ç. A steady state error in the skew angle ç can arise when operating the CVT 300 due to reacting the spin-induced side forces on the traction sun. In some embodiments, it is preferable for optimal efficiency of a CVT to generally operate with a skew angle ç equal to zero when a change in speed ratio is not desired. The embodiment of a skew control system shown in
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In one embodiment, the state of the traction sun position locker is based on a result from a decision process 532 that compares the control error 408 with an upper and lower limit for the error. If the control error 408 is within the limits set in the decision process 532, the positive or true result from the process 532 is sent to the traction sun position locker 530, which returns a command 531 to lock the traction sun at its current position. A positive or true result from the decision process 532 is also sent to a skew angle ç coordinator 534 that returns a command 536 to set the skew angle ç to an optimal skew angle çopt, which is some embodiments it means that the skew angle ç is zero. If the control error 408 is not within the limits of the decision process 532, a negative or false result is passed to the sun position locker 530, which returns a command 533 to unlock the traction sun. The false result is passed to the skew angle ç coordinator 534, which returns a command 537 that passes the control error 408 to, for example, a skew algorithm 400, to execute a change in the tilt angle γ. In this embodiment, the control error 408 can be determined by comparing a control reference 208 to a feedback 404. A control reference 408 can be a position, either angular or axial, a desired speed ratio, or any other relevant reference for operating a CVT 300.
The embodiments of a skew-based control system described previously can be used in conjunction with systems such as speed governors or torque governors, among others. In applications were it is desirable to maintain a constant input speed in the presence of a varying output speed, or vice versa, a mechanical, electrical, or hydraulic speed governor can be coupled to the shift nut or control reference in order to adjust the operating condition of the drive. In other applications, it might be desirable to maintain a constant input torque in the presence of a varying output torque, which is generally more challenging to implement with traditional controls systems. A skew control system, such control system 200 described here, can be coupled to a mechanism for controlling input torque in the presence of a varying output torque.
A CVT 1000 adapted to employ a skew-based control system related to those discussed above will now be described with reference to
The CVT 1000 includes carrier plates 1040, 1042 adapted to, among other things, support radially and axially an array of planet-leg assemblies 1044, which will be described further with reference to
Referring to
During operation, referencing
Adjustment in the speed ratio between the traction rings 1020, 1024, which adjustment results in the modulation of power flow through the CVT 1000, can be accomplished by tilting the axis of the planet axles 1046 relative to the longitudinal axis LA1. In the discussion that follows, mechanisms and methods for actuating and controlling a tilting of the planet axles 1046 will be described.
Referencing
To adjust a speed ratio of the CVT 1000, the reference input nut 1062 is turned to a selected position indicative of a desired speed ratio. If the axial forces (or, in other words, the clamping load provided by the axial force generators that yield a normal force at the contact) on the traction planets 1022 is relatively low or substantially zero, through the splined interface 1064 the reference input nut 1062 causes the feedback cam 1066 to rotate about the longitudinal axis LA1. Hence, when the clamp loads on the traction planets 1022 are relatively low, the skew cam 1068 tends not to translate. Consequently, the feedback cam 1066 is forced to translate axially as the feedback cam 1066 rotates about the axis LA1. The axial translation of the feedback cam 1066 causes an axial translation of the traction sun 1026 via thrust bearings 1078, 1080. Axial translation of the traction sun 1026 results in a tilting of the planet axles 1046 through the operational coupling between the traction sun 1026 and the planet axles 1046 via the shift cams 1056, 1058, shift cam rollers 1052, and legs 1050.
When the clamp loads on the traction planets 1022 are at, for example, average operating conditions, rotation of the reference input nut 1062 causes a rotation of the feedback cam 1066; however, under this operating condition, the resistance provided by the planet-leg assemblies 1044 and the shift cams 1056, 1058 tend to constrain axial translation of the feedback cam 1066. Since the feedback cam 1066 rotates but does not translate, the skew cam 1068 (which is constrained rotationally via the sliding spline portion 1082) is forced to translate axially via the threaded interface 1070, 1122 between the feedback cam 1066 and the skew cam 1068. Since the carrier plate 1042 is constrained axially but can have at least some angular rotation, the carrier plate 1042 is urged into angular rotation about the longitudinal axis LA1 through the sliding spline interface 1072, 1074 between the skew cam 1068 and the carrier plate 1042, resulting in the carrier plate 1042 inducing the planet axles 1046 into a skew condition. In one embodiment, the carrier plate 1042 rotates angularly until a maximum skew angle is achieved. The skew condition, as explained above, causes a tilting of the planet axles 1046. The tilting of the planet axles 1046 results in an adjustment of the speed ratio of the CVT 1000. However, the tilting of the planet axles 1046 additionally acts to translate axially the shift cams 1056, 1058 via the operational coupling between the planet axles 1046 and the shift cams 1056, 1058. The axial translation of the shift cams 1056, 1058 consequently results in an axial translation of the feedback cam 1066 via the thrust bearings 1078, 1080. Since the reference input nut 1062 prevents rotation of the feedback cam 1066, the skew cam 1068 and the feedback cam 1066 translate axially together. The axial translation of the skew cam 1068 causes a restoring angular rotation upon the carrier plate 1042, which consequently returns to a skew angle that generates sufficient skew forces to maintain the skew cam 1068 at an equilibrium axial position.
When the CVT 1000 is under an operation condition that is between a no load condition and a loaded condition, there can exist a cross over condition under which inducement of a skew condition of the planet axles 1046 (as well as the restoring action to zero skew condition) involves a translation and a rotation of the feedback cam 1066 with a simultaneous translation of the skew cam 1068. In all cases, the feedback cam 1066 and the skew cam 1068 are configured to cooperate to induce a skew condition of the planet axles 1046 via an angular rotation of the carrier plate 1042. The skew condition causes a tilting of the planet axles 1046 to set the CVT 1000 at a desired speed ratio. The feedback cam 1066, under action from the planet-leg assemblies 1044, cooperates with skew cam 1068 to restore the carrier plate 1042 to a position that induces a nominal zero skew.
Referring now to
Because of the nature of a ball planetary drive such as the CVT 1000, the traction sun 1026 tends to be subjected to an axial force (also, referred to as a “spin-induced side force”) through the contact between the traction planets 1022 and the traction sun 1026 during operation of the CVT 1000. When such an axial force is not counteracted, it is possible that the traction sun 1026 will tend to induce an axial translation of the skew cam 1068, resulting in operation at a non-zero skew angle.
In the embodiment of the CVT 1000 illustrated, the spin-induced side force on the traction sun 1026 is balanced, at least in part, by a skew-induced side force; hence, the skew cam 1068 is held in equilibrium. However, such a configuration produces a steady state non-zero skew angle condition, which can be less efficient than a zero skew angle condition. To achieve a zero skew angle condition, the spin-induced side forces are preferably balanced by a force other than a skew-induced side force.
In one embodiment, the CVT 1000 can be provided with a side force neutralizer assembly 1092, which is generally shown in Detail A view of
During operation, as the side force tends to induce an axial translation of the traction sun 1026, the tendency of the feedback cam 1066 and the skew cam 1068 to translate axially is resisted by either one of the resistance members 1094, 1100. If axial translation of the skew cam 1068 is to the left (based on the orientation of the CVT 1000 in
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The CVT 1002 is substantially similar to the CVT 1000, except in the following aspect which will now be described. To effect a speed ratio adjustment, the reference input ring 1166 is coupled to a feedback cam 1168. As depicted best in
To rotate the reference input ring 1166, a sun gear shaft 1170 is provided with a sun gear 1172, which is part of a planetary reference input 1174. The sun gear 1172 is coupled to a number of planet gears 1176, which are coupled to the reference input ring 1166 in a planetary gear configuration. A planet carrier 1178 of the planetary reference input 1174 is rigidly coupled to ground; hence, the planet carrier 1178 is constrained axially and rotationally relative to the longitudinal axis LA1. In one embodiment, the carrier plate 1040 is rigidly coupled to the planetary carrier 1178 via planetary axles 1180, which also serve to support the planet gears 1176. In some instances, the carrier plate 1040 can be coupled to the planetary carrier 1178 via a press fit or splines, for example. In some embodiments, a main axle 1182 can be adapted to couple rigidly to the planet carrier 1178 via the planetary axles 1180. Hence, the planetary carrier 1178, the carrier plate 1040, and the main axle 1182 are substantially constrained axially and prevented from rotation about the longitudinal axis LA1. In the embodiment shown in
Referencing
Moving now to
Referring now to
The CVT 1004 includes a feedback cam 1206 that couples to planet gears 1176 and that is operationally coupled to a skew cam 1208 and to the shift cam 1200. In one embodiment, the feedback cam 1206 and the shift cam 1200 are coupled through a threaded interface. In some embodiments, the feedback cam 1206 is configured to couple to the skew cam 1208 via a bearing 1210 and a skew cam slider 1212. The outer race of the bearing 1210 can be press fit, for example, to an inner bore of the feedback cam 1206. A clip provided in the inner bore of the feedback cam 1206 cooperates with a shoulder of the skew cam slider 1212 to constrain axially the bearing 1210. In some embodiments, a shoulder (not shown) can be provided on the feedback cam 1206 to axially capture the outer race of the bearing 1210 between the clip and the shoulder. The skew cam slider 1212 is mounted to a main axle 1214 via a sliding spline interface. The skew cam 1208 is axially constrained in the skew cam slider 1212 by, for example, a clip and the bearing 1210. In some embodiments, the skew cam 1208 can be provided with a shoulder that contacts the inner race of the bearing 1210.
During a speed ratio adjustment of the CVT 1004, mere rotation of the feedback cam 1206 causes translation of the shift cams 1200, 1202, but does not result in any movement of the skew cam slider 1212 or, consequently, the skew cam 1208. However, translation of the feedback cam 1206 drives axially the skew cam slider 1212, and thereby the skew cam 1208, via the bearing 1210. Translation of the skew cam 1208 results in an angular rotation of the carrier plate 1042 about the longitudinal axis LA1.
Referencing now
Passing now to
Referencing
A main axle 1320 is coupled to the planetary carrier 1310, which planetary carrier 1310 can be substantially similar to the planetary carrier 1178 of
In one embodiment, the main axle 1320 is coupled to a skew cam 1324 via, for example, a sliding spline interface 1326. Hence, the main axle 1320 and the skew cam 1324 can be provided with mating sliding splines. The skew cam 1324 is coupled to the feedback cam 1316 by, for example, a threaded interface 1328. Thus, in some embodiments, the skew cam 1324 and the feedback cam 1316 include mating threaded portions. In some embodiments, the skew cam 1324 is coupled to a shift cam anti-rotation retainer 1330 via an anti-rotation coupling 1332, which can be a sliding spline, for example. The shift cam anti-rotation retainer 1330 can be coupled to, or be integral with a shift cam 1334, which is substantially similar to the shift cam of
In one embodiment, the main axle 1320 can be fixed to ground by the planetary carrier 1310 and a carrier plate retainer 1344. Hence, the main axle 1320, the planetary carrier 130, and the carrier plate retainer 1344 are fixed axially, rotationally, and radially relative to the longitudinal axis LA1. Consequently, the skew cam 1324, the anti-rotation retainer 1330 and the shift cams 1334, 1336 are configured to be non-rotatable about the longitudinal axis LA1. In some embodiments, the anti-rotation retainer 1330 is provided with an extension (shown but no labeled) adapted to butt up against the carrier plate 1304, and thus, provide a limit stop when shifting the CVT 1006. In one embodiment, the carrier plate retainer 1344 threads to the main axle 1320 via a threaded interface 1348. The carrier plate retainer 1344 can be adapted to receive a carrier retaining bolt 1350 that is configured to cooperate with the carrier plate retainer 1344 to constrain axially the carrier plate 1304. In some such embodiments, the carrier plate 1304 can be provided with a carrier slot 1352 that allows the carrier plate 1304 to rotate angularly about the longitudinal axis LA1 in a plane perpendicular to said axis. Of course, it is preferable to ensure that the interfaces between the carrier plate 1304, the carrier plate retainer 1344, and the carrier retaining bolt 1350 minimize friction while allowing the carrier plate 1304 to rotate relative to the carrier plate retainer 1344 and the carrier retaining bolt 1350. In one embodiment, the carrier plate 1304 and/or the carrier plate retainer 1344 are provided with, for example, shoulders and/or recesses to provide radial support for the carrier plate 1304.
To adjust the speed ratio of the CVT 1006, a rotation of the sun shaft 1318 causes a rotation of the feedback cam 1316 via the sun gear 1314 and the planetary gears 1312. As previously discussed with reference to
In one embodiment, the CVT 1006 can be provided with a side force neutralizer mechanism. In the embodiment of
The main axle 1320 can be adapted to receive and support a pin carrier 1360 that is configured to receive and support a skew cam pin 1362. The pin carrier 1360 has a first end that engages the first reaction ring 1356 and a second end that engages a second reaction ring 1364. The pin carrier 1360 is provided with a substantially lateral bore configured to receive and support the skew cam pin 1362 by, for example, a press fit. The pin carrier 1360 is configured to mate with the main axle 1320 either by a clearance fit or through a sliding fit, for example. The main axle 1320 can be provided with a slot 1361 for facilitating the coupling of the skew cam pin 1362 to the skew cam 1324. The skew cam pin 1362 can facilitate an axial translation of the skew cam 1324. As shown in
The first resistance member 1354, the second resistance member 1368, the spacer 1370, and the set screw 1372 are preferably selected to provide a suitable preload and/or desired resistance response characteristic for overcoming the tendency of the side force to act upon the skew cam 1324 and induce a non-zero skew condition. During operation, an axial translation of the skew cam 1324 will tend to be resisted by the first and the second resistance members 1354, 1368. As the skew cam 1324 translates leftward (on the orientation of the page), the skew cam 1324 acts upon the skew cam pin 1362. This action translates the pin carrier 1360 axially, which engages the first reaction ring 1356. The first resistance member 1354 resists translation of the first reaction ring 1356. As the skew cam 1324 translates rightward, in a similar fashion, the skew cam 1234 operably engages the second reaction ring 1368, which is resisted by the second resistance member 1368. It should be noted that the action of the first and second resistance members 1354, 1368 is decoupled (that is, independent of one another) through the axial constraints provided by the shim 1358 and the retaining stop 1366.
To recap some of the disclosure above, in one embodiment, the main axle 1320 includes at least some of the following aspects. The central bore is adapted to receive the pin carrier 1360. The central bore can exhibit the retaining stop 1366, as well as, the threaded portion for receiving the preload adjuster 1372. The main axle 1320 preferably includes the slot 1361 adapted to allow passage of the skew cam pin 1362 from inside the main axle 1320 to an exterior space of the main axle 1320. An exterior diameter of the main axle 1320 can include the first threaded interface 1348 for rigidly coupling to a grounded member, such as the carrier plate retainer 1344. The exterior diameter of the main axle 1320 can further include a sliding spline portion for engaging a mating sliding spline of the skew cam 1324. The skew cam 1324 can be a tubular body having an inner diameter and an outer diameter. The inner diameter of the skew cam 1324 can be provided with a recess (shown but not labeled) for receiving the skew cam pin 1362. The inner diameter of the skew cam 1324 can include a splined portion for engaging corresponding splines of the main axle 1320. A portion of the exterior diameter of the skew cam 1324 can be provided with a high lead threaded portion for engaging a mating threaded portion of the carrier plate 1304. The skew cam 1324 can include a threaded portion, of relatively low lead when compared to the high lead portion, for engaging a similarly threaded portion of the feedback cam 1316. In some embodiments, the skew cam 1324 is adapted with a sliding spline portion on its outer diameter to engage a corresponding sliding spline of the anti-rotation retainer 1330.
Turning to
Referencing
In operation, axial translation of the skew cam 1325 toward the carrier plate 1302 is resisted by the first resistance member 1355, as the first resistance member 1355 is reacted by the translating cup cap 1414 and/or the flange 1402. It should be recalled that the main axle 1404 can be fixed to ground; hence, the main axle 1404 can be configured to not translate axially. As the skew cam 1325 translates axially toward the carrier plate 1304, the second resistance member 1369 tends to resist this axial movement of the skew cam 1324A, since the second resistance member 1369 is supported by the shoulder stop 1408, which is rigidly coupled to the main axle 1404 through the flange extension 1406. The resistance members 1355, 1369 are preferably selected to provide desired characteristics in overcoming the effects of the side force upon the skew cam 1325. It should be noted that in some embodiments the interface between the feedback cam 1316 and the flange extension 1406, as well as the interface between the translating cup 1412 and the flange extension 1406, are suitably configured to minimize sliding friction.
Passing to
During operation, as the skew cam 1502 translates towards the carrier plate 1302, the first resistance member 1357 tends to oppose the translation of the skew cam 1502 through the operational coupling between the skew cam 1502 and the first resistance member 1357 via the first resistance ring 1512, the catch flange 1520, and the extension sleeve 1504. Similarly, as the skew cam 1502 translates toward the carrier plate 1304, the second resistance member 1371 tends to oppose the translation of the skew cam 1502 through the operational coupling between the skew cam 1502 and the second resistance member 1371 via the second resistance ring 1518, the catch flange 1520, and the extension sleeve 1504. It should be noted that as the catch flange 1520 acts upon either one of the first and second resistance rings 1512, 1518, the other one of the first and second resistance members 1357, 1371 is not engaged or energized. Hence, the actions of the first and second resistance members 1357, 1371 are decoupled. Preferably, the first and second resistance members 1357, 1371 are suitably selected to provide the desired response characteristics to move the skew cam 1502 to a position corresponding to a CVT skew condition of nominal zero skew angle.
It should be noted that the neutralizer 1506 need not employ all of the components described above. For example, in some embodiments, the first resistance member 1357 and the first resistance ring 1512 can be provided as a suitable configured single piece component that performs the desired resistance function as it engages the catch flange 1520. As shown best in
Referring now to
In one embodiment of the control reference assembly 4300, the spring members 4306 and 4308 are torsion springs formed with legs 4322, 4324 and 4326, 4328, respectively, that are operationally connected to the control reference nut 4302 and the intermediate reaction member 4304. The leg 4322 is rotatably constrained in one direction by a shoulder 4320 on the control reference nut 4302. The leg 4324 is rotatably constrained in two directions by a bore 4330 formed on the intermediate reaction member 4304. Similarly, the leg 4328 is constrained by a shoulder 4315 in one direction, and the leg 4326 is constrained in two directions by a bore 4332 (see
Referencing
Passing now to
In one embodiment, the CVT 4100 can be provided with a side force neutralizer assembly 4192, an embodiment of which is generally shown in Detail G view of
Passing now to
Referring now to
In one embodiment, the planet support trunnion 5112 is a generally u-shaped body (
In one embodiment, the CVT 5100 is provided with traction sun 5120 that can be configured to rotate about the main axle 5108. The traction sun 5120 is positioned radially inward of, and in contact with, each of the traction planets 5106. In some embodiments, the traction sun 5120 is operably coupled to the first and the second carrier plates 5101 and 5102 via bearings, for example, that can be axially positioned by a number of bearing support fingers 5124 (see
Referring again to
Referring to
During operation of CVT 5100, a change in the speed ratio of the CVT 5100 can be achieved by tilting the planet axles 5110. The planet axles 5110 can be tilted by pivoting the planet support trunnions 5112. The planet support trunnions 5112 can be pivoted using any suitable method. One method for pivoting the planet support trunnion 5112 involves rotating the shift rod 5126 and, thereby, axially translating the sleeve 5130 and the pin 5132. A second method for pivoting the planet support trunnions 5112 involves rotating the shift rod 5126 thereby rotating the sleeve 5130. A rotation of the sleeve 5130 engages the reaction shoulders 5136 with the planet support trunnions 5112. The reaction shoulders 5136 urge the planet support trunnions 5112 to rotate about the skew cam center axes 51180A and 51180B, which moves the center axis 51190. The movement of the center axis 51190 induces a skew angle on the planet axle 5119. The skew angle, as discussed previously, motivates a change in the tilt angle of the planet axle 5110. Under some operating conditions, for example under a high torque condition, the second method may be preferred.
Passing now to
In one embodiment, the shift cam 5706 and the carrier plate 5702 can be adapted to couple to traction planet assemblies 1044 (not shown in
During operation, the torque governor 5700 can adjust the transmission speed ratio to maintain a constant operating torque. An axial translation of the traction sun 5704 due to a change in operating torque causes an axial translation of the shift cam 5706 and the threaded extension 5707. The threaded extension 5707 engages the first reaction arm 5710 and converts the axial translation into a rotation of the first reaction arm 5710. The rotation of the first reaction arm 5710 energizes the spring 5714A and urges the carrier plate 5702 to rotate. It should be readily apparent that the spring 5714B can be energized by the second reaction arm 5712 under an operating condition that causes an axial translation of the threaded extension 5707 in an opposite direction than the one described here as an illustrative example. The rotation of the carrier plate 5702 induces a skew angle on the traction planet assemblies 1044. As previously discussed, the skew angle motivates a shift in the transmission 5700. As the transmission shifts, the traction sun 5704 axially displaces and the carrier plate 5702 returns to an equilibrium position. Since the first reaction arm 5710 is operably coupled to the second reaction arm 5712 via springs 5714, the equilibrium condition can be set with the preload adjuster 5716 that is representative of a desired operating torque.
It should be noted that the description above has provided dimensions for certain components or subassemblies. The mentioned dimensions, or ranges of dimensions, are provided in order to comply as best as possible with certain legal requirements, such as best mode. However, the scope of the inventions described herein are to be determined solely by the language of the claims, and consequently, none of the mentioned dimensions is to be considered limiting on the inventive embodiments, except in so far as anyone claim makes a specified dimension, or range of thereof, a feature of the claim.
The foregoing description details certain embodiments of the invention. It will be appreciated, however, that no matter how detailed the foregoing appears in text, the invention can be practiced in many ways. As is also stated above, it should be noted that the use of particular terminology when describing certain features or aspects of the invention should not be taken to imply that the terminology is being re-defined herein to be restricted to including any specific characteristics of the features or aspects of the invention with which that terminology is associated.
This application is a continuation of U.S. application Ser. No. 12/667,681, filed Jan. 4, 2010, which is a national phase application of International Application No. PCT/US2008/068929, filed Jul. 1, 2008, which claims the benefit of U.S. Provisional Patent Application 60/948,152, filed Jul. 5, 2007. The disclosures of all of the above-referenced prior applications, publications, and patents are considered part of the disclosure of this application, and are incorporated by reference herein in their entirety.
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