JP4273750B2 - Toroidal continuously variable transmission - Google Patents

Description

[0001]
[Industrial application fields]
The toroidal type continuously variable transmission according to the present invention is used as a transmission unit of an automatic transmission for automobiles or as a transmission for adjusting the operating speed of various industrial machines such as pumps.
[0002]
[Prior art]
  The use of a toroidal type continuously variable transmission as shown in FIGS. 5 to 7 as an automatic transmission for automobiles has been studied and implemented in part. This toroidal-type continuously variable transmission is called a double cavity type, and around both ends of the input shaft 1,Claim 1The input side disks 2 and 2 which are the first disks are supported via ball splines 3 and 3. Therefore, both the input side disks 2 and 2 are supported concentrically and freely in a synchronized manner. An output gear 4 is supported around the intermediate portion of the input shaft 1 so as to be rotatable relative to the input shaft 1. And at both ends of the cylindrical portion provided at the center of the output gear 4,Claim 1The output side disks 5 and 5 which are the second disks are respectively spline engaged. Accordingly, both the output side disks 5 and 5 rotate in synchronism with the output gear 4.
[0003]
  A plurality (usually 2 to 3) of power rollers 6 and 6 are sandwiched between the input disks 2 and 2 and the output disks 5 and 5, respectively. Each of these power rollers 6 and 6Claim 1The trunnions 7 and 7 as support members are rotatably supported on the inner side surfaces via support shafts 8 and 8 and a plurality of rolling bearings. The trunnions 7 and 7 are pivotal shafts 9 and 9 provided concentrically with each other for each trunnion 7 and 7 at both ends in the length direction (the vertical direction in FIGS. 5 and 7 and the front and back direction in FIG. 6). Oscillating and displacing around the center. The operation of inclining the trunnions 7 and 7 is performed by displacing the trunnions 7 and 7 in the axial direction of the pivots 9 and 9 by the hydraulic actuators 10 and 10. The inclination angle of 7 is synchronized with each other hydraulically and mechanically.
[0004]
That is, when changing the inclination angle of the trunnions 7 and 7 in order to change the transmission ratio between the input shaft 1 and the output gear 4, the trunnions 7 and 7 are moved by the actuators 10 and 10, respectively. In the opposite directions, for example, the power roller 6 on the right side of FIG. 7 is displaced to the lower side of the figure, and the power roller 6 on the left side of the figure is displaced to the upper side of the figure. As a result, the direction of the tangential force acting on the rolling contact portion between the peripheral surfaces of the power rollers 6 and 6 and the inner surfaces of the input disks 2 and 2 and the output disks 5 and 5 changes. (Side slip occurs at the rolling contact portion). Then, the trunnions 7 and 7 swing (tilt) in opposite directions around the pivots 9 and 9 pivotally supported by the support plates 11 and 11 as the direction of the force changes. As a result, the contact position between the peripheral surface of each of the power rollers 6 and 6 and the inner surface of each of the input and output disks 2 and 5 changes, and rotation between the input shaft 1 and the output gear 4 occurs. The gear ratio changes.
[0005]
Regardless of the number of actuators 10, 10, the supply / discharge state of the pressure oil to each actuator 10, 10 is performed by one speed ratio control valve 12, and any one trunnion 7 is moved by this speed change. Feedback is made to the ratio control valve 12. This transmission ratio control valve 12 is fitted in a sleeve 14 that is displaced in the axial direction (left-right direction in FIG. 7, front-back direction in FIG. 5) by a stepping motor 13 and axially displaceable on the inner diameter side of the sleeve 14. Spool 15. A precess cam 18 is attached to the end of the rod 17 attached to any one of the trunnions 7 among the rods 17 and 17 connecting the trunnions 7 and 7 and the pistons 16 and 16 of the actuators 10 and 10. A feedback that transmits the combined value of the movement of the rod 17, that is, the displacement amount in the axial direction and the displacement amount in the rotation direction, to the spool 15 via the recess cam 18 and the link arm 19. The mechanism is configured. Further, a synchronizing cable 20 is spanned between the trunnions 7 and 7 so that the inclination angles of the trunnions 7 and 7 can be mechanically synchronized even when the hydraulic system fails.
[0006]
When switching the speed change state, the stepping motor 13 displaces the sleeve 14 to a predetermined position corresponding to the speed ratio to be obtained, and opens the flow path in the predetermined direction of the speed ratio control valve 12. As a result, pressure oil is sent to the actuators 10 and 10 in a predetermined direction, and the actuators 10 and 10 displace the trunnions 7 and 7 in a predetermined direction. That is, the trunnions 7 and 7 swing around the pivots 9 and 9 while being displaced in the axial direction of the pivots 9 and 9 as the pressure oil is fed. Then, the movement (axial direction and swing displacement) of any one of the trunnions 7 is transmitted to the spool 15 via a recess cam 18 and a link arm 19 fixed to the end of the rod 17, and this spool 15 is displaced in the axial direction. As a result, in the state where the trunnion 7 is displaced by a predetermined amount, the flow path of the transmission ratio control valve 12 is closed, and supply / discharge of the pressure oil to the actuators 10 and 10 is stopped.
[0007]
The movement of the transmission ratio control valve 12 based on the displacement of the trunnion 7 and the cam surface 21 of the recess cam 18 at this time is as follows. First, when the trunnion 7 is displaced in the axial direction as the flow path of the transmission ratio control valve 12 is opened, as described above, the peripheral surface of the power roller 6 and the input side disk 2 and the output side disk 5 The trunnion 7 starts swinging displacement about the pivots 9 and 9 due to the side slip generated at the rolling contact portion with the inner surface. Further, the displacement of the cam surface 21 is transmitted to the spool 15 via the link arm 19 in accordance with the axial displacement of the trunnion 7, and the spool 15 is displaced in the axial direction, so that the transmission ratio control valve 12 Change the switching state of. Specifically, the gear ratio control valve 12 is switched in a direction in which the actuator 10 returns the trunnion 7 to the neutral position.
[0008]
Therefore, immediately after the trunnion 7 is displaced in the axial direction, the trunnion 7 starts to be displaced in the opposite direction toward the neutral position. However, the trunnion 7 continues to swing around the pivots 9 and 9 as long as there is a displacement from the neutral position. As a result, the displacement in the circumferential direction of the cam surface 21 of the recess cam 18 is transmitted to the spool 15 via the link arm 19, and the spool 15 is displaced in the axial direction. Then, in a state where the inclination angle of the trunnion 7 has reached a predetermined angle commensurate with the speed ratio to be obtained, the trunnion 7 returns to the neutral position, and at the same time, the speed ratio control valve 12 is closed, and the actuator The supply and discharge of the pressure oil to 10 is stopped. As a result, the inclination angle of the trunnion 7 becomes an angle commensurate with the amount of displacement of the sleeve 14 in the axial direction by the stepping motor 13.
[0009]
During operation of the toroidal type continuously variable transmission as described above, one input side disk 2 (left side in FIGS. 5 and 6) is connected to a loading cam type as shown by a drive shaft 22 connected to a power source such as an engine. Alternatively, it is rotationally driven via a hydraulic pressing device 23. As a result, the pair of input side disks 2 and 2 supported at both ends of the input shaft 1 rotate synchronously while being pressed toward each other. Then, the rotation is transmitted to the output side disks 5 and 5 through the power rollers 6 and 6 and is taken out from the output gear 4.
[0010]
As described above, when power is transmitted from the input disks 2 and 2 to the output disks 5 and 5, the trunnions 7 and 7 have power troughs 6 and 7 supported on inner surfaces thereof. Along with the friction between the peripheral surface of the disk 6 and the inner surfaces of the disks 2 and 5, axial forces of the pivots 9 and 9 provided at both ends are applied. This force is so-called 2Ft, and the magnitude of the force is from the input disks 2 and 2 to the output disks 5 and 5 (or from the output disks 5 and 5 to the input disks 2 and 2). It is proportional to the power (power) transmitted to. Such a force 2Ft is supported by the actuators 10 and 10. Therefore, during operation of the toroidal continuously variable transmission, the pressure difference between the pair of hydraulic chambers 24a and 24b existing on both sides of the pistons 16 and 16 constituting the actuators 10 and 10 is the magnitude of the force 2Ft. Is proportional to
[0011]
  When the rotational speed of the input shaft 1 and the output gear 4 is changed, and when the deceleration is first performed between the input shaft 1 and the output gear 4, the trunnions 7 and 7 are moved by the actuators 10 and 10, respectively. The trunnions 9 and 9 are moved in the axial direction, and the trunnions 7 and 7 are swung to the positions shown in FIG. Andthe aboveAs shown in FIG. 6, the peripheral surface of each power roller 6, 6 is a portion near the center of the inner surface of each of the input side disks 2, 2 and a portion near the outer periphery of the inner surface of each of the output disks 5, 5 Respectively. On the contrary, when the speed is increased, each trunnion 7, 7 is swung in the opposite direction to FIG.the aboveContrary to the state shown in FIG. 6, the peripheral surface of each power roller 6, 6 is opposite to the outer peripheral portion of the inner surface of each input disk 2, 2 and the inner surface of each output disk 5, 5. The trunnions 7 and 7 are inclined so as to come into contact with the center portion of each. If the inclination angles of the trunnions 7 and 7 are set in the middle, an intermediate speed ratio (speed ratio) can be obtained between the input shaft 1 and the output gear 4.
[0012]
Furthermore, when the toroidal type continuously variable transmission configured and operated as described above is incorporated in an actual continuously variable transmission for an automobile, a continuously variable transmission can be configured in combination with a planetary gear mechanism. Has been proposed in the past. As shown in FIG. 8, the continuously variable transmission described in Patent Document 1 is formed by combining a toroidal continuously variable transmission 25 and a planetary gear type transmission 26. Of these, the toroidal-type continuously variable transmission 25 includes an input shaft 1, a pair of input-side disks 2, 2, an output-side disk 5 a, and a plurality of power rollers 6, 6. In the illustrated example, the output side disk 5a has a structure such that the outer surfaces of a pair of output side disks are brought into contact with each other and integrated.
[0013]
The planetary gear type transmission 26 includes a carrier 27 coupled and fixed to the input shaft 1 and the input side disk 2 on one side (right side in FIG. 8). A first transmission shaft 29 in which planetary gear elements 28a and 28b are fixed to both ends of the carrier 27 in the radial direction is supported rotatably. Further, on the opposite side of the input shaft 1 across the carrier 27, a second transmission shaft 31 having sun gears 30a and 30b fixed to both ends thereof is supported concentrically with the input shaft 1 so as to be rotatable. is doing. Then, the planetary gear elements 28a and 28b and the distal end portion (the right end portion in FIG. 8) of the hollow rotary shaft 32 having the base end portion (the left end portion in FIG. 8) coupled to the output side disk 5a are fixed. The sun gear 33 or the sun gear 30a fixed to one end (the left end in FIG. 8) of the second transmission shaft 31 is meshed with each other. One planetary gear element 28a (left side in FIG. 8) is meshed with a ring gear 35 rotatably provided around the carrier 27 via another planetary gear element 34.
[0014]
On the other hand, the planetary gear elements 37a and 37b are rotatably supported by the second carrier 36 provided around the sun gear 30b fixed to the other end portion (the right end portion in FIG. 8) of the second transmission shaft 31. is doing. The second carrier 36 is fixed to the base end portion (left end portion in FIG. 8) of the output shaft 38 disposed concentrically with the input shaft 1 and the second transmission shaft 31. The planetary gear elements 37a and 37b mesh with each other, and one planetary gear element 37a is rotatable around the sun gear 30b and the other planetary gear element 37b is rotatable around the second carrier 36. The second ring gear 39 provided is meshed with each other. The ring gear 35 and the second carrier 36 can be freely engaged and disengaged by a low speed clutch 40, and the second ring gear 39 and a fixed part such as a housing are engaged by a high speed clutch 41. It is considered to be removable.
[0015]
In the case of the continuously variable transmission shown in FIG. 8 as described above, in the so-called low speed mode state in which the low speed clutch 40 is connected and the high speed clutch 41 is disconnected, the power of the input shaft 1 is This is transmitted to the output shaft 38 via the ring gear 35. By changing the gear ratio of the toroidal continuously variable transmission 25, the gear ratio of the continuously variable transmission, that is, the gear ratio between the input shaft 1 and the output shaft 38 changes. In such a low speed mode state, the speed ratio of the continuously variable transmission as a whole changes to infinity. That is, by adjusting the gear ratio of the toroidal-type continuously variable transmission 25, the rotation state of the output shaft 38 is changed between forward rotation and reverse rotation with the input shaft 1 rotated, with the stop state interposed therebetween. Conversion is possible.
[0016]
On the other hand, in the so-called high speed mode state in which the low speed clutch 40 is disconnected and the high speed clutch 41 is connected, the power of the input shaft 1 causes the first and second transmission shafts 29 and 31 to be connected. Via the output shaft 38. Then, by changing the gear ratio of the toroidal-type continuously variable transmission 25, the gear ratio of the entire continuously variable transmission changes. In this case, the greater the gear ratio of the toroidal type continuously variable transmission 25, the greater the gear ratio of the continuously variable transmission.
[0017]
  As shown in FIGS. 5 to 7 described above, the toroidal type continuously variable transmission 25 can be used both in the case where the toroidal type continuously variable transmission is used alone and in the case where it is incorporated in the continuously variable transmission as shown in FIG. During operation, the inner side surfaces of the input disks 2 and 2 and the output disks 5 and 5athe aboveLubricating oil (traction oil) is continuously supplied (poured) to the rolling contact portions with the peripheral surfaces of the power rollers 6 and 6. And while preventing that a metal contact generate | occur | produces in this rolling contact part, the temperature rise of this rolling contact part is suppressed, and it prevents that said each surface is damaged. That is, when the inner surfaces of the disks 2, 5, 5a, each made of hard metal such as bearing steel, and the peripheral surfaces of the power rollers 6, 6 are brought into direct contact (metal contact), these surfaces become early. Wear and seize.
[0018]
Therefore, when the toroidal-type continuously variable transmission 25 is operated, the nozzles 43 and 43 (see FIGS. 5 and 7) provided on the support posts 42 and 42 supporting the support plates 11 and 11 are directed to the rolling contact portion. And constantly spray lubricant. As a result, an extremely thin oil film (for example, about 1 μm in thickness) is formed on the rolling contact portion between the inner surface of each of the disks 2, 5, 5a and the peripheral surface of the power rollers 6, 6. And in each of these rolling contact parts, power is transmitted through this oil film. Further, a part of the lubricating oil passes the power rollers 6 and 6 to the trunnions 7 and 7 through the lubricating oil passages 44 and 44 (see FIG. 7) provided in the trunnions 7 and 7, respectively. It is also fed into each rolling bearing that is rotatably supported.
[0019]
Conventionally, a hydraulic circuit for feeding lubricating oil to each of the rolling bearings and the rolling contact portion is configured as shown in FIG. 9, and the toroidal type continuously variable transmission is provided at each of the rolling bearings and the rolling contact portion. Regardless of the operating condition, a certain amount of lubricating oil was fed. In the case of a toroidal continuously variable transmission, the same traction oil is used as the lubricating oil for lubricating each part and the operating oil for operating the actuators 10 and 10 (see FIG. 7). The reason for this is to prevent the transmission of power at the rolling contact portion due to the mixing of different types of hydraulic oil in the traction oil.
[0020]
As shown in FIG. 9, the lubricating oil is sucked into the high pressure pump 46 and the low pressure pump 47 into the oil reservoir 45 such as an oil pan provided at the lower end of the casing in which the toroidal type continuously variable transmission is housed. It is discharged in a pressurized state. Of these, the lubricating oil discharged from the high pressure pump 46 is adjusted to a relatively high predetermined pressure by the relief valve type high pressure side pressure adjusting valve 48, and the transmission ratio control valve 12 (FIGS. 5 and 7) is adjusted. Via the hydraulic chambers 24a and 24b (FIG. 7) of the actuators 10 and 10. Further, as a pressing device for pressing the input side disks 2 and 2 toward the output side disks 5 and 5 (see FIGS. 5 and 6), a hydraulic type is used instead of the loading cam type as shown in the figure. In this case, relatively high-pressure lubricating oil is also fed into the hydraulic chamber of the hydraulic pressing device.
[0021]
On the other hand, the lubricating oil discharged from the low pressure pump 47 is adjusted to a relatively low predetermined pressure by a relief valve type low pressure side pressure adjusting valve 49, and the nozzles 43, 43 (FIG. 5, 7) and the lubricating oil passages 44, 44 (FIG. 7) through a throttle 50 such as an orifice. Since the oil pressure (gauge pressure) at the portion where the lubricating oil is ejected from the nozzles 43 and 43 is 0, the amount Q of the lubricating oil sent to the nozzles 43 and 43 is Cd, and the flow rate coefficient is Cd. The opening area of 50 is A, and the pressure on the upstream side of this throttle 50 (= the set pressure of the low pressure side pressure regulating valve) is P₁ And the downstream pressure is P₂ (= 0) and Q = Cd · A · {2 (P₁ -P₂ ) / Ρ}^1/2 It is represented by From this equation, it can be seen that a constant amount of lubricating oil is always sent to the nozzles 43 and 43. Further, when applied to the continuously variable transmission shown in FIG. 6, a part of the pressure oil discharged from the low pressure pump 47 and pressure-adjusted is applied to the low speed and high speed clutches 40 and 41, respectively. I am also trying to send it in.
[0022]
Patent Documents 2 to 5 exist as publications that describe a structure in which traction oil that functions as lubricating oil or hydraulic oil is fed to each part of a toroidal-type continuously variable transmission. Among them, Patent Document 2 is provided with a low-pressure pump for sending out lubricating oil in addition to the high-pressure pump for sending out the working oil for the gear ratio adjusting actuator as in the structure shown in FIG. Is described. Further, in Patent Document 3, a tank for storing the hydraulic oil is lubricated so that the hydraulic oil can be reliably sent to the actuator for adjusting the gear ratio regardless of the operation state of the vehicle. The structure provided in the tank which stores oil is described. Further, in Patent Document 4, in order to prevent lubrication failure at the rolling contact portion at the time of starting, lubricating oil is fed into the rolling contact portion before the rotation of the engine is transmitted to the toroidal continuously variable transmission. The structure is described.
[0023]
Further, Patent Document 5 discloses the amount of lubricating oil (traction oil) supplied from the nozzle of the toroidal type continuously variable transmission to the rolling contact portion between the inner surface of each disk and the peripheral surface of the power roller. A structure that changes according to the power transmitted by the step transmission is described. That is, as described in the paragraph numbers [0018] to [0021] of the specification of Patent Document 5, the rolling contact portion is deteriorated in transmission efficiency due to gross slip, and damage such as seizure occurs. In order to prevent this, it is necessary to supply a sufficient amount of lubricating oil to the rolling contact portion to suppress the temperature rise of the rolling contact portion. On the other hand, if the amount of lubricating oil supplied to the rolling contact portion becomes excessive, the stirring resistance of the lubricating oil by the components of the toroidal continuously variable transmission increases, and the transmission of the toroidal continuously variable transmission Efficiency is reduced.
[0024]
In view of such circumstances, in the case of the structure described in Patent Document 5, a flow rate adjusting valve is provided between a nozzle that sprays lubricating oil on the rolling contact portion and an oil supply pump that is a hydraulic source. ing. As the power transmitted by the toroidal continuously variable transmission increases, the amount of lubricating oil fed to the nozzle is increased. For this reason, it is possible to realize an efficient toroidal continuously variable transmission by preventing a reduction in transmission efficiency due to the gross slip and occurrence of damage such as seizure, and further preventing an increase in the stirring resistance of the lubricating oil.
[0025]
[Patent Document 1]
JP 2000-220719 A
[Patent Document 2]
Japanese Utility Model Publication No. 6-37224
[Patent Document 3]
JP-A-11-37242
[Patent Document 4]
JP-A-11-230494
[Patent Document 5]
JP 2001-132808 A
[0026]
[Problems to be solved by the invention]
As described above, according to the structure described in Patent Document 5, the transmission efficiency can be improved while ensuring the reliability and durability of the toroidal-type continuously variable transmission. However, in the specific structure described in Patent Document 5, it is inevitable that the number of parts increases and the cost increases. That is, in this structure, a flow rate adjusting valve is required, a sensor for detecting the magnitude of the power (torque x rotational speed) applied to the input part of the toroidal continuously variable transmission, and the detection value of this sensor. Accordingly, a controller that calculates the amount of lubricating oil required and issues a command signal to the flow rate adjusting valve is required, which increases costs. Furthermore, since the hydraulic piping is complicated, it also causes an increase in the size and weight of the toroidal continuously variable transmission.
In view of such circumstances, the present invention is to realize a structure that can be configured to be small and light by reducing the number of parts and obtain the same operation and effect as the invention described in Patent Document 5. Invented.
[0027]
[Means for Solving the Problems]
  Toroidal type continuously variable of the present inventionThe transmission described aboveSimilar to a conventionally known toroidal-type continuously variable transmission, it includes first and second disks, a plurality of power rollers, a pressing device, and an oil supply means.
  Of these, the first and second disks are arranged concentrically and rotatably relative to each other.
  Each of the power rollers is sandwiched between inner surfaces of the first and second disks facing each other, and transmits power between the first and second disks.
  The pressing device presses the first disk toward the second disk.
  The oil supply means supplies lubricating oil to a rolling contact portion between the inner side surfaces of the disks and the peripheral surfaces of the power rollers.
  And the supporting member which supported each said power roller is supported so that the rocking | fluctuation displacement centering | focusing on the pivot provided in the both ends of each center is possible.
[0028]
  In particular, the present inventionIn the toroidal type continuously variable transmission,The pressing device is hydraulic. Further, the hydraulic pressure sent to the pressing device increases as the power transmitted between the first and second disks increases. And the quantity of lubricating oil supplied to the said rolling contact part from the said oil supply means is increased, so that the hydraulic pressure sent to the said press apparatus becomes high.
[0029]
  For this reason, in the case of the toroidal type continuously variable transmission of the present invention, a relief valve type pressure adjusting device hydraulic pressure adjusting valve (pressurizing pressure adjusting valve 51) is provided. The pressure adjusting valve hydraulic pressure adjusting valve is a piston that is a hydraulic actuator for displacing the support members in the axial direction of the pivots in order to change the gear ratio between the first and second disks. The hydraulic pressure fed to the pressing device is increased as the difference in hydraulic pressure between the pair of hydraulic chambers provided with the gap increases. Then, the hydraulic pressure of the relief circuit portion of the hydraulic pressure regulating valve for the pressing device is adjusted to the rolling contact with the hydraulic circuit regulated by a pressure regulating valve (low pressure side pressure regulating valve 49) different from the hydraulic pressure regulating valve for the pressing device. Between a pair of throttles (throttle 50, second throttle 52) provided in series in the middle of the lubricating oil passage connecting the parts (intersection 53), and the pair of throttles (throttle 50) The oil supply means is configured by opening the downstream side of the throttle (second throttle 52) closer to the rolling contact portion of the second throttle 52) toward the rolling contact portion. Yes.
[0030]
[Action]
In the case of the toroidal type continuously variable transmission of the present invention configured as described above, an appropriate amount of lubricating oil can be fed into the rolling contact portion in accordance with the operating state of the toroidal type continuously variable transmission. Accordingly, it is possible to realize an efficient toroidal continuously variable transmission by preventing a reduction in transmission efficiency due to gross slip and occurrence of damage such as seizure, and further preventing an increase in the stirring resistance of the lubricating oil.
In particular, in the case of the toroidal-type continuously variable transmission of the present invention, the flow rate adjustment valve required in the structure described in Patent Document 5 is not necessary. For this reason, the number of parts can be reduced, and the apparatus can be made small and lightweight.
[0031]
DETAILED DESCRIPTION OF THE INVENTION
  1-4Of the present inventionAn example of an embodiment is shown. The present invention is characterized in that lubricating oil (traction oil) is applied to the rolling contact portion between the inner surface of each disk on the input side and output side and the peripheral surface of each power roller 6, and the operation of the toroidal continuously variable transmission. Depending on the situation, it is in the structure of the part that feeds the proper amount. Since the structure of the toroidal type continuously variable transmission itself is the same as that of the conventional structure shown in FIGS. 5 to 7, for example, the illustration and description regarding the equivalent parts are omitted or simplified. The description will focus on the characteristic part.
[0032]
  Lubricating oil is sucked into a high-pressure pump 46 and a low-pressure pump 47 and discharged in a pressurized state in an oil reservoir 45 such as an oil pan provided at the lower end of a casing containing a toroidal-type continuously variable transmission. . Of these, the lubricating oil discharged from the high pressure pump 46 is pressure-adjusted by a relief valve pressurizing pressure adjusting valve 51 as shown in FIGS. In order to adjust the gear ratio, the trunnion 7 is fed into the hydraulic chambers 24a and 24b of the actuator 10 which displaces the pivot shafts 9 and 9 in the axial direction. The lubricating oil pressure-adjusted by the pressure adjusting valve 51 for pressurization is a hydraulic press for pressing the input side disks 2 and 2 toward the output side disks 5 and 5a (see FIGS. 5, 6 and 8). It is also fed into the hydraulic chamber of the device 23a. In the case of this example, the pressure adjusting valve 51 for pressurization isClaim 1This corresponds to a hydraulic pressure adjusting valve for a pressing device.
[0033]
  On the other hand, the lubricating oil discharged from the low-pressure pump 47 is adjusted to a relatively low predetermined pressure by a relief valve type low-pressure pressure adjusting valve 49, and the nozzles 43, 43 and the lubricating oil. In the passages 44, 44 (see FIGS. 5 and 7), a restriction 50 such as an orifice,Provided in series with the diaphragm 50,It is also fed through a second restriction 52 such as an orifice. In this example,The aperture 50 andThe second aperture 52 isA pair of apertures according to claim 1Equivalent to. In the middle of the flow path for feeding the lubricating oil discharged from the low pressure pump 47 and pressure-adjusted by the low pressure side pressure regulating valve 49 to the nozzles 43, 43 and the lubricating oil passages 44, 44, the throttle 50 and the second A portion 53 between the throttle 52 and the pressure adjusting valve 51 for pressurization communicates with a relief circuit portion (discharge port). Further, in the pilot circuit of the pressure adjusting valve 51 for pressurization, a difference between the hydraulic pressures in the pair of hydraulic chambers 24a and 24b provided in the actuator 10 is introduced as a differential pressure signal. As described above, the hydraulic pressure difference between the hydraulic chambers 24a and 24b is as follows. From the input side disks 2 and 2 to the output side disks 5 and 5a (or from the output side disks 5 and 5a to the input side disk 2, 2, see FIGS. 5, 6 and 8). Therefore, the hydraulic pressure introduced into the pilot circuit of the pressurizing pressure regulating valve 51 is proportional to the magnitude of power passing through the toroidal type continuously variable transmission. Note that the differential pressure extracting valve 65 (see FIGS. 2 and 4) for outputting the differential pressure signal as described above will be described later together with the other members shown in FIG.
[0034]
In the illustrated example, a correction signal corresponding to the use state of the toroidal continuously variable transmission, such as temperature and accelerator opening, is input to the pressure adjusting valve 51 for pressurization, and the toroidal continuously variable transmission is provided. In accordance with the operating conditions, the hydraulic pressure fed into the hydraulic chamber of the pressing device 23a is corrected. Accordingly, the hydraulic pressure introduced from the pressurizing pressure regulating valve 51 to the actuator 10 and the pressing device 23a increases in proportion to the magnitude of power passing through the toroidal continuously variable transmission. Corrections are added according to the operating conditions of the toroidal type continuously variable transmission.
[0035]
In any case, the lubricating oil introduced into the actuator 10 and the pressing device 23a from the pressure adjusting valve 51 for pressurization hardly leaks out from the actuator 10 and the pressing device 23a. On the other hand, the high pressure pump 46 for feeding lubricating oil to the oil supply port of the pressurizing pressure adjusting valve 51 is rotationally driven by the engine together with the input shaft 1 constituting the toroidal continuously variable transmission. Therefore, the amount of lubricating oil fed into the oil supply port increases as the engine speed increases. The amount of lubricating oil discharged from the relief circuit portion (discharge port) of the pressurizing pressure adjusting valve 51 to the portion 53 between the throttle 50 and the second throttle 52 also increases.
[0036]
In short, among the pressure and flow rate of the lubricating oil discharged from the relief circuit portion, with regard to the pressure, the force 2Ft passing through the toroidal continuously variable transmission increases and is introduced into the pilot circuit of the pressurizing pressure regulating valve 51. The higher the hydraulic pressure is, the higher it is. Further, the flow rate increases as the rotational speed of the engine increases. Further, since the intermediate portion 53 is provided with the throttle 50 and the second throttle 52 on both sides, the hydraulic pressure of the intermediate portion 53 has a large force passing through the toroidal continuously variable transmission, and the engine The higher the rotation speed of, the higher. And, Q = Cd · A · {2 (P₁ -P₂ ) / Ρ}^1/2 As is apparent from the equation, the amount of lubricating oil that passes through the second throttle 52 and is fed into the nozzles 43 and 43 and the lubricating oil passages 44 and 44 increases as the hydraulic pressure in the intermediate portion 53 increases. Become.
[0037]
As a result, according to the structure of this example, depending on the driving situation of the toroidal type continuously variable transmission, the inner side surface of each of the input side and output side disks 2, 5, 5 a and the peripheral surface of each power roller 6. An appropriate amount of lubricant can be fed into the rolling contact area. Accordingly, it is possible to realize an efficient toroidal continuously variable transmission by preventing a reduction in transmission efficiency due to gross slip and occurrence of damage such as seizure, and further preventing an increase in the stirring resistance of the lubricating oil. In particular, in the case of the toroidal type continuously variable transmission of this example, the flow rate adjustment valve required in the structure described in Patent Document 5 is not necessary. For this reason, the number of parts can be reduced, and the apparatus can be made small and lightweight.
[0038]
2 to 4 show a more specific hydraulic control circuit for the continuously variable transmission shown in FIG. In the case of the structure shown in FIGS. 2 to 4, the transmission ratio control valve 12 can be adjusted not only by the stepping motor 13 but also by the differential pressure cylinder 54, and the torque passing through the toroidal continuously variable transmission can be adjusted. In order to adjust to the target value, the gear ratio of the toroidal type continuously variable transmission can be finely adjusted. The supply and discharge of the pressure oil to and from the differential pressure cylinder 54 is performed through the forward / reverse switching valve 58 by the first and second differential pressure control valves 56 and 57 controlled by the load solenoid valve 55. I have to. Further, supply and discharge of pressure oil to both the low speed and high speed clutches 40 and 41 are performed by the shift switching valve 59, the high speed and low speed switching valves 60 and 61, and the shift electromagnetic valve 62. I have to. Further, the opening pressure of the pressure adjusting valve 51 for pressurization can be adjusted based on the opening and closing of the electromagnetic valve 63. Further, the communication state of each part can be switched by a manual switching valve 64 operated by a shift lever provided in the driver's seat.
[0039]
The differential pressure take-out valve 65 for introducing the difference between the hydraulic pressures in the pair of hydraulic chambers 24a, 24b provided in the actuator 10 to the pressurizing pressure adjusting valve 51 is configured as follows. That is, as shown in FIGS. 2 and 4, a pair of springs 68 are sandwiched between the spools 67 that are axially displaceable in cylinder holes 66 in which small diameter portions and large diameter portions are alternately arranged. 68 and pilot portions 69a and 69b. The plurality of flanges provided on the spool 67 can be fitted into the small diameter portion of the cylinder hole 66 in an oil-tight manner. Then, the pressure oil adjusted by the pressure adjusting valve 51 for pressurization can be freely fed into the large diameter portion present at the center portion of the cylinder hole 66 through the first pressure introduction path 70.
[0040]
The spool 67 constituting the differential pressure take-out valve 65 is a pressure in a pair of hydraulic chambers 24a and 24b introduced into the pair of pilot portions 69a and 69b and provided with the piston 16 sandwiched between the actuator 10 and the piston. In accordance with the displacement in the axial direction. The conduction state between the downstream end of the first pressure introduction path 70 and the first and second pilot parts 71 and 72 attached to the pressure adjusting valve 51 for pressurization is set via the forward / reverse switching valve 58. Control. That is, the spool 67 constituting the differential pressure take-off valve 65 is displaced in the axial direction according to the difference in hydraulic pressure introduced into the pair of pilot portions 69a and 69b. Then, depending on which pilot section 69a (69b) has a higher hydraulic pressure than the other pilot section 69b (69a), each end is connected to the differential pressure take-off valve 65. Hydraulic pressure is introduced into the second pressure introduction path 73 a (73 b) and the reaction force chamber 74 a (74 b) provided in the portion facing both end faces of the spool 67.
[0041]
For example, consider a state in which the hydraulic pressure in one hydraulic chamber 24a of the actuator 10 is higher than that in the other hydraulic chamber 24b. In this state, the hydraulic pressure introduced into the pilot portion 69a is higher than the hydraulic pressure introduced into the other pilot portion 69b, the spool 67 moves to the right in FIG. 2, and the differential pressure take-off valve 65 is turned off. Change. As a result, the pressure oil sent through the first pressure introduction passage 70 passes through the second pressure introduction passage 73a on one side (right side in FIG. 2) and the first pilot of the pressure adjusting valve 51 for pressurization. Part 71 is introduced. At the same time, the pressure oil is introduced into the first and second differential pressure control valves 56, 57, and the differential pressure cylinder 54 is displaced via the forward / reverse switching valve 58 to thereby change the speed ratio control. The sleeve 14 of the valve 12 is slightly displaced.
[0042]
On the other hand, when the hydraulic pressure in the other hydraulic chamber 24b of the actuator 10 becomes higher than that of the one hydraulic chamber 24a, the hydraulic pressure introduced into the other pilot portion 69b is introduced into the one pilot portion 69a. The pressure becomes higher than the hydraulic pressure, the spool 67 moves to the left in FIG. 2, and the differential pressure take-off valve 65 is switched to the reverse of the state described above. As a result, the pressure oil sent through the first pressure introduction passage 70 passes through the third pressure introduction passage 73b on the other side (left side in FIG. 1), and the second pilot of the pressure adjusting valve 51 for pressurization. Part 72 is introduced. At the same time, the pressure oil is introduced into the first and second differential pressure control valves 56 and 57 to displace the differential pressure cylinder 54 via the forward / reverse switching valve 58.
[0043]
In any case, the pressure oil introduced into the second pressure introduction passages 73 a and 73 b is also introduced into the reaction force chamber 74 a (74 b) of the differential pressure take-off valve 65, and the axial end surface of the spool 67. Press. Accordingly, the force for displacing the spool 67 in the axial direction to cause the first pressure introduction path 70 and the second pressure introduction path 73a (73b) to communicate with each other is applied to the differential pressure extracting valve 65. This is proportional to the difference | ΔP | of the hydraulic pressure introduced into the provided pair of pilot portions 69a and 69b. As a result, the hydraulic pressure introduced into the first and second pilot portions 71 and 72 of the pressure adjusting valve 51 for pressurization is the difference between the hydraulic pressures in the hydraulic chambers 24a and 24b of the actuator 10 | ΔP | It is proportional to the power passing through the toroidal type continuously variable transmission.
[0044]
The valve opening pressure of the pressurizing pressure adjusting valve 51 increases as the hydraulic pressure introduced into the first and second pilot portions 71 and 72 increases, and the hydraulic pressure introduced into the pressing device 23a increases as described above. The pressure increases as the valve opening pressure of the pressure adjusting valve 51 increases. Accordingly, the hydraulic pressure introduced into the pressing device 23a, and hence the pressing force generated by the pressing device 23a, increases as the power passing through the toroidal-type continuously variable transmission increases. Along with this, the amount of lubricating oil discharged from the pressure adjusting valve 51 for pressurization increases, passes through the second throttle 52, and nozzles 43, 43 and lubricating oil passages 44, 44 (see FIGS. 5 and 7). ) The amount of lubricating oil fed into
[0045]
In the structure shown in FIG. 2 described above, the features of the present invention other than those described above are the same as those in FIG. 2 to 4 are represented by a general drawing method for forming a hydraulic circuit or by a sectional view for understanding the structure, respectively, so that the parts are the same as the structure shown in FIG. Are denoted by the same reference numerals, and redundant description is omitted.
[0046]
【The invention's effect】
Since the present invention is configured and operates as described above, it is a toroidal type that has excellent transmission efficiency while ensuring sufficient durability and reliability with a structure that can be manufactured at a low cost with a small number of parts. A continuously variable transmission can be realized.
[Brief description of the drawings]
FIG. 1 is a diagram showing a main part of a hydraulic circuit showing an example of an embodiment of the present invention.
FIG. 2 is a diagram showing a more specific hydraulic circuit for a continuously variable transmission that is configured by combining a toroidal type continuously variable transmission and a planetary gear type transmission and that can realize an infinite gear ratio.
FIG. 3 is an enlarged view of a pressure adjusting valve portion for pressurization.
FIG. 4 is an enlarged view of a differential pressure take-out valve portion.
FIG. 5 is a cross-sectional view showing an example of a conventionally known toroidal continuously variable transmission.
6 is a cross-sectional view taken along line AA in FIG.
FIG. 7 is a sectional view taken along the line BB in FIG.
FIG. 8 is a schematic cross-sectional view showing an example of a continuously variable transmission device that is a combination of a toroidal type continuously variable transmission and a planetary gear type transmission that is conventionally known and can realize an infinite gear ratio.
FIG. 9 is a diagram showing a main part of a conventional hydraulic circuit.
[Explanation of symbols]
1 Input shaft
2 Input disk
3 Ball spline
4 Output gear
5, 5a Output disk
6 Power roller
7 Trunnion
8 Support shaft
9 Axis
10 Actuator
11 Support plate
12 Gear ratio control valve
13 Stepping motor
14 sleeve
15 spool
16 piston
17 Rod
18 Precess Come
19 Link arm
20 Sync cable
21 Cam surface
22 Drive shaft
23, 23a Pressing device
24a, 24b Hydraulic chamber
25 Toroidal continuously variable transmission
26 Planetary gear type transmission
27 Career
28a, 28b Planetary gear element
29 First transmission shaft
30a, 30b Sun gear
31 Second transmission shaft
32 hollow rotating shaft
33 Sun Gear
34 Planetary gear element
35 Ring gear
36 Second career
37a, 37b planetary gear element
38 Output shaft
39 Second ring gear
40 Low speed clutch
41 High speed clutch
42 Support post
43 nozzles
44 Lubricating oil passage
45 Oil sump
46 High pressure pump
47 Low pressure pump
48 High pressure control valve
49 Low pressure control valve
50 aperture
51 Pressure regulating valve for pressurization
52 Second aperture
53 part
54 Differential pressure cylinder
55 Load solenoid valve
56 First differential pressure control valve
57 Second differential pressure control valve
58 Forward / reverse selector valve
59 Switching valve for shift
60 Switching valve for high speed
61 Switching valve for low speed
62 Solenoid valve for shift
63 Solenoid valve
64 Manual selector valve
65 Differential pressure relief valve
66 Cylinder hole
67 spools
68 Spring
69a, 69b Pilot part
70 First pressure inlet
71 First pilot part
72 Second pilot
73a, 73b Second pressure introduction path
74a, 74b Reaction force chamber

Claims (1)

The first and second discs are sandwiched between the inner and outer surfaces of the first and second discs that are concentrically arranged and relatively rotatable, and the first and second discs facing each other. Rolling between a plurality of power rollers that transmit power between them, a pressing device that presses the first disk against the second disk, and the inner surface of both disks and the peripheral surface of each of the power rollers And an oil supply means for supplying lubricating oil to the contact portion, and the support members that support these power rollers are supported at both end portions so as to be swingable and displaceable around the pivots concentrically provided to each other. In the toroidal type continuously variable transmission, the pressure device is hydraulic, and the hydraulic pressure fed to the pressure device increases as the power transmitted between the first and second disks increases. Stuff , As the oil pressure fed to the pressing device is increased in order to increase the amount of lubricant supplied to the rolling contact portion from said oil supply means, for changing the gear ratio between each other the first and second disk The hydraulic actuator for displacing each support member in the axial direction of each pivot is provided with a piston interposed therebetween, and the pressure difference between the pair of hydraulic chambers increases as the pressure difference increases. There is a relief valve type hydraulic adjustment valve for the pressure device that increases the hydraulic pressure. Introduced between a pair of throttles provided in series in the middle of a lubricating oil passage connecting the hydraulic circuit to be regulated and the rolling contact part, and the rolling contact part of the pair of throttles is introduced into the rolling contact part The downstream side of the throttle on the near side By which opens toward the rolling contact portion, the toroidal type continuously variable transmission, characterized in that constituted the oil supply means.

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