KR0168391B1 - Cvt for a vehicle - Google Patents

Abstract

To simplify the configuration, to reduce the manufacturing cost and to provide a continuously variable vehicle that can be easily applied to the front wheel drive vehicle; A power control mechanism for controlling the start of the vehicle while controlling the rotational power output from the engine; A forward and backward control mechanism comprising a first shaft on the rear side of the power control mechanism and a plurality of gears and friction members formed on a second shaft arranged in parallel with a predetermined distance therebetween to control forward and backward movement of the vehicle; A continuously variable transmission mechanism disposed at a rear end portion of the second shaft and a front end portion of the third shaft disposed parallel to the second shaft at a predetermined interval, and continuously transmitting rotational power of the second shaft to the third shaft; A transfer shaft which receives power from the third shaft and transfers rotational power to the differential; It provides a continuously variable transmission for a vehicle comprising a.

Description

Stepless Transmission for Vehicles

1 is a block diagram of a first embodiment according to the present invention.

2 is a block diagram of a pulley diameter displacement generating means applied to the present invention.

3 is a configuration diagram of a second embodiment according to the present invention.

The present invention relates to a continuously variable transmission for a vehicle. More particularly, the present invention relates to a continuously variable transmission for a vehicle that can be easily applied to a front wheel drive vehicle by reducing the manufacturing cost by simplifying the configuration.

The transmission of the vehicle has a function of transmitting the driving force of the engine to the drive wheels. The transmission includes a manual transmission that directly selects a shift stage at the driver's will, and an automatic transmission in which a shift is automatically made according to the driving conditions of the vehicle. The apparatus is roughly classified into a continuously variable transmission in which stepless continuous shifting is performed without a specific shift range between each gear stage.

In the above-described transmission, the present invention relates to a continuously variable transmission having great advantages in terms of fuel economy, power performance, and weight by compensating for the disadvantages of the automatic transmission using hydraulic pressure.

Such a continuously variable transmission has a diameter displacement of the pulleys mounted on the input shaft and the output shaft and additionally installs a planetary gear set to control forward and backward movements. The problem is that the configuration becomes very complicated.

Therefore, the present invention has been invented to solve the conventional problems as described above, the object of the present invention is to provide a continuously variable transmission for a vehicle that can simplify the configuration, reduce manufacturing costs, and can be easily applied to a front wheel drive vehicle. .

In order to realize this, the present invention includes a power control mechanism for controlling the start of the vehicle while controlling the rotational power output from the engine; A forward and backward control mechanism comprising a first shaft on the rear side of the power control mechanism and a plurality of gears and friction members formed on a second shaft arranged in parallel with a predetermined distance therebetween to control forward and backward movement of the vehicle; A continuously variable transmission mechanism disposed at a rear end portion of the second shaft and a front end portion of the third shaft disposed parallel to the second shaft at a predetermined interval, and continuously transmitting rotational power of the second shaft to the third shaft; A transfer shaft which receives power from the third shaft and transfers rotational power to the differential; It is characterized by providing a continuously variable transmission for a vehicle comprising a.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention that can specifically realize the above object will be described in detail.

FIG. 1 is a configuration diagram of the first embodiment according to the present invention, in which numeral 2 designates a power interruption mechanism for interrupting the rotational power output from the engine 4.

The power interruption mechanism 2 comprises a torsional damper 6 and a clutch 8 to control the rotational power output from the torsional damper 6.

As described above, the torsional damper 6 attenuates the torsional vibration caused by the change of the output of the engine, and is known in the art.

The first and second control mechanisms 14 formed on the first shaft 10 connected to the clutch 8 and the second shaft 12 disposed in parallel with the first shaft 10 thereof may include a first shaft. The forward and backward input gears 22 and 24 and the second and second frictional members 18 and 20 are interposed between the front and rear sides of the power transmission member 16 integrally formed with the shaft 10. It is composed of the front and reverse gears 26 and 28 disposed on the shaft 12 and engaged with the forward and reverse input gears 22 and 24, between the reverse input gear 24 and the reverse gear 28. There is made through the idling gear 30.

Accordingly, when the driver manipulates the select lever (not shown) for the forward driving, the first friction member 18 is operated while the forward input gear 22 is integrated with the first shaft 10 to drive the forward gear 26. By driving the second shaft 12 in the opposite direction.

In contrast to the above, when the driver selects reverse, the second friction member 20 is operated while the reverse input gear 24 is integrated with the first shaft 10 to be driven, thereby driving the idling gear 30 and the forward gear 28. ) To drive the second shaft 12 in the same direction.

A drive and driven pulley (34) (36) having a variable diameter on the second shaft (12) and a third shaft (32) disposed parallel to the second shaft (12) at predetermined intervals; A continuously variable transmission mechanism 40 including a belt 38 for interconnecting pulleys is disposed.

As described above, the driving and driven pulleys 34 and 36 allow the endless speed change to be made by a change in diameter, and FIG. 2 shows a configuration of an embodiment for enabling it.

That is, the driving pulley 34 is composed of the fixed side pulley 42 and the variable side pulley 44, the fixed side pulley 42 is formed integrally with the second shaft 12, the variable side pulley 44 ) Has arranged the ball splines 45 on the shaft 12 at equal intervals so as to be able to move left and right on the second shaft 12.

A casing member 46 is provided on the side of the variable side pulley 44 to form a hydraulic chamber 48 therebetween, and the hydraulic chamber 48 passes through a flow path 50 formed in the second shaft 12. The pressure fluid generated by the driving force of the engine can be supplied.

And the driven pulley 36 is composed of a fixed side pulley 52 and a variable side pulley 54 as described above, the fixed side pulley 52 is formed integrally with the third shaft 32, the variable side pulley 54 is coupled by ball splines 55 disposed at equal intervals on the shaft 32 so as to move left and right on the third shaft 32.

In addition, the variable-side pulley 54 is provided with a casing member 56 to form a hydraulic chamber 58, and the hydraulic chamber 58 is connected to the engine through a flow path 60 formed in the third shaft 32. The pressure fluid generated by the driving force of the gas can be supplied.

In addition, in order to prevent slipping between the driving and driven pulleys 34 and 36 and the belt 40, an elastic body 59 is interposed in the hydraulic chamber 58 to prevent slippage at all times.

Of course, the configuration of the drive and driven pulleys 34 and 36 is not limited to the above configuration, and includes all that can be easily invented from the configuration.

In addition, the third shaft 32 which receives the continuously variable rotational power from the second shaft 12 is transmitted to the transfer shaft 66 connected to the gears 62 and 64, and the transfer shaft 66 thereof is Power is transmitted to the differential 70 that is meshed with the front end output gear 68.

Then, the rotational power input to the differential 70 drives the driving wheels not shown through the driving shaft 72 again.

In the above, the transfer shaft 66 is formed in the same direction as all other axes and connected to the differential 70 by a spur gear, so that the drive shaft 72 is also arranged in the axial direction, thereby being applied to the transverse front wheel drive vehicle. can do.

In the continuously variable transmission according to the present invention, the forward and backward movements are determined and output according to the operation of the forward and backward mechanisms 14, and when the forward or reverse rotational power is input to the second shaft 12, The third shaft 32 is driven while the stepless speed change is performed through the transmission mechanism 40. In this case, the belt 38 and the contact radius change according to the change in the outer diameter of the driving pulley 34 and the driven pulley 36. The shift is made.

The conditions for changing the rotational speed are, first, when the outer diameters of the driving pulley 34 and the driven pulley 36 are the same, and when the outer diameter of the second driving pulley 34 is larger than the diameter of the driven pulley 36; The diameter of the drive pulley 34 may be considered to be smaller than the diameter of the driven pulley 36.

In the first condition, when the outer diameters of the driving and driven pulleys 34 and 36 are the same, the transmission ratio is 1: 1.

And secondly, when the outer diameter of the drive pulley 34 is larger than the diameter of the driven pulley 36, the speed of the driven pulley 36 is larger than the rotation speed of the drive pulley 34, so that the speed is increased, and the third drive pulley When the outer diameter of 34 is smaller than the diameter of the driven pulley 36, the rotation speed of the drive pulley 34 becomes smaller than the rotation speed of the driven pulley 36, thereby decelerating.

In this way, the driving range is gradually shifted from the starting point to the high-speed driving without any speed division.

The change in the outer diameter of the drive pulley 34 and the driven pulley 36 is determined according to the hydraulic pressure supplied to the hydraulic chambers 46 and 56, and such hydraulic control is usually used in a continuously variable vehicle. Since it becomes possible to use the detailed description thereof will be omitted.

In addition, when the driven pulley 36 is rotated by the operation as described above, the rotational power thereof drives the third shaft 32, and the rotational power thereof is differential through the transfer shaft 66. The vehicle is moved forward and backward.

3 shows a second embodiment according to the present invention. In the second embodiment, the power interruption mechanism 2 is formed of the torque converter 74 in the first embodiment, and the torque converter 74 is used. The pump impeller 76 is rotated in direct connection with the crankshaft of the engine 4, as known; A turbine runner 78 which is disposed to face the pump impeller 76 and rotates together by oil ejected; It is arranged between the pump impeller 76 and the turbine runner 78 to change the flow of oil to increase the rotational force of the pump impeller 76, and comprises a stator 80, its operation is the same as the conventional Detailed description will be omitted.

As described above, the continuously variable transmission of the present invention can be easily applied to a front wheel drive vehicle by reducing the manufacturing cost by simplifying the configuration.

Claims (1)

A power interruption mechanism including a torsion damper and a clutch to control the start of the vehicle while controlling the rotational power output from the engine; Arranged in parallel with the first and second input gears and the first shaft at predetermined intervals through the first and second friction members on the front and rear sides of the power transmission member integrally formed with the first shaft on the rear side of the power control mechanism. A forward and backward control mechanism disposed on a second shaft, the forward and reverse gears being engaged with the forward and backward input gears, the idle input gears being interposed between the reverse input gears and the reverse gears; A forward and backward control mechanism comprising a first shaft on the rear side of the power control mechanism and a plurality of gears and friction members formed on a second shaft arranged in parallel with a predetermined distance therebetween to control forward and backward movement of the vehicle; The rear end of the second shaft, the drive and the driven pulley disposed on the front end of the third shaft which is arranged so as to be variable in diameter and arranged in parallel with a predetermined distance from the second axis thereof, and the pulley mutual belt A continuously variable transmission mechanism that connects to the front end; A transfer shaft which receives power from the third shaft and transfers rotational power to the differential; A continuously variable transmission for a vehicle comprising a.