KR200155261Y1 - Transmission - Google Patents

Abstract

To provide a four-wheel drive continuously variable transmission of a longitudinal vehicle that can implement a four-wheel drive while reducing the manufacturing cost and contribute to light weight with a simple structure; An oscillation mechanism disposed on an input shaft connected to the engine; A forward and backward control mechanism disposed on a rear input shaft of the oscillation mechanism to control forward and backward directions of the vehicle; Drive pulleys disposed at the output side ends of the forward and reverse control mechanisms, driven pulleys disposed on the drive shaft for transmitting power to the rear wheels, and belts connecting the drive and driven pulleys to vary the diameter of these pulleys. A continuously variable transmission mechanism for performing continuously variable transmission; A center differential mechanism disposed on the drive shaft to receive power from the continuously variable transmission mechanism and perform a differential function for front and rear wheels; A front differential mechanism disposed at a front side of the center differential mechanism to receive power from the center differential mechanism and perform a differential function on both side wheels of the front wheel; It provides a four-wheel drive continuously variable transmission of the longitudinal vehicle comprising a.

Description

Four-wheel Drive Continuous Transmission

The present invention relates to a four-wheel drive continuously variable transmission of a longitudinal vehicle, and more particularly, to a continuously variable transmission for a vehicle that can realize four-wheel drive while contributing to a simple and lightweight structure.

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

In the transmission as described above, the present invention relates to a continuously variable transmission having a great advantage in terms of fuel economy, power transmission performance, and weight by supplementing the disadvantages of the automatic transmission using the hydraulic pressure, the continuously variable transmission thereof The method using the diameter displacement of the pulley mounted on the output shaft is mainly used.

In the continuously variable transmission as described above, the present invention has an object to provide a four-wheel drive continuously variable transmission of the longitudinal vehicle that can terminate the engine and drive four wheels.

Further, in forming the continuously variable transmission, an additionally simple structure is provided to provide a continuously variable transmission for a vehicle capable of implementing four-wheel drive while reducing manufacturing cost and contributing to light weight.

In order to realize this, the present invention includes an oscillation mechanism disposed on an input shaft connected to the engine; A forward and backward control mechanism disposed on a rear input shaft of the oscillation mechanism to control forward and backward directions of the vehicle; Drive pulleys disposed on the output side ends of the forward and reverse control mechanisms, driven pulleys disposed on the drive shafts for transmitting power to the rear wheels, and belts connecting the drive and driven pulleys with endlessly variable diameters of these pulleys. A continuously variable transmission mechanism for shifting; A center differential mechanism disposed on the drive shaft to receive power from the continuously variable transmission mechanism and perform a differential function for front and rear wheels; A front differential mechanism disposed at a front side of the center differential mechanism to receive power from the center differential mechanism and perform a differential function on both side wheels of the front wheel; It provides a continuously variable transmission for a vehicle comprising a.

1 is a block diagram of an endless transmission according to the present invention.

2 is a cross-sectional view of the continuously variable transmission means applied to the present invention.

* Explanation of symbols for main parts of the drawings

2: engine 6: oscillation mechanism

8: forward and backward control mechanism 14,16: 1st, 2nd friction member

28: continuously variable transmission mechanism 30: drive pulley

34: driven pulley 36: belt

60: center differential mechanism 64: front differential mechanism

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention capable of realizing the above object in detail as follows.

1 is a configuration diagram of a continuously variable transmission according to the present invention, in which rotational power generated from the engine 2 is transmitted to an oscillation mechanism 6 disposed on an input shaft 4 connected thereto.

The oscillation mechanism 6 is a mechanism that transmits and blocks rotational power of the engine 2 or absorbs torsional vibration when a torque conversion is made, and may include a torque converter or a torsional damper. You may use either.

In addition, a double pinion planetary gear set is applied to the front and reverse control mechanisms 8 disposed on the input shaft 4 on the rear side of the oscillation mechanism 6, and the sun gear 10 thereof is directly connected to the input shaft 4. The ring gear 12 is connected to the input shaft 4 via the first friction member 14 to act as an input element, and is connected to the transmission housing 18 through the second friction member 16 to react with the reaction force. It is made to act as an element.

In addition, the planetary carrier 24 connecting the first and second pinions 20 and 22 to be engaged between the sun gear 10 and the ring gear 12 may have a continuously variable transmission mechanism through the first power transmission member 26. Connected with 28.

In the above, the first friction member 14 may use a conventional multi-plate clutch as a clutch means, and the second friction element 16 may use a conventional band brake as a brake means.

The continuously variable transmission mechanism 28 includes a drive pulley 30 connected to the rear end of the first power transmission member 26 and a driven pulley 34 disposed on the drive shaft 32 without rotation interference. It comprises a belt 36 connecting the two pulleys (30) and (34).

In the above drive and driven pulley 30, 34 is controlled by the hydraulic pressure generated by the driving force of the engine 2, the outer diameter thereof is variable to perform the shifting operation, Figure 2 is an embodiment to enable it An example configuration is shown.

That is, the driving pulley 30 is composed of a fixed side pulley 38 and a variable side pulley 40, the fixed side pulley 38 is formed integrally with the first power transmission member 26, the variable side pulley 40 is coupled in a state capable of moving forward and backward on the first power transmission member 26.

A casing member 42 is provided on the side of the variable side pulley 40 to form a hydraulic chamber 44 therebetween.

The hydraulic chamber 44 is capable of supplying a pressure fluid generated by the driving force of the engine through the flow passage 46 formed in the first power transmission member 26.

And the driven pulley 34 is composed of a fixed side pulley 48 and a variable side pulley 50 as described above, the fixed side pulley 48 is integrally formed with a second power transmission member 52 made of a hollow shaft Is formed.

In addition, the variable side pulley 50 is coupled to move forward and backward on the second power transmission member 52, the variable side pulley 50 is provided with a casing member 54 is interposed to the hydraulic chamber 56 The hydraulic chamber 56 is configured to be supplied with a pressure fluid generated by the driving force of the engine through the flow path 58 formed in the second power transmission member 52.

Of course, the configuration of the drive and driven pulleys 30 and 34 is not limited to the above configuration, and includes all that can be easily devised from the configuration.

The second power transmission member 52 is formed to have a hollow shaft so that the drive shaft 32 can be penetrated without rotation interference.

In addition, a center differential mechanism 60 is connected to the front side of the second power transmission member 52, one center differential mechanism 60 is connected to the front end of the drive shaft 32, the other Is coupled between the pair of side gears 68 and 70 connected to the front differential mechanism 64 through a third power transmission member 62 and the side gears 68 and 70 to transfer the second power. And a pair of pinions 72 and 74 connected to the member 52.

Accordingly, the rotational power transmitted from the second power transmission member 52 is uniformly or differentially generated according to the load applied to the front and rear wheels, and is transmitted to the rear wheels through the drive shaft 32 and at the same time, the second power transmission member 62 is moved. It is transmitted to the front differential mechanism 64 through.

The front differential mechanism 64 connected to the center differential mechanism 60 through the third power transmission member 62 is perpendicular to the drive gear 76 disposed at the front end of the third power transmission member 62. A pair of side gears 84 and 86 connected to the front wheel drive shaft 82 for transmitting a driving force to the front wheels in the case 80 integrally formed with the driven gear 78 to be engaged; And pinions 88 and 90 that are engaged between 84 and 86 and are connected to the case 80.

Accordingly, in the front differential mechanism 64 in which the rotational power transmitted from the center differential mechanism 60 is disposed in the vehicle width direction, a constant speed or differential function is performed according to the load applied to the left and right wheels of the front wheel.

In the above, the center and front differential mechanisms 60 are well known using bevel gears, and thus description of the operation of the differential function is omitted.

In the continuously variable speed shift device according to the present invention, when the driver selects a selector lever (not shown) in the driving D range, the first friction member 14 is operated and controlled.

Then, the power of the input shaft 4 is input through the sun gear 10 and the ring gear 12, so that the double pinion planetary gear set is directly connected and the forward rotation power through the planet carrier 24 and the first power transmission member 26. Will print

When the power is output from the forward and reverse rotation control mechanism 8 as described above, the shift is made according to the change in the outer diameter of the driving pulley 30 and the driven pulley 34. The rotation speed change condition is, firstly, the driving pulley ( 30 and when the outer diameter of the driven pulley 34 is the same, the outer diameter of the second drive pulley 30 is larger than the diameter of the driven pulley 34, and the diameter of the third drive pulley 30 is driven pulley 34 It can be divided into the case smaller than the diameter of).

In the first condition, when the outer diameters of the driving and driven units 30 and 34 are the same, the transmission ratio is 1: 1.

And secondly, when the outer diameter of the drive pulley 30 is larger than the diameter of the driven pulley 34, the speed of the driven pulley 34 is increased because the rotation speed of the driven pulley 34 becomes larger, the third drive pulley When the outer diameter of the 30 is smaller than the diameter of the driven pulley 34, the rotation speed of the drive pulley 30 becomes smaller than the rotation speed of the driven pulley 34, so that the deceleration is performed.

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

The change in the outer diameter of the drive pulley 30 and the driven pulley 34 is determined according to the hydraulic pressure supplied to the hydraulic chambers 44 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 34 is increased and decelerated by the above-described action, and the power is transmitted, the rotational power thereof is transmitted to the center differential mechanism 60 through the second friction member 52 and according to the load conditions of the front and rear wheels. The constant velocity or differential is made to be transmitted to the front differential mechanism 64 and the rear wheel.

In addition, the rotational power transmitted to the front differential mechanism 64 is driven while performing the constant speed or differential function according to the load condition applied to both side wheels of the front wheel, and the power for the rear wheel drive is not shown through the drive shaft 88. It is delivered to a rear wheel differential mechanism to drive the rear wheels.

As described above, in forming the continuously variable transmission, there is an advantage that the four-wheel drive can be implemented while reducing the manufacturing cost and contributing to light weight by simplifying the structure.

Claims (5)

An oscillation mechanism 4 disposed on an input shaft connected to the engine 2; A forward and backward control mechanism 8 disposed on a rear input shaft of the oscillation mechanism 4 to control forward and backward directions of the vehicle; A drive pulley 30 disposed at an output side end of the forward and backward control mechanism 8, a driven pulley 34 disposed on a drive shaft 32 for transmitting power to the rear wheel, and the drive and driven pulley ( A continuously variable transmission mechanism consisting of a belt 36 connecting the 30 and 34 to continuously vary the diameter of these pulleys; A center differential mechanism (60) disposed at a front end of the drive shaft (32) to receive power from the continuously variable transmission mechanism (28) to perform differential functions for the front and rear wheels; A front differential mechanism 64 disposed at the front side of the center differential mechanism 60 in a vehicle width direction to receive power from the center differential mechanism 60 to perform a differential function on both side wheels of the front wheel; Four-wheel drive continuously variable speed of the longitudinal vehicle comprising a. The method of claim 1, wherein the forward and reverse control mechanism (8) is composed of a double pinion planetary gear set, the sun gear 10 is directly connected to the input shaft (4), the ring gear 12 to the first friction member (14) The first and second pinions, which are connected to the input shaft 4 and connected to the transmission housing 18 through the second friction member 16, are engaged between the sun gear 10 and the ring gear 12. 20) 22, the planetary carrier 24 is connected to the continuously variable transmission mechanism 28, characterized in that the four-wheel drive continuously variable transmission device, characterized in that via the first power transmission member (26). The four-wheel drive continuously variable transmission of claim 2, wherein the first friction member (14) uses a multi-plate clutch as the clutch means, and the second friction member (16) uses a band brake as the brake means. The center differential mechanism 60 is disposed on the drive shaft 32 without rotation interference so that one is connected to the drive shaft 32 to transmit power to the rear wheel, and the other is a third power transmission member ( A pair of side gears 68 and 70 connected to the front differential mechanism 64 through the pair of side gears 68 and 70 and connected to the second power transmission member 52. A four-wheel drive continuously variable transmission of a longitudinal vehicle, characterized in that it comprises a pair of pinions (72, 74). The case 80 according to claim 1, wherein the front differential mechanism 64 is integrally formed with the driven gear 78 engaged to be perpendicular to the drive shear 76 disposed at the front end of the third power transmission member 62. A pair of side gears 84 and 86 connected to the front wheel drive shaft 82 for transmitting a driving force to the front wheels and the side gears 84 and 86 to be connected to the case 80. Four-wheel drive continuously variable transmission of the longitudinal vehicle characterized in that it comprises a pinion (88, 90).