KR101159835B1 - Continuously Variable Transmission - Google Patents

Abstract

According to the present invention, the gear shifting operation may be freely performed under the constant biting state of the gear, but the impact does not occur during the shift from low speed to high speed or from high speed to low speed, and the torque reduction during shifting may be performed. It is about the transmission.
The present invention is a casing coupled input shaft and output shaft; A carrier coupled to the input shaft and the output shaft; A first planetary gear coupled to the first sun gear coupled to the input shaft, a carrier coupled to the first planetary gear, and a one-way clutch connecting the carrier and the output shaft; A low speed output unit configured to reduce the rotation speed of the output shaft; The second planetary gear coupled to the carrier rotates, and the high speed output unit increases the rotational speed of the output shaft by accelerating the second sun gear by the rotation of the second planetary gear.

Description

Continuously Variable Transmission

The present invention relates to a continuously variable transmission, and more particularly, so that the variable speed action can be freely performed under the constant bite of the gear, so that no impact occurs during the shift from low speed to high speed or from high speed to low speed, The present invention relates to a continuously variable transmission capable of preventing torque reduction during shifting.

In general, the continuously variable transmission using friction has an advantage in that it is easy to adjust the speed and has a relatively simple structure, so that when applied to a vehicle, driving performance and ride comfort are excellent.

The continuously variable transmission using such friction includes a belt pulley (various pulley-belt type) for variable pulleys and a traction drive type using a rotor (friction car).

The continuously variable transmission of the currently available variable pulley-belt type is configured to be movable by separating one side of the pulley to change the rotation radius of the belt by varying the pulley, and thus the speed is continuously changed.

Such a variable pulley-belt system is simple in structure and easy to adjust the position of the pulley.

Therefore, unlike the conventional manual transmission or automatic transmission, there is no shift shock, the driving method is the same as the automatic transmission and the fuel economy is the same or slightly superior to the manual transmission.

However, such a variable pulley-belt type transmission has a disadvantage in that the speed range is narrow and the belt must be specially manufactured, the range of power transmission is greatly limited, and a low speed ratio for re-starting after a panic stop is achieved. Additional gear is needed to shift.

In particular, the conventional transmission has a problem in that a shift shock occurs in a process of shifting from low speed to high speed or shifting from high speed to low speed, and a torque decrease occurs during shifting.

The present invention has been made in order to solve the above problems of the prior art, so that the stepless action can be freely performed under the constant bite of the gear, the impact occurs during the shift from low to high speed or from high speed to low speed It is an object of the present invention to provide a continuously variable transmission that can prevent the torque reduction during shifting.

An object of the present invention described above, the casing is coupled to the input shaft through one side, the output shaft through the other coupled; A carrier disposed in the casing and configured to be rotatable coupled to the input shaft and the output shaft; A first planetary gear coupled to the first sun gear coupled to the input shaft, a 1-1 planetary gear coupled to the same shaft as the first planetary gear, and a 1-1 planetary gear coupled to the 1-1 planetary gear and fixed to the casing It consists of a first ring gear, a carrier coupled to the first planetary gear, and a one-way clutch connecting the carrier and the output shaft, and the rotational speed of the output shaft is reduced by being decelerated by the first and 1-1 planetary gears. A low speed output unit; A second planetary gear coupled to the carrier and rotated; a second ring gear coupled to the second planetary gear and freely rotated in a casing; a control device for stopping the second ring gear; and the second planetary gear; The second sun gear coupled to the output shaft is coupled to the second planetary gear by the rotation of the second planetary gear is to be achieved by a continuously variable transmission characterized in that it comprises a high speed output unit for increasing the rotational speed of the output shaft. Can be.

The casing has a cylindrical shape with a space formed therein, a first through hole is coupled to the input shaft through one side is formed, a second through hole is coupled to the output shaft through the other side is formed, the first ring gear is fixed therein And an installation space in which the control device and the second ring gear are inserted.

The carrier is integrally formed and supported by the casing, and forms a first chamber such that a shaft for supporting the first planetary gear, the first-first planetary gear, and the first planetary gear and the first-first planetary gear is configured. The second chamber is characterized in that the shaft supporting the two planetary gears and the second planetary gear is configured.

The first and first-first planetary gears are spur gears and helical gears, the first planetary gears are formed larger than the diameter of the first-first planetary gears, and the first planetary gears are gear-coupled with the first sun gears, The 1-1 planetary gear is characterized in that the gear is coupled to the first ring gear.

The first ring gear is fixed to the inner circumferential surface of the casing, characterized in that the inner tooth is formed to be coupled to the gears with the 1-1 planetary gear inside.

The first sun gear is coupled to the input shaft, the second sun gear is coupled to the output shaft, the first sun gear is geared with the first planetary gear, the second sun gear is geared with the second planetary gear. .

The one-way clutch is operated by the carrier at low speed output, characterized in that the carrier and the output shaft to be integrally operated.

The second ring gear is inserted into the installation space of the casing is coupled to enable the rotation and rotation, the control device is inserted into the installation space is characterized in that it is installed to intercept the second ring gear.

The control device is characterized in that the disc brake by the friction or the centrifugal brake in friction contact by the centrifugal force.

According to the present invention, the gear shifting operation may be freely performed continuously under the constant biting state of the gear, the impact does not occur during the shift, and the torque reduction during the shift is prevented.

1 and 2 are cross-sectional views of the present invention, Figure 1 is a view showing a low speed output, Figure 2 is a view showing a high speed output,
Figure 3 is a perspective view of the 'carrier' applied to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 are cross-sectional views of the present invention, Figure 1 is a view showing a low speed output, Figure 2 is a view showing a high speed output, Figure 3 is a perspective view showing a 'carrier' applied to the present invention.

1 to 3, the continuously variable transmission A according to the present invention includes a casing 100 in which an input shaft 200 is penetrated and coupled to one side, and an output shaft 300 is penetrated and coupled to the other side; A carrier (4) disposed in the casing (100) and coupled to the input shaft (200) and the output shaft (300) to be rotatable and having a first chamber (45) and a second chamber (47) formed thereon; A first planetary gear R1 coupled to the first sun gear S1 coupled to the input shaft 200, and a 1-1 planetary gear R1-1 coupled to the same axis as the first planetary gear R1. And a first ring gear L1 coupled to the first-first planetary gear R1-1 and fixed to the casing 100, the first planetary gear R1 and the first-first planetary gear R1-1. ) Is composed of a carrier 4 coupled in the first chamber 45, a one-way clutch C connecting the carrier 4 and the output shaft 300, and the first and first-first planetary gears R1, A low speed output unit configured to decelerate by R1-1) so that the rotational speed of the output shaft 300 is lowered; A second planetary gear R2 coupled to and rotated in the second chamber 47 of the carrier 4, a second ring coupled to the second planetary gear R2 and freely rotated in the casing 100. Composed of a gear (L2), a control device (3) for stopping the second ring gear (L2), the second sun gear (S2) coupled to the second planetary gear (R2) and mounted on the output shaft 300 and And a high speed output unit configured to increase the rotational speed of the output shaft 300 by allowing the second sun gear S2 to be accelerated by the rotation of the second planetary gear R2.

The casing 100 is cylindrical in shape with a space inside.

In addition, a first through hole in which the input shaft 200 penetrates and is coupled to a disc provided at one side of the casing 100 is formed, and a second through hole in which the output shaft 300 penetrates and is coupled to the other disc is formed.

In addition, the installation space is formed by protruding to a larger diameter into which the control device 3 and the second ring gear L2 are inserted into the casing 100.

In the carrier 4, the first to third rotating plates 41, 42, and 43 are spaced apart from each other at regular intervals, and a first chamber 45 is formed between the first rotating plate 41 and the second rotating plate 42. The second chamber 47 is formed between the second rotating plate 42 and the third rotating plate 43.

That is, the carrier 4 is integrally formed, and the input shaft 200 is configured to support the first and first-first planetary gears R1 and R1-1, and the first sun gear S1 and the first ring gear. The first chamber 45 is formed so that the L1 may be formed, and the second planetary gear S2 and the second ring gear L2 are configured to support the second planetary gear R2 on the output shaft 300. The second chamber 47 is formed to be configured.

The first and first-first planetary gears R1 and R1-1 are spur gears and helical gears, and the diameter of the first planetary gear R1 is larger than the diameter of the first-first planetary gear R1-1. do.

The first planetary gear R1 is tooth-coupled with the first sun gear S1, and the first-first planetary gear R1-1 is tooth-coupled with the first ring gear L1.

The first sun gear S1 is a spur gear and a helical gear, and the second sun gear S2 to be described later is also a spur gear and a helical gear, and the first sun gear S1 has a smaller diameter than the second sun gear S2.

In addition, the first sun gear (S1) is coupled to the input shaft, the second sun gear (S2) is coupled to the output shaft 300, the first sun gear (S1) is geared with the first planetary gear (R1), The two-wire gear S2 is gear-coupled with the second planetary gear R2 and the second ring gear L2.

The first ring gear L1 has a ring shape fixedly installed on an inner circumferential surface of the casing 100, and an internal tooth is formed to be tooth-coupled with the first-first planetary gear R1-1.

The second ring gear (L2) is a ring shape having a size similar to the first ring gear (L1), is inserted into the installation space of the casing 100 is coupled to enable the rotation and rotation, the control device contacts the outer circumference The disk L2-2 to be formed is formed.

The second ring gear L2 is locked or released by the control device 3 being in contact with or detached from the disk L2-2.

The control device 3 is mounted in the installation space of the casing 100, and is installed to interrupt the second ring gear L2.

As a specific example of the control device 3, a brake by friction or a centrifugal brake in friction contact with a centrifugal force is applied.

Therefore, when the control device 3 is operated, the second ring gear L2 is locked, and the revolution and rotation are stopped.

The one-way clutch C is coupled between the output shaft 300 and the carrier 4 of the second through hole of the casing 100, and is operated at low speed so that the carrier 4 and the output shaft 300 operate integrally. .

Referring to the operation of the present invention configured as described above are as follows.

First, as shown in FIG. 1, when the first sun gear S1 is rotated by the rotation of the input shaft 200, the first planetary gear R1 and the first-first planetary gear R1-1 are shown. ) Is rotated.

At this time, the first deceleration is performed while the input power is transmitted from the first sun gear S1 to the first planetary gear R1.

Thereafter, the second deceleration is performed while the first-first planetary gear R1-1 is rotated along the first ring gear L1.

In addition, the carrier 4 rotates in conjunction with the first planetary gear R1 and the first-first planetary gear R1-1, and the one-way clutch C operates to operate the carrier 4 and the output shaft 300. Since it is locked and rotated together, it can be output to the secondary decelerated output.

On the other hand, the high speed output, as shown in Figure 2, when the first sun gear (S1) is rotated by the rotation of the input shaft 200, the first planetary gear (R1) and the 1-1 planetary gear (R1-1) ) Is rotated.

At this time, since the first ring gear L1 is fixed to the casing 100, power is transmitted to the second planetary gear R2 through the carrier 4.

The second planetary gear R2 is idle together with the second ring gear L2.

At this time, since the second ring gear L2 is stopped by the controller 3, the second planetary gear R2 is increased to rotate the second sun gear S2.

That is, the rotational speed of the output shaft 300 is increased by concentrating the rotational force of the second planetary gear R2 to the second sun gear S2 without being distributed to the second ring gear L2.

As such, the rotation speed of the output shaft 300 is gradually increased, and the highest speed can be output when the second ring gear L2 is completely stopped.

At this time, the one-way clutch C is not operated.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it will be apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the invention, It is obvious that the claims fall within the scope of the claims.

4: carrier 100: casing
200; Input shaft 300: output shaft
41 ~ 43: 1st ~ 3rd rotating plate R1: 1st planetary gear
R2: 2nd planetary gear R1-1: 1-1 planetary gear
L1: 1st Ring Gear L2: 2nd Ring Gear
S1; 1st Sun Gear S2: 2nd Sun Gear
48: first chamber 49: second chamber

Claims (9)

An input shaft penetrated and coupled to one side, and an output shaft penetrated and coupled to the other side;
A carrier disposed in the casing and having first and second chambers coupled to the input shaft and the output shaft to be rotatable, the first and first 1-1 planetary gears and the second planetary gears being coupled;
A first planetary gear coupled to the first sun gear coupled to the input shaft, a 1-1 planetary gear coupled to the same shaft as the first planetary gear, and a 1-1 planetary gear coupled to the 1-1 planetary gear and fixed to the casing It consists of a first ring gear, a carrier coupled to the first planetary gear, and a one-way clutch connecting the carrier and the output shaft, and the rotational speed of the output shaft is reduced by being decelerated by the first and 1-1 planetary gears. A low speed output unit;
A second planetary gear coupled to the carrier and rotated; a second ring gear coupled to the second planetary gear and freely rotated in a casing; a control device for stopping the second ring gear; and the second planetary gear; A high speed output unit coupled to the high speed output unit configured to include a second sun gear mounted to the output shaft and to increase the rotation speed of the output shaft by accelerating the second sun gear by the rotation of the second planetary gear.
A continuously variable transmission comprising a. The method of claim 1,
The casing has a cylindrical shape with a space formed therein, a first through hole is formed through the input shaft is coupled to one side, a second through hole is coupled to the output shaft through the other side, the control device and the second ring therein Continuously variable transmission characterized in that the installation space is formed the gear is inserted. The method of claim 1,
The carrier is integrally formed, the input shaft is configured to support the first and first-first planetary gear shafts, the first chamber is formed to form the first sun gear and the first ring gear, and the second is formed on the output shaft. And a second chamber configured to support the planetary gear shaft and to form a second sun gear and a second ring gear. The method of claim 1,
The first and first-first planetary gears are spur gears or helical gears, the first planetary gears are formed larger than the diameter of the first-first planetary gears, and the first planetary gears are gear-coupled with the first sun gears, 1-1 planetary gear is a continuously variable transmission, characterized in that the gear is coupled to the first ring gear. The method of claim 1,
The first ring gear is fixed to the inner circumferential surface of the casing, the continuously variable gear, characterized in that the inner tooth is formed so as to be geared with the first-first planetary gear inward. The method of claim 1,
The first sun gear is coupled to the input shaft, the second sun gear is coupled to the output shaft, the first sun gear is geared with the first planetary gear, the second sun gear is geared with the second planetary gear. Continuously variable transmission. The method of claim 1,
The one-way clutch is operated at a low speed output to continuously operate the carrier and the output shaft integrally. The method of claim 1,
The second ring gear is inserted into the installation space of the casing is coupled to enable the rotation and rotation, the control device is inserted into the installation space, characterized in that the continuously variable transmission characterized in that installed to control the second ring gear. The method of claim 1,
The control device is a continuously variable transmission, characterized in that the disc brake or the centrifugal brake in frictional contact by centrifugal force.

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