KR102469747B1 - Dual clutch device - Google Patents

Abstract

According to one embodiment of the present invention, in a dual clutch device provided inside a housing in which a transmission is coupled to one side and an engine is coupled to the other side, a motor including a stator and a rotor accommodated inside a cover, and the motor A dual clutch formed on the transmission side as a reference and connected to the rotor, an engine clutch formed on the engine side based on the motor and connected to the rotor, and formed between the motor and the dual clutch, It is provided between a flow path receiving hydraulic pressure from the outside of the housing and between the cover and the rotor shaft of the rotor or between the rotor shaft inner diameter of the rotor, and the portion of the stator, the rotor, and the rotor shaft located inside the cover Provided is a dual clutch device characterized in that it includes a sealing portion for sealing.

Description

Dual clutch device {DUAL CLUTCH DEVICE}

The present invention relates to a dual clutch device, and more particularly, to a dual clutch device used in a hybrid vehicle.

A dual clutch transmission (DCT) is a type of automated manual transmission (AMT) in which a clutch and a gear shift actuator are attached to a manual transmission.

In particular, a dual-clutch transmission is a device that has both the efficiency of a manual transmission and the convenience of an automatic transmission. It performs automatic shifting like a vehicle with an automatic transmission, but basically includes the mechanism of a manual transmission, so it can be combined with an automatic transmission and a manual transmission. It is possible to provide all shifting sensations of the transmission.

In addition, the above-described dual-clutch transmission is a transmission in which two clutches are applied to shift shifts while alternately operating each clutch when shifting odd and even gears. Through a mechanism that alternately operates odd and even gear shifts, It is possible to improve the sense of torque disconnection during shifting of an existing manual transmission (MT) and an automated manual transmission.

Recently, the above-described dual clutch transmission has been applied to a hybrid electric vehicle (HEV) to increase efficiency and maximize fuel efficiency of the hybrid electric vehicle.

Meanwhile, in a hybrid electric vehicle to which a dual clutch transmission is applied, an electric motor and an engine clutch capable of transmitting/cutting power between the electric motor and the engine are required.

Friction may occur when the above-described engine clutch is driven, and fine dust generated by friction of the engine clutch may flow into the electric motor, adversely affecting performance and durability of the motor.

In addition, external foreign substances and moisture may also flow into the electric motor, which adversely affects the performance and durability of the motor.

Publication No. 10-2018-0068392

An object of the present invention is to provide a structure capable of sealing a motor from dust, external foreign substances and moisture generated by driving an engine clutch in a hybrid electric vehicle to which a dual clutch device is applied.

A dual clutch device according to an embodiment of the present invention is provided inside a housing to which a transmission is coupled to one side and an engine is coupled to the other side, and includes a motor including a stator and a rotor accommodated inside a cover, and the motor as a reference. A dual clutch formed on the transmission side and connected to the rotor, an engine clutch formed on the engine side based on the motor and connected to the rotor, and formed between the motor and the dual clutch and the housing It is provided between a flow path receiving hydraulic pressure from the outside and between the cover and the rotor shaft of the rotor or between the rotor shaft inner diameter of the rotor to seal the stator, the rotor, and the part located inside the cover among the rotor shaft. It is characterized in that it comprises a sealing portion to.

Preferably, the cover is characterized in that located between the dual clutch and the engine clutch.

Preferably, the sealing part includes a first sealing member inserted between one end of the cover located on the engine clutch side and one side of the rotor shaft located on the engine clutch side and exposed to the outside of the cover; A second sealing member inserted between the other end of the cover located on the flow path side and the other side of the rotor shaft located on the flow path side and exposed to the outside of the cover, wherein the first sealing member and the second The sealing member may seal a part located inside the cover among the rotor, the stator, and the rotor shaft located inside the cover.

Preferably, the engine clutch is connected to an engine clutch actuator operated in an axial direction, and the engine clutch actuator is coupled to the cover.

Preferably, the engine clutch includes a through portion protruding toward the engine clutch actuator, and the through portion of the engine clutch passes through a through hole formed on one side of the rotor shaft exposed to the outside of the cover to Characterized in that it is connected to the actuator.

Preferably, the sealing part may further include a sealing plate provided between the engine clutch actuator and the through part, and an inner diameter part and an outer diameter part of the sealing plate are in contact with an inner diameter part of the rotor shaft.

Preferably, an engine clutch actuator bearing is provided between the sealing plate and the engine clutch actuator.

Preferably, at least a portion of the rotor shaft is formed to surround the engine clutch actuator bearing.

Preferably, when the hydraulic pressure is supplied through the passage and the engine clutch actuator is moved in the axial direction, the sealing plate is moved in the axial direction to block the inflow of dust from the through hole into the inner diameter portion of the rotor shaft. It is characterized by doing.

Preferably, a sealing member is provided on an inner diameter part and an outer diameter part of the sealing plate, respectively, and the sealing member is made of the same material as that of the rotor shaft.

Preferably, the passage passes through a cover and is connected to the engine clutch actuator.

Preferably, the housing further includes a damper provided inside the housing and connected to the engine clutch through a damper spline, outside the engine clutch, the damper spline is positioned between an outer diameter portion and an inner diameter portion of the engine clutch characterized by being

Preferably, the dual clutch, the motor, and the damper are arranged in a line with respect to an engine output shaft direction of the engine, and outside the rotor, at least a part of the engine clutch is located on an inner diameter side of the rotor. to be

According to the present invention, by densely configuring the sealing structure between the motor and the engine clutch using a plurality of sealing members, it is possible to seal the motor from dust, external foreign substances and moisture generated according to the driving of the engine clutch.

In addition, the performance and durability of the motor can be maintained by the above-described motor sealing structure.

1 is a diagram showing a schematic structure of a hybrid vehicle to which a dual clutch device according to an embodiment of the present invention is applied.
2 is a view showing a dual clutch device according to an embodiment of the present invention.
FIG. 3 is a view showing a part of FIG. 2 .

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to components of each drawing, it should be noted that the same components have the same numerals as much as possible even if they are displayed on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted. In addition, although preferred embodiments of the present invention will be described below, the technical idea of the present invention is not limited or limited thereto and can be modified and implemented in various ways by those skilled in the art.

1 is a diagram showing a schematic structure of a hybrid vehicle to which a dual clutch device 100 according to an embodiment of the present invention is applied.

Referring to FIG. 1 , the dual clutch device 100 may be provided inside the housing H.

As an example, the dual clutch device 100 may include a motor M, dual clutches K1 and K2, an engine clutch 10, and a damper 20 inside the housing H.

In addition, as shown in FIG. 1 , a transmission TM may be coupled to one side of the housing H, and an engine E may be coupled to the other side.

The motor M is a type of electric motor, and is composed of a rotor R and a stator S, and may simultaneously perform motor and generator functions.

As an example, in the EV mode, power can be transmitted to the transmission TM only by driving the motor M, and in the HEV mode, rotational power of the motor M can act as auxiliary power and be transmitted to the transmission TM.

The engine clutch 10 may transmit or block power from the engine E to the motor M.

In addition, the damper 20 may be configured to be connected to the engine E and the engine clutch 10 and to mitigate shock that may occur when the engine clutch 10 is driven.

As an example, the damper 20 may function to relieve the spring motion of the damper spring 24 to be described later.

In one embodiment of the present invention, the dual clutch device 100 may be applied to a hybrid vehicle.

As an example, in the dual clutch device 100 applied to a hybrid vehicle, the rotational power transmitted from the engine output shaft of the engine E is transmitted through the engine clutch 10 and the rotor R in the motor M to the dual clutch K1. , K2).

Thereafter, the dual clutches K1 and K2 may be selectively connected to transmission input shafts (not shown), and the received rotational power may be selectively transmitted to odd-numbered gear shift stages or even-numbered gear stages of the transmission TM through the transmission input shaft. have.

At this time, at least two transmission input shafts may be provided so as to be selectively connected to odd-numbered gear shift stages or even-numbered gear stages of the transmission TM according to power transmission, and K1 among the dual clutches K1 and K2 is the transmission TM. ), and K2 can transmit rotational power to even-numbered gears of the transmission TM.

FIG. 2 is a view showing a dual clutch device 100 according to an embodiment of the present invention, and FIG. 3 is a view showing a portion of FIG. 2 .

With reference to FIGS. 2 and 3 , the configuration of the dual clutch device 100 according to an embodiment of the present invention will be described in detail.

At this time, in FIGS. 2 and 3, the above-described transmission TM and engine E are omitted.

Referring to FIGS. 2 and 3 , the motor M described above includes a stator S and a rotor R.

The aforementioned stator (S) and rotor (R) may be accommodated in the cover (C), and the rotor (R) may be connected to the rotor shaft (R0).

As an example, the cover C may be positioned between the aforementioned dual clutches K1 and K2 and the engine clutch 10, and may be a part of the housing H.

The rotor R may be rotatably supported by being spline-connected to the dual clutch input shaft K0 connected to the dual clutches K1 and K2 through the rotor shaft R0, and the stator S may cover ( C) can be fixed in

Also, as shown in FIGS. 2 and 3 , at least a portion of the rotor shaft R0 may extend outside the cover C and be spline-connected to the dual clutch input shaft K0.

In one embodiment of the present invention, the dual clutches K1 and K2 may be formed on the side of the transmission TM based on the motor M described above, as shown in FIGS. 2 and 3 .

In addition, the dual clutches K1 and K2 may be connected to a dual clutch input shaft K0 that is spline-connected to the rotor shaft R0 of the rotor R.

At this time, the dual clutches K1 and K2 may be connected to the dual clutch actuators A1 and A2 operated in the axial direction, respectively, and the dual clutch actuators A1 and A2 may be provided on the transmission side.

In one embodiment of the present invention, as described above, K1 of the dual clutches K1 and K2 may transmit rotational power to odd gear stages of the transmission TM, and in detail, may be connected to A1 of the dual clutch actuator, , A1 may transmit power to the transmission input shaft connected to the odd-numbered shift stages of the transmission TM.

In addition, K2 of the dual clutches K1 and K2 may transmit rotational power to even-numbered shift stages of the transmission TM, and in detail, may be connected to A2 of the dual-clutch actuators, and A2 may transmit power to even-numbered shift stages of the transmission TM. Power can be transmitted to the transmission input shaft connected to the gear.

In one embodiment of the present invention, a flow path 0 may be formed between the motor M and the dual clutches K1 and K2, and the oil path O receives hydraulic pressure from the outside of the housing H and the engine clutch (10) can be driven.

The engine clutch 10 may be formed on the side of the engine E based on the aforementioned motor M, and the engine clutch 10 may be spline-connected to the rotor shaft R0 of the rotor R.

In one embodiment of the present invention, the engine clutch 10 may be connected to the engine output shaft E0 of the engine E, receive rotational power transmitted from the engine output shaft E0 and transfer it to the rotor R .

The engine clutch 10 is connected to an engine clutch actuator 16 operated in an axial direction, and the engine clutch actuator 16 may be coupled to the cover C.

Here, the engine clutch 10 includes a through portion 18 protruding toward the engine clutch actuator 16 .

The through-portion 18 of the engine clutch 10 may be connected to the engine clutch actuator 16 through a through-hole R01 formed on one side of the rotor shaft R0 exposed to the outside of the cover C. .

In this case, an engine clutch actuator bearing 162 may be provided between the through portion 18 of the engine clutch 10 and the engine clutch actuator 16 .

The engine clutch actuator bearing 162 can rotationally support the engine clutch actuator 16 and support axial force generated by the operation of the engine clutch actuator 16 .

In addition, the above-described flow path O may be connected to the engine clutch actuator 16 through the cover C, and the engine clutch actuator 16 receives hydraulic pressure from the flow path O and penetrates the engine clutch 10. The engine clutch 10 can be driven by pushing the part 18.

At this time, the operating directions of the dual clutch actuators A1 and A2 and the engine clutch actuator 16 may be the same from the transmission TM side to the engine E direction.

In one embodiment of the present invention, as shown in FIGS. 2 and 3, the aforementioned dual clutches K1 and K2, the motor M, and the damper 20 are in the direction of the engine output shaft E0 of the engine E. can be arranged in a row.

As an example, outside the rotor R, at least a part of the engine clutch 10 may be located on the inside diameter side of the rotor R.

In addition, a terminal (T) may be connected to one side of the stator (S) of the motor (M).

At this time, the terminal (T) is located between the motor (M) and the engine (E), one side may be opened in the direction of the engine (E).

As an example, the aforementioned terminal (T) may be a connector (Connector).

Referring to FIGS. 2 and 3 , the dual clutch device 100 includes a damper 20 provided inside a housing H and connected to the engine clutch 10 through damper splines 22 .

A damper spring 24 may be disposed above the damper 20, and a radial center of the damper spring 24 may be located below the aforementioned terminal T.

Due to the configuration described above, the dual clutch device 100 according to an embodiment of the present invention has an effect of reducing the overall length by optimizing the layout of each component provided in the housing H.

More specifically, in the dual clutch device 100 according to an embodiment of the present invention, the dual clutches K1 and K2, the motor M, and the damper 20 are moved in the direction of the engine output shaft E0 of the engine E. Components (engine clutch 10, etc.) provided inside the housing H may be disposed in a state in which they are arranged in a line with respect to each other.

In this state, at least a portion of the engine clutch 10 may be positioned on the inner diameter side of the rotor R as shown in FIGS. 2 and 3 .

Further, in a state where the terminal T is located between the motor M and the engine E, the radial center of the damper spring 24 may be positioned lower than the terminal T.

In addition, the dual clutch actuators A1 and A2 may be provided on the side of the transmission TM, and the motor M accommodated in the above-described cover C may operate on the above-described dual clutches K1 and K2 and the engine clutch 10 ) can be positioned between them.

In addition, the engine clutch actuator 16 is coupled to the cover C, and the position of the oil passage 0 supplying hydraulic pressure to the engine clutch actuator 16 is positioned between the motor M and the dual clutches K1 and K2. can be positioned.

Accordingly, the dual clutch device 100 for a hybrid vehicle according to an embodiment of the present invention is a dual clutch device even when the motor M and the engine clutch 10 are applied to an existing conventional DCT vehicle. By shortening the overall length of (100), it is possible to improve mountability when the dual clutch device 100 is mounted on a vehicle.

Referring to FIGS. 2 and 3 , the engine clutch 10 may include a retainer 12 supported on an outer diameter portion of the rotor shaft R0 and connected to the damper 20 through a damper spline 22. .

As an example, the damper splines 22 described above may be located outside the engine clutch 10 and between the outer diameter portion and the inner diameter portion of the engine clutch 10 .

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In one embodiment of the present invention, the retainer 12 may be supported on the outer diameter portion of the rotor shaft R0 via the support bearing B.

In addition, the disk 14 may be connected to the inner diameter of the retainer 12, and the disk 14 may be stably fixed to the rotor shaft R0 through the snap ring 30.

The snap ring 30 may limit the axial movement of at least a portion of the disk 14 toward the engine E in a state in which the aforementioned disk 14 is fixed to the rotor shaft R0.

In addition, the snap ring 30, in a state in which the entire engine clutch 10 including the disk 14 is fixed to the rotor shaft R0, at least a portion of the engine clutch 10 in the axial direction toward the engine E Movement may be restricted.

In one embodiment of the present invention, as shown in FIGS. 2 and 3, the disk 14 is spline-connected to the outer diameter of the rotor shaft R0 and fixed to the rotor shaft R0 through a snap ring 30. It includes at least one inner disk 142 and at least one outer disk 144 disposed between the inner disk 142 and connected to the inner diameter of the retainer 12 by splines.

As an example, the above-described penetrating portion 18, as shown in FIGS. 2 and 3 , may be formed in an inner disk 142 located on the side of the engine clutch actuator 16 among at least one inner disk 142. have.

Also, a separating spring 19 may be interposed between the inner disks 142 , and an outer diameter of the separating spring 19 may be smaller than an inner diameter of the outer disk 144 .

As an example, when hydraulic pressure is supplied to the engine clutch actuator 16 from the aforementioned oil passage O to move the through portion 18, the inner disk 142 located on the engine clutch actuator 16 side direction can be moved.

At this time, among the at least one inner disk 142, as shown in FIGS. 2 and 3 , the inner disk 142 in contact with the snap ring 30 may be restricted from moving in the axial direction toward the engine E.

Further, when the inner disc 142 located on the side of the engine clutch actuator 16 is moved in the axial direction, the aforementioned separating spring 19 can be compressed.

Meanwhile, when the hydraulic pressure supplied from the oil passage O to the engine clutch actuator 16 is released, the inner disk 142 located on the side of the engine clutch actuator 16 is moved by the elastic restoring force of the separating spring 19. It can be returned to its position, and thus a gap between the inner disks 142 can be formed.

In the above-described embodiment of the present invention, the rotational power of the engine E is transmitted through the engine output shaft E0 to the retainer 12 of the engine clutch 10, the outer disk 144, the inner disk 142, the rotor shaft ( R0), and the dual clutch input shaft K0 in order, and can be transmitted to the dual clutches K1 and K2.

And, among at least one inner disk 142, as shown in FIGS. 2 and 3, the inner disk 142 in contact with the snap ring 30 has a stepped portion 1422 (step difference) in the direction of the engine E described above. can be formed

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Due to the configuration described above, the dual clutch device 100 according to an embodiment of the present invention has an effect of reducing the overall length of the dual clutch device 100 by adjusting the size and position of the damper spline 22 .

In detail, as shown in FIGS. 2 and 3 , in the dual clutch device 100 according to an embodiment of the present invention, the damper spline 22 is applied from the outside of the outer disk 144 to the outer disk 144. The engine fastening member E1 may be positioned into the housing H.

In addition, by forming a stepped portion 1422 in the direction of the engine E on the inner disk 142 in contact with the snap ring 30, it is possible to sufficiently secure a space in which the above-described support bearing B is disposed.

Also, since the outer diameter of the separating spring 19 is smaller than the inner diameter of the outer disk 144, the space occupied by the entire engine clutch 10 can be reduced.

With the above configuration, the dual clutch device 100 for a hybrid vehicle according to an embodiment of the present invention sufficiently secures a space in which parts can be disposed close to the engine output shaft E0 and the dual clutch input shaft K0. By doing so, the overall length of the dual clutch device 100 can be shortened, and mountability can be improved when the dual clutch device 100 is mounted on a vehicle.

Referring to FIGS. 2 and 3 , a fixing member 40 may be coupled to an end of the rotor shaft R0 located on the engine E side.

The aforementioned dual clutches K1 and K2 and the engine clutch 10 operate in the axial direction (from the transmission TM side to the engine E side) via the dual clutch actuators A1 and A2 and the engine clutch actuator 16, respectively. ) can be driven.

At this time, when each actuator operates, the dual clutches K1 and K2 and the engine clutch 10 require a reaction force for their driving, so that axial fixation is essential.

To this end, the dual clutch device 100 according to an embodiment of the present invention includes a fixing member 40 for fixing the aforementioned support bearing B and the rotor shaft R0 in the axial direction.

As an example, the fixing member 40 may be a nut, and one side may be coupled to the dual clutch input shaft K0.

As shown in FIGS. 2 and 3 , the fixing member 40 includes the support bearing B and the rotor shaft R0 located between the retainer 12 of the engine clutch 10 and the outer diameter of the rotor shaft R0. It can be fixed in the axial direction.

By means of the fixing member 40 described above, the engine clutch 10 supported on the outer diameter portion of the rotor shaft R0 by the support bearing B can also be fixed in the axial direction.

At this time, since the dual clutch input shaft K0 is spline-connected to the rotor shaft R0 as described above, the dual clutches K1 and K2 connected to the dual clutch input shaft K0 are also connected to the aforementioned fixing member 40. can be fixed about the axial direction by

Accordingly, since the axial movement of the dual clutches K1 and K2, the engine clutch 10, and the rotor R toward the engine E can be restrained by one fixing member 40, the dual clutch device 100 ) can be reduced in the number of parts, reduced processing area, and improved assembly.

Meanwhile, a support ring 50 may be inserted between the fixing member 40, the support bearing B, and the rotor shaft R0 as shown in FIGS. 2 and 3.

As an example, the support ring 50 may increase the coupling surface pressure between the fixing member 40, the support bearing B, and the rotor shaft R0.

Hereinafter, the configuration of the sealing unit 60 of the dual clutch device 100 according to an embodiment of the present invention will be described with reference to FIGS. 2 and 3 .

Referring to FIGS. 2 and 3 , at least one sealing unit 60 may be provided between the cover C of the motor M and the rotor shaft R0 of the rotor R.

As an example, the sealing unit 60 may seal a portion of the rotor shaft R located inside the cover C, as shown in FIGS. 2 and 3 .

Also, the sealing unit 60 may seal the rotor R and the stator S located inside the cover C.

In detail, the above-described sealing portion 60 includes one end of the cover C located on the engine clutch 10 side and a rotor shaft located on the engine clutch 10 side and exposed to the outside of the cover C ( and a first sealing member 62 inserted between one side of R0).

In addition, the sealing part 60 is between the other end of the cover C located on the flow path O side and the other side of the rotor shaft R0 located on the flow path O side and exposed to the outside of the cover C. It includes a second sealing member 64 that is inserted.

As described above, the first sealing member 62 and the second sealing member 64 are the inner side of the cover C among the rotor R and the stator S and the rotor shaft R0 located inside the cover C. The part located on can be sealed.

As an example, the first sealing member 62 and the second sealing member 64 may be seal bearings.

Through the configuration of the first sealing member 62 and the second sealing member 64 of the above-described sealing part 60, dust or external foreign matter and moisture generated according to the driving of the engine clutch 10 are removed from the cover of the motor M. It can be prevented from flowing into the gap between (C) and the rotor shaft (R0) of the rotor (R).

In addition, the sealing part 60 may be provided between the engine clutch 10 and the inner diameter of the rotor shaft R0 of the rotor R.

In detail, the sealing part 60 further includes a sealing plate 66 provided between the aforementioned engine clutch actuator 16 and the through part 18 of the engine clutch 10 .

As described above, the through-hole 18 may be connected to the engine clutch actuator 16 through the through-hole R01 formed on one side of the rotor shaft R0.

The above-described engine clutch actuator bearing 162 may be provided between the sealing plate 66 and the engine clutch actuator 16 .

Since the dual clutch device 100 according to an embodiment of the present invention has a structure in which the penetrating portion 18 penetrates the rotor shaft R0 and operates, the rotor shaft ( At least a portion of R0 (specifically, a portion of the inner diameter of the rotor shaft R0) may be formed to surround the engine clutch actuator bearing 162.

In this structure, the inner diameter portion and the outer diameter portion of the sealing plate 66 may be positioned between the inner diameter portion of the rotor shaft R0.

Meanwhile, the engine clutch actuator 16 may receive hydraulic pressure from the flow path O as described above.

At this time, the hydraulic pressure supplied from the flow path O pushes the engine clutch actuator 16 in the axial direction (specifically, in the direction of the engine output shaft E0), and as the engine clutch actuator 16 moves in the axial direction, the engine clutch actuator 16 The actuator bearing 162 and the sealing plate 66 can be moved axially.

As the engine clutch actuator bearing 162 and the sealing plate 66 are moved in the axial direction according to the axial movement of the engine clutch actuator 16, the through portion 18 of the engine clutch 10 is also moved in the axial direction so that the engine The clutch 10 can be driven in the axial direction.

When the through portion 18 is moved in the axial direction by the drive of the engine clutch actuator 16, the sealing plate 66 may apply an axial load to the through portion 18 while being moved in the axial direction.

At this time, the sealing plate 66 is moved in the axial direction to push the through portion 18 in the axial direction to prevent dust passing through the through hole R01 from being introduced into the inner diameter portion of the rotor shaft R0. have.

In addition, while the sealing plate 66 is moved in the axial direction by driving the engine clutch actuator 16, the inner and outer diameters of the sealing plate 66 may come into contact with the inner diameter of the rotor shaft R0. .

As an example, sealing members 662 may be formed on the inner and outer diameters of the sealing plate 66 , respectively.

The sealing member 662 is in contact with the inner diameter of the rotor shaft R0, and may block gaps between the inner diameter of the rotor shaft R0 and the inner and outer diameters of the sealing plate 66, respectively.

In addition, since the penetrating portion 18 is moved in the axial direction according to the axial movement of the sealing plate 66, dust that may flow into the inner diameter portion of the rotor shaft R0 from the through hole RO1 may be blocked.

Meanwhile, the sealing member 662 may be made of the same material as that of the rotor shaft R0.

Therefore, since the sealing member 662 is in contact with the rotor shaft R0 of the same material, reduction in efficiency due to the driving of the engine clutch 10 may not occur.

By densely configuring the sealing structure between the motor M and the engine clutch 10 by the above-described configuration of the sealing unit 60, dust or external foreign matter and moisture generated according to the driving of the engine clutch 10 are prevented by the motor ( M) can be sealed.

In addition, the performance and durability of the motor can be maintained by the above-described motor (M) sealing structure.

The above description is merely an example of the technical idea of the present invention, and those skilled in the art can make various modifications, changes, and substitutions without departing from the essential characteristics of the present invention. will be. Therefore, the embodiments disclosed in the present invention and the accompanying drawings are not intended to limit the technical idea of the present invention, but to explain, and the scope of the technical idea of the present invention is not limited by these embodiments and the accompanying drawings. . The protection scope of the present invention should be construed according to the claims below, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

100: dual clutch device
H: Housing
M: Motor
R: Rotor
E: engine
TM : Transmission
K1, K2 : Dual Clutch
O: Euro
10: engine clutch
60: sealing part

Claims (13)

In the dual clutch device provided inside a housing in which a transmission is coupled to one side and an engine is coupled to the other side,
A motor including a stator and a rotor accommodated inside the cover;
a dual clutch formed on the transmission side with respect to the motor and connected to the rotor;
an engine clutch formed on the engine side with respect to the motor and connected to the rotor;
a passage formed between the motor and the dual clutch and supplied with hydraulic pressure from the outside of the housing; and
A sealing portion provided between the cover and the rotor shaft of the rotor or between the inner diameter of the rotor shaft of the rotor to seal a portion of the stator, the rotor, and the rotor shaft located inside the cover,
The sealing part,
A first sealing member inserted between one end of the cover located on the engine clutch side and one side of the rotor shaft located on the engine clutch side and exposed to the outside of the cover;
and a second sealing member inserted between the other end of the cover positioned on the flow path side and the other end of the rotor shaft positioned on the flow path side and exposed to the outside of the cover. According to claim 1,
the cover,
The dual clutch device, characterized in that located between the dual clutch and the engine clutch. According to claim 1,
The dual clutch device of claim 1 , wherein the first sealing member and the second sealing member seal a part located inside the cover among the rotor, the stator, and the rotor shaft located inside the cover. According to claim 1,
The dual clutch device according to claim 1 , wherein the engine clutch is connected to an engine clutch actuator operated in an axial direction, and the engine clutch actuator is coupled to the cover. According to claim 4,
The engine clutch includes a through portion protruding toward the engine clutch actuator,
The dual clutch device of claim 1 , wherein the through-portion of the engine clutch passes through a through-hole formed on one side of the rotor shaft exposed to the outside of the cover and is connected to the engine clutch actuator. According to claim 5,
The sealing part,
Further comprising a sealing plate provided between the engine clutch actuator and the through portion,
The dual clutch device, characterized in that the inner diameter and the outer diameter of the sealing plate contact the inner diameter of the rotor shaft. According to claim 6,
An engine clutch actuator bearing is provided between the sealing plate and the engine clutch actuator. According to claim 7,
At least a portion of the rotor shaft is formed to surround the engine clutch actuator bearing. According to claim 7,
When hydraulic pressure is supplied through the flow path to move the engine clutch actuator in the axial direction, the sealing plate is moved in the axial direction to block the inflow of dust from the through hole into the inner diameter of the rotor shaft. A dual clutch device that does. According to claim 6,
The dual clutch device of claim 1 , wherein a sealing member is provided on an inner diameter part and an outer diameter part of the sealing plate, and the sealing member is made of the same material as that of the rotor shaft. According to claim 4,
The dual clutch device according to claim 1 , wherein the passage passes through a cover and is connected to the engine clutch actuator. According to claim 1,
Further comprising a damper provided inside the housing and connected to the engine clutch through a damper spline;
Outside of the engine clutch, the damper spline is located between an outer diameter portion and an inner diameter portion of the engine clutch. According to claim 12,
The dual clutch, the motor, and the damper are arranged in a line with respect to an engine output shaft direction of the engine,
Outside the rotor, at least a part of the engine clutch is located on the inner diameter side of the rotor.

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