KR20140021341A - Torque converter and torque converter control system - Google Patents

Abstract

The present invention relates to a torque convertor comprising: a friction clutch (10) having a torsional spring (20) in which direct damping force for transmitting the power of an engine (50) is generated by frictional force by oil pressure; and a lock up clutch (5) comprising electromagnet clutch (30) in which direct damping force is generated by electromagnetic force by being controlled by an ECU (70) in the same conditions as that of the power-on state of the friction clutch. The electromagnetic clutch (30) is penetrated to the space in which the lock up clutch (5) is equipped and a cooling oil route (40) providing transmission oil for the friction clutch (10) in the space, so that direct harness operability can be obtained without an increase in oil pump capacity. Also, the present invention can solve a problem relating to the increase in oil temperature of the transmission oil (ATF) by an active slip control of the electromagnetic clutch under a damp direct release condition by an accelerator minute tip-in or kick-down.

Description

TECHNICAL FIELD [0001] The present invention relates to a torque converter and torque converter control system,

The present invention relates to a torque converter, and in particular, by applying a lock-up clutch equipped with a friction clutch hydraulic system and an electromagnetic clutch electromagnetic clutch system, it is easy to secure direct drive rigidity and drivability without increasing the oil pump capacity, To a torque converter control system in which the effect of oil temperature rise of the transmission oil (ATF) can be solved.

Generally, a torque converter is installed between an engine of an automobile and an automatic transmission, and transmits the driving force of the engine to the transmission using a fluid. In particular, the torque converter contributes to an improvement in driving force through a torque multiplying effect.

On the other hand, the torque converter may be deteriorated in power transmission efficiency when the load acting on the engine becomes large, and a lockup clutch (a damper clutch or a torque converter clutch), which is a means for directly connecting the engine and the automatic transmission, is further applied.

For example, when the lockup clutch reaches a predetermined operating condition, the torque converter is locked up, and the engine power is directly transmitted to the automatic transmission, so that the power transmission efficiency is further improved and the fuel economy is improved.

The fuel economy improvement as described above is further improved when the lockup clutch is directly connected to the lower speed change stage such as the first and second stages. This is due to the improvement in fuel economy by reducing the energy loss due to the torque converter slip.

Particularly, when the lockup clutch is directly connected to the low gear stage such as the first and second gear stages, the driver can feel the direct coupling feeling like the manual transmission MT.

However, the lockup clutch is synchronized with the engine speed and the turbine speed by the differential pressure of the transmission oil (ATF) by the solenoid control signal, and is directly connected by the wet multi-plate (single plate) friction force and is released by using the hydraulic pressure.

Therefore, the damper is released when the lock-up clutch is directly connected to the accelerator pedal tip. It is difficult to expect a time delay and instantaneous response due to the control by the hydraulic pressure. Particularly, The NVH is inevitably generated.

Korean Patent Publication No. 10-2009-0124422 (December 03, 2009)

This patent document shows an example of a technique capable of ensuring the durability of the lockup clutch with the improvement of the fuel economy by implementing the appropriate slip control for the torque converter according to the loss power of the clutch.

To this end, the patent document discloses a slip control for a set time according to the degree of loss power calculated by detecting a slip occurrence of a lock-up clutch during running, and in the case of a transition slip control area, Or the sleep control is terminated.

In this way, the patent document can solve the durability degradation due to damage of the damper clutch with appropriate slip control, and improve the fuel economy through proper slip control.

However, in the slip control system of the patent document, the increase of the temperature of the transmission oil (ATF) due to the friction heat due to the slip is restricted and the situation in which the lockup clutch is released can not be prevented. -in) or kick down (damper direct disengagement condition).

In particular, even in the case of the slip control of the above-mentioned patent, the size and capacity of the oil pump, which depends on the engine RPM, can be increased to solve the hydraulic vibration at the time of direct entry of the low speed damper. However,

In view of the above, the invention of the present invention which is invented in consideration of the above is applied to a lock-up clutch constituted by a combination of an electromagnetic clutch of a friction clutch and an electromagnetic clutch capable of cooperative control in direct control or electromagnetic control during slip control, And it is possible to solve the damper direct disengagement condition by the tip of the accelerator pedal (Tip-in) or the kick down by the fine slip amount control by the fine current control of the electromagnetic clutch, The present invention provides a torque converter control system capable of solving the influence of the increase in the temperature of the transmission oil (ATF) due to active slip control using the torque converter control system.

In order to accomplish the above object, the torque converter of the present invention includes a friction clutch having a direct spring, a direct-coupling damping force for transmitting the power of the engine to the automatic transmission as a frictional force due to hydraulic pressure, Up clutch, which is controlled by an ECU (Engine Control Unit) under the same condition as the operation ON condition and is composed of an electromagnetic clutch in which the direct-coupled damping force is generated by an electromagnetic force;

A cooling oil passage through which the transmission oil flows into the space in which the lockup clutch is built, and the transmission oil is supplied to the friction clutch through the electromagnetic clutch;

Is included.

The electromagnetic clutch includes a rotor, a coil that is disposed in the rotor and that forms an electric circuit with the ECU to generate an electromagnetic force, and a coil rod to which the coil is fixed and fixed to the rotor and through which the cooling passage penetrates.

The coil rod is formed of a hollow pipe to form the cooling channel.

The rotor is formed with an annular rim protruding concentrically with respect to a shaft hole that is opened at the center. The coil rod is inserted into a slot formed in one of the annular rims so as to be opened, and the coil is wound on the coil rod, As shown in FIG.

The annular rim protrudes from the inner diameter of the shaft hole and the outer rim of the rotor to form a space in which the coil is located.

In order to accomplish the above object, the present invention provides a torque converter control system comprising: a torque converter that is directly disconnected or disconnected to directly transmit power of an engine to an automatic transmission;

A damping force for direct connection is generated by frictional force due to oil pressure, and a frictional clutch having a torque spring and a damping force for direct connection are generated by an electromagnetic force under the same condition as the operation on condition of the friction clutch A lockup clutch comprising an electromagnetic clutch;

A cooling oil passage through which the transmission oil flows into the space in which the lockup clutch is installed and the transmission oil is supplied to the friction clutch through the electromagnetic clutch;

An ECU (Engine Control Unit) connected to a battery sensor for monitoring SOC (State Of Charge) of a battery mounted on the vehicle, and performing slip control of the lockup clutch by current control of the electromagnet clutch under a damping condition of the battery;

Is included.

Wherein the electromagnetic clutch includes a rotor having an annular rim protruding from an inner periphery of the shaft hole and a rim protruding from the rim, a coil disposed in the space formed by the annular rim and forming an electric circuit with the ECU to generate an electromagnetic force, A coiled bar that is fixed and fixed to the annular rim; The cooling passage is formed through the coil rod.

According to the present invention, since the lock-up clutch is constituted by an electromagnet clutch which is capable of direct control or cooperative control at the time of slip control in addition to the hydraulic system of the friction clutch, quick response is secured compared with the case where only hydraulic pressure is used at the time of direct damper connection.

Further, the present invention also has an effect of maintaining the direct connection state by an electric power under the condition of the damper direct connection or the acceleration pedal tip during the slip control.

Further, according to the present invention, slip amount control is finely controlled by fine current control of an electromagnetic clutch under a damper direct releasing condition by an accelerator pedal fine tip (Tip-in) or kick down There is also an effect of ensuring the direct rigidity and operability by reducing the slip amount.

Further, the present invention eliminates the influence of the increase in the temperature of the transmission oil (ATF) due to the positive slip control using the electromagnetic clutch, so that the damper can be used more positively. Particularly, There is also an effect that the fuel efficiency can be improved by eliminating the hydraulic vibration when entering.

Further, the present invention has an effect of increasing the transmission efficiency by reducing the oil pressure loss due to the torque converter slip and damper oil pressure rise when the low-speed and low-end damper are directly coupled and reinforced by the active slip control using the electromagnet clutch.

Further, the present invention also has the effect of maximizing the utilization of electric energy by expanding the torque converter to which the lockup clutch is applied to the mild hybrid vehicle and the ISG application vehicle, wherein the electromagnet clutch using electric energy is constituted as a member of the lockup clutch.

FIG. 1 is a configuration diagram of a torque converter equipped with an electromagnetic type dual type lockup clutch according to the present invention, FIG. 2 is a configuration diagram of a cooling passage provided in the torque converter according to the present invention, Fig. 5 is a configuration diagram of a torque converter control system according to the present invention, and Fig. 6 is a diagram showing the layout of a lockup clutch according to the present invention. Fig. 7 is a performance diagram of the torque converter and the booster diagram of the friction clutch and the electromagnetic clutch of the lockup clutch according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which illustrate exemplary embodiments of the present invention. The present invention is not limited to these embodiments.

Fig. 1 shows the construction of a torque converter equipped with an electromagnet dual type lock-up clutch according to the present embodiment.

The torque converter 1 is provided with an impeller and a turbine in an internal space formed by the housing 2 and the clutch plate 3 so that the power of the engine 50 is transmitted to the automatic transmission A lockup clutch 5 directly connected to the control of the ECU 70 is provided in the internal space so as to be transmitted to the lockup clutch 5 and the oil passage 40 is formed so that the oil pressure for direct disengagement is provided to the lockup clutch 5 side.

The lockup clutch 5 includes a friction clutch 10 that generates a damping force by a frictional force in response to the action of hydraulic pressure when the torque converter 1 is directly connected to the friction clutch 10, And an electromagnet clutch 30 which generates an auxiliary damping force together with the slip control.

The friction clutch 10 includes a hub plate 11 rotated in a splined manner with a shaft 4 receiving power of the engine 50, a piston 12 moved for direct connection and disengagement, a hub plate 11 A cover plate 13 rotated together with a spring plate and a liner 14 provided on the piston 12 and forming a frictional force for direct engagement.

The friction clutch 10 further includes a torque spring 20 for providing an elastic restoring force.

The electromagnet clutch 30 includes a rotating rotor 31, a coil 32 coupled to the rotor 31 to energize battery power, a liner 32 provided on the outer surface of the rotor 31 to form a frictional force for direct connection 33).

The electromagnetic clutch 30 is controlled by the ECU 70. The ECU 70 controls the vehicle at the highest level using detection information about the engine, the battery, and the vehicle as a whole, .

The cooling passage 40 has a flow passage forming space 41 for supplying oil to the friction clutch 10 in the internal space of the torque converter 1 and an electromagnetic clutch 30 for closing the flow passage forming space 41 And a flow path connecting space (42).

2 shows the configuration of the electromagnetic clutch 30 and the cooling passage 40 according to the present embodiment.

As shown in Fig. 2 (A), the rotor 31 of the electromagnetic clutch 30 is provided with a shaft hole at its center, and an annular rim 31a protrudes from the shaft hole inner diameter and rotor rim, A coil rod 32a is inserted into the slot 31b and a coil 32 is wound around the coil rod 32a so that the space between the annular rims 31a The coil 32 is inserted.

The slots 31b are formed symmetrically with a sharp angle (a).

As shown in FIG. 2 (B), a passage connecting space 42 is passed through the coil rod 32a.

Since the coil rod 32a is communicated with the passage forming space 41 through the passage connecting space 42 so that the rotor 31 closes the passage forming space 41, The oil flow can be smoothly formed between the clutch 30 and the friction clutch 10. [

Therefore, the oil (ATF) supplied to the cooling passage 40 flows into the internal space of the torque converter 1 and is collected in the oil passage forming space 41 forming the space below the electromagnetic clutch 30. Then, The frictional heat of the friction clutch 10 can be cooled by passing through the oil passage 42 into the oil passage forming space 41 which forms the space above the electromagnetic clutch 30. [

That is, the cooling flow path 40 of this embodiment is formed by using the rotor 31 of the electromagnetic clutch 30, so that the basic flow path design of the torque converter 1 is not changed.

3 shows an example of the layout of the friction clutch 10 and the electromagnetic clutch 30 with respect to the center line A-A of the lock-up clutch 5. As shown in Fig.

This is because the friction clutch 10 is positioned above the torsional spring 20 while the electromagnet clutch 30 is positioned below the torsional spring 20, This layout is advantageous in that even if the torsional spring 20 has a double structure, it can be easily configured.

4 shows another example of the layout of the friction clutch 10 and the electromagnet clutch 30 with respect to the center line A-A of the lock-up clutch 5. As shown in Fig.

This is the case where both the friction clutch 10 and the electromagnet clutch 30 are located above the local spring 20 when the local spring 20 is taken as a reference, , But there is an advantage that the electromagnetic clutch 30 is constructed together with the friction clutch 10.

5 shows a control system for controlling the torque converter according to the present embodiment.

As shown in the figure, the torque converter system includes a torque converter 1 that cuts off the power of the engine 50 or transmits the power to the automatic transmission 60, and a damping force built in the torque converter 1, Up clutch 5 composed of an electromagnet clutch 30 that generates a damping force by an electromagnetic force so as to assist the friction clutch 10 that is generated and controls the vehicle to the highest level by using detection information about the engine and the vehicle as a whole An ECU 70 for controlling the power supplied to the electromagnet clutch 30 and a battery sensor 90 for detecting the power and voltage of the battery 80 mounted on the vehicle and providing it to the ECU 70. [

The logic for controlling the electromagnetic clutch 30 by the ECU 70 is a function of operating on control logic and fine slip when the damper is directly disconnected due to an accelerator pedal fine tip (Tip-in) or kick down Additional power control logic for volume control is included.

In this case, the rotor 31 and the coil 32 are rotated in the same manner as the cover plate 13 of the friction clutch 10, .

The additional power control logic is a method in which the amount of power consumption by the hydraulic pressure is reduced and the SOC (State Of Charge) of the battery 80 is monitored through the battery sensor 90 so that the power of the battery 80 is used. do.

Particularly, the ECU 70 can allocate the amount of power consumption by the hydraulic pressure to be reduced by checking the state of charge (SOC) of the battery 80 by using the battery sensor 90 so as to utilize the electric current positively charged in the battery buffering condition, By implementing such a control method, it is possible to realize a maximized effect when the lockup clutch 5 is applied to a mild hybrid vehicle or an ISG vehicle.

6 shows a direct-coupled control state of the lock-up clutch according to the present embodiment.

As shown in the figure, the direct coupling action of the friction clutch 10 is performed by generating a hydraulic frictional force Fa for operating the liner 14 on the direct coupling condition determined by the ECU 70, The electromagnetic clutch 30 having the same operating on condition as the one for the case clutch 10 is also directly connected.

The direct connection of the electromagnetic clutch 30 is controlled by the control of the ECU 70 so that the coil 32 is magnetized by supplying the current of the battery 80 and the liner 33 is pressurized by the electromagnetic force through the magnetization of the coil 32 And an electromagnetic friction force Fb is generated.

The direct coupling of the friction clutch 10 and the electromagnet clutch 30 as described above is made from a low gear stage such as the first stage and the second stage so that the operation state of the lock-up clutch 5 is changed from a low gear stage The torque converter 1 can reduce the energy loss due to the slip, thereby contributing to the improvement of the fuel economy.

At the same time, the driver is able to feel the direct coupling feeling like the manual transmission MT due to the lock-up clutch 5 which is directly connected to the lower speed change stage such as the first and second stages.

Fig. 7 is a performance diagram of the friction clutch and the electromagnet clutch of the lockup clutch and the torque converter of the lockup clutch according to the present embodiment, in which the electromagnet duty of the electromagnet clutch 30 assists the friction clutch 10, It can be seen that the damper duty of the shunt clutch 10 is reduced.

Therefore, in the lock-up clutch 1 according to the present embodiment, the electromagnet clutch 30 is controlled by the ECU 70 at the time of the slip control, so that there is little burden on the oil pump depending on the engine speed, It is possible to eliminate the hydraulic vibration when the low speed damper is directly connected without increasing.

In addition, since the electromagnet clutch 30 is finely controlled by the micro-current control by the ECU 70, the slip amount control can be finely performed, thereby enabling the direct clutch to be maintained. Particularly, the accelerator pedal fine tip (Tip-in) or kick down The direct connection state can be maintained even under the damper direct disengagement condition.

In addition, since the electromagnet clutch 30 is actively applied to the slip control, the transmission efficiency can be increased by reducing the slip of the torque converter 1 and the hydraulic pressure loss due to the rise of the damper oil pressure. Especially, when the low- The same performance can be implemented.

As described above, the torque converter according to the present embodiment includes the friction clutch 10 in which the direct-coupled damping force for transmitting the power of the engine 50 to the automatic transmission 60 is generated by the frictional force by the hydraulic pressure, Up clutch (5) composed of an electromagnetic clutch (30) controlled by the ECU (70) under the same conditions as the operating condition (On) condition of the clutch (40) for supplying the transmission fluid through the electromagnetic clutch (30) to the friction clutch (10) in a space in which the oil pump And the influence of the increase in the temperature of the transmission oil (ATF) due to the active slip control of the electromagnetic clutch can be solved under the damper direct releasing condition by the accelerator pedal fine tip (Tip-in) or kick down (Kick Down).

Particularly, the dual damper type lockup clutch 5 to which the electromagnet clutch 30 is applied is applied to the torque converter 1 as in the present embodiment, and this is applied to the mild hybrid vehicle and the ISG application vehicle to maximize the utilization of electric energy .

1: torque converter 2: housing
3: clutch plate 5: lockup clutch
10: Friction clutch 11: hub plate
12: piston 13: cover plate
14,33: Liner
20: Traction spring 30: Electromagnet clutch
31: rotor 31a: annular rim
31b: slot 32: coil
32a: Coils
40: cooling passage 41: passage forming space
42: Connection space
50: engine 60: automatic transmission
70: ECU 80: battery
90: Battery sensor

Claims (7)

A damping force for directly transmitting an engine power to an automatic transmission is generated by frictional force generated by hydraulic pressure, and a friction clutch having a torque spring and an engine control Unit, and the direct-coupled damping force is generated by an electromagnetic force;
A cooling oil passage through which the transmission oil flows into the space in which the lockup clutch is built, and the transmission oil is supplied to the friction clutch through the electromagnetic clutch;
The torque converter comprising:
The electromagnetic clutch as set forth in claim 1, wherein the electromagnetic clutch comprises: a rotor; a coil that is disposed in the rotor and that forms an electric circuit with the ECU to generate an electromagnetic force; and a coil rod fixed to the rotor, .
The torque converter according to claim 2, wherein the coil rod is a hollow pipe, and the cooling passage is penetrated.
The method according to claim 2, wherein the rotor is formed with an annular border projecting to form a concentric circle with respect to the axial hole drilled in the center, the coil rod is fitted into the slot formed so that one side is opened in the annular border, the coil is the coil rod Torque converter, characterized in that it is wound into the space between the annular border.
[4] The torque converter of claim 4, wherein the annular rim protrudes from an inner diameter of the shaft hole and an outer rim of the rotor to form a space in which the coil is located.
A torque converter that is directly disengaged to be directly connected or disconnected to transmit the power of the engine to the automatic transmission;
A damping force for direct connection is generated by frictional force due to oil pressure, and a frictional clutch having a torque spring and a damping force for direct connection are generated by an electromagnetic force under the same condition as the operation on condition of the friction clutch A lockup clutch comprising an electromagnetic clutch;
A cooling oil passage through which the transmission oil flows into the space in which the lockup clutch is installed and the transmission oil is supplied to the friction clutch through the electromagnetic clutch;
An ECU (Engine Control Unit) connected to a battery sensor for monitoring SOC (State Of Charge) of a battery mounted on the vehicle, and performing slip control of the lockup clutch by current control of the electromagnet clutch under a damping condition of the battery;
Wherein the torque converter control system comprises:
[7] The electromagnetic clutch as set forth in claim 6, wherein the electromagnetic clutch includes: a rotor having an annular rim protruding from a rim of the shaft hole and a rim protruding from the rim; a coil disposed in a space formed by the annular rim and constituting an electric circuit with the ECU to generate an electromagnetic force; And a coiling rod to which the coil is fixed and fixed to the annular rim;
And the cooling passage is formed by passing through the coil rod.

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