KR100882652B1 - Dual mass flywheel breakage prevention device and method - Google Patents

Abstract

Protecting apparatus and the method for dual mass flywheel are provided that the fuel amount injected to the engine is limited. A protecting apparatus for dual mass flywheel comprises a first sensor(30) measuring RPM of the ring gear of the dual mass flywheel, a second sensor(40) measuring RPM of the gear rotating with the input of transmission, a controller(20) limiting the fuel amount injected to the engine. The controller compares RPM of the ring gear(15) of the dual mass flywheel which the first sensor measures with RPM of the gear rotating with the input of the transmission(2) which the second sensor measures.

Description

Preventing Apparatus And Method For Damage Of Dual Mass Flywheel}

The present invention relates to a dual mass flywheel, and more particularly to a dual mass flywheel breakage prevention device and method that prevents repetitive generation of strong engine torque beyond the endurance limit of the flange of the dual mass flywheel.

Flywheel is a part that transmits the energy generated by the engine to the wheels.When the energy generated by the engine is transmitted to the wheels, the flywheel reduces the difference between the rotational speed of the engine and the rotational speed of the load by mitigating the increase or decrease of the force on the crankshaft. give.

There are two types of flywheels: Single Mass Flywheel (SMF) or Dual Mass Flywheel (DMF), among which DMF is the NVH (Noise / Vibration / Harshness) greatly improves.

1 is a view showing a DMF in a flywheel.

Engine torque generated by the explosion in the engine is transmitted to the primary wheel (111) of the DMF 101, the secondary wheel (113) through a buffer action of the arc spring (112) (113) It is delivered to both ends of the flange (114) connected integrally with the. In this process, the DMF 101 reduces the difference between the rotational speed of the engine and the rotational speed of the load, and transmits the uneven engine torque generated by the engine to the wheels with a smooth driving force.

However, if a sudden contact of the clutch, a low speed driving (300 to 500 rpm) of the vehicle due to the braking, or a sudden excel operation to increase the vehicle speed during the low speed driving occurs, a strong engine that exceeds the endurance limit of the flange 114 in the engine due to resonance. Torque may occur. In the above situation, the strong engine torque exceeding the endurance limit of the flange 114 generated in the engine does not occur once but occurs repeatedly as shown in FIG. 2.

If strong engine torque repeatedly occurs beyond the endurance limit of the flange 114, the flange 114 will depress the arc spring 112. When the flange 114 presses the arc spring 112 with a force greater than the shrinkage limit of the arc spring 112 due to the strong engine torque exceeding the endurance limit of the flange 114 repeatedly generated, the flange 114 Can be broken.

If the flange 114 is broken, the DMF 101 does not buffer the non-uniform engine torque, so the non-uniform engine torque is transmitted to the wheel through the drive system as it is. That is, the driver is shocked as it is.

Accordingly, it is an object of the present invention to provide a dual mass flywheel breakage prevention device and method which prevents the repetitive generation of strong engine torque beyond the endurance limit of the flange of the dual mass flywheel in the engine.

In order to achieve the above object, the dual mass flywheel breakage prevention device according to an embodiment of the present invention includes a first sensor for measuring the AlPM of the ring gear of the dual mass flywheel; A second sensor for measuring an ALPM of a gear which rotates integrally with the input side of the transmission; AlpM of the ring gear of the dual mass flywheel measured by the first sensor and AlpM of the gear which rotates integrally with the input side of the transmission measured by the second sensor are transmitted, and the ring gear of the transmitted dual mass flywheel It is provided with a control unit for limiting the amount of fuel injected into the engine by using the PM and the LP of the gear that rotates integrally with the input side of the transmission.

The control unit calculates the difference between the transmitted ALMP of the ring gear of the dual mass flywheel and the ALMP of the gear which rotates integrally with the input side of the transmission, and when the calculated difference exceeds the threshold, the dual mass flywheel in the engine It is determined that a strong engine torque exceeding the endurance limit of the flange is generated, and the amount of fuel injected into the engine is limited by the limit fuel amount according to the ring gear of the dual gear flywheel.

The limiting fuel amount is proportional to the rpm of the ring gear of the dual mass flywheel.

The dual mass flywheel breakage prevention method according to an embodiment of the present invention includes the steps of calculating the difference between the ALPM of the ring gear of the dual mass flywheel and the ALPM of the gear which rotates integrally with the input side of the transmission; Determining whether the calculated difference exceeds a threshold; If the calculated difference exceeds a threshold, reading a predetermined limit fuel amount according to the RPM of the ring gear of the dual mass flywheel; Injecting the read limit fuel into the engine.

The dual mass flywheel breakage preventing device and method according to an embodiment of the present invention is to calculate the difference between the ALPM of the ring gear of the dual mass flywheel and the ALPM of the gear which rotates integrally with the input side of the transmission, and the calculated difference of ALPM is the threshold value. If exceeded, the amount of fuel injected into the engine is limited. By limiting the amount of fuel injected into the engine, the engine torque is reduced. Therefore, the dual mass flywheel breakage preventing device and method according to an embodiment of the present invention to prevent the strong engine torque that exceeds the endurance limit of the flange of the dual mass flywheel to be repeatedly generated to prevent the flange of the dual mass flywheel is broken. Can be.

Hereinafter, exemplary embodiments of the present invention will be described with reference to FIGS. 3 to 6.

3 is a view showing a DMF damage prevention apparatus according to an embodiment of the present invention.

Referring to FIG. 3, an apparatus for preventing damage to a DMF according to an embodiment of the present invention may include a first sensor 30 and a transmission 2 configured to measure rpm of a ring gear 15 of a DMF 1. 2nd sensor 40 which measures the rpm of the gear rotated integrally with an input side, rpm of the ring gear 15 of the DMF 1 measured by the 1st sensor 30, and 2nd sensor The rpm of the gear which rotates integrally with the input side of the transmission 2 measured by 40 is transmitted, and integrally with the rpm of the ring gear 15 of the transmitted DMF 1 and the input side of the transmission 2. The control unit 20 for adjusting the amount of fuel injected into the engine by using the rpm of the rotating gear is provided.

The first sensor 30 measures the rpm of the ring gear 15 of the DMF 1. The rpm of the ring gear 15 of the DMF 1 is equal to the engine rpm.

The second sensor 40 measures the rpm of the gear that rotates integrally with the input side of the transmission 2. The rpm of the gear which rotates integrally with the input side of the transmission 2 is the rpm transmitted to the transmission 2 via the DMF 1.

The first sensor 30 transmits the rpm of the ring gear 15 of the DMF 1 to the control unit 20, and the second sensor 40 is the rpm of the gear that rotates integrally with the input side of the transmission 2. Transmits to the control unit 20.

The control unit 20 calculates the difference between the rpm of the ring gear 15 of the DMF 1 and the rpm of the gear which rotates integrally with the input side of the transmission 2, and the calculated difference of rpm exceeds the threshold value. Then, it is determined that the engine generates a strong engine torque exceeding the endurance limit of the flange 14 of the DMF (1).

That is, the control unit 20 generates a low speed (300-500 rpm) of the vehicle due to a sudden contact of the clutch, a sudden excel operation to raise the vehicle speed during low speed driving, etc., and the flange of the DMF 1 in the engine due to resonance. It is determined that a strong engine torque exceeding the endurance limit of (14) occurs.

If the control unit 20 determines that the engine generates a strong engine torque exceeding the endurance limit of the flange 14 of the DMF 1, the controller 20 according to the rpm of the ring gear 15 of the transmitted DMF 1, that is, the engine rpm. Inject the engine into a predetermined threshold fuel level. At this time, the limit fuel amount is limited differently according to the rpm of the ring gear 15 of the DMF 1 transmitted by the first sensor 30 as shown in FIG.

If the rpm of the ring gear 15 of the DMF 1 transmitted by the first sensor 30, that is, the current engine rpm is high, the limit fuel amount to limit is high, and if the current engine rpm is low, the limit fuel amount to limit is also low. This is to prevent the engine torque from suddenly changing due to the limitation of the fuel amount.

When the control unit 20 limits the amount of fuel injected into the engine, the engine torque is reduced. The control unit 20 calculates the difference between the rpm of the ring gear 15 of the DMF 1 and the rpm of the gear which is integrally rotated with the input side of the transmission 2, which are transmitted even after the engine torque is reduced. If the difference exceeds the threshold, the amount of fuel injected into the engine is limited. This reduces the engine torque. Therefore, as shown in FIG. 5, the engine 14 does not generate strong engine torque that exceeds the endurance limit of the flange 14 of the DMF 1, thereby preventing the flange 14 of the DMF 1 from being damaged. .

6 is a flowchart illustrating a method for preventing damage to a DMF according to an embodiment of the present invention.

Referring to FIG. 6, a method for preventing damage to a DMF according to an embodiment of the present invention may include a method of preventing damage to a DMF from a rpm (N ₁ ) of a ring gear 15 of a DMF 1 from a first sensor 30 and a second sensor 40. Calculate the difference (N _diff ) of the rpm (N ₂ ) of the gear that rotates integrally with the input side of the transmission (2) of (S12), and the difference of rpm (N _diff ) calculated in step S12 is the threshold value (N) _{When the threshold value} is exceeded (S14), the threshold fuel amount is set in advance according to the rpm (N ₁ ) of the ring gear 15 of the DMF 1 from the first sensor 30, that is, the current engine rpm. In step S16, the limit fuel amount is injected into the engine (S18).

If the fuel amount is limited, the engine torque is reduced because the fuel amount is limited in the engine.

In the method for preventing damage to DMF according to an embodiment of the present invention, the steps S12 to S18 are repeated again while the engine torque is reduced. That is, DMF damage prevention method DMF (1), the ring gear 15 of the rpm (N ₁₎ and the input side and integrally rpm of the gear to rotate back to the transmission (2) of the (N ₂₎ according to an embodiment of the present invention If the difference (N _diff ) exceeds the threshold (N _Threshold ), the engine torque is reduced by reducing the amount of fuel injected into the engine, and a strong engine torque is repeatedly generated that exceeds the endurance limit of the flange 14 of the DMF (1). Do not do it. Therefore, the method for preventing damage to the DMF according to the embodiment of the present invention prevents the engine 14 from repeatedly generating a strong engine torque exceeding the endurance limit of the flange 14 of the DMF 1. It can prevent damage.

1 is a view showing a DMF of the flywheel,

2 shows the repetition of strong engine torque over the endurance limit of the flange;

3 is a view showing a DMF damage prevention apparatus according to an embodiment of the present invention,

4 is a view showing an example of the amount of fuel restricted differently according to the engine rpm;

5 is a diagram showing intermittent appearance of strong engine torque beyond the endurance limit of the flange;

6 is a flowchart illustrating a method for preventing damage to a DMF according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

1, 101: DMF 2, 102: transmission

11, 111: primary wheel 12, 112: arc spring

13, 113: secondary wheel 14, 114: flange

15: ring gear 20: control unit

30: first sensor 40: second sensor

Claims (4)

A first sensor measuring an RPM of the ring gear of the dual mass flywheel; A second sensor for measuring an ALPM of a gear which rotates integrally with the input side of the transmission; AlpM of the ring gear of the dual mass flywheel measured by the first sensor and AlpM of the gear which rotates integrally with the input side of the transmission measured by the second sensor are transmitted, and the ring gear of the transmitted dual mass flywheel And a control unit for limiting the amount of fuel injected into the engine by using an LPPM and an ALPM of a gear which is integrally formed with the input side of the transmission. The method according to claim 1, The control unit, Calculate the difference between the transmitted ALPM of the ring gear of the dual mass flywheel and the ALMP of the gear which rotates integrally with the input side of the transmission, and if the calculated difference exceeds the threshold, the durability of the flange of the dual mass flywheel in the engine It is determined that a strong engine torque exceeds the limit, and the dual mass flywheel breakage prevention device, characterized in that for limiting the amount of fuel injected into the engine by the limit fuel amount according to the ALPM of the ring gear of the dual mass flywheel. The method according to claim 2, The limiting fuel amount is Dual mass flywheel breakage prevention device, characterized in that proportional to the rpm of the ring gear of the dual mass flywheel. Calculating a difference between an ALPM of the ring gear of the dual mass flywheel and an ALPM of the gear which rotates integrally with the input side of the transmission; Determining whether the calculated difference exceeds a threshold; If the calculated difference exceeds a threshold, reading a predetermined limit fuel amount according to the RPM of the ring gear of the dual mass flywheel; Dual mass flywheel breakage prevention method comprising the step of injecting the read limit fuel amount into the engine.

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