阅读说明：本技术 用于控制传动轴上的齿轮的内部联接器的释放的方法、变速器和动力传动系 (Method for controlling the release of an inner coupling of a gearwheel on a drive shaft, transmission and drive train ) 是由 C·尚特雷尔 A·沙默鲁瓦 L·勒毛 于 2019-01-08 设计创作，主要内容包括：一种用于控制内部变速器联接器(8,12)的齿的释放的方法,该内部变速器联接器由换挡致动器(16)控制,用于在没有断开连接离合器的情况下将传动比应用于连接到该变速器的输入端的燃烧发动机提供的扭矩或从该扭矩取消该传动比,其特征在于,当该燃烧发动机进入在已接合的齿轮下进行减速期间存在失速的风险的临界情况时,根据该燃烧发动机转速(ω)来确定第一临界区域,在该第一临界区域中,该致动器(16)被强制释放该已接合的齿轮以防止失速,并且根据该发动机转速和该发动机的减速度来确定第二临界区域,在该第二临界区域中,通过阻止燃料的喷射来控制该发动机失速。(A method for controlling the release of teeth of an internal transmission coupling (8, 12) controlled by a shift actuator (16), for applying or cancelling a gear ratio from a torque provided by a combustion engine connected to an input of the transmission without disconnecting the clutch, characterized in that, when the combustion engine enters a critical situation where there is a risk of stalling during deceleration under an engaged gear, determining a first critical region, in which, the actuator (16) is forced to release the engaged gear to prevent stalling, and a second critical region is determined from the engine speed and the deceleration of the engine, in which the engine stalls is controlled by preventing injection of fuel.)

1. A control method for controlling disengagement of teeth of an internal transmission coupling (8, 12) placed under control of a gear shift actuator (16) for engaging or disengaging a gear ratio for transmitting torque supplied by a combustion engine connected to an input of the transmission without disengaging the coupling clutch, characterised in that, when the combustion engine enters a critical situation where there is a risk of stalling when decelerating with an engaged gear ratio,

-determining a first critical region as a function of the combustion engine speed (ω), in which the actuator (16) is forced to disengage the gear ratio to prevent stalling, and

-determining a second critical zone, in which the engine stall is managed by preventing the injection of fuel, as a function of the engine speed and deceleration.

2. A control method according to claim 1, characterised in that the first critical region is a region in which the actuator (16) has the ability to disengage the gear ratio in dependence on the resultant torque exerted by the rotating part of the variator on the teeth of the coupling.

3. A control method according to claim 1 or 2, characterised in that the second critical region is a region in which the actuator (16) does not have the ability to disengage the gear ratio according to the resultant torque exerted by the rotating part of the variator on the teeth of the coupling.

4. A control method according to claim 1, 2 or 3, characterised in that the engine deceleration is determined by the value of the derivative of its rotational speed (d ω/dt).

5. A control method as claimed in claim 1, 2 or 3, characterised in that the deceleration of the engine is determined by the vehicle braking system.

6. A control method according to claim 3, 4 or 5, characterised in that the second critical region is a region in which the time during which the actuator (16) has the ability to disengage the gear ratio is too short.

7. Control method according to claim 4 or 6, characterized in that the following three operating regions are identified from the combustion engine speed (ω) and its derivative (d ω/dt):

-a first area (A) in which no specific policy is applied,

-a second zone (B) where an anti-stall strategy is enabled, and

-a third zone (c) where the stall strategy is enabled.

8. A transmission for a hybrid powertrain, comprising at least one internal transmission coupling (8, 11) placed under the control of a shift actuator (16) for engaging or disengaging, without disengaging a coupling clutch, a gear ratio for transmitting the torque supplied by a combustion engine connected to the input of the transmission, characterized in that the shift actuator (16) and the injection of the combustion engine are managed according to one of the preceding claims.

9. The transmission according to claim 8, characterised in that the couplings (8, 11) considered are couplings involving sliding gears (14) and pawls (12).

10. A hybrid powertrain consisting of: a combustion engine (Mth) connected to the first transmission input shaft (4) without a disconnect clutch; an electric Machine (ME) connected to the second transmission input shaft; and at least one coupling (8, 11) having coupling teeth coupled to a gear and being placed under the control of a gear shift actuator, characterized in that the combustion engine and the coupling actuators are managed according to one of claims 1 to 7.

Technical Field

The present invention relates to control of a powertrain of a hybrid vehicle.

More specifically, the subject of the invention is a control method for controlling the disengagement of the teeth of an internal transmission coupling, placed under the control of a gear shift actuator, for engaging or disengaging, without disengaging a coupling clutch, a gear ratio for transmitting the torque supplied by a combustion engine connected to the input of the transmission.

Another subject of the invention is a transmission and a hybrid powertrain consisting of: a combustion engine connected to the first transmission input shaft without a disconnect clutch; an electric machine connected to the second transmission input shaft; and at least one coupler having coupling teeth coupled to the gear and placed under control of the shift actuator.

Background

In most road vehicles, power transfer from the engine to the wheels is achieved through a gearbox having a variety of configurations.

Some hybrid vehicles have a dog or "dog" clutch coupling arrangement between the combustion engine and the transmission without a disconnect clutch.

From publication WO 2014/207332 a hybrid transmission of this type is known, which has a plurality of electric gear ratios, an engine gear ratio and a hybrid gear ratio, wherein the torque from the combustion engine and the torque from the at least one electric machine are combined in the direction of the wheels. Torque originating from the combustion engine is transferred to the wheels at an "engine" gear ratio, and torque from the main electric machine is transferred at an "electric" gear ratio.

The combustion engine cannot be operated below a certain rotational speed. In a conventional semi-automatic or automatic transmission, the clutch is subjected to a requirement to decouple the engine from the wheels under braking, which carries the risk of causing the engine to stall. Without the disconnect clutch on the input side of the transmission, braking may place the engine in a condition that does not allow its normal operation and may cause the engine to stall.

In the above hybrid Powertrain (PT), engagement and disengagement of the dog coupling is achieved by strategies involving both management of the internal actuators of the transmission and management of the torque actuators of the vehicle (internal combustion engine and electric motor).

To ensure disengagement of the gearbox gears, it is necessary to reduce the residual torque at the dog coupling below a determined threshold for a sufficiently long period of time. In the event of sudden braking, the actuators under consideration do not always have the ability to achieve these goals before the engine enters the degraded operating range.

When the engine speed is in a speed range too low to allow normal operation, the internal combustion engine may cause an explosion that is prone to generating positive torque and regulating idle speed. These explosions can cause jolts and vibrations that can affect the entire vehicle through the drive train. These jolts and vibrations can be very uncomfortable for the user.

Disclosure of Invention

The object of the invention is to limit the jerks and vibrations transmitted to the drive train and the vehicle by degraded operation of the combustion engine or by stalling of the combustion engine.

For this reason, when the combustion engine enters a critical situation in which there is a risk of stalling when decelerating at an engaged gear ratio:

-determining a first critical zone as a function of the combustion engine speed, in which the actuator is forced to disengage the gear ratio to prevent stalling, and

-determining a second critical zone, in which the engine stall is managed by preventing the injection of fuel, as a function of the engine speed and deceleration.

Preferably, the first critical region is a region in which the actuator has the ability to disengage the gear ratio in dependence on the resultant torque exerted by the rotating part of the variator on the teeth of the coupling.

Preferably, the second critical region is a region in which the actuator does not have the ability to disengage the gear ratio in dependence on the resultant torque exerted by the rotating part of the variator on the teeth of the coupling.

In the proposed transmission and hybrid PT, the shift actuators and the injection of the combustion engine are managed according to this strategy.

Drawings

The invention will be better understood from a reading of the following description of non-limiting embodiments thereof, with reference to the attached drawings, in which:

figure 1 schematically depicts a hybrid PT architecture,

figure 2 shows the forces involved on the dog clutch gearbox coupling,

figure 3 illustrates the proposed strategy.

Detailed Description

The gearbox 1 of fig. 1 is for example of the "semi-automatic" type. The operation is that of a manual gearbox, but the gear shifting is automatic. The diagram depicts an electric machine, referred to as HSG (hybrid start generator) 2, a combustion engine 3 on a solid main shaft 4. Mounted on the hollow spindle 6 is a further electric machine 5, referred to as ME, which is more powerful than the first. The layshaft 7 of the gearbox is connected to a differential (not depicted) and then to the wheels of the vehicle.

The first coupling 8 with sliding gears and pawls on the layshaft 7 makes it possible to vary the gear ratio of the electric machine ME 5 independently of the rest of the gearbox in order to have two available electric gear ratios EV1 and EV 2. The second coupling 9 with sliding gear and pawl on the solid main shaft 4 makes it possible to modify the gear ratio of the combustion engine 3 separately from the electric gear ratio in order to establish two engine gear ratios Th2 and Th4 independent of the electric gear ratio. A third coupling 11 with sliding gears and pawls on the parallel shaft 10 makes it possible to establish a third engine gear ratio Th3 as it moves to the right in the diagram. The desired gear ratio on the first electric machine ME and the desired gear ratio on the combustion engine unit Mth and the second electric machine HSG 2 can be selected independently at each moment. The combination of the engine gear ratio and the electric gear ratio enables hybrid gear ratios to be achieved.

Fig. 2 schematically depicts a toothed coupling device of a gearbox or a coupling device with straight claws (also called claw pieces), such as the couplings 8 and 11 of fig. 1. The couplings 8, 11 have coupling teeth 12 fixed to a sliding gear 14 rotatably connected to the shaft 1a (shown in broken lines in the diagram) and sliding on it under the control of a fork 15 of a gear shift actuator 16 (not depicted). The axial movement of the sliding gear 14 determines the engagement or disengagement of the gear ratios by coupling/uncoupling its jaws 12 with respect to the jaws 13 of a gear (not depicted) rotating on the shaft 1 a. The slide gear 14 is rotationally fixed to the shaft 1 a. The axial movement thereof is effected by the action of a fork 15 which is placed under the control of a gear shift actuator 16. The straight arrow f represents the force with which the actuator 16 disengages the gear ratio. The rotational arrow C1 illustrates the torque applied to the sliding gear at the drive shaft. Rotational arrow C2 illustrates the torque on the drive shaft (not depicted) applied to the idle pinion. The combined torque C1 and C2 on the jaws of the idle pinion has a tangential component T and a longitudinal component, which results in a frictional force/between the jaws 12 and 13. The force l opposes the force of the actuator 16 and may delay or slow disengagement of the gear ratios. To ensure disengagement of the jaws, the actuator 16 applies a force to the sliding gear 14 having a degree of freedom to slide relative to the transmission shaft 1 a.

The capacity of the gearbox actuator is limited, which means that the composition of the applied torques C1, C2 must be limited as much as possible or preferably eliminated to ensure that the pawls are disengaged under optimum conditions. However, the ability of PT's electric machines and combustion engines to achieve torque set points is itself limited in magnitude by the inherent performance of these components. Finally, product-approved constraints and dynamic performance also limit the achievement of torque set points.

In this case, there are cases where disengagement of the pawls cannot be achieved:

in some instances, the resultant of the torque is not reduced sufficiently to allow the sliding gear to move,

in other examples, the resultant of the torque is sufficiently reduced, but the resultant value allows the sliding gear to move for too short a duration before the torque reverses and increases again in the opposite direction.

The method of the invention comprises the following steps: controlling the disengagement of the teeth of the internal transmission coupling 8, 12, which is placed under the control of the shift actuator 16, for engaging or disengaging the gear ratio for transmitting the torque supplied by the combustion engine connected to the input of the transmission without disengaging the coupling clutch. The proposed method is based on the detection of critical situations. The detection relies on observing the engine speed and its derivative. The detection of a critical situation may also be based on an alarm from the brake system without departing from the scope of the invention.

When the combustion engine enters a critical situation where there is a risk of stalling when decelerating in an engaged gear ratio,

determining a first critical region, in which actuator 16 is forced to disengage the gear ratio to prevent stalling, as a function of combustion engine speed ω, and

-determining a second critical zone, in which the engine stall is managed by preventing the injection of fuel, as a function of the engine speed and deceleration.

The deceleration of the engine can be determined by the value of the derivative of its rotational speed (d ω/dt) or by the vehicle braking system.

The general principle is to detect these two distinct critical regions from observations of engine speed and deceleration:

-a first critical region, where there is a risk of stall, and where the system has the ability to decouple the engine from the wheels, an

-a second critical region, where there is a risk of stalling, and where the system does not have the ability to decouple the engine from the wheels.

In the first region, the response is given by forcing the decoupling by exceeding the general driveline state set point: in this region, the actuator 16 has the ability to disengage the gear ratios in accordance with the resultant torque exerted by the rotating portion of the variator on the teeth of the coupling.

In the second zone, this response consists in managing the stall of the combustion engine by preventing the injection of fuel: in this region, the actuator does not have the ability to disengage the gear ratios according to the resultant torque exerted by the rotating portion of the transmission on the teeth of the coupling.

In the specific case where the hybrid PT does not have a disconnect clutch on the input side of the transmission (as is the case in fig. 1), the transmission combines torque from the combustion engine and torque from at least one electric machine into a plurality of different transmission gear ratios. In this case, the invention contemplates enabling the described dual strategy: depending on the conditions encountered, the first strategy is referred to as the "anti-stall strategy" and the second strategy is referred to as the "stall strategy". As indicated above, the application region of both strategies may be determined by the range of values of the engine speed ω and their variation over time (preferably filtered). According to the diagram in fig. 3, the following three operating regions are thus identified as a function of the combustion engine speed ω and its derivative d ω/dt:

the first area a, in which no specific policy is applied, is considered to be in nominal operation or "nominal mode",

-an intermediate second zone B in which the "anti-stall strategy" is activated, and

-a third zone C where a "stall strategy" is enabled.

The proposed transmission illustrated in fig. 1 comprises at least one internal coupling 8, 11, which is placed under the control of a shift actuator 16 for engaging or disengaging, without disengaging a coupling clutch, a gear ratio for transmitting the torque supplied by a combustion engine connected to the input side of the transmission.

According to the invention, the shift actuator 16 and the injection of the combustion engine are managed according to the method described above.

In a particular embodiment, the coupling 8, 11 in question is of the type having a sliding gear 14 and a pawl 12.

The proposed hybrid PT consists of: a combustion engine connected to the first transmission input shaft 4 without a disconnect clutch; an electric Machine (ME) connected to the second transmission input shaft; and at least one coupling 8, 11 having coupling teeth coupled to the gear wheel and being placed under the control of the shift actuator. According to the invention, the combustion engine and the coupling actuator are managed according to the method described above.

Such a hybrid power PT may comprise, in addition to the combustion engine and the main motor ME, a supplementary electric machine HSG providing torque in the engine gear ratio. The described strategy will then apply under the following conditions:

engaged "engine gear ratio", which means that the combustion engine is mechanically coupled to the wheels at gear ratio, whatever the state of the combustion engine, in particular when using a supplementary electric machine to compensate for the hole in torque (hole) during the shift between Z1 and Z2 in the case of decoupling of the combustion engine, and

the derivative d ω/dt of the rotational speed of the supplementary electric machine HSG is in the first activation region.

The "stall strategy" applies in the following cases:

the "engine gear ratio" is engaged, i.e. when the combustion engine is mechanically coupled to the wheels in gear ratios, whatever the state of the combustion engine, in particular when the complementary electric machine HSG is used to compensate for the torque void during the shift between the two electric gear ratios, with the combustion engine decoupled, and

the derivative d ω/dt of the rotational speed of the supplementary electric machine HSG is in a second activation region in which an anti-lock braking system (ABS) is activated.

The invention makes it possible to limit the effect of bumps on the drive train, which may have an effect on the reliability of the drive train, and to limit the discomfort caused by these bumps to the passengers.