CN110775038B - Integrated electronic parking system for new energy vehicle and control method thereof - Google Patents

Abstract

The invention relates to the technical field of vehicle control, in particular to an integrated electronic parking system for a new energy vehicle and a control method thereof, and the integrated electronic parking system comprises the following steps: A) monitoring and recording the service condition of a brake in the running process of a vehicle; B) when the vehicle is parked, the efficiency evaluation of the brake disc is obtained according to the service condition of the brake; C) and determining the clamping force of the brake disc when parking according to the performance evaluation of the brake disc. The substantial effects of the invention are as follows: the temperature of the brake disc is calculated by monitoring the service condition of the brake in the running process of the vehicle, the efficiency of the brake disc is evaluated, when the efficiency of the brake disc is poor, the clamping force is supplemented in time, the parking clamping force of the vehicle is ensured, and the stability of the vehicle during parking is improved.

Description

Integrated electronic parking system for new energy vehicle and control method thereof

Technical Field

The invention relates to the technical field of vehicle control, in particular to an integrated electronic parking system for a new energy vehicle and a control method thereof.

Background

ESC is called car electron stable control system in the car control field, is the novel initiative safety coefficient of vehicle, is the further extension of car anti-lock braking system (ABS) and Traction Control System (TCS) function to on this basis, increased yaw rate sensor, lateral acceleration sensor and steering wheel corner sensor when the vehicle turns to the driving, ESC burns record in automobile-used ECU, through the drive power and the brake force of controlling front and back, left and right wheels, ensures the lateral stability that the vehicle went. EPB is the abbreviation of electric Park Brake, and the Chinese name is electronic parking Brake system, and it has replaced traditional mechanical lever and tire cable wire, can provide better help for the driver, and is safer than traditional pull rod handbrake, can not change braking effect because of driver's dynamics, has changed traditional handbrake pull rod into a button. In EPB, the braking force is adjustable to match the demand for longitudinal inclination. When the automobile is started, the brake can be automatically released by pressing the button. The brake disc can generate heat and the temperature rises in the braking process, the efficiency of the brake disc after the temperature rises is reduced, and if the efficiency of the brake disc is lower than a certain threshold value, the clamping force is insufficient, so that the parking of the vehicle is unstable. In the prior art, the ESC and the EPB are positioned in two ECUs, so that the vehicle cost is increased, and meanwhile, the EPB in the prior art cannot evaluate the efficiency of a brake disc and cannot ensure the stability of parking.

Chinese patent CN108995641A, published 2018, 12 months and 14 days, a vehicle parking control method based on an EPB system, includes a vehicle parking process and a vehicle parking release process, the vehicle parking release process is the reverse process of the vehicle parking request process, and includes that a driver releases parking through an EPB switch and the driver releases parking through an electronic shifter P-shift switch; in the method, in the process of requesting the parking of the vehicle, two conditions of trampling a brake pedal and an accelerator pedal by a driver are fully considered, and before the parking is executed, the torque limiting process of an engine is added until a preset torque value is reached, and then the parking is carried out, so that the stable transition is realized; in the process of requesting parking of the vehicle, when parking failure occurs or an EPB system fails, a driver is prompted to start emergency parking, and parking safety is guaranteed. But it does not solve the problem of brake disc clamping force deficiency due to temperature rise.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: the existing EPB can not ensure the stable parking. The integrated electronic parking system for the new energy vehicle and the control method thereof are provided, wherein the parking temperature of the brake disc efficiency is evaluated by calculating the temperature of the brake disc.

In order to solve the technical problems, the technical scheme adopted by the invention is as follows: a control method of an integrated electronic parking system for a new energy vehicle is suitable for the electronic parking system integrated in an ESC, and comprises the following steps: A) monitoring and recording the service condition of a brake in the running process of a vehicle; B) when the vehicle is parked, the efficiency evaluation of the brake disc is obtained according to the service condition of the brake; C) and determining the clamping force of the brake disc when parking according to the performance evaluation of the brake disc. The temperature and the efficiency of the brake disc are evaluated by monitoring the service condition of the brake in the driving process, and whether the brake disc needs to be further clamped when parking is judged. The brake disc is difficult to release due to over-tight clamping, stress damage is caused to the brake disc, and the service life of the brake disc is shortened. Among the prior art, EPB can provide an appropriate clamp force according to the vehicle longitudinal direction degree of inclination, and this technical scheme is based on this clamp force, and the step-up or do not do the processing again solves the problem that the clamp force that the brake disc leads to because of the temperature risees descends, improves the security and the stability of parking.

Preferably, in the step a), the service conditions of the brakes are monitored, wherein the service conditions of the brakes comprise the starting time of each brake, the vehicle speed at the starting time of the brake, the ending time of the brake and the vehicle speed at the ending time of the brake; and recording and monitoring the service condition of the brake in the starting and running processes of the vehicle, and storing the service condition as a brake record. It is sufficient to carry out an evaluation of the efficacy of the brake disc.

Preferably, in step B), the method for obtaining an evaluation of the effectiveness of the brake disc comprises: B1) initializing parameters: setting a speed threshold value v and a temperature threshold value K as a brake disc temperature T_eSetting an initial value T₀(ii) a B2) Sequentially reading each record of the brake records, and circularly executing the steps B3-B4 until each record of the brake records is traversed; B3) updating the brake disc temperature T at the starting time of the brake according to the ending time of the last brake record, the brake disc temperature at the ending time of the last brake record and the starting time of the brake_s(ii) a B4) Updating the temperature T of the brake disc according to the vehicle speed at the beginning and the vehicle speed at the end of the current brake record_e(ii) a B5) According to the last recorded brake ending time of the brake record and the brake disc temperature T at the brake ending time_eObtaining the temperature T of the brake disc at the pull-up time of the hand brake during parking_e(ii) a B6) If the temperature T of the brake disc_sIf the temperature is larger than the temperature threshold K, the efficiency of the brake disc is judged to be poor, and the clamping force of the brake disc needs to be increased, otherwise, the efficiency of the brake disc is judged to be normal, and the clamping force of the brake disc does not need to be increased.

Preferably, step a) further comprises: A1) when the automobile is braked each time, the amplitude x of the treaded brake pedal is obtained by using the position sensor of the brake pedal, and the deceleration of the automobile in the braking process is calculated

Wherein t is₁To the brake start time, t₂To brake end time, v₁Speed of the vehicle at the start of braking, v₂Recording braking parameters for the vehicle speed at the end of braking

Obtaining a set of parameters { λ₁，λ₂，…，λ_n}，λ_{i；i∈[1，n]}The braking parameter of the ith brake is represented; step B) also includes: calculating the parameter difference d ═ lambda_n-λ_n-1If d is larger than the preset threshold value, judging the brake discAnd if the efficiency is poor, otherwise, judging that the efficiency of the brake disc is normal.

Preferably, in step B3), the disc temperature at the time of starting the current braking

If T_sLess than T₀Then T is_s＝T₀Wherein, in the step (A),

indicating the temperature of the brake disc at the end of the last braking, if the braking is the first braking, the temperature of the brake disc is measured

Eta is the cooling rate of the brake disc,

is the last brake ending time.

Preferably, in step B4), brake disc temperature T is updated_eThe method comprises the following steps:

wherein, P is the heat production amount of a single rear wheel brake disc in the braking process, c represents the specific heat capacity of the brake disc, and m represents the mass of the brake disc.

Preferably, the heat generated by the single rear wheel brake disc during braking

Wherein M is the mass of the whole vehicle, Delta G is the variation of the gravitational potential energy of the vehicle, s is the distribution coefficient of the absorbed energy of the brake and the tire, a is the conversion efficiency of the energy, l is the heat distribution coefficient of the brake disc, q is the braking force distribution coefficient of the front brake and the rear brake, and r is the energy recovery coefficient.

Preferably, the brake disc temperature T at the start time of braking is calculated each time_sIn time, dynamically correcting the cooling rate eta of the brake disc comprises the following steps: B31) at last brake end time

Then, the ESC controls the brake disc to carry out non-inductive braking with preset clamping force and duration, and the average deceleration a of the vehicle in the non-inductive braking is obtained₁After a preset time interval, the non-inductive braking with the same clamping force and duration is carried out again to obtain the average deceleration a of the vehicle in the non-inductive braking₂(ii) a B32) Cooling rate of brake disc

η' is the cooling efficiency under laboratory conditions, η ═ f (T)_e) Function f (T)_e) And (5) performing experiments under laboratory conditions and fitting to obtain the correction factor k. The heat dissipation efficiency of the brake disc is not constant, the brake disc changes along with factors such as ambient temperature, ambient wind speed, wind direction, vehicle running speed, road surface dust, rainwater and the like, deceleration changes of the vehicle are measured twice through a non-inductive brake, the change of friction force between the brake disc and a brake drum under the same clamping force is reflected, namely the change of the temperature of the brake disc is reflected, further, the change of the heat dissipation condition of the brake disc can be reflected from the change of the deceleration, the change of the heat dissipation condition of the brake disc is large, the change of the deceleration shows that the heat dissipation condition is good, and the heat dissipation efficiency measured under laboratory conditions is corrected, so that the accuracy of calculating the temperature of the brake disc can be.

The integrated electronic parking system for the new energy vehicle executes the control method of the integrated electronic parking system for the new energy vehicle, and comprises an ECU for the new energy vehicle, wherein an ESC program and an EPB program are burnt in the ECU.

The substantial effects of the invention are as follows: the temperature of the brake disc is calculated by monitoring the service condition of the brake in the running process of the vehicle, the efficiency of the brake disc is evaluated, when the efficiency of the brake disc is poor, the clamping force is supplemented in time, the parking clamping force of the vehicle is ensured, and the stability of the vehicle during parking is improved.

Drawings

FIG. 1 is a flow chart of a control method of an integrated electronic parking system according to an embodiment.

Fig. 2 is a flowchart of a method for evaluating the performance of a brake disc according to an embodiment.

FIG. 3 is a flowchart illustrating a method for modifying a cooling rate of a brake disc according to an embodiment.

Detailed Description

The following provides a more detailed description of the present invention, with reference to the accompanying drawings.

The first embodiment is as follows:

a control method of an integrated electronic parking system for a new energy vehicle is suitable for an electronic parking system integrated in an ESC, as shown in FIG. 1, the embodiment includes the following steps:

A) and monitoring and recording the service condition of the brake in the running process of the vehicle. Monitoring the service condition of the brake, wherein the service condition comprises the starting time of each brake, the vehicle speed at the starting time of the brake, the ending time of the brake and the vehicle speed at the ending time of the brake; and recording and monitoring the service condition of the brake in the starting and running processes of the vehicle, and storing the service condition as a brake record.

When the automobile is braked each time, the amplitude x of the treaded brake pedal is obtained by using the position sensor of the brake pedal, and the deceleration of the automobile in the braking process is calculated

Wherein t is₁To the brake start time, t₂To brake end time, v₁Speed of the vehicle at the start of braking, v₂Recording braking parameters for the vehicle speed at the end of braking

Obtaining a set of parameters { λ₁，λ₂，…，λ_n}，λ_{i，i∈[1，n]}The braking parameter of the ith brake is represented; step B) also includes: calculating the parameter difference d ═ lambda_n-λ_n-1If d is larger than the preset threshold value, the efficiency of the brake disc is judged to be poor, otherwise, the efficiency of the brake disc is judged to be normal.

B) When the vehicle is parked, the effectiveness evaluation of the brake disc is obtained according to the use condition of the brake. As shown in fig. 2, the method for obtaining the performance evaluation of the brake disc includes: b is1) Initializing parameters: setting a speed threshold value v and a temperature threshold value K as a brake disc temperature T_eSetting an initial value T₀. B2) And reading each record of the brake record in turn, and executing the steps B3-B4 in a circulating mode until each record of the brake record is traversed.

B3) Updating the brake disc temperature T at the starting time of the brake according to the ending time of the last brake record, the brake disc temperature at the ending time of the last brake record and the starting time of the brake_s(ii) a Temperature of brake disc at the time of starting of the present brake

If T_sLess than T₀Then T is_s＝T₀Wherein, in the step (A),

indicating the temperature of the brake disc at the end of the last braking, if the braking is the first braking, the temperature of the brake disc is measured

Eta is the cooling rate of the brake disc,

is the last brake ending time.

As shown in fig. 3, the disc temperature T at the start time of braking is calculated each time_sIn time, dynamically correcting the cooling rate eta of the brake disc comprises the following steps: B31) at last brake end time

Then, the ESC controls the brake disc to carry out non-inductive braking with preset clamping force and duration, and the average deceleration a of the vehicle in the non-inductive braking is obtained₁After a preset time interval, the non-inductive braking with the same clamping force and duration is carried out again to obtain the average deceleration a of the vehicle in the non-inductive braking₂(ii) a B32) Cooling rate of brake disc

η' is the cooling efficiency under laboratory conditions, η ═ f (T)_e) Function f (T)_e) And (5) performing experiments under laboratory conditions and fitting to obtain the correction factor k. The heat dissipation efficiency of the brake disc is not constant, the brake disc changes along with factors such as ambient temperature, ambient wind speed, wind direction, vehicle running speed, road surface dust, rainwater and the like, deceleration changes of the vehicle are measured twice through a non-inductive brake, the change of friction force between the brake disc and a brake drum under the same clamping force is reflected, namely the change of the temperature of the brake disc is reflected, further, the change of the heat dissipation condition of the brake disc can be reflected from the change of the deceleration, the change of the heat dissipation condition of the brake disc is large, the change of the deceleration shows that the heat dissipation condition is good, and the heat dissipation efficiency measured under laboratory conditions is corrected, so that the accuracy of calculating the temperature of the brake disc can be.

B4) Updating the temperature T of the brake disc according to the vehicle speed at the beginning and the vehicle speed at the end of the current brake record_e；

Wherein, P is the heat production amount of a single rear wheel brake disc in the braking process, c represents the specific heat capacity of the brake disc, and m represents the mass of the brake disc. Heat generation amount of single rear wheel brake disc during braking

Wherein M is the mass of the whole vehicle, Delta G is the variation of the gravitational potential energy of the vehicle, s is the distribution coefficient of the absorbed energy of the brake and the tire, a is the conversion efficiency of the energy, l is the heat distribution coefficient of the brake disc, q is the braking force distribution coefficient of the front brake and the rear brake, and r is the energy recovery coefficient.

B5) According to the last recorded brake ending time of the brake record and the brake disc temperature T at the brake ending time_eObtaining the temperature T of the brake disc at the pull-up time of the hand brake during parking_e。

B6) If the temperature T of the brake disc_eIf the temperature is higher than the temperature threshold K, the efficiency of the brake disc is judged to be poor, the clamping force of the brake disc needs to be increased, otherwise, the efficiency of the brake disc is judged to be normal, and the brake disc does not need to be increasedAnd (4) clamping force.

C) And determining the clamping force of the brake disc when parking according to the performance evaluation of the brake disc.

The control method of the integrated electronic parking system for the new energy vehicle comprises an ECU for the new energy vehicle, wherein an ESC program and an EPB program are burnt in the ECU.

The embodiment has the following beneficial effects: the temperature and the efficiency of the brake disc are evaluated by monitoring the service condition of the brake in the driving process, and whether the brake disc needs to be further clamped when parking is judged. The brake disc is difficult to release due to over-tight clamping, stress damage is caused to the brake disc, and the service life of the brake disc is shortened. Among the prior art, EPB can provide an appropriate clamp force according to the vehicle longitudinal direction degree of inclination, and this technical scheme is based on this clamp force, and the step-up or do not do the processing again solves the problem that the clamp force that the brake disc leads to because of the temperature risees descends, improves the security and the stability of parking.

The above-described embodiments are only preferred embodiments of the present invention, and are not intended to limit the present invention in any way, and other variations and modifications may be made without departing from the spirit of the invention as set forth in the claims.

Claims (7)

1. A control method of an integrated electronic parking system for a new energy vehicle is suitable for the electronic parking system integrated in an ESC and is characterized in that,

the method comprises the following steps:

A) monitoring and recording the service condition of a brake in the running process of a vehicle;

B) when the vehicle is parked, the efficiency evaluation of the brake disc is obtained according to the service condition of the brake;

C) determining the clamping force of the brake disc during parking according to the efficiency evaluation of the brake disc;

in the step A), monitoring the service condition of the brake, wherein the service condition of the brake comprises the starting time of each brake, the vehicle speed at the starting time of the brake, the braking ending time and the vehicle speed at the ending time of the brake; recording and monitoring the service condition of the brake in the starting and running processes of the vehicle, and storing the service condition as a brake record;

step A) also includes:

A1) when the automobile is braked each time, the amplitude x of the treaded brake pedal is obtained by using the position sensor of the brake pedal, and the deceleration of the automobile in the braking process is calculated

Wherein t is₁To the brake start time, t₂To brake end time, v₁Speed of the vehicle at the start of braking, v₂Recording braking parameters for the vehicle speed at the end of braking

Obtaining a set of parameters { λ₁,λ₂,…,λ_n}，λ_i,i∈[1,n]The braking parameter of the ith brake is represented;

step B) also includes: calculating the parameter difference d ═ lambda_n-λ_n-1If d is larger than the preset threshold value, the efficiency of the brake disc is judged to be poor, otherwise, the efficiency of the brake disc is judged to be normal.

2. The method for controlling the integrated electronic parking system for the new energy vehicle as claimed in claim 1,

in the step B), the method for obtaining the efficiency evaluation of the brake disc comprises the following steps:

B1) initializing parameters: setting a speed threshold value v and a temperature threshold value K as a brake disc temperature T_eSetting an initial value T₀；

B2) Sequentially reading each record of the brake records, and circularly executing the steps B3-B4 until each record of the brake records is traversed;

B3) updating the brake disc temperature T at the starting time of the brake according to the ending time of the last brake record, the brake disc temperature at the ending time of the last brake record and the starting time of the brake_s；

B4) Recording the starting and ending vehicle speeds according to the current brakingSpeed of vehicle, updating brake disc temperature T_e；

B5) According to the last recorded brake ending time of the brake record and the brake disc temperature T at the brake ending time_eObtaining the temperature T of the brake disc at the pull-up time of the hand brake during parking_e；

B6) If the temperature T of the brake disc_eIf the temperature is larger than the temperature threshold K, the efficiency of the brake disc is judged to be poor, and the clamping force of the brake disc needs to be increased, otherwise, the efficiency of the brake disc is judged to be normal, and the clamping force of the brake disc does not need to be increased.

3. The method for controlling the integrated electronic parking system for the new energy vehicle as claimed in claim 2,

step B3), the temperature of the brake disc at the starting time of the brake

Wherein the content of the first and second substances,

indicating the temperature of the brake disc at the end of the last braking, if the braking is the first braking, the temperature of the brake disc is measured

If T_sLess than T₀Then T is_s＝T₀Eta is the cooling rate of the brake disc,

is the last brake ending time.

4. The method for controlling the integrated electronic parking system for the new energy vehicle as claimed in claim 2,

step B4), updating the brakeDisc temperature T_eThe method comprises the following steps:

wherein, P is the heat production amount of a single rear wheel brake disc in the braking process, C represents the specific heat capacity of the brake disc, and m represents the mass of the brake disc.

5. The method for controlling the integrated electronic parking system for the new energy vehicle as claimed in claim 4,

heat generation amount of single rear wheel brake disc during braking

Wherein M is the mass of the whole vehicle, Delta G is the variation of the gravitational potential energy of the vehicle, s is the distribution coefficient of the absorbed energy of the brake and the tire, a is the conversion efficiency of the energy, l is the heat distribution coefficient of the brake disc, q is the braking force distribution coefficient of the front brake and the rear brake, and r is the energy recovery coefficient.

6. The method for controlling the integrated electronic parking system for the new energy vehicle as claimed in claim 3,

calculating the brake disc temperature T at the moment of starting the braking each time_sIn time, dynamically correcting the cooling rate eta of the brake disc comprises the following steps:

B31) at last brake end time

Then, the ESC controls the brake disc to carry out non-inductive braking with preset clamping force and duration, and the average deceleration a of the vehicle in the non-inductive braking is obtained₁After a preset time interval, the non-inductive braking with the same clamping force and duration is carried out again to obtain the average deceleration a of the vehicle in the non-inductive braking₂；

B32) Cooling rate of brake disc

η' is the cooling efficiency under laboratory conditions, η ═ f (T)_e) Function f (T)_e) And (5) performing experiments under laboratory conditions and fitting to obtain the correction factor k.

7. An integrated electronic parking system for a new energy vehicle, which executes the control method of the integrated electronic parking system for the new energy vehicle according to any one of claims 1 to 6,

the system comprises an ECU for the new energy vehicle, wherein an ESC program and an EPB program are burnt in the ECU.

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