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JP2007092711A - Learning device of electrically controlled throttle - Google Patents

Learning device of electrically controlled throttle Download PDF

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Publication number
JP2007092711A
JP2007092711A JP2005286107A JP2005286107A JP2007092711A JP 2007092711 A JP2007092711 A JP 2007092711A JP 2005286107 A JP2005286107 A JP 2005286107A JP 2005286107 A JP2005286107 A JP 2005286107A JP 2007092711 A JP2007092711 A JP 2007092711A
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correlation
ignition timing
throttle
intake air
air amount
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JP2005286107A
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JP4779543B2 (en
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Hiromi Shimazaki
博己 嶋▲崎▼
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Nissan Motor Co Ltd
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Nissan Motor Co Ltd
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02TCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
    • Y02T10/00Road transport of goods or passengers
    • Y02T10/10Internal combustion engine [ICE] based vehicles
    • Y02T10/40Engine management systems

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  • Combined Controls Of Internal Combustion Engines (AREA)
  • Electrical Control Of Ignition Timing (AREA)
  • Control Of Throttle Valves Provided In The Intake System Or In The Exhaust System (AREA)
  • Electrical Control Of Air Or Fuel Supplied To Internal-Combustion Engine (AREA)

Abstract

<P>PROBLEM TO BE SOLVED: To accurately learn the correlation between the opening of an electrically controlled throttle and the amount of suction air of an internal combustion engine in a large domain within an idle range. <P>SOLUTION: When the feedback control of idling is performed, the opening of the throttle is increased and corrected by retarding the ignition timing, and the correlation is learned on the side of a larger openings/larger amount of suction air than under normal idle control. Then the correlation between the opening of the throttle and the amount of the suction air is updated from a correlation at a plurality of points determined by a gradual increase in a retard angle correction amount. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

本発明は、内燃機関の吸気通路に介装される電制スロットルの開度と前記内燃機関の吸入空気量との相関を学習する電制スロットルの学習装置に関する。   The present invention relates to a learning device for an electric throttle that learns the correlation between the opening of an electric throttle installed in an intake passage of the internal combustion engine and the amount of intake air of the internal combustion engine.

特許文献1には、内燃機関のアイドル運転時に、実際の吸入空気量が要求値に達するように電制スロットルの開度を調整し、要求の吸入空気量に対応するスロットル基準開度と実際のスロットル開度とのずれ量をスロットル学習値として学習すると共に、前記スロットル学習値を機関運転状態に基づき補正した値を目標スロットル開度の補正値として算出する吸入空気量制御装置が開示されている。
特開2000−257490号公報
In Patent Document 1, during the idling operation of the internal combustion engine, the opening degree of the electric throttle is adjusted so that the actual intake air amount reaches the required value, and the throttle reference opening corresponding to the required intake air amount and the actual An intake air amount control device that learns the amount of deviation from the throttle opening as a throttle learning value and calculates a value obtained by correcting the throttle learning value based on the engine operating state as a correction value for the target throttle opening is disclosed. .
JP 2000-257490 A

上記のように、従来の学習制御は、アイドル運転状態で要求の吸入空気量が得られるようにスロットル開度を通常に制御したときのデータから、スロットル開度と吸入空気量との相関を学習する構成であり、スロットル開度と吸入空気量との相関の変化を判断するための情報が、通常制御状態での1点データに限定されていた。
このため、通常制御状態を外れた領域での相関の推定精度が悪く、開度と吸入空気量との相関の経時的な変化を広い領域で精度良く学習させることができず、経時的な特性変化に対してアイドル空気量の制御精度を高く維持させることが困難であるという問題があった。
As described above, the conventional learning control learns the correlation between the throttle opening and the intake air amount from the data when the throttle opening is normally controlled so that the required intake air amount can be obtained in the idling state. The information for determining the change in the correlation between the throttle opening and the intake air amount is limited to one point data in the normal control state.
For this reason, the estimation accuracy of the correlation in the area out of the normal control state is poor, and the change over time in the correlation between the opening degree and the intake air amount cannot be learned accurately in a wide area, and the characteristics over time There is a problem that it is difficult to maintain high control accuracy of the idle air amount against changes.

本発明は上記問題点に鑑みなされたものであり、電制スロットルの開度と内燃機関の吸入空気量との相関をアイドル域内の広い領域で精度良く学習できる学習装置を提供することを目的とする。   The present invention has been made in view of the above problems, and an object of the present invention is to provide a learning device capable of accurately learning the correlation between the opening degree of the electric throttle and the intake air amount of the internal combustion engine in a wide region within the idle region. To do.

そのため、本発明に係る電制スロットルの学習装置では、内燃機関のアイドル運転時に、内燃機関の点火時期を補正すると共に、該点火時期の補正によるトルク変化を相殺するように電制スロットルの開度を変化させ、該変化させた開度において開度と吸入空気量との相関を学習することを特徴とする。   Therefore, in the electric throttle learning device according to the present invention, during the idling operation of the internal combustion engine, the ignition timing of the internal combustion engine is corrected, and the electric throttle opening is adjusted so as to cancel the torque change due to the correction of the ignition timing. And the correlation between the opening degree and the intake air amount is learned at the changed opening degree.

上記構成によると、点火時期を補正することで機関の出力トルクが変化するので、トルクが変化しないようにスロットル開度を変化させて機関の吸入空気量を変化させる。
これにより、通常の点火時期でのスロットル開度・吸入空気量状態とは異なるスロットル・吸入空気量状態を強制的に発生させて、アイドル域内の複数のデータに基づいて相関を推定学習させることができ、アイドル域内の広い領域でスロットル開度と吸入空気量との相関を精度良く学習できるようになる。
According to the above configuration, the output torque of the engine changes by correcting the ignition timing. Therefore, the amount of intake air of the engine is changed by changing the throttle opening so that the torque does not change.
This makes it possible to forcibly generate a throttle / intake air amount state different from the throttle opening / intake air amount state at the normal ignition timing, and to estimate and learn the correlation based on a plurality of data in the idle region. Thus, the correlation between the throttle opening and the intake air amount can be learned with high accuracy in a wide region within the idle region.

以下に本発明の実施の形態を図に基づいて説明する。
図1は、実施形態における車両用内燃機関のシステム図である。
図1において、内燃機関(ガソリン機関)1の各気筒には、エアクリーナ2を通過した空気が、吸気ダクト3,吸気コレクタ4,吸気マニホールド5,吸気バルブ6を介して吸引される。
Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a system diagram of an internal combustion engine for a vehicle according to an embodiment.
In FIG. 1, air that has passed through an air cleaner 2 is sucked into each cylinder of an internal combustion engine (gasoline engine) 1 through an intake duct 3, an intake collector 4, an intake manifold 5, and an intake valve 6.

内燃機関1の吸入空気量は、前記吸気ダクト3に介装される電制スロットル7によって調整される。
前記電制スロットル7は、バタフライ式のスロットルバルブ7aをスロットルモータ(スロットルアクチュエータ)7bで開閉駆動する機構である。
各気筒の吸気ポート部には、燃料噴射弁9がそれぞれ設けられる。
The intake air amount of the internal combustion engine 1 is adjusted by an electric control throttle 7 interposed in the intake duct 3.
The electric throttle 7 is a mechanism that opens and closes a butterfly throttle valve 7a with a throttle motor (throttle actuator) 7b.
A fuel injection valve 9 is provided in each intake port portion of each cylinder.

そして、前記燃料噴射弁9から噴射される燃料(ガソリン)によって形成される混合気は、燃焼室10内で点火プラグ15による火花点火により着火燃焼する。
前記点火プラグ15それぞれには、パワートランジスタを内蔵する点火コイル16が直付けされている。
尚、燃料噴射弁9が燃焼室10内に直接燃料を噴射する構成とすることができる。
The air-fuel mixture formed by the fuel (gasoline) injected from the fuel injection valve 9 is ignited and combusted by spark ignition by the spark plug 15 in the combustion chamber 10.
Each ignition plug 15 is directly attached with an ignition coil 16 incorporating a power transistor.
Note that the fuel injection valve 9 can directly inject fuel into the combustion chamber 10.

前記燃焼室10内の燃焼排気は、排気バルブ11,排気マニホールド12,排気ダクト13を介して大気中へ排出される。
前記排気ダクト13には、排気中の有害成分を浄化するための触媒コンバータ14が介装される。
前記スロットルモータ8、燃料噴射弁9、及び、点火コイル16への通電を制御するパワートランジスタは、マイクロコンピュータを内蔵するエンジンコントロールユニット(ECU)21によって制御される。
The combustion exhaust in the combustion chamber 10 is discharged to the atmosphere via an exhaust valve 11, an exhaust manifold 12, and an exhaust duct 13.
The exhaust duct 13 is provided with a catalytic converter 14 for purifying harmful components in the exhaust.
The power transistor for controlling energization to the throttle motor 8, the fuel injection valve 9, and the ignition coil 16 is controlled by an engine control unit (ECU) 21 incorporating a microcomputer.

前記エンジンコントロールユニット21には、各種センサからの検出信号が入力される。
前記各種センサとしては、前記電制スロットル7の上流側で内燃機関1の吸入空気流量(質量流量)を検出するエアフローメータ22、前記触媒コンバータ14の上流側で排気中の酸素濃度に基づいて排気空燃比を検出する空燃比センサ23、内燃機関1の回転速度を検出する回転速度センサ24、運転者が操作するアクセルペダルの踏み込み量(アクセル開度)を検出するアクセル開度センサ25、前記スロットルバルブ7aの開度を検出するスロットルセンサ26が設けられている。
Detection signals from various sensors are input to the engine control unit 21.
The various sensors include an air flow meter 22 that detects the intake air flow rate (mass flow rate) of the internal combustion engine 1 on the upstream side of the electric throttle 7, and an exhaust gas on the upstream side of the catalytic converter 14 based on the oxygen concentration in the exhaust gas. An air-fuel ratio sensor 23 that detects the air-fuel ratio, a rotation speed sensor 24 that detects the rotation speed of the internal combustion engine 1, an accelerator opening sensor 25 that detects the amount of depression of the accelerator pedal operated by the driver (accelerator opening), and the throttle A throttle sensor 26 for detecting the opening degree of the valve 7a is provided.

前記エンジンコントロールユニット21は、前記燃料噴射弁9による燃料噴射量を以下のようにして制御する。
まず、エアフローメータ22で検出される吸入空気流量と、回転速度センサ24で検出される機関回転速度とから、そのときのシリンダ吸入空気量において目標空燃比の混合気を形成するための基本燃料噴射量を算出する一方、内燃機関1の冷却水温度等に基づいて各種補正係数を算出し、更に、空燃比センサ23で検出される空燃比が目標空燃比に近づくように空燃比フィードバック補正係数を算出し、これら補正係数で前記基本燃料噴射量を補正して最終的な燃料噴射量を設定する。
The engine control unit 21 controls the fuel injection amount by the fuel injection valve 9 as follows.
First, basic fuel injection for forming an air-fuel mixture with a target air-fuel ratio in the cylinder intake air amount at that time from the intake air flow rate detected by the air flow meter 22 and the engine rotational speed detected by the rotational speed sensor 24. While calculating the amount, various correction coefficients are calculated based on the coolant temperature of the internal combustion engine 1 and the air-fuel ratio feedback correction coefficient is set so that the air-fuel ratio detected by the air-fuel ratio sensor 23 approaches the target air-fuel ratio. The final fuel injection amount is set by calculating and correcting the basic fuel injection amount with these correction coefficients.

そして、前記最終的な燃料噴射量に相当するパルス幅の噴射パルス信号を、各気筒の行程に合わせてそれぞれの燃料噴射弁9に出力する。
また、前記エンジンコントロールユニット21は、前記基本燃料噴射量(機関負荷)及び機関回転速度から点火時期(点火進角値)を算出し、該点火時期と所定の通電時間とに基づいて前記点火コイル16に内蔵されたパワートランジスタのオン・オフを制御する。
Then, an injection pulse signal having a pulse width corresponding to the final fuel injection amount is output to each fuel injection valve 9 in accordance with the stroke of each cylinder.
The engine control unit 21 calculates an ignition timing (ignition advance value) from the basic fuel injection amount (engine load) and the engine rotation speed, and the ignition coil based on the ignition timing and a predetermined energization time. The power transistor built in 16 is controlled to be turned on / off.

更に、前記エンジンコントロールユニット21は、以下のようにして、内燃機関1の吸入空気量を制御する。
機関1の非アイドル運転時には、前記アクセル開度センサ25で検出されるアクセルペダルの踏み込み量(アクセル開度)等に応じた要求トルクに基づき、目標吸入空気量、更には目標スロットル開度を設定し、該目標スロットル開度に基づいて前記電制スロットル7の開度を制御する。
Further, the engine control unit 21 controls the intake air amount of the internal combustion engine 1 as follows.
During non-idle operation of the engine 1, a target intake air amount and further a target throttle opening are set based on a required torque corresponding to an accelerator pedal depression amount (accelerator opening) detected by the accelerator opening sensor 25. Then, the opening degree of the electric control throttle 7 is controlled based on the target throttle opening degree.

また、機関1のアイドル運転時には、冷却水温度や補機負荷などからアイドル時基本空気量を設定し、該アイドル時基本空気量に基づいて電制スロットル7の開度をフィードホワード制御する一方、冷却水温度等の運転条件に応じて設定される目標アイドル回転速度と実際のアイドル回転速度との偏差に応じてアイドル時空気量をフィードバック補正する。   Further, during idling operation of the engine 1, the idling basic air amount is set from the cooling water temperature and the auxiliary load, and the opening degree of the electric throttle 7 is feedforward controlled based on the idling basic air amount, The air amount during idling is feedback-corrected according to the deviation between the target idle speed set according to the operating conditions such as the cooling water temperature and the actual idle speed.

ところで、電制スロットル7の開度と吸入空気量との相関が経時的に変化し、初期状態で得られていた吸入空気量が同じ開度で得られなくなった状態で、初期の相関に基づいていて電制スロットル7の開度をフィードホワード制御すると、吸入空気量を要求通りに制御することができなくなってしまう。
そこで、本実施形態では、スロットル開度と吸入空気量との相関を学習し、該学習結果に基づいて目標スロットル開度が補正されるようにしており、前記学習の詳細を図2のフローチャートに従って詳細に説明する。
By the way, the correlation between the opening degree of the electric throttle 7 and the intake air amount changes with time, and the intake air amount obtained in the initial state cannot be obtained at the same opening degree. If the opening degree of the electric throttle 7 is feedforward controlled, the intake air amount cannot be controlled as required.
Therefore, in the present embodiment, the correlation between the throttle opening and the intake air amount is learned, and the target throttle opening is corrected based on the learning result. Details of the learning are according to the flowchart of FIG. This will be described in detail.

図2のフローチャートにおいて、まず、ステップS1では、アクセルが全閉であるアイドル運転時であるか否かを判断する。
機関1のアイドル運転時であるときには、ステップS2へ進み、アイドル回転フィードバック制御中であって、機関回転速度が目標アイドル回転速度に安定している状態であるか否かを判断する。
In the flowchart of FIG. 2, first, in step S <b> 1, it is determined whether or not the idling operation is performed when the accelerator is fully closed.
When the engine 1 is in the idling operation, the process proceeds to step S2, and it is determined whether or not the idling rotation feedback control is being performed and the engine rotation speed is stable at the target idle rotation speed.

そして、目標アイドル回転速度に安定しているときには、ステップS3へ進み、点火時期を強制的に所定量だけ遅角補正する。
次のステップS4では、前記遅角補正に対応して、前記電制スロットル7の開度が増大補正される。
点火時期を遅角すると、機関の出力トルクが低下するために、アイドル回転速度が低下するが、前述のように、目標アイドル回転速度を維持すべく前記電制スロットル7の開度がフィードバック制御される結果、前記トルク低下を相殺するようにスロットル開度が増大変化することになる(図3参照)。
When the target idle rotation speed is stable, the process proceeds to step S3, and the ignition timing is forcibly retarded by a predetermined amount.
In the next step S4, the opening degree of the electric throttle 7 is corrected to increase corresponding to the retardation correction.
If the ignition timing is retarded, the engine output torque is reduced and the idle rotation speed is reduced. As described above, the opening degree of the electric throttle 7 is feedback-controlled to maintain the target idle rotation speed. As a result, the throttle opening increases and changes so as to offset the torque drop (see FIG. 3).

ステップS5では、点火時期を遅角補正した状態で、スロットルセンサ26で検出されるスロットル開度とエアフローメータ22で検出される吸入空気量との相関を、学習メモリに格納する。
次のステップS6では、点火時期を遅角補正した結果、燃焼が不安定となって(失火が発生して)、機関1の回転変動が所定以上になっているか否かを判断する。
In step S5, the correlation between the throttle opening detected by the throttle sensor 26 and the intake air amount detected by the air flow meter 22 is stored in the learning memory in a state where the ignition timing is corrected to be retarded.
In the next step S6, it is determined whether or not the combustion has become unstable (misfire has occurred) as a result of retarding the ignition timing, and the rotational fluctuation of the engine 1 is not less than a predetermined value.

ステップS6で回転変動の発生が判断されなかった場合には、ステップS7へ進み、遅角補正の総量(通常の点火時期から現点火時期までの遅角量)が予め設定されている学習限界値に達しているか否かを判別する。
そして、遅角補正の総量が前記学習限界値に達していない場合には、ステップS3に戻り、前回までの遅角量に加えて更に所定量だけ点火時期を遅角補正させることで、よりスロットル開度・吸入空気量が大きい状態での開度と吸入空気量との相関を学習メモリに格納させる。
If it is not determined in step S6 that rotation fluctuation has occurred, the process proceeds to step S7, where the total amount of retardation correction (retard amount from the normal ignition timing to the current ignition timing) is set in advance as a learning limit value. It is determined whether or not.
If the total amount of retardation correction has not reached the learning limit value, the process returns to step S3, and the ignition timing is further retarded by a predetermined amount in addition to the retardation amount up to the previous time, thereby further reducing the throttle. The correlation between the opening degree and the intake air amount when the opening degree and the intake air amount are large is stored in the learning memory.

点火時期の総遅角量が前記学習限界値に達する前に、ステップS6で所定値を超える回転変動が発生していると判断されると、ステップS10で遅角補正をキャンセルして点火時期を通常値に戻すことで学習を停止させた後、ステップS1に戻るようにする。
これにより、点火時期の遅角補正を伴う学習制御によって、機関1の燃焼性が悪化することを回避でき、失火による燃料の後燃えによる触媒コンバータ14の劣化を防止できる。
If it is determined in step S6 that the rotational fluctuation exceeding the predetermined value has occurred before the total retard amount of the ignition timing reaches the learning limit value, the retard correction is canceled in step S10 and the ignition timing is set. After the learning is stopped by returning to the normal value, the process returns to step S1.
Thereby, it is possible to avoid the deterioration of the combustibility of the engine 1 by learning control accompanied by the retardation correction of the ignition timing, and it is possible to prevent the catalytic converter 14 from deteriorating due to the afterburning of fuel due to misfire.

尚、遅角補正をキャンセルして点火時期を通常値に戻す場合には、遅角補正量を漸減させて通常の点火時期にまで徐々に戻すようにする。
一方、遅角補正量を漸増させ、複数の遅角補正量毎にそのときのスロットル開度と吸入空気量との相関を学習メモリに格納させ、ステップS7で総遅角量が限界値に達したと判断されると、ステップS8へ進み、遅角補正をキャンセルして点火時期を通常値に戻す。
When canceling the retard correction and returning the ignition timing to the normal value, the retard correction amount is gradually decreased to gradually return to the normal ignition timing.
On the other hand, the retardation correction amount is gradually increased, and the correlation between the throttle opening and the intake air amount at that time is stored in the learning memory for each of the plurality of retardation correction amounts, and the total retardation amount reaches the limit value in step S7. If it is determined, the process proceeds to step S8 where the retard correction is canceled and the ignition timing is returned to the normal value.

更に、次のステップS9では、前記学習メモリに格納した、複数のスロットル開度毎の吸入空気量データに基づき、スロットル開度と吸入空気量との相関を更新設定する。
上記スロットル開度と吸入空気量との相関の更新においては、複数のスロットル開度それぞれに対応する吸入空気量のデータから、例えば最小二乗法等などを用いてスロットル開度と吸入空気量との相関を更新する(図4参照)。
In the next step S9, the correlation between the throttle opening and the intake air amount is updated based on the intake air amount data for each of the plurality of throttle openings stored in the learning memory.
In updating the correlation between the throttle opening and the intake air amount, from the intake air amount data corresponding to each of the plurality of throttle openings, the throttle opening and the intake air amount are calculated using, for example, the least square method. The correlation is updated (see FIG. 4).

そして、更新後の開度と吸入空気量との相関を用いて、要求吸入空気量に対応する開度を求め、前記電制スロットル7を制御する。
上記のように、本実施形態によると、通常のアイドル制御におけるスロットル開度よりも高開度(高空気量)側で、スロットル開度と吸入空気量との相関データを複数得て、これらの複数の相関データから、スロットル開度と吸入空気量との相関を更新させる(図4参照)。
Then, using the correlation between the updated opening degree and the intake air amount, an opening degree corresponding to the required intake air amount is obtained, and the electric throttle 7 is controlled.
As described above, according to the present embodiment, a plurality of pieces of correlation data between the throttle opening and the intake air amount are obtained on the higher opening (high air amount) side than the throttle opening in the normal idle control. The correlation between the throttle opening and the intake air amount is updated from a plurality of correlation data (see FIG. 4).

従って、通常のアイドル制御状態でのスロットル開度と吸入空気量との1点データのみからスロットル開度と吸入空気量との相関を更新させる場合に比べて、アイドル域の広い領域で離散的に求めた複数のデータから開度と吸入空気量との相関を精度良く更新させることができ、経時的な特性変化があっても、更新させた相関に基づいてスロットル開度を制御させることで、要求の吸入空気量に精度良く制御できるようになる。   Therefore, compared with the case where the correlation between the throttle opening and the intake air amount is updated from only one point data of the throttle opening and the intake air amount in the normal idle control state, it is discretely distributed in a wide idle region. The correlation between the opening and the intake air amount can be accurately updated from the obtained multiple data, and even if there is a change in characteristics over time, by controlling the throttle opening based on the updated correlation, The required intake air amount can be accurately controlled.

尚、通常の点火時期に対して進角補正し、該進角補正によるトルクアップ分を相殺するようにスロットル開度を減少変化させて、進角補正量毎にスロットル開度と吸入空気量との相関を学習させることが可能であり、また、通常の点火時期を中心に進角側と遅角側との双方に点火時期を変化させることも可能であり、更に、通常制御状態でのスロットル開度から、点火時期の変化方向及び範囲を決定することもできる。   In addition, the advance angle is corrected with respect to the normal ignition timing, and the throttle opening is decreased and changed so as to cancel out the torque increase due to the advance angle correction. It is also possible to learn the correlation between the ignition timing and the ignition timing on both the advance side and the retard side with the normal ignition timing as the center, and the throttle in the normal control state. The change direction and range of the ignition timing can also be determined from the opening.

実施形態における車両用内燃機関のシステム図。The system figure of the internal combustion engine for vehicles in an embodiment. 実施形態におけるスロットル開度と吸入空気量との相関の学習処理を示すフローチャート。The flowchart which shows the learning process of the correlation with the throttle opening and intake air amount in embodiment. 実施形態における学習時における点火時期・スロットル開度・吸入空気量の変化を示すタイムチャート。The time chart which shows the change of the ignition timing at the time of learning in embodiment, throttle opening, and intake air amount. 実施形態におけるスロットル開度と吸入空気量との相関の更新特性を示す線図。The diagram which shows the update characteristic of the correlation with the throttle opening and intake air amount in embodiment.

符号の説明Explanation of symbols

1…内燃機関,2…エアクリーナ,3…吸気ダクト,4…吸気コレクタ,5…吸気マニホールド,6…吸気バルブ,7…スロットルバルブ,8…スロットルモータ,9…燃料噴射弁,10…燃焼室,11…排気バルブ,12…排気マニホールド,13…排気ダクト,14…触媒コンバータ,21…エンジンコントロールユニット,22…エアフローメータ,23…空燃比センサ,24…回転速度センサ,25…アクセル開度センサ,26…スロットルセンサ DESCRIPTION OF SYMBOLS 1 ... Internal combustion engine, 2 ... Air cleaner, 3 ... Intake duct, 4 ... Intake collector, 5 ... Intake manifold, 6 ... Intake valve, 7 ... Throttle valve, 8 ... Throttle motor, 9 ... Fuel injection valve, 10 ... Combustion chamber, DESCRIPTION OF SYMBOLS 11 ... Exhaust valve, 12 ... Exhaust manifold, 13 ... Exhaust duct, 14 ... Catalytic converter, 21 ... Engine control unit, 22 ... Air flow meter, 23 ... Air-fuel ratio sensor, 24 ... Rotational speed sensor, 25 ... Accelerator opening sensor, 26 ... Throttle sensor

Claims (6)

内燃機関の吸気通路に介装される電制スロットルの開度と前記内燃機関の吸入空気量との相関を学習する電制スロットルの学習装置であって、
前記内燃機関のアイドル運転時に、前記内燃機関の点火時期を補正すると共に、該点火時期の補正によるトルク変化を相殺するように前記電制スロットルの開度を変化させ、該変化させた開度において前記開度と吸入空気量との相関を学習することを特徴とする電制スロットルの学習装置。
An electric throttle learning device for learning a correlation between an opening degree of an electric throttle installed in an intake passage of the internal combustion engine and an intake air amount of the internal combustion engine,
During the idling operation of the internal combustion engine, the ignition timing of the internal combustion engine is corrected, and the opening of the electric throttle is changed so as to cancel the torque change due to the correction of the ignition timing. A learning device for an electric throttle, which learns a correlation between the opening degree and an intake air amount.
前記点火時期を遅角補正すると共に、該点火時期の遅角補正によるトルク低下を補うように前記電制スロットルの開度を増大させ、該増大させた開度において前記開度と吸入空気量との相関を学習することを特徴とする請求項1記載の電制スロットルの学習装置。 The ignition timing is corrected to retard, and the opening of the electric throttle is increased so as to compensate for the torque reduction due to the ignition timing retardation correction. The learning apparatus for an electric throttle according to claim 1, wherein the correlation is learned. 前記点火時期の補正量を複数に変化させることを特徴とする請求項1又は2記載の電制スロットルの学習装置。 The learning device for the electric throttle according to claim 1 or 2, wherein the correction amount of the ignition timing is changed to a plurality. 前記点火時期の補正によって前記内燃機関に回転変動が発生したときに、前記点火時期の補正をキャンセルし、前記開度と吸入空気量との相関の学習を停止させることを特徴とする請求項1〜3のいずれか1つに記載の電制スロットルの学習装置。 2. The correction of the ignition timing is canceled and the learning of the correlation between the opening degree and the intake air amount is stopped when a rotation fluctuation occurs in the internal combustion engine due to the correction of the ignition timing. The learning device for an electric throttle according to any one of? 前記点火時期の補正量を漸増していき、前記補正量が所定の学習限界値に至るまで、前記開度と吸入空気量との相関の学習を継続させることを特徴とする請求項1〜4のいずれか1つに記載の電制スロットルの学習装置。 5. The correction amount of the ignition timing is gradually increased, and the learning of the correlation between the opening degree and the intake air amount is continued until the correction amount reaches a predetermined learning limit value. The electronic throttle learning device according to any one of the above. 前記内燃機関のアイドル回転速度を目標アイドル回転速度に一致させるべく前記電制スロットルの開度がフィードバック制御されるときに、点火時期を補正し、前記電制スロットルの開度と吸入空気量との相関を学習することを特徴とする請求項1〜5のいずれか1つに記載の電制スロットルの学習装置。 When the opening degree of the electric throttle is feedback controlled so that the idle speed of the internal combustion engine matches the target idle speed, the ignition timing is corrected, and the opening degree of the electric throttle and the intake air amount are corrected. 6. The learning device for an electric throttle according to claim 1, wherein correlation is learned.
JP2005286107A 2005-09-30 2005-09-30 Electric throttle learning device Expired - Fee Related JP4779543B2 (en)

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