JP3948294B2 - Fuel injection device - Google Patents

Description

但し、Ｋ１、Ｋ２は定数で、ＱＣＰＢはマルチ噴射の各々の噴射開始時の基本気筒内圧で、ＰＩＭは今回サイクルでのマルチ噴射の各々の燃料噴射直前の吸気圧で、ＱＣＰは、エンジン１のＴＤＣ付近の気筒内圧による燃料噴射量と噴射期間特性に対する、マルチ噴射の各々の燃料噴射開始時の気筒内圧による燃料噴射量と噴射期間特性の変化分を考慮した噴射量補正量である。
【００３９】
次に、マルチ噴射の各々の燃料噴射直前のコモンレール圧（ＰＣ）より、マルチ噴射の各々の燃料噴射のコモンレール圧補正係数（ＰＣＣ）をマップ補間して算出する（補正係数算出手段：ステップＳ６）。すなわち、マルチ噴射の各々の燃料噴射直前のコモンレール圧（ＰＣ）とコモンレール圧補正係数（ＰＣＣ）との関係を予め実験等により求めて作成した特性マップ（図５参照）を用いて、マルチ噴射の各々の燃料噴射のコモンレール圧補正係数（ＰＣＣ）を算出する。これは、エンジン１のＴＤＣ付近のコモンレール圧（ＰＣ）による噴射量と噴射期間特性との関係に対する、マルチ噴射の各々の燃料噴射直前のコモンレール圧（ＰＣ）による噴射量と噴射期間特性の変化分を考慮した燃料圧補正係数である。具体的には、特性マップを用いてパイロット噴射のコモンレール圧補正係数（ＰＣＣｐｉｌｏｔ）、プレ噴射量のコモンレール圧補正係数（ＰＣＣｐｒｅ）およびメイン噴射のコモンレール圧補正係数（ＰＣＣｍａｉｎ）を算出する。
【００４０】
次に、ステップＳ５で算出したマルチ噴射の各々の燃料噴射の噴射量補正量（ＱＣＰ）とステップＳ６で算出したマルチ噴射の各々の燃料噴射のコモンレール圧補正係数（ＰＣＣ）より下記の数２の計算式を用いて、マルチ噴射の各々の燃料噴射の気筒内圧補正噴射量（ＱＣＰＱ）を算出する（補正量算出手段：ステップＳ７）。具体的には、下記の数２の計算式を用いて、エンジン１の気筒内圧の変化およびコモンレール圧の変化による燃料噴射量に対する噴射期間特性の変化分に対応したパイロット噴射の気筒内圧補正噴射量（ＱＣＰＱｐｉｌｏｔ）、プレ噴射の気筒内圧補正噴射量（ＱＣＰＱｐｒｅ）およびメイン噴射の気筒内圧補正噴射量（ＱＣＰＱｍａｉｎ）を算出する。
【数２】

但し、ＱＣＰはマルチ噴射の各々の燃料噴射の噴射量補正量で、ＰＣＣはマルチ噴射の各々の燃料噴射のコモンレール圧補正係数で、ＱＣＰＱはマルチ噴射の各々の燃料噴射の気筒内圧補正噴射量である。
【００４１】
次に、マルチ噴射の各々の燃料噴射量（Ｑ）とマルチ噴射の各々の燃料噴射の気筒内圧補正噴射量（ＱＣＰＱ）とマルチ噴射の各々の燃料噴射直前のコモンレール圧（ＰＣ）より、マルチ噴射の各々の燃料噴射の最終噴射期間（ＴＱＦ）をマップ補間して算出する（ステップＳ８）。その後に、図３のルーチンを抜ける。すなわち、マルチ噴射の各々の燃料噴射量（Ｑ）とコモンレール圧（ＰＣ）とマルチ噴射の各々の燃料噴射の最終噴射期間（ＴＱＦ）との関係を予め実験等により求めて作成した特性マップ（図示せず）を用いて、マルチ噴射の各々の燃料噴射の最終噴射期間（ＴＱＦ）を算出する。具体的には、特性マップを用いて、パイロット噴射の最終噴射期間（ＴＱＦｐｉｌｏｔ）、プレ噴射の最終噴射期間（ＴＱＦｐｒｅ）およびメイン噴射の最終噴射期間（ＴＱＦｍａｉｎ）を算出する。
【００４２】
なお、上記の図３のルーチンでは、メイン噴射開始時の基本気筒内圧（ＱＣＰＢ）とプレ噴射用およびメイン噴射用のコモンレール圧補正係数（ＰＣＣ）とをマップ補間して算出しているが、計算式でも求めることができる。また、コモンレール式燃料噴射システム用にコモンレール圧補正係数（ＰＣＣ）を使用して補正を実施しているが、分配型燃料噴射ポンプ等を備えたコモンレールを有しない燃料装置においても、コモンレール圧の補正を無しにして使用することができる。
【００４３】
［実施例の特徴］
次に、本実施例のインジェクタ５の駆動方法を図１ないし図５に基づいて簡単に説明する。ここで、図２（ａ）はエンジン１の特定気筒のインジェクタ５の無噴射状態を示した図である。
【００４４】
エンジン１の特定気筒のインジェクタ５の電磁弁１２に印加する噴射指令パルスは、パイロット噴射→プレ噴射→メイン噴射の順にエンジン１の１燃焼行程中に出力される。このエンジン１の１燃焼行程中のマルチ噴射の各噴射間隔およびエンジン１の１燃焼行程中の噴射回数は、本実施例の２回だけでなく、エンジン１の運転条件および指令噴射量によって任意に決定される。
【００４５】
エンジン１の特定気筒のインジェクタ５からエンジン１への燃料噴射は、図２（ｂ）に示したように、インジェクタ駆動回路の常開型スイッチ２３が閉じられて、特定気筒のインジェクタ５の電磁弁１２のソレノイドコイル２４に噴射指令パルスが印加されると、電磁弁１２の弁体２５が開弁する。この電磁弁１２が開弁している間は、背圧制御室１９内の燃料がオリフィス２１を介してリーク配管３６にリークされるので、図示しないスプリングの付勢力に打ち勝ってノズルニードル１３がノズル本体１５を構成するノズルボデーの弁座よりリフト（離間）する。これにより、噴射孔１６と燃料溜まり１７とが連通するため、コモンレール４に蓄圧された高圧燃料がエンジン１の特定気筒の燃焼室内に噴射供給される。
【００４６】
その後に、噴射パルス開始時期から噴射期間が経過して噴射パルス終了時期になると、つまりインジェクタ駆動回路の常開型スイッチ２３が開かれると、図２（ｃ）に示したように、電磁弁１２の弁体２５が閉弁する。この電磁弁１２が閉弁している間は、燃料通路（高圧通路）１８からオリフィス２０を介して背圧制御室１９内に高圧燃料が充満するため、リターンスプリングの付勢力によってノズルニードル１３がノズルボデーの弁座に着座する。これにより、噴射孔１６と燃料溜まり１７との連通状態が遮断されるため、エンジン１の特定気筒の燃焼室内への燃料噴射が終了する。
【００４７】
ここで、エンジン１のＴＤＣ付近で実施されるメイン噴射よりも前に実施されるパイロット噴射およびプレ噴射は、インジェクタ５の電磁弁１２のソレノイドコイル２４への噴射指令パルスの通電開始時刻から所定の噴射開始遅れ時間が経過してからノズルニードル１３が開弁し、噴射指令パルスの通電終了時刻から所定の噴射終了遅れ時間が経過してからノズルニードル１３が閉弁するはずが、燃料噴射量と噴射期間特性を適合させた時のＴＤＣ付近の気筒内圧およびコモンレール圧に対して、エンジン１の気筒内圧やコモンレール圧が変化することにより、ノズルニードル１３の開弁時期または閉弁時期が本来の開弁時期または閉弁時期よりも早くなったり、遅くなったりする場合がある。これにより、ノズルニードル１３の閉弁時期または開弁時期が予め設定された閉弁時期または開弁時期であると、当然のごとく実際噴射される燃料噴射量が、計算で出されたパイロット噴射量（Ｑｐｉｌｏｔ）およびプレ噴射量（Ｑｐｒｅ）よりも増えたり、あるいは減ったりしてしまい、正しい値の燃料を噴射できないという問題が生じる。
【００４８】
そこで、本実施例のコモンレール式燃料噴射システムにおいては、マルチ噴射の各々の燃料噴射量（Ｑ）に対する噴射期間特性を適合した時のエンジン１のＴＤＣ付近の気筒内圧およびコモンレール圧と実際噴射される時の気筒内圧およびコモンレール圧とが異なり、マルチ噴射の各々の燃料噴射量（Ｑ）に対する噴射期間特性が変化するという点に着目し、上記の図３のルーチンに示したように、マルチ噴射の各々の燃料噴射の基本噴射期間（ＴＱ）およびインジェクタ噴射開始角度（ＱＣＡ）を計算し、インジェクタ噴射開始角度（ＱＣＡ）よりマルチ噴射の各々の燃料噴射開始時の基本気筒内圧（ＱＣＰＢ）を計算し、マルチ噴射の各々の燃料噴射量（Ｑ）と噴射期間特性に適合させた時のエンジン１のＴＤＣ付近の気筒内圧に対する、マルチ噴射の各々の燃料噴射開始時の気筒内圧変化量を計算するようにしている。
【００４９】
そして、マルチ噴射の各々の噴射開始時の基本気筒内圧（ＱＣＰＢ）と吸気圧（ＰＩＭ）より、エンジン１の気筒内圧の変化による燃料噴射量に対する噴射期間特性の変化分に対応した噴射量補正量（ＱＣＰ）を計算し、エンジン１の気筒内圧の変化およびコモンレール圧の変化による燃料噴射量に対する噴射期間特性の変化分に対応したマルチ噴射の各々の燃料噴射の気筒内圧補正噴射量（ＱＣＰＱ）を計算し、マルチ噴射の各々の燃料噴射量（Ｑ）とマルチ噴射の各々の燃料噴射の気筒内圧補正噴射量（ＱＣＰＱ）とマルチ噴射の各々の燃料噴射直前のコモンレール圧（ＰＣ）より、マルチ噴射の各々の燃料噴射の最終噴射期間（ＴＱＦ）をマップ補間して計算している。
【００５０】
したがって、実際噴射される時の気筒内圧の変化量を計算で出して気筒内圧の変化およびコモンレール圧の変化による燃料噴射量に対する噴射期間特性の変化分を最適な噴射期間特性となるように補正することにより、エンジン１のＴＤＣ前後の広い範囲で燃料噴射するマルチ噴射のパイロット噴射、プレ噴射およびメイン噴射時においても、エンジン１の運転条件に応じて設定されたマルチ噴射の各々の燃料噴射量（パイロット噴射量、プレ噴射量、メイン噴射量）を正しく噴射することができる。
【００５１】
また、本実施例のコモンレール式燃料噴射システムでは、エンジン１の各気筒の１燃焼行程中に燃料を３回に分けて噴射する制御、つまりパイロット噴射、プレ噴射およびメイン噴射よりなるマルチ噴射を行なうことにより、初期噴射率の急激な上昇を抑えることができるので、エンジン１の騒音やエンジン振動を抑制することができ、プレ噴射の前にパイロット噴射を行なうことによってエンジン１の騒音やエンジン振動を更に抑制することができる。
【００５２】
また、エンジン１の各気筒の１燃焼行程中に燃料を３回に分けて噴射する制御、つまりプレ噴射、メイン噴射およびアフター噴射よりなるマルチ噴射を行なう場合には、メイン噴射の後にアフター噴射を行なうことによってメイン噴射での未燃ガスを燃やすことができるので、スモークの排出を抑え排気ガス性能の向上を図ることができる。また、エンジン１の各気筒の１燃焼行程中に燃料を５回に分けて噴射する制御、つまりパイロット噴射、プレ噴射、メイン噴射、アフター噴射およびポスト噴射よりなるマルチ噴射を行なう場合には、アフター噴射の後にポスト噴射を行なうことによって触媒の活性化を図ることができる。
【００５３】
［変形例］
本実施例では、本発明の燃料噴射装置の一例として、コモンレール式燃料噴射システムに適用した例を説明したが、コモンレール等の蓄圧配管を持たず、燃料供給ポンプから高圧配管を経て直接インジェクタに高圧燃料を供給するタイプの燃料噴射装置に適用しても良い。また、本実施例では、エンジン１の各気筒の燃焼室内に燃料を噴射供給するインジェクタの一例として、２方弁式電磁弁付きのインジェクタ５を使用した例を説明したが、３方弁式電磁弁付きのインジェクタやその他のタイプのインジェクタを使用しても良い。
【００５４】
本実施例では、コモンレール圧センサ４５をコモンレール４に直接取り付けて、コモンレール４内に蓄圧される燃料圧（コモンレール圧）を検出するようにしているが、燃料圧力検出手段をサプライポンプ３のプランジャ室（加圧室）からインジェクタ５内の燃料通路までの間の燃料配管等に取り付けて、サプライポンプ３の加圧室より吐出された燃料圧を検出するようにしても良い。
【００５５】
本実施例では、サプライポンプ３のプランジャ室（加圧室）内に吸入される燃料の吸入量を変更（調整）する吸入調量弁７を設けた例を説明したが、サプライポンプ３のプランジャ室（加圧室）からコモンレール４への燃料の吐出量を変更（調整）する吐出調量弁を設けても良い。なお、吸入調量弁７または吐出調量弁の弁開度がその電磁弁への通電を停止した時に全開となるノーマリオープンタイプの電磁弁を用いても良いが、吸入調量弁７または吐出調量弁の弁開度がその電磁弁を通電した時に全開となるノーマリクローズタイプの電磁弁を用いても良い。
【００５６】
本実施例では、本発明の燃料噴射装置の一例として、エンジン１の特定気筒のインジェクタ５においてエンジン１の１燃焼行程中に３回のマルチ噴射（例えばパイロット噴射・プレ噴射・メイン噴射）を行うことが可能なコモンレール式燃料噴射システムを適用した例を説明したが、２回のマルチ噴射（例えばパイロット噴射・メイン噴射）、あるいは３回のマルチ噴射（例えばパイロット噴射・メイン噴射・アフター噴射）を行うことが可能なコモンレール式燃料噴射システムに適用しても良く、あるいは、４回のマルチ噴射（例えばパイロット噴射・プレ噴射・メイン噴射・アフター噴射またはパイロット噴射・メイン噴射・アフター噴射・ポスト噴射）を行うことが可能なコモンレール式燃料噴射システムに適用しても良い。
【００５７】
また、５回のマルチ噴射（例えばパイロット噴射・プレ噴射・メイン噴射・アフター噴射・ポスト噴射）を行うことが可能なコモンレール式燃料噴射システムに適用しても良く、また、６回以上のマルチ噴射を行うことが可能なコモンレール式燃料噴射システムに適用しても良い。このエンジン１の１燃焼行程中の６回以上のマルチ噴射の各噴射間隔およびエンジン１の１燃焼行程中の噴射回数は、エンジン１の運転条件および指令噴射量によって任意に決定される。
【図面の簡単な説明】
【図１】コモンレール式燃料噴射システムの全体構造を示した概略図である（実施例）。
【図２】（ａ）〜（ｃ）はインジェクタの作動状態を示した説明図である（実施例）。
【図３】インジェクタのパイロット噴射、プレ噴射およびメイン噴射の噴射期間補正方法の概略を示したフローチャートである（実施例）。
【図４】噴射開始角度と基本気筒内圧との関係を示した特性図である（実施例）。
【図５】コモンレール圧とコモンレール圧補正係数との関係を示した特性図である（実施例）。
【符号の説明】
１ エンジン
３ サプライポンプ（燃料供給ポンプ）
４ コモンレール
５ インジェクタ（電磁式燃料噴射弁）
７ 吸入調量弁
１０ ＥＣＵ（噴射量制御手段）
４１ 気筒判別センサ（気筒判別手段、運転条件検出手段）
４２ クランク角センサ（回転速度検出手段、運転条件検出手段）
４３ アクセル開度センサ（運転条件検出手段）
４４ 吸気圧センサ（吸気圧検出手段）
４５ コモンレール圧センサ（燃料圧検出手段）[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a fuel injection device that injects high-pressure fuel into each cylinder of an internal combustion engine via a fuel injection valve mounted on each cylinder of the internal combustion engine such as a diesel engine, and is particularly accumulated in a common rail. The present invention relates to a common rail fuel injection system that supplies high pressure fuel to each cylinder of an internal combustion engine via an electromagnetic fuel injection valve mounted on each cylinder of the internal combustion engine.
[0002]
[Prior art]
Conventionally, a supply pump pressurizes and accumulates high-pressure fuel in a common rail, and the high-pressure fuel accumulated in the common rail is installed in each cylinder of an internal combustion engine (hereinafter referred to as an engine) such as a diesel engine. 2. Description of the Related Art A common rail fuel injection system that distributes and supplies to an electromagnetic fuel injection valve (injector) and supplies high pressure fuel from each injector to each cylinder of an engine at a predetermined injection timing is known. In such a common rail fuel injection system, when injecting fuel, a characteristic map created by previously obtaining a relationship between the fuel injection amount set according to the operating condition of the engine and the injection period characteristic through experiments or the like. The injection amount control of the injector is executed by calculating and outputting an injection command pulse to the injector.
[0003]
Here, the characteristic map for calculating the fuel injection amount and the injection period characteristic is a map in which fuel is injected in the vicinity of the TDC of the engine, and the injection period characteristic with respect to the fuel injection amount is measured in advance and adapted. Although the injection period characteristic is affected by the cylinder internal pressure and the common rail pressure for injecting fuel, the range used in the conventional single injection is near the TDC of the engine that matches the injection period characteristic with respect to the fuel injection amount. The effect of cylinder pressure was negligible.
[0004]
[Problems to be solved by the invention]
However, in order to achieve the exhaust gas regulation value of a vehicle equipped with a diesel engine in recent years, an injection rate control for injecting fuel into a plurality of times during one combustion stroke of the engine called multi-injection has been developed. When performing such multi-injection, the fuel is injected in a plurality of times over a wide range before and after the TDC of the engine, so the cylinder internal pressure near the TDC of the engine and the actual fuel when the fuel injection amount and the injection period characteristics are adapted The cylinder internal pressure at the start of injection is different. Note that the cylinder internal pressure of the engine generally has a low value before and after the engine TDC with the vicinity of the engine TDC at the top. Thereby, the fuel injection amount and the injection period characteristic change in response to the change in the cylinder internal pressure, and the actual fuel injection amount varies with respect to each fuel injection amount of the multi-injection set according to the operating condition of the engine. There is a problem that the correct value of fuel cannot be injected.
[0005]
OBJECT OF THE INVENTION
In the present invention, the cylinder internal pressure near the top dead center of the engine when the fuel injection amount and the injection period characteristic of each of the multi-injections are adapted differs from the cylinder internal pressure at the start of each fuel injection of the multi-injection. Paying attention to the fact that each fuel injection amount and injection period characteristics change, calculate the cylinder internal pressure at the start of each fuel injection of multi-injection, and change the fuel injection amount and injection period characteristics due to the amount of change in cylinder internal pressure. It is an object to correct each of the fuel injection amounts so that the fuel injection amounts of the multi-injections set in accordance with the engine operating conditions can be correctly injected.
[0006]
[Means for Solving the Problems]
According to the first aspect of the present invention, the fuel injection is made near the top dead center of the engine, and the fuel injection amount and the fuel injection period characteristics of each of the fuel injection are measured and adapted to the multi-injection. The basic injection period of each fuel injection is calculated. Then, the injection start angle at the start of each fuel injection of the multi-injection is calculated from the injection timing set according to the engine operating conditions and the basic injection period. Then, the cylinder internal pressure at the start of each fuel injection of the multi-injection is calculated from a map or a calculation formula obtained by measuring and fitting the injection start angle and the cylinder internal pressure characteristics at the start of each fuel injection of the multi-injection.
[0007]
And according to the change amount of the cylinder internal pressure at the start of each fuel injection of the multi-injection with respect to the cylinder internal pressure near the top dead center of the engine when the fuel injection amount and the injection period characteristic of each of the multi-injection are adapted, By correcting the fuel injection amount of each of the multi-injections and the basic injection period of each of the fuels of the multi-injection, each fuel injection of the multi-injection that performs fuel injection in a wide range before and after the top dead center of the engine It becomes possible to correctly inject each fuel injection amount of the multi-injection set according to the operating conditions. The injection period determining means may calculate the basic injection period of each fuel injection in the multi-injection in consideration of the fuel pressure detected by the fuel pressure detecting means.
[0008]
further, Claim 1 According to the invention described in the above, each of the multi-injection fuel injection amounts and injections are calculated by adding the intake pressure detected by the intake pressure detecting means to the calculated value of the cylinder internal pressure at the start of each fuel injection of the multi-injection. By calculating the injection amount correction amount considering the change in the cylinder pressure at the start of each fuel injection of multi-injection from the cylinder pressure near the top dead center of the engine when the period characteristics are adapted, When performing multi-injection fuel injection over a wide range before and after the dead center, the difference between the command injection amount set according to the engine operating conditions and the total injection amount obtained by adding each fuel injection amount of the multi-injection Can be suppressed.
[0009]
Claim 2 The fuel pressure correction coefficient is calculated from the fuel pressure immediately before each fuel injection in the multi-injection. And claims 1 A value obtained by multiplying the injection amount correction amount described in (1) by the calculated fuel pressure correction coefficient is used as the cylinder pressure correction injection amount of each fuel injection of the multi-injection. As a result, the claim 1 The effect of the invention described in (1) can be further improved.
[0010]
Claim 3 According to the invention described in claim 1, the fuel injection amount of each of the multi-injections set by the injection amount control means described in claim 1 is claimed. 2 The final corrected injection amount of each fuel injection of the multi-injection is calculated in consideration of the cylinder internal pressure correction injection amount described in claim 2. 1 The effect of the invention described in (1) can be further improved. Claims 4 In the basic injection period of each fuel injection of the multi-injection set by the injection period determining means according to claim 1, the fuel pressure immediately before each fuel injection of the multi-injection and 2 The final injection period of each fuel injection of the multi-injection is calculated in consideration of the cylinder internal pressure correction injection amount described in claim 2. 1 The effect of the invention described in (1) can be further improved.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
[Configuration of Example]
DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the invention will be described based on examples with reference to the drawings. Here, FIG. 1 is a diagram showing the overall structure of a common rail fuel injection system, and FIG. 2 is a diagram showing an injector with a two-way valve type solenoid valve.
[0012]
The common rail fuel injection system of the present embodiment is a supply pump 3 that is rotationally driven by an internal combustion engine (hereinafter referred to as an engine) 1 such as a four-cylinder diesel engine, and a pressure accumulation container that accumulates high-pressure fuel corresponding to the fuel injection pressure. Common rail 4 and a plurality of (four in this example) injectors with two-way solenoid valves (hereinafter abbreviated as injectors) that inject and supply high pressure fuel accumulated in the common rail 4 into the combustion chamber of each cylinder of the engine 1. ) 5 and an electronic control unit (hereinafter referred to as ECU) 10 for electronically controlling the supply pump 3 and the plurality of injectors 5.
[0013]
The supply pump 3 includes a well-known feed pump (low pressure supply pump) that pumps up fuel in the fuel tank 6 by rotating a pump drive shaft 32 as the crankshaft (crankshaft) 31 of the engine 1 rotates. A pump chamber into which the fuel sucked out by the pump flows, a plunger (not shown) driven by the pump drive shaft 32, and a pressurizing chamber (plunger chamber) for pressurizing the fuel flowing in from the pump chamber by the reciprocating motion of the plunger. ). The supply pump 3 is a high-pressure supply pump (fuel supply pump) that pressurizes fuel and discharges high-pressure fuel from the discharge port to the common rail 4. An intake metering valve 7 as an electromagnetic actuator for opening and closing the fuel flow path is attached to the fuel flow path from the pump chamber to the pressurizing chamber of the supply pump 3.
[0014]
The intake metering valve 7 is electronically controlled by a pump drive signal from the ECU 10 through a pump drive circuit (not shown), thereby adjusting the intake amount of the fuel sucked into the pressurized chamber of the supply pump 3. The fuel injection pressure supplied from each injector 5 to the engine 1, that is, the common rail pressure is changed by the electromagnetic valve. The suction metering valve 7 is a normally open type pump flow control valve whose valve state is fully opened when energization is stopped.
[0015]
The common rail 4 needs to continuously accumulate a high pressure corresponding to the fuel injection pressure (common rail pressure), and is connected to the discharge port of the supply pump 3 that discharges high-pressure fuel through the fuel pipe 33 for this purpose. ing. Note that a pressure limiter 34 is opened between the fuel pipe 33 or the common rail 4 that forms the high-pressure fuel passage inside and the relief pipe 35 that forms the fuel return passage inside and opens when the common rail pressure exceeds the limit set pressure. Is provided to prevent the common rail pressure from becoming higher than the limit set pressure. Further, the leaked fuel from the supply pump 3 is returned to the fuel tank 6 through a leak pipe 36 that forms a fuel return path (leak fuel path) inside.
[0016]
The injector 5 mounted for each cylinder of the engine 1 is connected to the downstream end of a plurality of branch pipes (high pressure fuel flow paths) 39 branched from the common rail 4, and injects high pressure fuel into the combustion chamber of each cylinder of the engine 1. A fuel injection nozzle 11 to be supplied and a two-way valve type electromagnetic valve (hereinafter abbreviated as an electromagnetic valve) 12 as an electromagnetic actuator for driving the fuel injection nozzle 11 are configured. The fuel injection nozzle 11 includes a nozzle needle 13 that opens and closes a plurality of injection holes 16, a return spring (not shown) that urges the nozzle needle 13 in the valve closing direction, and a command piston that operates in conjunction with the nozzle needle 13. 14 and a nozzle body 15 for accommodating them.
[0017]
Here, 17 is a fuel reservoir to which high-pressure fuel is always supplied, 18 is a fuel passage (high-pressure passage) for supplying high-pressure fuel to the fuel reservoir 17 and the back pressure control chamber 19, and 20 and 21 are flow rates of fuel passing therethrough. It is an orifice (fixed restriction) for adjusting the pressure. The solenoid valve 12 is attracted upward in the figure by a solenoid coil 24 electrically connected via a normally open switch 23 built in an in-vehicle power source 22 and an injector drive circuit (EDU), and a magnetomotive force of the solenoid coil 24. And a return spring 26 that urges the valve body 25 in the valve closing direction. The leaked fuel leaking from the injector 5 to the fuel tank 6 is discharged from the fuel outlet 28 through the sliding portions in the injector 5 and the flow path 27 around the solenoid coil 24 from the back pressure control chamber 19. Then, it is configured to return to the fuel tank 6 through a leak pipe 37 that forms a fuel return path (leak fuel path) inside (see FIGS. 1 and 2).
[0018]
The fuel injection from the injector 5 of each cylinder to the engine 1 is electronically controlled by an electromagnetic valve control signal to an injector drive circuit (EDU) that drives the electromagnetic valve 12. While the injector drive current is applied from the injector drive circuit (EDU) to the solenoid coil 24 of the solenoid valve 12 of the injector 5 for each cylinder and the solenoid valve 12 is opened, the nozzle needle 13 is lifted from the valve seat. By separating (separating), the injection hole 16 and the fuel reservoir 17 communicate with each other. As a result, the high-pressure fuel accumulated in the common rail 4 is injected and supplied into the combustion chamber of each cylinder of the engine 1.
[0019]
The ECU 10 includes functions such as a CPU for performing control processing and arithmetic processing, a storage device (memory such as ROM and RAM) for storing various programs and data, an input circuit, an output circuit, a power supply circuit, an injector drive circuit, and a pump drive circuit. There is provided a microcomputer having a well-known structure including the above. And the sensor signal from various sensors is comprised so that it may input into a microcomputer, after A / D-converting with an A / D converter.
[0020]
Here, the cylinder discriminating means of this embodiment includes a signal rotor that rotates corresponding to the camshaft of the engine 1 (for example, a rotating body that rotates once while the crankshaft 31 rotates twice), and an outer periphery of the signal rotor. The cylinder teeth (projections) corresponding to the respective cylinders provided, and a cylinder discrimination sensor (electromagnetic pickup) 41 that generates a cylinder discrimination signal pulse by the approach and separation of these cylinder teeth. The cylinder discriminating sensor 41 outputs a wide reference cylinder discriminating signal pulse (G) when the piston of the # 1 cylinder reaches the position immediately before injection as the crankshaft 31 of the engine 1 rotates, and then When the # 3 cylinder piston reaches the position just before injection, a narrow cylinder discrimination signal pulse (G) is output, and after that, when the # 4 cylinder piston reaches the position just before injection, the narrow cylinder discrimination signal is output. A signal pulse (G) is output, and then a narrow cylinder discrimination signal pulse (G) is output when the piston of the # 2 cylinder reaches the position immediately before injection.
[0021]
Further, the rotation speed detecting means of the present embodiment includes a signal rotor that rotates corresponding to the crankshaft 31 of the engine 1 (for example, a rotating body that rotates once while the crankshaft 31 rotates once), and an outer periphery of the signal rotor. And a crank angle sensor (electromagnetic pickup) 42 that generates NE signal pulses by the approach and separation of these teeth. The crank angle sensor 42 outputs a plurality of NE signal pulses while the signal rotor makes one revolution (the crankshaft 31 makes one revolution). Then, the ECU 10 detects the engine speed (hereinafter referred to as engine speed: NE) by measuring the interval time of the NE signal pulse.
[0022]
The ECU 10 has a discharge amount control means (SCV control means) that calculates the optimum common rail pressure according to the operating conditions of the engine 1 and drives the suction metering valve 7 of the supply pump 3 via the pump drive circuit. is doing. That is, the ECU 10 determines the target common rail pressure from the engine operation information such as the engine speed (NE) detected by the rotation speed detecting means such as the crank angle sensor 42 and the accelerator opening (ACCP) detected by the accelerator opening sensor 43. In order to calculate (Pt) and achieve this target common rail pressure (Pt), the pump drive signal (drive current value, SCV energization value) to the intake metering valve 7 is adjusted and discharged from the supply pump 3. It is configured to control the fuel pumping amount (pump discharge amount).
[0023]
More preferably, for the purpose of improving the control accuracy of the fuel injection amount, the common rail pressure (PC) detected by the common rail pressure sensor 45 is substantially matched with the target common rail pressure (Pt) determined by the engine operation information. In addition, it is desirable to feedback control the pump drive signal to the suction metering valve 7 of the supply pump 3. The control of the drive current value (SCV energization value) to the intake metering valve 7 is preferably performed by duty control. That is, the duty for changing the valve opening degree of the intake metering valve 7 by adjusting the ON / OFF ratio (energization time ratio / duty ratio) of the pump drive signal per unit time according to the target common rail pressure (Pt). By using the control, high-precision digital control becomes possible.
[0024]
Further, the ECU 10 has an injection amount control means for controlling the injection amount of the injector 5 of each cylinder. This is because the injection amount determining means for determining the optimum command injection amount according to the operating conditions of the engine 1 and the injection timing according to the operating conditions of the engine 1 and the command injection amount (= the injection start timing of the main injection, the injection timing) Injection timing determining means for determining the injection period and the injector energization from the start of energization to the solenoid coil 24 of the solenoid valve 12 of the injector 5 to the common rail pressure (PC) and the command injection amount (= Injection period determining means for calculating a period, an injection command pulse time, and an injection command pulse width), and a pulsed injector drive current (hereinafter referred to as injection) to the solenoid coil 24 of the solenoid valve 12 of the injector 5 of each cylinder via an injector drive circuit. And injector drive means for applying a command pulse).
[0025]
That is, the ECU 10 includes the engine coolant temperature in the engine operation information such as the engine speed (NE) detected by the rotation speed detecting means such as the crank angle sensor 42 and the accelerator opening (ACCP) detected by the accelerator opening sensor 43. The command injection amount is calculated in consideration of the fuel temperature and the fuel temperature, and an injection command pulse is applied to the solenoid coil 24 of the solenoid valve 12 of the injector 5 of each cylinder according to the injection period calculated from the common rail pressure (PC) and the command injection amount. It is comprised so that it may apply. As a result, the engine 1 is operated.
[0026]
Here, in this embodiment, as the operating condition detecting means for detecting the operating condition of the engine 1, the rotational speed detecting means such as the crank angle sensor 42 and the accelerator opening sensor 43 are used to command the injection amount, the injection timing, and the injection period. The target common rail pressure is calculated, but the common rail pressure (PC) detected by the common rail pressure sensor 45 or other sensors (for example, an intake pressure sensor 44, an intake air amount sensor, The command injection amount, injection timing, injection period, and target common rail pressure may be corrected in consideration of detection signals (engine operation information) from the intake air temperature sensor, cooling water temperature sensor, fuel temperature sensor, injection timing sensor, etc. good. The intake pressure sensor 44 is an intake pressure detection means for detecting the pressure of intake air (intake pressure: PIM) sucked into the cylinder of the engine 1 and is attached to the intake manifold of the engine 1.
[0027]
Here, in the common rail fuel injection system of the present embodiment, in the injector 5 of a specific cylinder of the engine 1, during one cycle of the engine 1 (one stroke: intake stroke-compression stroke-combustion stroke-exhaust stroke), that is, the engine 1 The multi-injection (for example, multi-stage injection including pilot injection, pre-injection, and main injection) is performed twice or more during one combustion stroke of each cylinder of the engine 1 while the crankshaft 31 of the engine rotates twice (720 ° CA). It is possible.
[0028]
Therefore, the ECU 10 determines each fuel injection amount (Q) of the multi-injection, that is, the pilot injection amount (Qpilot), the pre-injection amount (Qpre), and the main injection from the operating conditions (operation information) of the engine 1 and the command injection amount. Injection amount determining means for calculating an amount (Qmain), interval determining means for calculating an interval between pilot injection and pre-injection, and an interval between pre-injection and main injection, pilot injection amount (Qpilot) and Pilot injection period determination means for calculating the pilot basic injection period (TQpilot) from the common rail pressure (PC), and pre-injection period determination for calculating the pre basic injection period (TQpre) from the pre-injection amount (Qpre) and the common rail pressure (PC) Means, main injection amount (Qmain) and common rate Pressure and a main injection period determining means for calculating a main basic injection period (TQmain) from (PC).
[0029]
[Control method of embodiment]
Next, an injection period correction method for each fuel injection of the multi-injection of the injector 5 according to the present embodiment will be briefly described with reference to FIGS. Here, FIG. 3 is a flowchart showing an outline of an injection period correction method for pilot injection, pre-injection, and main injection of the injector.
[0030]
The routine of FIG. 3 is repeated at predetermined timings after an ignition switch (not shown) is turned on. For example, the injection amount control of the k-cylinder injector 5 may be started immediately after the end of the injection of the k-cylinder injector 5 in the previous cycle, or the immediately preceding injection cylinder (k cylinder is # 1 in the current cycle). # 2 cylinder for cylinder, # 1 cylinder for k cylinder # 3, # 3 cylinder for k cylinder # 4, # 4 cylinder for k cylinder # 2) You may start immediately. Alternatively, the correction of the pilot injection period of the k cylinder may be performed immediately before the pilot injection of the k cylinder in this cycle, or the correction of the pre injection period of the k cylinder may be performed immediately before the pre injection. In addition, the correction of the main injection period of the k cylinder may be performed immediately before the main injection.
[0031]
First, engine parameters such as a cylinder discrimination signal pulse and an NE signal pulse are read. In particular, the engine speed (NE), the accelerator opening (ACCP), and the like necessary for calculating the command injection amount and the injection timing are read. Next, the cylinder for which the injection amount control is to be performed is discriminated (k cylinder?) From the cylinder discrimination signal pulse and the NE signal pulse. Subsequently, the injection amount, the injection timing command value, and the like are calculated in the same manner as in the conventional control (step S1).
[0032]
That is, the command injection amount is calculated from the engine speed (NE) and the accelerator opening (ACCP). Next, the injection timing (main injection timing: T), the number of injections, and the injection interval (interval) are calculated from the engine speed (NE) and the command injection amount. Next, each fuel injection amount (Q) of the multi-injection is calculated. Specifically, the pilot injection amount (Qpilot) is calculated using a characteristic map or a calculation formula created by previously obtaining a relationship between the command injection amount, the engine speed (NE), and the pilot injection amount (Qpilot) through experiments or the like. Calculate (pilot injection amount determining means).
[0033]
Further, the pre-injection amount (Qpre) is calculated using a characteristic map or a calculation formula created by previously obtaining a relationship between the command injection amount, the engine speed (NE), and the pre-injection amount (Qpre) through experiments or the like ( Pre-injection amount determining means). Further, the main injection amount (Qmain) is calculated by subtracting the pilot injection amount (Qpilot) and the pre-injection amount (Qpre) from the command injection amount (main injection amount determining means).
[0034]
Further, a characteristic map or a calculation formula created by previously obtaining an injection interval (pilot interval) between pilot injection and pre-injection, a relationship between a command injection amount, an engine speed (NE), and a pilot interval (TINTpilot) by an experiment or the like in advance. (Pilot interval determining means). In addition, a characteristic map or calculation formula created by previously determining the injection interval (pre-interval) between the pre-injection and the main injection, the relationship between the command injection amount, the engine speed (NE), and the pre-interval (TINTpre) by experiments or the like. (Pre-interval determining means).
[0035]
Next, the basic injection period (TQ) of each fuel injection of the multi-injection is calculated by map interpolation from each fuel injection amount (Q) of the multi-injection and the common rail pressure (PC) taken in at the previous cycle (injection). Period determining means: Step S2). Specifically, using a characteristic map that is created by experimentally determining the relationship between the common rail pressure (PC) detected by the common rail pressure sensor 45, the fuel injection amount (Q), and the basic injection period (TQ), A pilot basic injection period (TQpilot), a pre basic injection period (TQpre), and a main basic injection period (TQmain) are calculated. Here, the characteristic map for calculating the basic injection period (TQ) of each fuel injection in the multi-injection is such that fuel is injected in the vicinity of the TDC (top dead center) of the engine 1 and each fuel injection in the multi-injection. It is the map adapted by measuring quantity (Q), common rail pressure (PC), and injection period characteristics by experiment etc.
[0036]
Next, from the injection timing (main injection timing: T) calculated in step S1, the basic injection period (TQ) calculated in step S2, etc., the injector injection start angle (fuel) at the start of each fuel injection of multi-injection An injection start crank angle: QCA) is calculated (injection start angle calculation means: step S3). Specifically, the injection timing (main injection timing: T) calculated in step S1, the pilot interval (TINTpilot), the pre-interval (TINTpre), the pilot basic injection period (TQpilot) calculated in step S2, and the pre-basic injection A pilot injection start angle (QCApilot), a pre-injection start angle (QCApre), and a main injection start angle (QCAmain) are calculated from the period (TQpre) and the like.
[0037]
Next, the basic cylinder internal pressure (QCPB) at the start of each fuel injection in the multi-injection is calculated by map interpolation from the injection start angle (QCA) at the start of each fuel injection in the multi-injection (in-cylinder pressure prediction means: step) S4). That is, each fuel injection of the multi-injection is performed using a characteristic map (see FIG. 4) created in advance by experiment or the like to determine the relationship between the injection start angle (QCA) of each multi-injection and the basic cylinder internal pressure (QCPB). The basic cylinder internal pressure (QCPB) at the start is calculated. Specifically, the basic cylinder internal pressure at the start of pilot injection (QCPBpilot), the basic cylinder internal pressure at the start of pre-injection (QCPBpre), and the basic cylinder internal pressure at the start of main injection (QCPBmain) are calculated using the above characteristic map. To do.
[0038]
Next, the amount of change in the cylinder pressure at the start of each fuel injection in the multi-injection is calculated with respect to the cylinder pressure in the vicinity of the TDC of the engine 1 when the fuel injection amount (Q) in each multi-injection and the injection period characteristic are adapted. (Cylinder internal pressure change amount calculating means), and further, the following formula 1 is calculated from the basic cylinder internal pressure (QCPB) at the start of each of the multi-injections and the intake pressure (PIM) detected by the intake pressure sensor 44. The injection amount correction amount (QCP) corresponding to the change in the injection period characteristic with respect to the fuel injection amount due to the change in the cylinder internal pressure of the engine 1 is calculated (injection amount correction amount calculating means: step S5). Specifically, a pilot injection amount correction amount (QCPpilot) and a pre-injection amount correction corresponding to the change in the injection period characteristic with respect to the fuel injection amount due to the change in the cylinder pressure of the engine 1 are calculated using the following equation (1). An amount (QCPpre) and a main injection amount correction amount (QCPmain) are calculated.
[Expression 1]

However, K1 and K2 are constants, QCPB is a basic cylinder internal pressure at the start of each injection of multi-injection, PIM is an intake pressure immediately before each fuel injection of multi-injection in the current cycle, and QCP is an engine 1 This is an injection amount correction amount that takes into account the change in the fuel injection amount and the injection period characteristic due to the cylinder internal pressure at the start of each fuel injection in the multi-injection with respect to the fuel injection amount and the injection period characteristic due to the cylinder internal pressure near TDC.
[0039]
Next, the common rail pressure correction coefficient (PCC) of each fuel injection of the multi-injection is calculated by map interpolation from the common rail pressure (PC) immediately before each fuel injection of the multi-injection (correction coefficient calculating means: step S6). . That is, using a characteristic map (see FIG. 5) that is created in advance by experiment or the like to determine the relationship between the common rail pressure (PC) immediately before each fuel injection and the common rail pressure correction coefficient (PCC). A common rail pressure correction coefficient (PCC) for each fuel injection is calculated. This is because the change in the injection amount and the injection period characteristic due to the common rail pressure (PC) immediately before each fuel injection in the multi-injection with respect to the relationship between the injection amount due to the common rail pressure (PC) near the TDC of the engine 1 and the injection period characteristic. Is a fuel pressure correction coefficient that takes into account Specifically, a common rail pressure correction coefficient (PCCpilot) for pilot injection, a common rail pressure correction coefficient (PCCpre) for pre-injection amount, and a common rail pressure correction coefficient (PCCmain) for main injection are calculated using a characteristic map.
[0040]
Next, from the injection amount correction amount (QCP) of each fuel injection calculated in step S5 and the common rail pressure correction coefficient (PCC) of each fuel injection calculated in step S6, Using the calculation formula, the cylinder pressure correction injection amount (QCPQ) of each fuel injection of the multi-injection is calculated (correction amount calculating means: step S7). Specifically, the cylinder pressure correction injection amount for pilot injection corresponding to the change in the injection period characteristic with respect to the fuel injection amount due to the change in the cylinder pressure of the engine 1 and the change in the common rail pressure, using the following equation (2) (QCPQpilot), pre-injection cylinder pressure correction injection amount (QCPQpre) and main injection cylinder pressure correction injection amount (QCPQmain) are calculated.
[Expression 2]

However, QCP is an injection amount correction amount of each fuel injection of multi-injection, PCC is a common rail pressure correction coefficient of each fuel injection of multi-injection, and QCPQ is an in-cylinder pressure correction injection amount of each fuel injection of multi-injection. is there.
[0041]
Next, the multi-injection is determined from the fuel injection amount (Q) of each multi-injection, the cylinder pressure correction injection amount (QCPQ) of each fuel injection of the multi-injection, and the common rail pressure (PC) immediately before each fuel injection of the multi-injection. The final injection period (TQF) of each fuel injection is calculated by map interpolation (step S8). Thereafter, the routine of FIG. 3 is exited. That is, a characteristic map (Fig. 1) created by previously obtaining the relationship between the fuel injection amount (Q), the common rail pressure (PC) of each multi-injection, and the final injection period (TQF) of each fuel injection of the multi-injection. (Not shown) is used to calculate the final injection period (TQF) of each fuel injection of the multi-injection. Specifically, the final injection period (TQFpilot) of pilot injection, the final injection period (TQFpre) of pre-injection, and the final injection period (TQFmain) of main injection are calculated using the characteristic map.
[0042]
In the routine shown in FIG. 3, the basic cylinder internal pressure (QCPB) at the start of main injection and the common rail pressure correction coefficient (PCC) for pre-injection and main injection are calculated by map interpolation. It can also be obtained by an expression. In addition, although correction is performed using a common rail pressure correction coefficient (PCC) for a common rail fuel injection system, correction of common rail pressure is also performed in a fuel device that does not have a common rail equipped with a distributed fuel injection pump or the like. It can be used without.
[0043]
[Features of Example]
Next, a method for driving the injector 5 of this embodiment will be briefly described with reference to FIGS. Here, FIG. 2A is a diagram showing a non-injection state of the injector 5 of the specific cylinder of the engine 1.
[0044]
The injection command pulse applied to the solenoid valve 12 of the injector 5 of the specific cylinder of the engine 1 is output during one combustion stroke of the engine 1 in the order of pilot injection → pre-injection → main injection. Each injection interval of the multi-injection during one combustion stroke of the engine 1 and the number of injections during one combustion stroke of the engine 1 are not limited to two times in the present embodiment, but are arbitrarily determined depending on the operating conditions of the engine 1 and the command injection amount. It is determined.
[0045]
As shown in FIG. 2B, the fuel injection from the injector 5 of the specific cylinder of the engine 1 to the engine 1 is performed by closing the normally open switch 23 of the injector drive circuit and the solenoid valve of the injector 5 of the specific cylinder. When an injection command pulse is applied to the 12 solenoid coils 24, the valve body 25 of the solenoid valve 12 opens. While the solenoid valve 12 is open, the fuel in the back pressure control chamber 19 leaks to the leak pipe 36 through the orifice 21, so that the nozzle needle 13 overcomes the urging force of a spring (not shown). It lifts (separates) from the valve seat of the nozzle body constituting the main body 15. Thereby, since the injection hole 16 and the fuel reservoir 17 communicate with each other, the high pressure fuel accumulated in the common rail 4 is injected and supplied into the combustion chamber of the specific cylinder of the engine 1.
[0046]
Thereafter, when the injection period elapses from the injection pulse start timing and the injection pulse end timing is reached, that is, when the normally open switch 23 of the injector drive circuit is opened, as shown in FIG. The valve body 25 is closed. While the solenoid valve 12 is closed, high pressure fuel is filled into the back pressure control chamber 19 from the fuel passage (high pressure passage) 18 through the orifice 20, so that the nozzle needle 13 is moved by the urging force of the return spring. Sit on the nozzle body valve seat. As a result, the communication state between the injection hole 16 and the fuel reservoir 17 is cut off, so that the fuel injection into the combustion chamber of the specific cylinder of the engine 1 is completed.
[0047]
Here, pilot injection and pre-injection that are performed before the main injection that is performed in the vicinity of the TDC of the engine 1 are performed at predetermined times from the start of energization of the injection command pulse to the solenoid coil 24 of the solenoid valve 12 of the injector 5. The nozzle needle 13 opens after the injection start delay time elapses, and the nozzle needle 13 should close after a predetermined injection end delay time elapses from the energization end time of the injection command pulse. When the cylinder internal pressure and common rail pressure of the engine 1 change with respect to the cylinder internal pressure and common rail pressure near the TDC when the injection period characteristic is adapted, the valve opening timing or valve closing timing of the nozzle needle 13 is originally opened. The valve timing or valve closing timing may be earlier or later. As a result, when the valve closing timing or the valve opening timing of the nozzle needle 13 is a preset valve closing timing or valve opening timing, the fuel injection amount actually injected as a matter of course becomes the pilot injection amount calculated. This increases or decreases from (Qpilot) and the pre-injection amount (Qpre), causing a problem that fuel of the correct value cannot be injected.
[0048]
Therefore, in the common rail fuel injection system of the present embodiment, the cylinder internal pressure and the common rail pressure near the TDC of the engine 1 when the injection period characteristics for each fuel injection amount (Q) of the multi-injection are adapted are actually injected. Paying attention to the fact that the injection period characteristic for each fuel injection amount (Q) of multi-injection differs from the cylinder internal pressure and common rail pressure at the time, as shown in the routine of FIG. 3 above, The basic injection period (TQ) and injector injection start angle (QCA) of each fuel injection are calculated, and the basic cylinder internal pressure (QCPB) at the start of each fuel injection of multi-injection is calculated from the injector injection start angle (QCA). , With respect to the cylinder internal pressure near the TDC of the engine 1 when the fuel injection amount (Q) and the injection period characteristic of each of the multi-injections are adapted. It is as to calculate the cylinder internal pressure variation of the fuel injection start time of each multiple injection.
[0049]
An injection amount correction amount corresponding to the change in the injection period characteristic with respect to the fuel injection amount due to the change in the cylinder internal pressure of the engine 1 from the basic cylinder internal pressure (QCPB) and the intake pressure (PIM) at the start of each injection of the multi-injection. (QCP) is calculated, and the cylinder pressure correction injection quantity (QCPQ) of each fuel injection of the multi-injection corresponding to the change of the injection period characteristic with respect to the fuel injection quantity due to the change of the cylinder pressure of the engine 1 and the change of the common rail pressure is calculated. The multi-injection is calculated from the fuel injection amount (Q) of each multi-injection, the cylinder pressure correction injection amount (QCPQ) of each fuel injection of the multi-injection, and the common rail pressure (PC) immediately before each fuel injection of the multi-injection. The final injection period (TQF) of each fuel injection is calculated by map interpolation.
[0050]
Therefore, the amount of change in the cylinder pressure at the time of actual injection is calculated, and the change in the injection period characteristic with respect to the fuel injection amount due to the change in the cylinder pressure and the change in the common rail pressure is corrected so as to be the optimum injection period characteristic. Thus, the fuel injection amount of each of the multi-injections set according to the operating conditions of the engine 1 (in the pilot injection, the pre-injection, and the main injection of the multi-injection in which fuel is injected in a wide range before and after the TDC of the engine 1 ( Pilot injection amount, pre-injection amount, main injection amount) can be correctly injected.
[0051]
Further, in the common rail fuel injection system of the present embodiment, control for injecting fuel into three portions during one combustion stroke of each cylinder of the engine 1, that is, multi-injection including pilot injection, pre-injection, and main injection is performed. As a result, the rapid increase in the initial injection rate can be suppressed, so that the noise and engine vibration of the engine 1 can be suppressed. By performing pilot injection before the pre-injection, the noise and engine vibration of the engine 1 can be reduced. Further suppression can be achieved.
[0052]
In addition, in the case of performing control in which fuel is injected in three times during one combustion stroke of each cylinder of the engine 1, that is, when performing multi-injection including pre-injection, main injection, and after-injection, after-injection is performed after main-injection. By doing so, the unburned gas in the main injection can be burned, so that smoke emission can be suppressed and exhaust gas performance can be improved. Further, in the case of performing control in which fuel is injected in five times during one combustion stroke of each cylinder of the engine 1, that is, when performing multi-injection including pilot injection, pre-injection, main injection, after-injection, and post-injection, after- The catalyst can be activated by performing post injection after injection.
[0053]
[Modification]
In this embodiment, an example in which the present invention is applied to a common rail fuel injection system has been described as an example of the fuel injection device of the present invention. However, no pressure accumulation piping such as a common rail is provided, and a high pressure is directly supplied from the fuel supply pump to the injector through the high pressure piping. The present invention may be applied to a fuel injection device that supplies fuel. In this embodiment, an example in which the injector 5 with a two-way valve type electromagnetic valve is used as an example of an injector that injects fuel into the combustion chamber of each cylinder of the engine 1 has been described. An injector with a valve or other types of injectors may be used.
[0054]
In this embodiment, the common rail pressure sensor 45 is directly attached to the common rail 4 so as to detect the fuel pressure accumulated in the common rail 4 (common rail pressure), but the fuel pressure detection means is used as the plunger chamber of the supply pump 3. The fuel pressure discharged from the pressurizing chamber of the supply pump 3 may be detected by attaching to a fuel pipe or the like between the (pressurizing chamber) and the fuel passage in the injector 5.
[0055]
In this embodiment, the example in which the intake metering valve 7 for changing (adjusting) the intake amount of the fuel sucked into the plunger chamber (pressurizing chamber) of the supply pump 3 is described. A discharge metering valve that changes (adjusts) the amount of fuel discharged from the chamber (pressurization chamber) to the common rail 4 may be provided. Note that a normally open type solenoid valve that is fully open when the valve opening degree of the suction metering valve 7 or the discharge metering valve stops energizing the solenoid valve may be used. A normally closed type solenoid valve that is fully opened when the valve opening degree of the discharge metering valve energizes the solenoid valve may be used.
[0056]
In this embodiment, as an example of the fuel injection device of the present invention, the multi-injection (for example, pilot injection, pre-injection, main injection) is performed three times during one combustion stroke of the engine 1 in the injector 5 of a specific cylinder of the engine 1. Although an example in which a common rail fuel injection system capable of being applied has been described, two multiple injections (for example, pilot injection / main injection) or three multiple injections (for example, pilot injection / main injection / after injection) are performed. It may be applied to a common rail fuel injection system that can be performed, or four multi-injections (eg pilot injection, pre-injection, main injection, after-injection or pilot injection, main injection, after-injection, post-injection) You may apply to the common rail type fuel injection system which can perform.
[0057]
Moreover, the present invention may be applied to a common rail fuel injection system capable of performing five times of multi-injection (for example, pilot injection, pre-injection, main injection, after-injection, and post-injection), and more than six times of multi-injection. You may apply to the common rail type fuel injection system which can perform. Each injection interval of six or more multi-injections during one combustion stroke of the engine 1 and the number of injections during one combustion stroke of the engine 1 are arbitrarily determined according to the operating conditions of the engine 1 and the command injection amount.
[Brief description of the drawings]
FIG. 1 is a schematic view showing the overall structure of a common rail fuel injection system (Example).
FIGS. 2A to 2C are explanatory views showing an operating state of an injector (Example). FIG.
FIG. 3 is a flowchart showing an outline of an injection period correction method for pilot injection, pre-injection, and main injection of an injector (Example).
FIG. 4 is a characteristic diagram showing a relationship between an injection start angle and a basic cylinder internal pressure (Example).
FIG. 5 is a characteristic diagram showing a relationship between a common rail pressure and a common rail pressure correction coefficient (Example).
[Explanation of symbols]
1 engine
3 Supply pump (fuel supply pump)
4 Common rail
5 Injector (Electromagnetic fuel injection valve)
7 Inhalation metering valve
10 ECU (injection amount control means)
41 Cylinder discrimination sensor (cylinder discrimination means, operating condition detection means)
42 Crank angle sensor (rotational speed detection means, operating condition detection means)
43 Accelerator opening sensor (operating condition detection means)
44 Intake pressure sensor (intake pressure detection means)
45 Common rail pressure sensor (fuel pressure detection means)

Claims (4)

A fuel supply pump that pressurizes the fuel to increase the pressure; and
A fuel injection valve that injects and supplies the high-pressure fuel discharged from the fuel supply pump to each cylinder of the engine;
An injection amount control means for calculating a command injection amount and an injection timing according to the operating condition of the engine, and driving the fuel injection valve according to the calculated command injection amount and the injection timing;
In the fuel injection device capable of performing multi-injection in which fuel is injected in a plurality of times during one combustion stroke of the engine,
The injection amount control means performs fuel injection near the top dead center of the engine, measures the fuel injection amount and the injection period characteristic of each of the multi-injections, and maps or calculates the multi-injection from the map or calculation formula. Injection period determining means for calculating a basic injection period of each fuel injection;
An injection start angle calculating means for calculating an injection start angle at the start of each fuel injection of the multi-injection from the injection timing and the basic injection period;
Cylinder pressure calculation for calculating the cylinder pressure at the start of each fuel injection of the multi-injection from a map or a calculation formula adapted by measuring the injection start angle and cylinder pressure characteristics at the start of each fuel injection of the multi-injection Means,
According to the amount of change in the cylinder pressure at the start of each fuel injection of the multi-injection with respect to the cylinder internal pressure near the top dead center of the engine when the fuel injection amount and the injection period characteristic of the multi-injection are adapted A fuel injection device for correcting a fuel injection amount of each of the multi-injections and a basic injection period of each fuel injection of the multi-injections ,
Fuel pressure detecting means for detecting a fuel pressure corresponding to the fuel injection pressure;
An intake pressure detecting means for detecting an intake pressure of air sucked into the cylinder of the engine,
The injection amount control means takes into account the intake pressure detected by the intake pressure detection means to the calculated value of the cylinder internal pressure at the start of each fuel injection of the multi-injection,
Considering the change in the cylinder pressure at the start of each fuel injection of the multi-injection from the cylinder internal pressure near the top dead center of the engine when the fuel injection amount and the injection period characteristic of each of the multi-injections are adapted A fuel injection device comprising correction amount calculation means for calculating the injection amount correction amount . The fuel injection device according to claim 1,
The correction amount calculation means has correction coefficient calculation means for calculating a fuel pressure correction coefficient from the fuel pressure immediately before each fuel injection of the multi-injection, which is detected by the fuel pressure detection means,
A fuel injection device characterized in that a value obtained by multiplying the injection amount correction amount by the fuel pressure correction coefficient is used as an in-cylinder pressure correction injection amount of each fuel injection of the multi-injection . The fuel injection device according to claim 2, wherein
The injection amount control means calculates the final corrected injection amount of each fuel injection of the multi-injection by adding the cylinder pressure correction injection amount to the fuel injection amount of the multi-injection. a fuel injection apparatus characterized by having means. The fuel injection device according to claim 2 or 3 ,
The injection amount control means takes into account the fuel pressure immediately before each fuel injection of the multi-injection and the cylinder pressure correction injection amount in the basic injection period of each fuel injection of the multi-injection. A fuel injection apparatus comprising: an injection period correcting means for calculating a final injection period of the fuel injection.

Images