JP3892403B2 - Vehicle control device - Google Patents

Description

ここで、ＴＱＤＮＢＬＴＦは、前記ステップ２で算出された駆動側伝達トルクの基本値ＴＱＤＲＢＬＴＦに変速比ＲＡＴＩＯを乗算した値として設定される、従動側伝達トルクＴＱＤＮＢＬＴＭの基本値である。
【００４２】
図７は、図６のステップ１で実行される余裕トルク補正項算出処理のサブルーチンを示すフローチャートである。まず、ステップ１１では、悪路判定処理を実行する。図８は、この悪路判定処理のサブルーチンを示すフローチャートである。まず、ステップ３１では、前回時および今回時に検出された車速ＶＰの偏差である車速変化量の今回値ＤＴＶと前回値ＤＴＶ０との偏差を、変化量偏差ＤＤＴＶとして設定する。次いで、今回得られた車速変化量ＤＴＶをその前回値ＤＴＶ０としてシフトする（ステップ３２）。
【００４３】
次に、ポインタ値ＣＴＤＤＴＶが所定値ＹＤＤＴＶＢＦ（例えば８）よりも小さいか否かを判別する（ステップ３３）。この答がＹＥＳのときには、ポインタ値ＣＴＤＤＴＶをインクリメントし（ステップ３４）、ステップ３５に進む。また、この答がＮＯのときには、このステップ３４をスキップし、ステップ３５に進む。なお、ポインタ値ＣＴＤＤＴＶは、エンジン４の始動時に値０に設定される。
【００４４】
このステップ３５および３６ではそれぞれ、スロットル弁開度ＴＨが所定の第１および第２の判定開度ＹＴＨＡＫＵＬ、ＹＴＨＡＫＵＨで規定される範囲内にあるか否か、および前記ステップ３１で設定された変化量偏差の絶対値｜ＤＤＴＶ｜が所定値ＹＤＤＴＶＡＫＵ以上であるか否かを判別する。この所定値ＹＤＤＴＶＡＫＵは、車両３が舗装された路面を走行している場合において、スロットル弁８が上記の所定範囲内にあるときに、車両３の加速度の変化量がとるべき範囲よりも大きな値に設定されている。
【００４５】
ステップ３５および３６の答のいずれかがＮＯのときには、車両３が悪路を走行していないと仮判定し、バッファＤＤＴＶＢＦのビットをシフトするとともに、０ビットに値０をセットし（ステップ３７）、ステップ３９に進む。
【００４６】
一方、ステップ３５および３６の答がいずれもＹＥＳで、スロットル弁開度ＴＨが上記の所定の範囲内にあり、かつ変化量の絶対値｜ＤＤＴＶ｜が所定値ＹＤＤＴＶＡＫＵ以上であるときには、車両３が悪路を走行していると仮判定し、バッファＤＤＴＶＢＦのビットをシフトするとともに、０ビットに値１をセットし（ステップ３８）、ステップ３９に進む。
【００４７】
このステップ３９では、ポインタ値ＣＴＤＤＴＶが、前記所定値ＹＤＤＴＶＢＦ以上であるか否かを判別する。この答がＮＯのときには、悪路判定フラグＦ＿ＡＫＵＲＯを「０」にセットし（ステップ４０）、本プログラムを終了する。
【００４８】
ステップ３９の答がＹＥＳで、前記３７または３８の実行により、バッファＤＤＴＶＢＦに所定値ＹＤＤＴＶＢＦ以上の数のデータが確保されたときには、所定値ＹＤＤＴＶＢＦに相当する数分の最新のデータの総和を悪路仮判定回数ＣＴＤＴＶＡＫＵとして設定する（ステップ４１）。
【００４９】
次いで、この悪路仮判定回数ＣＴＤＴＶＡＫＵが、所定回数ＹＣＴＡＫＵ（例えば４回）以上であるか否かを判別する（ステップ４２）。この答がＹＥＳで、所定値ＹＤＤＴＶＢＦに相当する時間内において、スロットル弁開度ＴＨが所定の範囲内にあり、かつ車速変化量ＤＴＶが大きく変化している状態が、所定回数ＹＣＴＡＫＵ以上、検出されており、このような状態が頻繁に検出されているので、車両３が悪路を走行しているとして、悪路判定フラグＦ＿ＡＫＵＲＯを「１」にセットし（ステップ４３）、本プログラムを終了する。なお、上記の所定回数ＹＣＴＡＫＵは、ヒステリシス付きの値に設定されている。
【００５０】
ステップ４２の答がＮＯのときには、車両３が悪路を走行していないとして、前記ステップ４０を実行し、本プログラムを終了する。
【００５１】
図７に戻り、前記ステップ１１に続くステップ１２では、シフトレバーの位置が走行レンジ、すなわち「Ｄ」「Ｓ」「Ｒ」のいずれかにあるか否かを判別する。この答がＮＯのときには、余裕トルク補正項ＴＱＭＡＲＧＰを値０に設定し（ステップ１３）、ダウンカウント式のディレイタイマのタイマ値ＴＭＴＱＭＧＰを値０にセットし（ステップ１４）、本プログラムを終了する。一方、ステップ１２の答がＹＥＳで、シフトレバーの位置が走行レンジにあるときには、前述した発進クラッチ３０の滑り率ＥＳＣが、滑りが発生していない状態を表す所定滑り率ＥＳＣＲＥＦ（例えば１００％）であるか否かを判別する（ステップ１５）。
【００５２】
この答がＮＯで、発進クラッチ３０が滑っているときには、余裕トルク補正項ＴＱＭＡＲＧＰが値０よりも大きいか否かを判別する（ステップ１６）。この答がＮＯのときには、余裕トルク補正項ＴＱＭＡＲＧＰを比較的小さな初期値ＴＱ１（例えば２．０Ｎ・ｍ）に設定し（ステップ１７）、ディレイタイマのタイマ値ＴＭＴＱＭＧＰを第１所定時間ＹＴＴＱＭＴＩＮ（例えば０．６ｓｅｃ）にセットする（ステップ１８）とともに、ステップ１９に進む。また、前記ステップ１７を実行した後には、前記ステップ１６の答がＹＥＳになり、その場合には、前記ステップ１７および１８をスキップし、ステップ１９に進む。
【００５３】
このステップ１９では、前記ステップ１８で設定されたディレイタイマのタイマ値ＴＭＴＱＭＧＰが値０であるか否かを判別する。この答がＮＯのときには、そのまま本プログラムを終了する。一方、この答がＹＥＳで、ディレイタイマＴＭＴＱＭＧＰのセット後、第１所定時間ＹＴＴＱＭＴＩＮが経過したときには、そのときの余裕トルク補正項ＴＱＭＡＲＧＰから所定の減算項ＹＤＴＱＭＡＲＧＰ（例えば０．０１ｋｇｆ・ｍ）を減算した値を、今回の余裕トルク補正項ＴＱＭＡＲＧＰとして設定し（ステップ２０）、本プログラムを終了する。
【００５４】
一方、ステップ１５の答がＹＥＳで、発進クラッチ３０が滑っていないときには、スロットル弁開度ＴＨの今回値と前回値との偏差ＤＴＨがその第１所定値ＹＤＴＨＴＱＰ（例えば２０゜）以上であり、かつスロットル弁開度ＴＨがその第１所定開度ＹＴＨＴＱＰ（例えば２０゜）以上であるか否かを判別する（ステップ２１）。これらの第１所定値ＹＤＴＨＴＱＰおよび第１所定開度ＹＴＨＴＱＰは、ヒステリシス付きの値にそれぞれ設定されている。
【００５５】
この答がＹＥＳで、スロットル弁開度ＴＨの偏差ＤＴＨが非常に大きく、かつスロットル弁開度ＴＨが非常に大きいとき（以下、このような状態を「チップイン」という）、すなわちスロットル弁８が急激に開弁したときには、エンジン４の出力の変化量が急激に増加しているとして、前記ステップ１６以降を実行し、本プログラムを終了する。一方、この答がＮＯのときには、スロットル開度ＴＨの偏差ＤＴＨが、負値である第２所定値ＹＤＴＨＴＱＭ（例えば−２０゜）よりも小さく、かつスロットル弁開度ＴＨが、前記第１所定開度ＹＴＨＴＱＰよりも小さな第２所定開度ＹＴＨＴＱＭ（例えば１０゜）よりも小さいか否かを判別する（ステップ２２）。これらの第２所定値ＹＤＴＨＴＱＭおよび第２所定開度ＹＴＨＴＱＭもまた、ヒステリシス付きの値にそれぞれ設定されている。
【００５６】
この答がＹＥＳで、スロットル弁開度ＴＨの偏差ＤＴＨが負値で、その絶対値が非常に大きく、かつスロットル弁開度ＴＨが非常に小さいとき（以下、このような状態を「チップアウト」という）、すなわちスロットル弁８が急激に閉弁したときには、エンジン４の出力の変化量が急激に減少しているとして、前記ステップ１６以降を実行し、本プログラムを終了する。一方、この答がＮＯのときには、図８の悪路判定処理で設定された悪路判定フラグＦ＿ＡＫＵＲＯが「１」であるか否かを判別する（ステップ２３）。この答がＹＥＳで、車両３が悪路を走行していると判定されたときには、前記ステップ１６以降を実行し、本プログラムを終了する。
【００５７】
一方、ステップ２３の答がＮＯで、発進クラッチ３０が締結しており、チップインおよびチップアウト時でもなく、かつ車両３が悪路を走行していないと判定されたときには、前記ステップ１３以降を実行し、本プログラムを終了する。
【００５８】
以上のように、チップイン時、チップアウト時、車両３が悪路を走行していると判定されたとき、または発進クラッチ３０が滑っているときには、余裕トルク補正項ＴＱＭＡＲＧＰを比較的小さな初期値ＴＱ１に設定する。そして、この余裕トルク補正項ＴＱＭＡＲＧＰを、前式（１）、（２）に適用することによって、駆動側および従動側伝達トルクＴＱＤＲＢＬＴＭおよびＴＱＤＮＢＬＴＭが若干、増加される。それにより、伝達ベルト２４の滑りを確実に防止することができる。また、この余裕トルク補正項ＴＱＭＡＲＧＰは、第１所定時間ＹＴＴＱＭＴＩＮが経過するまでは、初期値ＴＱ１に保たれ、その後、減算項ＹＤＴＱＭＡＲＧＰの適用によって漸減される。
【００５９】
図９は、前述した発進クラッチ３０の締結力を制御するための目標油圧ＰＣＣＭＤＬを算出するＰＣＣＭＤＬ算出処理を示すフローチャートである。まず、ステップ５１では、図８の悪路判定処理で設定された悪路判定フラグＦ＿ＡＫＵＲＯが「１」であるか否かを判別する。この答がＹＥＳで、車両３が悪路を走行していると判定されたときには、目標油圧ＰＣＣＭＤＬを、その基本値ＰＣＣＭＤに値１．０よりも小さな所定の低減係数α（例えば０．８）を乗算した値に設定し（ステップ５２）、本プログラムを終了する。これにより、悪路判定時には、発進クラッチ３０の締結力が低減されることによって、発進クラッチ３０に滑りが生じる。なお、基本値ＰＣＣＭＤは、エンジントルクと変速比ＲＡＴＩＯと所定係数との積に、前述した発進クラッチ３０のリターンスプリングの付勢力を加算した値として設定されるものであり、これが目標油圧ＰＣＣＭＤＬに適用された場合には、十分な発進クラッチ３０の締結力が得られ、発進クラッチ３０の滑りは生じない。なお、エンジントルクは、エンジン回転数ＮＥおよび吸気管内絶対圧ＰＢＡに応じて設定される。
【００６０】
一方、ステップ５１の答がＮＯで、Ｆ＿ＡＫＵＲＯ＝０のときには、今回がチップインまたはチップアウトに移行した直後のループであるか否かを判別する（ステップ５３）。この答がＹＥＳのときには、ダウンカウント式のディレイタイマのタイマ値ＴＭＴＲＳを第２所定時間ＴＭＲＥＦ（例えば０．５ｓｅｃ）にセットする（ステップ５４）とともに、目標油圧ＰＣＣＭＤＬを、基本値ＰＣＣＭＤから所定値ＰＣＴＨ（例えば１ｋｇｆ／ｃｍ²）を減算した値である初期値に設定し（ステップ５５）、本プログラムを終了する。これにより、発進クラッチ３０の締結力が低減されることによって、発進クラッチ３０に滑りが生じる。
【００６１】
一方、ステップ５３の答がＮＯで、チップインまたはチップアウトへの移行直後でないときには、滑り率ＥＳＣが図７のステップ１５で用いた所定滑り率ＥＳＣＲＥＦであるか否かを判別する（ステップ５６）。この答がＮＯで、前記ステップ５５の実行により発進クラッチ３０が滑っているときには、前記ステップ５４でセットしたディレイタイマのタイマ値ＴＭＴＲＳが値０であるか否かを判別する（ステップ５８）。
【００６２】
この答がＮＯで、チップインまたはチップアウトへの移行後、第２所定時間ＴＭＲＥＦが経過していないときには、目標油圧の前回値ＰＣＣＭＤＬ０を今回値ＰＣＣＭＤＬとして設定し（ステップ５９）、本プログラムを終了する。一方、ステップ５８の答がＹＥＳのときには、目標油圧の前回値ＰＣＣＭＤＬ０が基本値ＰＣＣＭＤよりも小さいか否かを判別する（ステップ６０）。
【００６３】
この答がＹＥＳで、ＰＣＣＭＤＬ０＜ＰＣＣＭＤのときには、補正加算項ΔＰＣを算出する（ステップ６１）。この補正加算項ΔＰＣは、滑り率ＥＳＣに応じて、図１０に示すＥＳＣ−ΔＰＣテーブルを検索することによって算出される。このテーブルでは、補正加算項ΔＰＣは、滑り率ＥＳＣが所定滑り率ＥＳＣＲＥＦのときに最大値ＰＣＭＡＸ（例えば０．５ｋｇｆ／ｃｍ²）に設定され、滑り率ＥＳＣが所定滑り率ＥＳＣＲＥＦから遠ざかるほど、より小さな値にリニアに設定されている。
【００６４】
次いで、目標油圧の前回値ＰＣＣＭＤＬ０に、ステップ６１で算出された補正加算項ΔＰＣを加算した値を、目標油圧ＰＣＣＭＤＬとして算出し（ステップ６２）、本プログラムを終了する。
【００６５】
一方、前記ステップ６０の答がＮＯで、前記ステップ６２で算出された目標油圧ＰＣＣＭＤＬが基本値ＰＣＣＭＤに達したときには、目標油圧ＰＣＣＭＤＬを基本値ＰＣＣＭＤに設定し（ステップ５７）、本プログラムを終了する。
【００６６】
また、前記ステップ５６の答がＹＥＳで、発進クラッチ３０の滑りがなくなったときには、目標油圧ＰＣＣＭＤＬを基本値ＰＣＣＭＤに設定し（ステップ５７）、本プログラムを終了する。
【００６７】
以上のように、目標油圧ＰＣＣＭＤＬは、チップインまたはチップアウトが検出されたときに、基本値ＰＣＣＭＤから所定値ＰＣＴＨを減算した初期値に設定され、その後、第２所定時間ＴＭＲＥＦが経過するまでは、初期値に保持された後、補正加算項ΔＰＣが加算されることによって、基本値ＰＣＣＭＤに達するまで漸増される。
【００６８】
図１１は、無段変速機２０の変速比ＲＡＴＩＯを制御するための変速比制御処理を示すフローチャートである。まず、ステップ７１では、悪路判定フラグＦ＿ＡＫＵＲＯが「１」であるか否かを判別する。この答がＮＯのときには、車速ＶＰおよびスロットル弁開度ＴＨに応じてＣＶＴ変速マップを検索することによって、目標変速比ＲＡＴＴＧＴを設定する（ステップ７２）。また、設定された目標変速比ＲＡＴＴＧＴに実際の変速比ＲＡＴＩＯが一致するように、駆動側および従動側作動油圧ＤＲＯＩＬおよびＤＮＯＩＬを制御し（ステップ７３）、本プログラムを終了する。
【００６９】
一方、ステップ７１の答がＹＥＳで、車両３が悪路を走行していると判定されたときには、ＣＶＴ変速マップを検索するために用いられるスロットル弁開度ＴＨに、フィルタ処理を施す（ステップ７４）とともに、前記ステップ７２以降を実行し、本プログラムを終了する。このフィルタ処理は、加重平均や移動平均または一次フィルタなどによって行われる。その具体的な説明については省略する。
【００７０】
以上のように、本実施形態によれば、図９の前記ステップ５１および５２の実行により、悪路判定時に、要求油圧ＰＣＣＭＤＬを、基本値ＰＣＣＭＤに低減係数αを乗算することによって低減することにより、発進クラッチ３０を滑らせるので、着地時に駆動輪７，７に発生したイナーシャトルクが、発進クラッチ３０の部分で逃がされ、エンジン４に伝達される度合を抑制でき、それにより、エンジン回転数ＮＥの変動を抑制でき、したがって、ドライバビリティーを向上させることができる。また、このようにイナーシャトルクを発進クラッチ３０の部分で逃がせるので、伝達ベルト２４の滑りを防止できるとともに、伝達ベルト２４の負荷を軽減でき、それにより、駆動側および従動側作動油圧ＤＲＯＩＬおよびＤＮＯＩＬを必要以上に高める必要がなくなる。したがって、伝達ベルト２４の寿命を延ばせるとともに、燃費を向上させることができる。
【００７１】
さらに、前記ステップ７４の実行により、悪路判定時にＣＶＴ変速マップを検索するために用いられるスロットル弁開度ＴＨに、フィルタ処理を施しており、それにより、悪路走行に起因するアクセル開度ＡＰの変動によるスロットル弁開度ＴＨへの影響分を、このフィルタ処理で除去できる。それにより、スロットル弁開度ＴＨに応じて設定される目標変速比ＲＡＴＴＧＴの変動を防止でき、したがって、変速比ＲＡＴＩＯおよびエンジン回転数ＮＥを安定させることができる。
【００７２】
また、前記ステップ５３および５５の実行により、チップインおよびチップアウト時に、基本値ＰＣＣＭＤから所定値ＰＣＴＨを減算することにより、要求油圧ＰＣＣＭＤＬを低減し、発進クラッチ３０を滑らせるので、急激に変動したエンジン４の出力トルクを発進クラッチ３０の部分で逃がすことができる。したがって、急激に変動した出力トルクをそのまま無段変速機２０を介して伝達する必要がなくなるので、伝達ベルト２４の滑りを防止できるとともに、伝達ベルト２４の負荷を軽減でき、それにより、駆動側および従動側作動油圧ＤＲＯＩＬおよびＤＮＯＩＬを必要以上に高める必要がなくなる。したがって、この場合にも、悪路判定時と同様の効果を得ることができる。さらに、発進クラッチ３０の滑り制御によって、アクセルペダルの急激な踏み込みやその解除を行った際のギクシャク感は発生せず、ドライバビリティーを維持できる。
【００７３】
また、前記ステップ６１および６２の実行により、要求油圧ＰＣＣＭＤＬを漸増させる補正加算項ΔＰＣを、滑り率ＥＳＣが所定滑り率ＥＳＣＲＥＦから遠ざかるほど、すなわち、発進クラッチ３０の滑り度合が大きいほど、より小さな値に設定することにより、要求油圧ＰＣＣＭＤＬを、発進クラッチ３０の滑り度合が大きい初期にはより小さな値に設定し、発進クラッチ３０の滑り度合が小さくなるにつれて徐々に増加させるので、発進クラッチ３０を滑らかにつなぐことができる。したがって、発進クラッチ３０を急激につなぐことによるイナーシャトルクの発生を回避できるので、駆動側および従動側作動油圧ＤＲＯＩＬおよびＤＮＯＩＬの高設定も不要になる。さらに、前記ステップ５８の実行により、急激に変動したエンジン４の出力が落ち着くのを待ってから、発進クラッチ３０を滑らかにつなぐので、上記のイナーシャトルクの発生をより確実に回避できる。
【００７４】
図１２は、図１１の変速比制御処理の変形例を示している。この処理は、本実施形態ではスロットル弁開度ＴＨをアクセル開度ＡＰに応じて制御することから、スロットル弁開度ＴＨの代わりに、アクセル開度ＡＰを補正するものである。まず、そのステップ８５では、悪路判定フラグＦ＿ＡＫＵＲＯが「１」であるか否かを判別する。この答がＮＯのときには、アクセル開度ＡＰに応じてスロットル弁開度ＴＨを制御する（ステップ８６）とともに、目標変速比ＲＡＴＴＧＴを前記ステップ７２と同様に設定し（ステップ８７）、前記ステップ７３と同様、実際の変速比ＲＡＴＩＯが算出された目標変速比ＲＡＴＴＧＴに一致するように、駆動側および従動側作動油圧ＤＲＯＩＬおよびＤＮＯＩＬを制御し（ステップ８８）、本プログラムを終了する。
【００７５】
一方、ステップ８５の答がＹＥＳで、車両３が悪路を走行していると判定されたときには、アクセル開度ＡＰに、フィルタ処理を施す（ステップ８９）とともに、前記ステップ８６以降を実行し、本プログラムを終了する。このフィルタ処理もまた、加重平均、移動平均または一次フィルタなどによって行われる。
【００７６】
このように、悪路判定時に、アクセル開度ＡＰにフィルタ処理を施すことによって、運転者の意図しないアクセルペダルの踏み込みまたは解除が行われても、それによるアクセル開度ＡＰの変動分をフィルタ処理で除去できるので、スロットル弁開度ＴＨが変動することがなく、したがって、この場合にも、変速比ＲＡＴＩＯおよびエンジン回転数ＮＥを安定させることができる。
【００７７】
次に、図１３を参照しながら、本発明の第２実施形態について説明する。本実施形態は、第１実施形態と比較して、変速機伝達トルク算出処理の内容のみが異なっているので、以下、この点について説明する。まず、ステップ９１では、滑り率ＥＳＣが所定滑り率ＥＳＣＲＥＦであるか否かを判別する。この答がＹＥＳで、発進クラッチ３０が滑りなく締結されているときには、ステップ９２および９３において、駆動側および従動側伝達トルクＴＱＤＲＢＬＴＭおよびＴＱＤＮＢＬＴＭを、それぞれの基本値ＴＱＤＲＢＬＴＦおよびＴＱＤＮＢＬＴＦに設定し、本プログラムを終了する。これらの基本値ＴＱＤＲＢＬＴＦおよびＴＱＤＮＢＬＴＦは、図６の前記ステップ２および３と同様にして算出される。
【００７８】
一方、ステップ９１の答がＮＯで、発進クラッチ３０が滑っているときには、クラッチ伝達トルクＴＱＣＬを、目標油圧ＰＣＣＭＤＬに応じて算出する（ステップ９４）。このクラッチ伝達トルクＴＱＣＬは、発進クラッチ３０が駆動輪７，７に伝達すべきトルクであり、目標油圧ＰＣＣＭＤＬが大きいほど、より大きな値にリニアな関係で算出される。
【００７９】
次いで、悪路判定フラグＦ＿ＡＫＵＲＯが「１」であるか否かを判別する（ステップ９５）。この答がＮＯで、車両３が悪路を走行していないと判定されたときには、図９の前記ステップ５４でセットされたディレイタイマのタイマ値ＴＭＴＲＳが値０であるか否かを判別する（ステップ９６）。この答がＮＯで、チップインまたはチップアウトへの移行後、第２所定時間ＴＭＲＥＦが経過していないときには、クラッチ伝達トルクＴＱＣＬを駆動側伝達トルクＴＱＤＲＢＬＴＭとして設定する（ステップ９７）。
【００８０】
一方、ステップ９６の答がＹＥＳのときには、クラッチ伝達トルクＴＱＣＬに所定の加算項βを加算した値を、駆動側伝達トルクＴＱＤＲＢＬＴＭとして設定する（ステップ９８）。また、前記ステップ９５の答がＹＥＳで、車両３が悪路を走行していると判定されたときには、前記ステップ９６をスキップして、上記ステップ９８を実行する。
【００８１】
前記ステップ９７または９８に続くステップ９９では、従動側伝達トルクＴＱＤＮＢＬＴＭを、駆動側伝達トルクＴＱＤＲＢＬＴＭに変速比ＲＡＴＩＯを乗算した値に設定し、本プログラムを終了する。
【００８２】
前述したように、チップイン、チップアウトまたは悪路判定時には、目標油圧ＰＣＣＭＤＬが低減される（図９の前記ステップ５２、５５）。そして、この目標油圧ＰＣＣＭＤＬに基づきクラッチ伝達トルクＴＱＣＬが算出され（前記ステップ９４）、それに応じて駆動側および従動側伝達トルクＴＱＤＲＢＬＴＭおよびＴＱＤＮＢＬＴＭが設定され（前記ステップ９８、９９）、さらに、それに応じて駆動側および従動側作動油圧ＤＲＯＩＬおよびＤＮＯＩＬが設定される（図５の前記ステップ８１）。したがって、チップイン、チップアウトまたは悪路判定時に、減少した目標油圧ＰＣＣＭＤＬに応じて駆動側および従動側作動油圧ＤＲＯＩＬおよびＤＮＯＩＬを減少側に過不足なく設定でき、燃費を向上させることができる。
【００８３】
また、前記ステップ９６〜９９の実行により、チップインまたはチップアウトへの移行後、ディレイタイマの計時により、第２所定時間ＴＭＲＥＦが経過するまで、すなわち滑らせた発進クラッチ３０を再び締結させるまでは、駆動側伝達トルクＴＱＤＲＢＬＴＭがクラッチ伝達トルクＴＱＣＬに設定され、その後に発進クラッチ３０を再び締結させ始めた以降は、クラッチ伝達トルクＴＱＣＬに加算項βを加算した値を駆動側伝達トルクＴＱＤＲＢＬＴＭとして設定するので、発進クラッチ３０の再締結に伴うイナーシャトルクが発生しても、それによる伝達ベルト２４の滑りを確実に防止できるとともに、駆動側および従動側作動油圧ＤＲＯＩＬおよびＤＮＯＩＬが無駄に高められるのを防止でき、したがって、さらに燃費を向上させることができる。
【００８４】
次に、図１４を参照しながら、本発明の第３実施形態について説明する。本実施形態は、第１実施形態と比較して、第２実施形態と同様、変速機伝達トルク算出処理の内容のみが異なっているので、この点についてのみ説明する。まず、ステップ１０１では、余裕トルク補正項算出処理を図７と同様に実行する。次いで、ステップ１０２では、図６の前記ステップ２と同様に算出された駆動側伝達トルクの基本値ＴＱＤＲＢＬＴＦに余裕トルク補正項ＴＱＭＡＲＧＰを加算した値を、駆動側第１暫定値ＴＱＤＲＢＬＴα（第１暫定値）として設定する。次に、この駆動側第１暫定値ＴＱＤＲＢＬＴαに変速比ＲＡＴＩＯを乗算した値を、従動側第１暫定値ＴＱＤＮＢＬＴα（第１暫定値）として設定する（ステップ１０３）。
【００８５】
次いで、クラッチ伝達トルクＴＱＣＬを図１３のステップ９４と同様に算出し（ステップ１０４）、このクラッチ伝達トルクＴＱＣＬに所定の加算項γを加算した値を、駆動側第２暫定値ＴＱＤＲＢＬＴβ（第２暫定値）として設定する（ステップ１０５）とともに、この駆動側第２暫定値ＴＱＤＲＢＬＴβに変速比ＲＡＴＩＯを乗算した値を、従動側第２暫定値ＴＱＤＮＢＬＴβ（第２暫定値）として設定する（ステップ１０６）。
【００８６】
次いで、前記ステップ１０２および１０５でそれぞれ設定された駆動側第１暫定値ＴＱＤＲＢＬＴαと駆動側第２暫定値ＴＱＤＲＢＬＴβを比較し（ステップ１０７）、前者ＴＱＤＲＢＬＴαの方が大きいときには、これを駆動側伝達トルクＴＱＤＲＢＬＴＭとして設定するとともに、従動側第１暫定値ＴＱＤＮＢＬＴαを従動側伝達トルクＴＱＤＮＢＬＴＭとして設定する（ステップ１０８）。一方、駆動側第２暫定値ＴＱＤＲＢＬＴβの方が大きいときには、これを駆動側伝達トルクＴＱＤＲＢＬＴＭとして設定するとともに、従動側第２暫定値ＴＱＤＮＢＬＴβを従動側伝達トルクＴＱＤＮＢＬＴＭとして設定し（ステップ１０９）、本プログラムを終了する。
【００８７】
以上のように、本実施形態によれば、エンジン４の運転状態に応じて算出された駆動側第１暫定値ＴＱＤＲＢＬＴα、およびクラッチ伝達トルクＴＱＣＬに応じて算出された駆動側第２暫定値ＴＱＤＲＢＬＴβのうち、大きい方を駆動側伝達トルクＴＱＤＲＢＬＴＭとして採用するので、伝達ベルト２４の滑りを確実に防止することができる。
【００８８】
なお、本発明は、説明した実施形態に限定されることなく、種々の態様で実施することができる。例えば、本実施形態は、無段変速機２０よりも駆動輪７側に発進クラッチ３０を設けた車両３の例であるが、これに代えて、本発明を、エンジンと駆動プーリとの間に発進クラッチを設けた車両に適用してもよい。その他、本発明の趣旨の範囲内で、細部の構成を適宜、変更することが可能である。
【００８９】
【発明の効果】
以上のように、本発明の車両の制御装置によれば、伝達ベルトの滑り防止しながら、伝達ベルトの寿命を延ばすことができるとともに、燃費およびドライバビリティーを向上させることができるなどの効果を有する。
【図面の簡単な説明】
【図１】車両駆動系の構造線図である。
【図２】制御装置および駆動系の油圧回路の概略構成を示す図である。
【図３】駆動プーリの動作例を示す図である。
【図４】従動プーリの動作例を示す図である。
【図５】作動油圧設定処理を示すフローチャートである。
【図６】変速機伝達トルク算出処理を示すフローチャートである。
【図７】余裕トルク補正項算出処理を示すフローチャートである。
【図８】悪路判定処理を示すフローチャートである。
【図９】ＰＣＣＭＤＬ算出処理を示すフローチャートである。
【図１０】ＥＳＣ−ΔＰＣテーブルの一例を示す図である。
【図１１】変速比制御処理を示すフローチャートである。
【図１２】変速比制御処理の他の例を示すフローチャートである。
【図１３】本発明の第２実施形態における変速機伝達トルク算出処理を示すフローチャートである。
【図１４】本発明の第３実施形態における変速機伝達トルク算出処理を示すフローチャートである。
【符号の説明】
１ 制御装置
２ ＥＣＵ（運転状態検出手段、変速機伝達トルク設定手段、クラッチ伝
達トルク設定手段、悪路判定手段、目標変速比設定手段、変
速比制御手段、スロットル弁開度補正手段）
３ 車両
４ エンジン（内燃機関）
７，７ 駆動輪
２０ 無段変速機
２２ 駆動プーリ
２３ 従動プーリ
２４ 伝達ベルト
３０ 発進クラッチ（摩擦式のクラッチ）
４０ クランク角センサ（運転状態検出手段）
４１ スロットル弁開度センサ（スロットル弁開度検出手段）
４２ 吸気管内絶対圧センサ（運転状態検出手段）
ＰＤＲＤ 有効径
ＰＤＮＤ 有効径
ＴＱＤＲＢＬＴＭ 駆動側伝達トルク（変速機伝達トルク）
ＴＱＤＮＢＬＴＭ 従動側伝達トルク（変速機伝達トルク）
ＰＣＣＭＤＬ 目標油圧（クラッチ伝達トルク）
ＴＱＤＲＢＬＴα 駆動側第１暫定値（第１暫定値）
ＴＱＤＮＢＬＴα 従動側第１暫定値（第１暫定値）
ＴＱＤＲＢＬＴβ 駆動側第２暫定値（第２暫定値）
ＴＱＤＮＢＬＴβ 従動側第２暫定値（第２暫定値）
ＡＰ アクセル開度（アクセルペダルの開度）
ＴＨ スロットル弁開度
ＲＡＴＴＧＴ 目標変速比
ＲＡＴＩＯ 変速比[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a control device for a vehicle having a belt-type continuously variable transmission.
[0002]
[Prior art]
As this type of conventional control device, for example, one disclosed in Patent Document 1 is known. The continuously variable transmission includes a drive pulley connected to the engine, a driven pulley connected to the drive wheel, a transmission belt for transmitting power between the two pulleys, and a hydraulic control valve. The drive pulley has a movable part and a fixed part. The movable part is attached to a pulley shaft connected to the engine so as to be movable in the axial direction and non-rotatable. The fixed part is fixed to the pulley shaft and faces the movable part. A V-shaped groove is formed by these movable part, fixed part and pulley shaft. The driven pulley is configured similarly to the drive pulley. The transmission belt is wound around the grooves of the drive pulley and the driven pulley. In addition, a hydraulic pump having an engine as a drive source is connected to movable parts of the drive pulley and the driven pulley via a hydraulic control valve. By controlling the hydraulic control valve according to the operating state of the engine, the hydraulic pressure supplied from the hydraulic pump to at least one of the movable portion of the drive pulley and the driven pulley is controlled. As a result, the movable part moves and the effective diameter of the groove changes, whereby the transmission ratio is controlled steplessly and the transmission belt is sandwiched between the fixed part so as not to slip.
[0003]
In addition, this control device is configured to increase the clamping force of the transmission belt described above when the vehicle is traveling on a rough road. This is for the following purpose. In other words, when the vehicle is traveling on a rough road with severe irregularities, when the vehicle gets over the convex part, the drive wheel idles, the engine speed increases rapidly, and the drive wheel lands. An inertia torque is generated when the driving wheel receives a large rotational resistance from the road surface. This is because this inertia torque causes the rotational balance between the driving pulley and the driven pulley to be lost, so that a load is applied to the transmission belt and the transmission belt may slip, which is prevented.
[0004]
[Patent Document 1]
JP-A-4-285361
[0005]
[Problems to be solved by the invention]
However, according to the above-described conventional control device, when traveling on a rough road, while the transmission belt is loaded, the clamping force of the transmission belt is increased. It will be shorter. Further, when traveling on a rough road, inertia torque generated when the driving wheel is landed is transmitted to the internal combustion engine, so that the rotational speed of the internal combustion engine fluctuates, resulting in a decrease in drivability. In addition, the output of the hydraulic pump must be increased by the amount that increases the holding force of the transmission belt, which places a load on the engine and deteriorates fuel consumption. On rough roads, when the vehicle shakes violently, the accelerator pedal unintended and released by the driver is repeated in a short cycle. For this reason, when the throttle valve opening is controlled according to the depression state of the accelerator pedal, and the gear ratio of the continuously variable transmission is controlled according to the throttle valve opening, Since the throttle valve opening is controlled according to the stepping-in operation, the throttle valve opening fluctuates, and the gear ratio controlled accordingly fluctuates, so the engine speed fluctuates. As a result, drivability is degraded.
[0006]
The present invention has been made to solve such a problem, and can prevent the slippage of the transmission belt, extend the life of the transmission belt, and improve the fuel consumption and drivability. An object of the present invention is to provide a control device.
[0007]
[Means for Solving the Problems]
  In order to achieve this object, the invention according to claim 1 is connected to an internal combustion engine (an engine 4 in the embodiment (hereinafter, the same applies in this section)) and drive wheels 7 and 7 respectively mounted on a vehicle 3, and has an effective diameter. A drive pulley 22 and a driven pulley 23 having variable PDRD and PDND, and a transmission belt 24 wound around the drive pulley 22 and the driven pulley 23, and an effective diameter PDRD, PDND of at least one of the drive pulley 22 and the driven pulley 23. By changing the power of the internal combustion engine steplessly and transmitting it to the drive wheels 7, 7, and a frictional type provided between the internal combustion engine and the drive wheels 7, 7. A control device 1 for a vehicle 3 having a clutch (start clutch 30),Operating state detecting means (crank angle sensor 40, ECU 2, intake pipe absolute pressure sensor 42) for detecting the operating state of the internal combustion engine (engine speed NE, intake pipe absolute pressure PBA);Transmission transmission torque setting means (ECU2) for setting transmission transmission torque (driving side transmission torque TQDRBLTM, driven side transmission torque TQDNBLTM) to be transmitted from the driving pulley 22 to the driven pulley 23, and clutch transmission torque to be transmitted by the clutch Rough road running for determining whether or not the vehicle 3 is running on a rough road and clutch transmission torque setting means (ECU 2, steps 52, 55, 57, 59, 62 in FIG. 9) for setting (target hydraulic pressure PCCMDL) Determination means (ECU 2, steps 40 and 43 in FIG. 8), and the clutch transmission torque setting means applies the clutch when the rough road traveling determination means determines that the vehicle 3 is traveling on a rough road. The clutch transmission torque is reduced so as to slip (step 52 in FIG. 9), and the transmission transmission torque setting means isA first provisional value (driving side first provisional value TQDRBLTα, driven side first provisional value TQDNBLTα) is set according to the detected operating state of the internal combustion engine (steps 102 and 103 in FIG. 14), and according to the clutch transmission torque. The second provisional value (driving side second provisional value TQDRBLTβ, driven side second provisional value TQDNBLTβ) is set (steps 105 and 106 in FIG. 14), and among the set first provisional value and second provisional value, Is set as transmission transmission torque (steps 107 to 109 in FIG. 14).It is characterized by that.
[0008]
  According to this vehicle control device, the clutch transmission torque to be transmitted by the clutch is set by the clutch transmission torque setting means, and the transmission transmission torque to be transmitted from the driving pulley to the driven pulley is set to the transmission transmission torque setting. Set by means. Further, when it is determined that the vehicle is traveling on a rough road, the clutch transmission torque is reduced so as to slide the clutch. As a result, the inertia torque generated on the drive wheel when landing on a rough road can be released at the clutch portion and can be suppressed from being transmitted to the internal combustion engine, so that fluctuations in the rotational speed of the internal combustion engine can be suppressed. Therefore, drivability can be improved. Further, since the inertia torque can be released at the clutch portion in this way, it is possible to prevent the transmission belt from slipping and to reduce the load on the transmission belt, thereby extending its life. further,A first provisional value is set according to the detected operating state of the internal combustion engine, a second provisional value is set according to the clutch transmission torque, and a larger one of the set first provisional value and second provisional value is set. Is set as transmission transmission torque.
[0009]
  The invention according to claim 2 detects the opening TH of the throttle valve 8 controlled according to the opening of the accelerator pedal (accelerator opening AP) of the vehicle 3 in the vehicle control device 1 according to claim 1. Throttle valve opening degree detecting means (throttle valve opening degree sensor 41) for performing, and target gear ratio setting means (ECU2) for setting the target gear ratio RATTGT of the continuously variable transmission 20 according to the detected opening degree TH of the throttle valve. 11, step 72 in FIG. 11 and step 87 in FIG. 12) and the gear ratio control means (ECU 2, step 73 in FIG. 11) for controlling the gear ratio RATIO of the continuously variable transmission so as to become the set target gear ratio RATTGT. 12), and throttle valve opening correction means (ECU2, FIG. 1) for correcting the throttle valve opening TH when it is determined that the vehicle 3 is traveling on a rough road. And step 74) of, and further comprising a.
[0010]
  According to this configuration,A target gear ratio is set according to the opening of the throttle valve controlled according to the accelerator pedal opening, and the gear ratio of the continuously variable transmission is controlled so as to be the target gear ratio. Further, when it is determined that the vehicle is traveling on a rough road, the opening degree of the throttle valve is corrected. For this reason, when driving on rough roads, even if the throttle valve opening fluctuates in small increments as the accelerator pedal is depressed and released by the driver, the throttle valve opening is corrected. It is possible to prevent the target speed ratio set accordingly from fluctuating. As a result, the gear ratio of the continuously variable transmission and the rotational speed of the internal combustion engine can be stabilized, and drivability can be further improved.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a vehicle control apparatus according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows a schematic configuration of a drive system of a vehicle 3 to which the control device 1 according to the present embodiment is applied, and FIG. 2 shows a schematic configuration of the control device 1 and a hydraulic circuit 28 of the drive system. .
[0012]
As shown in FIG. 1, in the drive system of the vehicle 3, an engine 4 (internal combustion engine) as a power source includes a forward / reverse switching mechanism 10, a belt type continuously variable transmission 20, a starting clutch 30 (friction type clutch). ) And the differential gear mechanism 6 and the like, and is connected to the drive wheels 7 and 7, and the torque of the engine 4 is transmitted to the drive wheels 7 and 7 by the above configuration.
[0013]
The forward / reverse switching mechanism 10 includes an input shaft 11 and a planetary gear device 12 attached to the input shaft 11. One end of the input shaft 11 is connected to the crankshaft 4 a of the engine 4 via the flywheel 5 and penetrates through the hollow main shaft 21 in a rotatable manner. The planetary gear device 12 includes a sun gear 12a, a carrier 12d that rotatably supports a plurality of (for example, four) pinion gears 12b that mesh with the sun gear 12a, a ring gear 12c that meshes with each pinion gear 12b, and the like.
[0014]
The sun gear 12 a is provided integrally with the input shaft 11, and a portion of the input shaft 11 closer to the engine 4 than the sun gear 12 a is connected to the inner plate 13 a of the forward clutch 13. Further, the outer plate 13 b of the forward clutch 13 is connected to the ring gear 12 c and the main shaft 21. Engagement / disconnection of the forward clutch 13 is controlled by an ECU 2 described later. A reverse brake 14 is connected to the carrier 12d. The operation of the reverse brake 14 is also controlled by the ECU 2.
[0015]
With the above configuration, in the forward / reverse switching mechanism 10, when the vehicle 3 moves forward, the reverse brake 14 is released and the forward clutch 13 is engaged, whereby the input shaft 11 and the main shaft 21 are directly connected, and the input shaft 11 The rotation is transmitted as it is to the main shaft 21, and each pinion gear 12 b does not rotate around its axis, and the carrier 12 d rotates together with the input shaft 11 in the same direction. As described above, when the vehicle 3 moves forward, the main shaft 21 rotates in the same direction as the input shaft 11 at the same rotational speed.
[0016]
On the other hand, when the vehicle 3 moves backward, contrary to the above, the forward clutch 13 is disconnected and the reverse brake 14 is locked, so that the carrier 12d is locked so as not to rotate. Thereby, the rotation of the input shaft 11 is transmitted to the ring gear 12c via the sun gear 12a and the pinion gear 12b, whereby the ring gear 12c and the main shaft 21 connected thereto rotate in the opposite direction to the input shaft 11. As described above, when the vehicle 3 moves backward, the main shaft 21 rotates in the direction opposite to the input shaft 11.
[0017]
The continuously variable transmission 20 is of the so-called belt CVT type, and is the main shaft 21, the drive pulley 22, the driven pulley 23, the transmission belt 24, the counter shaft 25, the drive pulley width variable mechanism 26, and the driven pulley width variable mechanism 27. Etc.
[0018]
The drive pulley 22 has a frustoconical movable portion 22a and a fixed portion 22b. The movable portion 22a is attached to the main shaft 21 so as to be movable in the axial direction and relatively non-rotatable. The fixed portion 22b is disposed so as to face the movable portion 22a and is fixed to the main shaft 21. Has been. In addition, the opposing surfaces of the movable portion 22a and the fixed portion 22b are each formed in a slope shape, so that a V-shaped for winding the transmission belt 24 between the movable portion 22a and the fixed portion 22b. A belt groove is formed.
[0019]
The drive pulley width variable mechanism 26 changes its effective diameter PDRD (see FIG. 3) by changing the pulley width of the drive pulley 22, and DR (drive side) oil formed in the movable portion 22a. A chamber 26a, a DR electromagnetic valve 26b for controlling the hydraulic pressure supplied to the DR oil chamber 26a, a return spring (not shown) for urging the movable portion 22a toward the fixed portion 22b, and the like are provided.
[0020]
As shown in FIG. 2, the DR solenoid valve 26b is provided between the hydraulic pump 28a of the hydraulic circuit 28 and the DR oil chamber 26a, and is connected to these via oil passages 28b and 28b, respectively. The hydraulic pump 28 a is connected to the crankshaft 4 a of the engine 4, and discharges hydraulic pressure by being driven by the crankshaft 4 a during the operation of the engine 4. Thus, during operation of the engine 4, the hydraulic pressure discharged from the hydraulic pump 28a is always supplied to the DR electromagnetic valve 26b via the oil passage 28b.
[0021]
The DR electromagnetic valve 26b is a normally open type that combines a solenoid and a spool valve (both not shown), and is configured so that the valve opening degree can be set linearly. Further, the DR electromagnetic valve 26b is controlled by the ECU 2 to control the hydraulic pressure supplied from the hydraulic pump 28a to the DR oil chamber 26a via the oil passage 28b so as to become the driving side operating hydraulic pressure DROIL.
[0022]
With the above configuration, in the drive pulley variable width mechanism 26, the DR electromagnetic valve 26b is controlled by the ECU 2 during the operation of the engine 4, whereby the movable portion 22a is driven in the axial direction. As a result, the force with which the movable portion 22a presses the transmission belt 24 against the fixed portion 22b is controlled, so that the effective diameter PDRD of the drive pulley 22 has a small diameter for the low speed side gear ratio shown in FIG. It is changed steplessly between the large diameter for the high speed side gear ratio shown in FIG. When the supply of hydraulic pressure to the DR oil chamber 26a by the DR solenoid valve 26b is stopped, the drive pulley 22 is held at an effective diameter PDRD in which the urging force of the return spring and the tension of the transmission belt 24 are balanced. The
[0023]
The driven pulley 23 is configured in the same manner as the drive pulley 22. That is, the driven pulley 23 has a frustoconical movable portion 23a and a fixed portion 23b. The movable portion 23a is attached to the counter shaft 25 so as to be movable in the axial direction and non-rotatable, and the fixed portion 23b is disposed so as to face the movable portion 23a and is fixed to the counter shaft 25. . In addition, the opposing surfaces of the movable portion 23a and the fixed portion 23b are each formed in a slope shape, so that a V-shaped belt for winding the transmission belt 24 between the movable portion 23a and the fixed portion 23b is formed. A belt groove is formed. The transmission belt 24 is made of metal and is wound around the pulleys 22 and 23 while being fitted in the belt grooves of the pulleys 22 and 23.
[0024]
The driven pulley width variable mechanism 27 changes the effective diameter PDND (see FIG. 4) by changing the pulley width of the driven pulley 23, and is configured similarly to the drive pulley width variable mechanism 26. . That is, the driven pulley width variable mechanism 27 includes a DN (driven side) oil chamber 27a formed in the movable portion 23a, a DN electromagnetic valve 27b for controlling the hydraulic pressure supplied to the DN oil chamber 27a, A return spring (not shown) for urging the movable portion 23a toward the fixed portion 23b is provided.
[0025]
The DN solenoid valve 27b is provided between the hydraulic pump 28a of the hydraulic circuit 28 and the DN oil chamber 27a of the movable portion 23a, and is connected to these via oil passages 28b and 28b, respectively. Thereby, during operation of the engine 4, the hydraulic pressure discharged from the hydraulic pump 28a is always supplied to the DN electromagnetic valve 27b via the oil passage 28b. This DN electromagnetic valve 27b is a normally open type linear electromagnetic valve in which a solenoid and a spool valve (both not shown) are combined, like the DR electromagnetic valve 26b. Further, the DN electromagnetic valve 27b is controlled by the ECU 2 to control the hydraulic pressure supplied from the hydraulic pump 28a to the DN oil chamber 27a via the oil passage 28b so as to become the driven side operating hydraulic pressure DNOIL.
[0026]
With the above configuration, in the driven pulley width variable mechanism 27, the movable portion 23 a is driven in the axial direction by controlling the DN electromagnetic valve 27 b by the ECU 2 during operation of the engine 4. As a result, the force with which the movable portion 23a presses the transmission belt 24 against the fixed portion 23b is controlled, so that the effective diameter PDND of the driven pulley 23 has a large diameter for the low speed side gear ratio shown in FIG. It is changed steplessly between the small diameter for the high speed side gear ratio shown in FIG. When the hydraulic pressure supply to the DN oil chamber 27a by the DN electromagnetic valve 27b is stopped, the driven pulley 23 is held at an effective diameter PDND that balances the urging force of the return spring and the tension of the transmission belt 24. .
[0027]
As described above, in the continuously variable transmission 20, the two solenoid valves 26b and 27b are controlled by the ECU 2, whereby the effective diameters PDRD and PDND of the two pulleys 22 and 23 are changed steplessly. A speed ratio RATIO (= NDR / NDN), which is a ratio of the drive pulley rotation speed NDR of the drive pulley 22 and the driven pulley rotation speed NDN of the driven pulley 23, is controlled steplessly. Specifically, the gear ratio RATIO is controlled to be a value within a predetermined range (for example, 0.4 to 2.5).
[0028]
The starting clutch 30 is a hydraulically controlled friction type multi-plate clutch that is controlled to be engaged / disengaged by supplying hydraulic pressure, and includes a large number of inner plates 31, a large number of outer plates 32, and these plates 31, 32. A clutch fastening mechanism 33 that fastens and shuts the gap between the two plates 31 and 32, and a return spring (not shown) that biases the plates 31 and 32 in a direction that cuts the gap between them. These inner plates 31 are connected to a gear 34 that is rotatably provided on the counter shaft 25, and rotate integrally therewith as the gear 34 rotates. The outer plate 32 is connected to the counter shaft 25 and rotates integrally with the counter shaft 25 as the counter shaft 25 rotates.
[0029]
The clutch fastening mechanism 33 includes a clutch oil chamber 33a and an SC electromagnetic valve 33b. As shown in FIG. 2, the SC solenoid valve 33b is provided between the hydraulic pump 28a of the hydraulic circuit 28 and the clutch oil chamber 33a, and is connected to these via oil passages 28b and 28b, respectively.
[0030]
The SC solenoid valve 33b is a normally closed type that combines a solenoid and a spool valve (both not shown), and is configured as a linear solenoid valve whose valve opening can be set linearly. The SC solenoid valve 33b is controlled by the ECU 2 so that the hydraulic pressure supplied from the hydraulic pump 28a to the clutch oil chamber 33a via the oil passage 28b is controlled to the target hydraulic pressure PCCMDL (clutch transmission torque). To do. The gear 34 meshes with the gear 6 a of the differential gear mechanism 6 via large and small idler gears 35 a and 35 b provided on the idler shaft 35.
[0031]
With the above configuration, when the SC solenoid valve 33b is excited under the control of the ECU 2 during operation of the engine 4, hydraulic pressure is supplied to the clutch oil chamber 33a, and a frictional force is generated between the inner plate 31 and the outer plate 32. Thus, the starting clutch 30 is fastened. As a result, the rotation and torque of the countershaft 25 are transmitted to the drive wheels 7 and 7. At that time, in the start clutch 30, the greater the hydraulic pressure supplied to the clutch oil chamber 33a, the greater the fastening force of the start clutch 30, and when the supply of hydraulic pressure is stopped, the start clutch 30 is driven by the urging force of the return spring. 30 is held in the shut-off state.
[0032]
The intake pipe 4b of the engine 4 is provided with a throttle valve 8, and this throttle valve 8 is connected to a rotating shaft of a motor 9 constituted by a DC motor. The opening degree TH of the throttle valve 6 (hereinafter referred to as “throttle valve opening degree”) TH is controlled by controlling the duty value of the drive current supplied to the motor 9 by the ECU 2.
[0033]
  In addition, the ECU 2 includes a crank angle sensor 40.(Operating state detection means), Throttle valve opening sensor 41, intake pipe absolute pressure sensor 42(Operating state detection means)The accelerator opening sensor 43, the driving pulley rotational speed sensor 44, the driven pulley rotational speed sensor 45, the idler shaft rotational speed sensor 46, and the shift position sensor 47 are electrically connected.
[0034]
The crank angle sensor 40 is configured by combining a magnet rotor and an MRE pickup (both not shown), and outputs a CRK signal, which is a pulse signal, to the ECU 2 as the crankshaft 4a rotates. The CRK signal is output with one pulse every predetermined crank angle (for example, 30 °), and the ECU 2 calculates the engine speed NE of the engine 4 based on the CRK signal.
[0035]
The throttle valve opening sensor 41 (throttle valve opening detection means) opens the throttle valve opening TH, and the intake pipe absolute pressure sensor 42 opens the intake pipe absolute pressure PBA, which is the absolute pressure in the intake pipe 4b of the engine 4, and opens the accelerator. The degree sensor 43 detects an accelerator opening AP (an accelerator pedal opening) that is a depression amount of an accelerator pedal (not shown) of the vehicle 3, and sends a detection signal to the ECU 2. Further, the ECU 2 controls the throttle valve opening TH according to the accelerator opening AP.
[0036]
Further, the drive side pulley speed sensor 44 is a drive side pulley speed NDR which is the speed of the drive pulley 22, and the driven side pulley speed sensor 45 is a driven side pulley speed NDN which is the speed of the driven pulley 23. The idler shaft rotational speed sensor 46 detects an idler shaft rotational speed NDI, which is the rotational speed of the idler shaft 35, and sends a detection signal to the ECU 2. The ECU 2 calculates the gear ratio RATIO based on the driving pulley rotation speed NDR and the driven pulley rotation speed NDN. Further, the ECU 2 calculates the slip ratio ESC of the starting clutch 30 based on the driven pulley rotational speed NDN and the idler shaft rotational speed NDI, and calculates the vehicle speed VP based on the idler shaft rotational speed NDI.
[0037]
The shift position sensor 47 detects whether the position of a shift lever (not shown) is in a shift range “P”, “R”, “N”, “D”, “S (sports)”, or “L”. Is sent to the ECU 2. The S range is a shift range for forward travel. When the shift lever is in the S range, the gear ratio RATIO is controlled to a value slightly higher than the D range.
[0038]
  In the present embodiment, the ECU 2Operating state detection means,The transmission transmission torque setting means, the clutch transmission torque setting means, the rough road determination means, the target gear ratio setting means, the gear ratio control means, and the throttle valve opening correction means are configured. The CPU, RAM, ROM, and I / Consists of a microcomputer composed of an O interface, etc., and sets the drive side and driven side hydraulic oil pressures DROIL and DNOIL and the target hydraulic pressure PCCMDL according to detection signals input from the various sensors 40 to 47 described above. The drive-side transmission torque TQDRBLTM (transmission transmission torque) to be transmitted from the drive pulley 22 to the driven pulley 23 and the driven-side transmission torque TQDNBLTM (transmission transmission torque) to be transmitted from the driven pulley 23 to the drive wheels 7 and 7 For controlling the gear ratio RATIO Set the target gear ratio RATTGT, controls the shift operation of the continuously variable transmission 20.
[0039]
FIG. 5 is a flowchart showing the operating oil pressure setting process. In step 81, the driving side hydraulic pressure DROIL is set according to the driving side transmission torque TQDRBLTM, and the driven side hydraulic pressure DNOIL is set according to the driven side transmission torque TQDNBLTM. These drive side and driven side hydraulic pressures DROIL and DNOIL are set to larger values as the drive side and driven side transmission torques TQDRBLTM and TQDNBLTM are larger. This is because, as the torque to be transmitted by the drive pulley 22 and the driven pulley 23 is larger, the transmission belt 24 is more likely to slip. Therefore, by increasing the force with which the drive pulley 22 and the driven pulley 23 sandwich the transmission belt 24, This is to prevent the belt 24 from slipping.
[0040]
FIG. 6 is a flowchart showing transmission transmission torque calculation processing. This process calculates the drive side transmission torque TQDRBLTM and the driven side transmission torque TQDNBLTM, and is executed every predetermined time (for example, 10 msec). First, in step 1, a margin torque correction term calculation process is executed. In this process, the margin torque correction term TQMARGP is calculated as will be described later. Next, at step 2, the drive side transmission torque TQDRBLTM is calculated by the following equation (1) using the margin torque correction term TQMARGP and the like.
TQDRBLTM = TQDRBLTF + TQMARGP (1)
Here, TQDRBLTF is a basic value of drive-side transmission torque TQDRBLTM set according to engine speed NE and intake pipe absolute pressure PBA.
[0041]
Next, in step 3, the driven side transmission torque TQDNBLTM is calculated by the following equation (2) using the margin torque correction term TQMARGP, the gear ratio RATIO, and the program is terminated.

Here, TQDNBLTF is a basic value of the driven side transmission torque TQDNBLTM set as a value obtained by multiplying the basic value TQDRBLTF of the driving side transmission torque calculated in Step 2 by the speed ratio RATIO.
[0042]
FIG. 7 is a flowchart showing a subroutine of margin torque correction term calculation processing executed in step 1 of FIG. First, in step 11, a rough road determination process is executed. FIG. 8 is a flowchart showing a subroutine of this rough road determination process. First, in step 31, the deviation between the current value DTV and the previous value DTV0 of the vehicle speed change amount, which is the deviation of the vehicle speed VP detected at the previous time and the current time, is set as the change amount deviation DDTV. Next, the vehicle speed change amount DTV obtained this time is shifted as its previous value DTV0 (step 32).
[0043]
Next, it is determined whether or not the pointer value CTDDTV is smaller than a predetermined value YDDTVBF (for example, 8) (step 33). When the answer is YES, the pointer value CTDDTV is incremented (step 34) and the process proceeds to step 35. If this answer is NO, step 34 is skipped and the process proceeds to step 35. The pointer value CTDDTV is set to 0 when the engine 4 is started.
[0044]
In steps 35 and 36, whether or not the throttle valve opening TH is within the range defined by the predetermined first and second determination openings YTHAKUL and YTHAKUH, and the amount of change set in step 31 above. It is determined whether or not the deviation absolute value | DDTV | is equal to or greater than a predetermined value YDDTVAKU. This predetermined value YDDTVAKU is a value larger than the range in which the amount of change in the acceleration of the vehicle 3 is to be taken when the throttle valve 8 is within the predetermined range when the vehicle 3 is traveling on a paved road surface. Is set to
[0045]
If any of the answers to Steps 35 and 36 is NO, it is temporarily determined that the vehicle 3 is not traveling on a rough road, the bit of the buffer DDTVBF is shifted, and the value 0 is set to the 0 bit (Step 37). The process proceeds to step 39.
[0046]
On the other hand, if the answer to steps 35 and 36 is YES, the throttle valve opening TH is within the predetermined range, and the absolute value | DDTV | of the amount of change is equal to or greater than the predetermined value YDDTVAKU, It is temporarily determined that the vehicle is traveling on a rough road, the bit of the buffer DDTVBF is shifted, a value 1 is set to 0 bit (step 38), and the process proceeds to step 39.
[0047]
In step 39, it is determined whether or not the pointer value CTDDTV is equal to or greater than the predetermined value YDDTVBF. When this answer is NO, the rough road determination flag F_AKURO is set to “0” (step 40), and this program is terminated.
[0048]
If the answer to step 39 is YES and the execution of 37 or 38 ensures that a number of data equal to or larger than the predetermined value YDDTVBF is secured in the buffer DDTVBF, the sum total of the latest data corresponding to the predetermined value YDDTVBF is set as a bad road. The provisional determination number of times CDTTVAKU is set (step 41).
[0049]
Next, it is determined whether or not the rough road temporary determination number CDTTVAKU is equal to or greater than a predetermined number YCTAKU (for example, four times) (step 42). If the answer is YES, a state in which the throttle valve opening TH is within a predetermined range and the vehicle speed change amount DTV is greatly changed within a time corresponding to the predetermined value YDDTVBF is detected a predetermined number of times YCTAKU or more. Since such a state is frequently detected, it is assumed that the vehicle 3 is traveling on a rough road, the rough road determination flag F_AKURO is set to “1” (step 43), and this program is terminated. . The predetermined number of times YCTAKU is set to a value with hysteresis.
[0050]
If the answer to step 42 is NO, it is determined that the vehicle 3 is not traveling on a rough road, the step 40 is executed, and the program is terminated.
[0051]
Returning to FIG. 7, in step 12 following step 11, it is determined whether or not the position of the shift lever is in the travel range, that is, “D”, “S”, or “R”. When the answer is NO, the margin torque correction term TQMARGP is set to 0 (step 13), the timer value TMTQMGP of the down-count delay timer is set to 0 (step 14), and this program is terminated. On the other hand, when the answer to step 12 is YES and the position of the shift lever is in the travel range, the aforementioned slip ratio ESC of the start clutch 30 is a predetermined slip ratio ESCREF (for example, 100%) indicating that no slip has occurred. Is determined (step 15).
[0052]
If the answer is NO and the start clutch 30 is slipping, it is determined whether or not the margin torque correction term TQMARGP is larger than 0 (step 16). When this answer is NO, the margin torque correction term TQMARGP is set to a relatively small initial value TQ1 (eg, 2.0 N · m) (step 17), and the timer value TMTQMGP of the delay timer is set to the first predetermined time YTTQMTIN (eg, 0). .6 sec) (step 18), the process proceeds to step 19. In addition, after executing Step 17, the answer to Step 16 is YES. In this case, Steps 17 and 18 are skipped and the process proceeds to Step 19.
[0053]
In step 19, it is determined whether or not the timer value TMTQMGP of the delay timer set in step 18 is 0. If the answer is no, the program is terminated as it is. On the other hand, if the answer is YES and the first predetermined time YTTQMTIN has elapsed after the delay timer TMTQMGP has been set, a predetermined subtraction term YDTQMARGP (for example, 0.01 kgf · m) is subtracted from the surplus torque correction term TQMARGP at that time. The value is set as the current margin torque correction term TQMARGP (step 20), and the program is terminated.
[0054]
On the other hand, if the answer to step 15 is YES and the start clutch 30 is not slipping, the deviation DTH between the current value and the previous value of the throttle valve opening TH is equal to or greater than a first predetermined value YDTHTQP (for example, 20 °), Further, it is determined whether or not the throttle valve opening TH is equal to or greater than the first predetermined opening YTHTQP (for example, 20 °) (step 21). The first predetermined value YDTHTQP and the first predetermined opening YTHTQP are set to values with hysteresis, respectively.
[0055]
If the answer is YES, the deviation DTH of the throttle valve opening TH is very large and the throttle valve opening TH is very large (hereinafter, this state is referred to as “chip-in”), that is, the throttle valve 8 is When the valve is suddenly opened, it is assumed that the amount of change in the output of the engine 4 has increased abruptly. On the other hand, when this answer is NO, the deviation DTH of the throttle opening TH is smaller than a negative second predetermined value YDTHTQM (for example, −20 °), and the throttle valve opening TH is the first predetermined opening. It is determined whether it is smaller than a second predetermined opening degree YTHTQM (for example, 10 °) smaller than the degree YTHTQP (step 22). The second predetermined value YDTHTQM and the second predetermined opening degree YTHTQM are also set to values with hysteresis, respectively.
[0056]
When the answer is YES, the deviation DTH of the throttle valve opening TH is a negative value, the absolute value thereof is very large, and the throttle valve opening TH is very small (hereinafter, this state is referred to as “chip out”). That is, when the throttle valve 8 is suddenly closed, it is assumed that the amount of change in the output of the engine 4 is rapidly decreasing, and the above step 16 and subsequent steps are executed, and this program is terminated. On the other hand, when the answer is NO, it is determined whether or not the rough road determination flag F_AKURO set in the rough road determination processing of FIG. 8 is “1” (step 23). If the answer to this question is YES and it is determined that the vehicle 3 is traveling on a rough road, step 16 and the subsequent steps are executed, and this program is terminated.
[0057]
On the other hand, if the answer to step 23 is NO, the start clutch 30 is engaged, it is not during tip-in and chip-out, and it is determined that the vehicle 3 is not traveling on a rough road, step 13 and subsequent steps are performed. Execute and end this program.
[0058]
As described above, when it is determined that the vehicle 3 is traveling on a rough road during tip-in, chip-out, or when the start clutch 30 is slipping, the margin torque correction term TQMARGP is set to a relatively small initial value. Set to TQ1. Then, by applying this margin torque correction term TQMARGP to the previous equations (1) and (2), the driving side and driven side transmission torques TQDRBLTM and TQDNBLTM are slightly increased. Thereby, it is possible to reliably prevent the transmission belt 24 from slipping. Further, the margin torque correction term TQMARGP is maintained at the initial value TQ1 until the first predetermined time YTTQMTIN elapses, and then gradually decreased by application of the subtraction term YDTQMARGP.
[0059]
FIG. 9 is a flowchart showing a PCCMDL calculation process for calculating the target hydraulic pressure PCCMDL for controlling the engagement force of the starting clutch 30 described above. First, in step 51, it is determined whether or not the rough road determination flag F_AKURO set in the rough road determination process of FIG. 8 is “1”. If the answer is YES and it is determined that the vehicle 3 is traveling on a rough road, the target hydraulic pressure PCCMDL is set to a predetermined reduction coefficient α (for example, 0.8) that is smaller than 1.0 in the basic value PCCMD. Is set to the multiplied value (step 52), and the program is terminated. Thereby, at the time of bad road determination, the starting clutch 30 slips by reducing the fastening force of the starting clutch 30. The basic value PCCMD is set as a value obtained by adding the urging force of the return spring of the starting clutch 30 to the product of the engine torque, the speed ratio RATIO, and a predetermined coefficient, and this is applied to the target hydraulic pressure PCCMDL. In this case, a sufficient fastening force of the starting clutch 30 is obtained, and the starting clutch 30 does not slip. The engine torque is set according to the engine speed NE and the intake pipe absolute pressure PBA.
[0060]
On the other hand, if the answer to step 51 is NO and F_AKURO = 0, it is determined whether or not this time is a loop immediately after shifting to chip-in or chip-out (step 53). When the answer is YES, the timer value TMTRS of the down-count delay timer is set to a second predetermined time TMREF (for example, 0.5 sec) (step 54), and the target hydraulic pressure PCCMDL is changed from the basic value PCCMD to the predetermined value PCTH. (For example, 1 kgf / cm²) Is set to an initial value which is a value obtained by subtracting (step 55), and the program ends. Thereby, the starting clutch 30 is slipped by reducing the fastening force of the starting clutch 30.
[0061]
On the other hand, if the answer to step 53 is NO and not immediately after the transition to chip-in or chip-out, it is determined whether or not the slip ratio ESC is the predetermined slip ratio ESCREF used in step 15 of FIG. 7 (step 56). . If the answer is NO and the start clutch 30 is slipping due to the execution of the step 55, it is determined whether or not the timer value TMTRS of the delay timer set in the step 54 is a value 0 (step 58).
[0062]
If the answer is NO and the second predetermined time TMREF has not elapsed after the transition to chip-in or chip-out, the previous value PCCMDL0 of the target hydraulic pressure is set as the current value PCCMDL (step 59), and this program ends. To do. On the other hand, when the answer to step 58 is YES, it is determined whether or not the previous value PCCMDL0 of the target hydraulic pressure is smaller than the basic value PCCMD (step 60).
[0063]
If the answer is YES and PCCMDL0 <PCCMD, the correction addition term ΔPC is calculated (step 61). This correction addition term ΔPC is calculated by searching the ESC-ΔPC table shown in FIG. 10 according to the slip ratio ESC. In this table, the correction addition term ΔPC is a maximum value PCMAX (for example, 0.5 kgf / cm) when the slip ratio ESC is a predetermined slip ratio ESCREF.²) And the slip rate ESC is linearly set to a smaller value as the slip rate ESC is further away from the predetermined slip rate ESCREF.
[0064]
Next, a value obtained by adding the correction addition term ΔPC calculated in step 61 to the previous value PCCMDL0 of the target hydraulic pressure is calculated as the target hydraulic pressure PCCMDL (step 62), and this program ends.
[0065]
On the other hand, when the answer to step 60 is NO and the target hydraulic pressure PCCMDL calculated in step 62 reaches the basic value PCCMD, the target hydraulic pressure PCCMDL is set to the basic value PCCMD (step 57), and this program is terminated. .
[0066]
On the other hand, if the answer to step 56 is YES and the start clutch 30 is no longer slipped, the target hydraulic pressure PCCMDL is set to the basic value PCCMD (step 57), and the program ends.
[0067]
As described above, the target hydraulic pressure PCCMDL is set to an initial value obtained by subtracting the predetermined value PCTH from the basic value PCCMD when chip-in or chip-out is detected, and thereafter, until the second predetermined time TMREF elapses. After being held at the initial value, the correction addition term ΔPC is added to gradually increase until the basic value PCCMD is reached.
[0068]
FIG. 11 is a flowchart showing a gear ratio control process for controlling the gear ratio RATIO of the continuously variable transmission 20. First, in step 71, it is determined whether or not a rough road determination flag F_AKURO is “1”. When the answer is NO, the target gear ratio RATTGT is set by searching the CVT shift map according to the vehicle speed VP and the throttle valve opening TH (step 72). Further, the drive side and driven side hydraulic oil pressures DROIL and DNOIL are controlled so that the actual speed ratio RATIO matches the set target speed ratio RATTGT (step 73), and this program is terminated.
[0069]
On the other hand, if the answer to step 71 is YES and it is determined that the vehicle 3 is traveling on a rough road, the throttle valve opening TH used for searching the CVT shift map is filtered (step 74). ) And the above steps 72 and after are executed, and this program is terminated. This filtering process is performed by a weighted average, a moving average, a primary filter, or the like. Detailed description thereof will be omitted.
[0070]
As described above, according to the present embodiment, the required hydraulic pressure PCCMDL is reduced by multiplying the basic value PCCMD by the reduction coefficient α at the time of rough road determination by executing the steps 51 and 52 in FIG. Since the start clutch 30 is slid, the inertia torque generated on the drive wheels 7 and 7 at the time of landing can be released at the start clutch 30 and transmitted to the engine 4, thereby reducing the engine speed. NE fluctuations can be suppressed, and therefore drivability can be improved. In addition, since the inertia torque can be released at the start clutch 30 in this way, the transmission belt 24 can be prevented from slipping and the load on the transmission belt 24 can be reduced, whereby the driving side and driven side hydraulic pressures DROIL and DNOIL are reduced. There is no need to increase the power more than necessary. Therefore, the life of the transmission belt 24 can be extended and the fuel consumption can be improved.
[0071]
Further, by executing the step 74, the throttle valve opening TH used for searching the CVT shift map at the time of rough road determination is subjected to a filter process, whereby the accelerator opening AP due to rough road running is applied. The influence of the fluctuation on the throttle valve opening TH can be removed by this filter processing. Thereby, fluctuations in the target gear ratio RATTGT set according to the throttle valve opening TH can be prevented, and therefore the gear ratio RATIO and the engine speed NE can be stabilized.
[0072]
Further, by executing steps 53 and 55, the required hydraulic pressure PCCMDL is reduced and the starting clutch 30 is slid by subtracting the predetermined value PCTH from the basic value PCCMD at the time of chip-in and chip-out. The output torque of the engine 4 can be released at the start clutch 30 portion. Accordingly, since it is not necessary to transmit the output torque that has fluctuated rapidly through the continuously variable transmission 20, it is possible to prevent the transmission belt 24 from slipping and to reduce the load on the transmission belt 24. There is no need to increase the driven hydraulic oil pressures DROIL and DNOIL more than necessary. Therefore, also in this case, the same effect as that at the time of rough road determination can be obtained. Further, the slip control of the starting clutch 30 does not cause a jerky feeling when the accelerator pedal is suddenly depressed or released, so that drivability can be maintained.
[0073]
In addition, the correction addition term ΔPC that gradually increases the required hydraulic pressure PCCMDL by the execution of the steps 61 and 62 becomes smaller as the slip ratio ESC moves away from the predetermined slip ratio ESCREF, that is, as the slip degree of the start clutch 30 increases. Therefore, the required hydraulic pressure PCCMDL is set to a smaller value in the initial stage when the slipping degree of the starting clutch 30 is large, and gradually increases as the slipping degree of the starting clutch 30 becomes smaller. Can be connected. Therefore, the occurrence of inertia torque due to the sudden engagement of the starting clutch 30 can be avoided, so that it is not necessary to set the driving side and driven side hydraulic oil pressures DROIL and DNOIL to be high. Furthermore, since the start clutch 30 is smoothly connected after waiting for the output of the engine 4 that has fluctuated to settle down by executing the step 58, the occurrence of the inertia torque can be avoided more reliably.
[0074]
FIG. 12 shows a modification of the gear ratio control process of FIG. In this embodiment, since the throttle valve opening TH is controlled in accordance with the accelerator opening AP in this embodiment, the accelerator opening AP is corrected instead of the throttle valve opening TH. First, in step 85, it is determined whether or not the rough road determination flag F_AKURO is “1”. When the answer is NO, the throttle valve opening TH is controlled in accordance with the accelerator opening AP (step 86), and the target gear ratio RATTGT is set in the same manner as in step 72 (step 87). Similarly, the drive-side and driven-side hydraulic oil pressures DROIL and DNOIL are controlled so that the actual gear ratio RATIO matches the calculated target gear ratio RATTGT (step 88), and this program ends.
[0075]
On the other hand, when the answer to step 85 is YES and it is determined that the vehicle 3 is traveling on a rough road, the accelerator pedal opening AP is subjected to filter processing (step 89), and the steps 86 and thereafter are executed. Exit this program. This filtering process is also performed by a weighted average, a moving average, a primary filter, or the like.
[0076]
In this way, by filtering the accelerator pedal opening AP at the time of rough road determination, even if the accelerator pedal unintended or released by the driver is performed, the fluctuation of the accelerator pedal opening AP caused by the filter is filtered. Therefore, the throttle valve opening TH does not fluctuate. Therefore, the gear ratio RATIO and the engine speed NE can be stabilized also in this case.
[0077]
Next, a second embodiment of the present invention will be described with reference to FIG. Since this embodiment is different from the first embodiment only in the content of the transmission transmission torque calculation process, this point will be described below. First, in step 91, it is determined whether or not the slip ratio ESC is a predetermined slip ratio ESCREF. If the answer is YES and the start clutch 30 is engaged without slipping, the driving side and driven side transmission torques TQDRBLTM and TQDNBLTM are set to the basic values TQDRBLTF and TQDNBLTF in steps 92 and 93, respectively. finish. These basic values TQDRBLTF and TQDNBLTF are calculated in the same manner as Steps 2 and 3 in FIG.
[0078]
On the other hand, if the answer to step 91 is NO and the start clutch 30 is slipping, the clutch transmission torque TQCL is calculated according to the target hydraulic pressure PCCMDL (step 94). The clutch transmission torque TQCL is a torque that the start clutch 30 should transmit to the drive wheels 7 and 7, and is calculated in a linear relationship with a larger value as the target hydraulic pressure PCCMDL is larger.
[0079]
Next, it is determined whether or not the rough road determination flag F_AKURO is “1” (step 95). If the answer is NO and it is determined that the vehicle 3 is not traveling on a rough road, it is determined whether or not the timer value TMTRS of the delay timer set in step 54 of FIG. Step 96). If the answer is NO and the second predetermined time TMREF has not elapsed after the transition to chip-in or chip-out, the clutch transmission torque TQCL is set as the drive-side transmission torque TQDRBLTM (step 97).
[0080]
On the other hand, when the answer to step 96 is YES, a value obtained by adding a predetermined addition term β to the clutch transmission torque TQCL is set as the drive side transmission torque TQDRBLTM (step 98). If the answer to step 95 is YES and it is determined that the vehicle 3 is traveling on a rough road, the step 96 is skipped and the step 98 is executed.
[0081]
In Step 99 following Step 97 or 98, the driven side transmission torque TQDNBLTM is set to a value obtained by multiplying the driving side transmission torque TQDRBLTM by the speed ratio RATIO, and the program is terminated.
[0082]
As described above, the target hydraulic pressure PCCMDL is reduced at the time of chip-in, chip-out, or rough road determination (steps 52 and 55 in FIG. 9). Based on this target hydraulic pressure PCCMDL, the clutch transmission torque TQCL is calculated (step 94), and the drive side and driven side transmission torques TQDRBLTM and TQDNBLTM are set accordingly (steps 98 and 99). Drive side and driven side hydraulic pressures DROIL and DNOIL are set (step 81 in FIG. 5). Therefore, at the time of tip-in, chip-out, or rough road determination, the driving side and driven side hydraulic oil pressures DROIL and DNOIL can be set to the reduction side without excess or deficiency according to the reduced target oil pressure PCCMDL, and fuel consumption can be improved.
[0083]
In addition, after execution of steps 96 to 99, after shifting to chip-in or chip-out, until the second predetermined time TMREF elapses, that is, until the slidable starting clutch 30 is re-engaged by the time count of the delay timer. Then, after the drive side transmission torque TQDRBLTM is set to the clutch transmission torque TQCL and then the start clutch 30 is started again, the value obtained by adding the addition term β to the clutch transmission torque TQCL is set as the drive side transmission torque TQDRBLTM. Therefore, even if an inertia torque is generated due to the re-engagement of the starting clutch 30, it is possible to reliably prevent the transmission belt 24 from slipping and to prevent the drive side and driven side hydraulic oil pressures DROIL and DNOIL from being increased unnecessarily. Can and therefore further improve fuel economy Door can be.
[0084]
  Next, a third embodiment of the present invention will be described with reference to FIG. Since the present embodiment is different from the first embodiment only in the content of the transmission transmission torque calculation process as in the second embodiment, only this point will be described. First, in step 101, a margin torque correction term calculation process is executed as in FIG. Next, in step 102, a value obtained by adding the margin torque correction term TQMARGP to the basic value TQDRBLTF of the drive side transmission torque calculated in the same manner as in step 2 of FIG. 6 is used as the drive side first provisional value TQDRBLTα.(First provisional value)Set as. Next, a value obtained by multiplying the drive side first provisional value TQDRBLTα by the transmission ratio RATIO is set as a driven side first provisional value TQDNBLTα.(First provisional value)(Step 103).
[0085]
  Next, the clutch transmission torque TQCL is calculated in the same manner as in step 94 of FIG. 13 (step 104), and a value obtained by adding a predetermined addition term γ to the clutch transmission torque TQCL is obtained as a drive side second provisional value TQDRBLTβ.(Second provisional value(Step 105), and a value obtained by multiplying the drive side second provisional value TQDRBLTβ by the speed ratio RATIO is set as a driven side second provisional value TQDNBLTβ.(Second provisional value)(Step 106).
[0086]
Next, the drive side first provisional value TQDRBLTα set in steps 102 and 105 is compared with the drive side second provisional value TQDRBLTβ (step 107). If the former TQDRBLTα is larger, the drive side transmission torque TQDRBLTM is calculated. And the driven side first provisional value TQDNBLTα is set as the driven side transmission torque TQDNBLTM (step 108). On the other hand, when the drive-side second provisional value TQDRBLTβ is larger, this is set as the drive-side transmission torque TQDRBLTM, and the driven-side second provisional value TQDNBLTβ is set as the driven-side transmission torque TQDNBLTM (step 109). Exit.
[0087]
As described above, according to the present embodiment, the drive side first provisional value TQDRBLTα calculated according to the operating state of the engine 4 and the drive side second provisional value TQDRBLTβ calculated according to the clutch transmission torque TQCL. Of these, the larger one is employed as the drive-side transmission torque TQDRBLTM, so that the transmission belt 24 can be prevented from slipping.
[0088]
In addition, this invention can be implemented in various aspects, without being limited to the described embodiment. For example, the present embodiment is an example of the vehicle 3 in which the starting clutch 30 is provided on the drive wheel 7 side with respect to the continuously variable transmission 20, but instead, the present invention is arranged between the engine and the drive pulley. You may apply to the vehicle which provided the starting clutch. In addition, it is possible to appropriately change the detailed configuration within the scope of the gist of the present invention.
[0089]
【The invention's effect】
As described above, according to the vehicle control device of the present invention, it is possible to extend the life of the transmission belt while preventing the transmission belt from slipping, and to improve the fuel consumption and drivability. Have.
[Brief description of the drawings]
FIG. 1 is a structural diagram of a vehicle drive system.
FIG. 2 is a diagram showing a schematic configuration of a control device and a hydraulic circuit of a drive system.
FIG. 3 is a diagram illustrating an operation example of a drive pulley.
FIG. 4 is a diagram illustrating an operation example of a driven pulley.
FIG. 5 is a flowchart showing a working oil pressure setting process.
FIG. 6 is a flowchart showing a transmission transmission torque calculation process.
FIG. 7 is a flowchart showing a margin torque correction term calculation process.
FIG. 8 is a flowchart illustrating a rough road determination process.
FIG. 9 is a flowchart showing PCCMDL calculation processing;
FIG. 10 is a diagram illustrating an example of an ESC-ΔPC table.
FIG. 11 is a flowchart showing a gear ratio control process.
FIG. 12 is a flowchart showing another example of the gear ratio control process.
FIG. 13 is a flowchart showing transmission transmission torque calculation processing in the second embodiment of the present invention.
FIG. 14 is a flowchart showing transmission transmission torque calculation processing in a third embodiment of the present invention.
[Explanation of symbols]
              1 Control device
              2 ECU (Operating state detection means,Transmission transmission torque setting means, clutch transmission
                          Torque setting means, rough road judgment means, target gear ratio setting means,
                          (Speed ratio control means, throttle valve opening correction means)
              3 Vehicle
              4 engine (internal combustion engine)
          7,7 Drive wheel
            20 continuously variable transmission
            22 Drive pulley
            23 Driven pulley
            24 Transmission belt
            30 Starting clutch (friction clutch)
            40  Crank angle sensor (operating state detection means)
            41 Throttle valve opening sensor (throttle valve opening detection means)
            42  Intake pipe absolute pressure sensor
        PDRD effective diameter
        PDND effective diameter
TQDRBLTM Drive side transmission torque (transmission transmission torque)
TQDNBLTM Drive side transmission torque (transmission transmission torque)
    PCCMDL target hydraulic pressure (clutch transmission torque)
TQDRBLTα  Drive side first provisional value (first provisional value)
TQDNBLTα  Driven side first provisional value (first provisional value)
TQDRBLTβ  Driving side second provisional value (second provisional value)
TQDNBLTβ  Driven side second provisional value (second provisional value)
            AP accelerator opening (accelerator pedal opening)
            TH throttle valve opening
    RATTGT target gear ratio
      RATIO gear ratio

Claims (2)

A driving pulley and a driven pulley, each of which is connected to an internal combustion engine and a driving wheel mounted on a vehicle and has a variable effective diameter, and a transmission belt wound around the driving pulley and the driven pulley; A continuously variable transmission that changes the power of the internal combustion engine steplessly and transmits it to the drive wheels by changing the effective diameter of at least one of the driven pulleys, and is provided between the internal combustion engine and the drive wheels. A vehicle control device having a friction type clutch,
An operating state detecting means for detecting an operating state of the internal combustion engine;
Transmission transmission torque setting means for setting transmission transmission torque to be transmitted from the drive pulley to the driven pulley;
Clutch transmission torque setting means for setting a clutch transmission torque to be transmitted by the clutch;
A rough road traveling determination means for determining whether or not the vehicle is traveling on a rough road,
The clutch transmission torque setting means reduces the clutch transmission torque so that the clutch is slid when it is determined by the rough road traveling determination means that the vehicle is traveling on a rough road,
The transmission transmission torque setting means sets a first provisional value according to the detected operating state of the internal combustion engine, sets a second provisional value according to the clutch transmission torque, and sets the set first value. A vehicle control device , wherein a larger one of the first provisional value and the second provisional value is set as the transmission transmission torque . Throttle valve opening detecting means for detecting the opening of the throttle valve controlled according to the opening of the accelerator pedal of the vehicle;
Target gear ratio setting means for setting a target gear ratio of the continuously variable transmission according to the detected opening of the throttle valve;
Transmission ratio control means for controlling the transmission ratio of the continuously variable transmission so as to achieve the set target transmission ratio;
The vehicle according to claim 1, further comprising throttle valve opening correction means for correcting the opening of the throttle valve when it is determined that the vehicle is traveling on a rough road. Control device.

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