JP3966073B2 - Braking control device - Google Patents

Description

【００２６】
一方、制動トルク指令値のフィードバック項Ｔd-FBを算出するため、まずブロックＢ２で、前記目標減速度αdem に対し、下記２式で示す規範モデル特性Ｆref (s) 処理を施して規範減速度αref を算出する。
【００２７】
【数２】

【００２８】
このようにして算出された規範減速度αref から、前記自車両で発生する減速度αV と基準減速度αB との差（αV −αB ）を加減算器で減じて減速度のフィードバック差分値Δαを算出する。そして、この減速度のフィードバック差分値Δαに対し、ブロックＢ３で、下記３式で示すフィードバック補償器ＣFB(s) 処理を施して制動トルク指令値のフィードバック項Ｔd-FBを算出する。なお、前記フィードバック補償器ＣFB(s) は、基本的なＰＩ（比例−積分）制御器であり、式中の制御定数ＫP 、ＫI はゲイン余裕や位相余裕を考慮して設定する。
【００２９】
【数３】

【００３０】
従って、前記制動トルク指令値のフィードフォワード項Ｔd-FFと制動トルク指令値のフィードバック項Ｔd-FBとを加算器で加算して制動トルク指令値Ｔd-comを算出することができる。
次に、前記回生協調ブレーキ制御コントロールユニット１９内で行われる制動流体圧指令値及び回生トルク指令値算出のための演算処理を図３のフローチャートに従って説明する。
【００３１】
この演算処理は、所定時間ΔＴ（例えば１０msec. ）毎のタイマ割込処理として実行される。なお、このフローチャートでは、特に通信のためのステップを設けていないが、演算によって得られた情報は随時記憶され、記憶されている情報は、必要に応じて、随時読込まれる。
この演算処理は、まずステップＳ１で、前記マスタシリンダ圧センサ１１で検出されたマスタシリンダ圧Ｐmc及びホイールシリンダ圧センサ１２で検出された各ホイールシリンダ圧Ｐwcを前記制動流体圧コントロールユニット１３から読込む。
【００３２】
次にステップＳ２に移行して、前記駆動輪速度センサ２０で検出された駆動輪速度を車両の走行速度として読込み、更に下記４式の伝達関数Ｆbpf (s) で示されるバンドパスフィルタ処理を施して駆動輪減速度を求め、それを前記実際の車両に発生している車両減速度αV とする。但し、式中のωは固有角周波数、ζは減衰定数である。
【００３３】
【数４】

【００３４】
次にステップＳ３に移行して、前記モータコントロールユニット１８から利用可能な最大回生トルクＴmmaxを読込む。
次にステップＳ４に移行して、前記ステップＳ１で読込んだマスタシリンダ圧Ｐmcに所定の定数Ｋ1 を乗じ、その負値を前記目標減速度αdem として算出する。
【００３５】
次にステップＳ５に移行して、エンジンブレーキ力による減速度の推定値、エンジンブレーキ減速度推定値αeng を算出する。具体的には、まず前記ステップＳ２で読込んだ駆動輪速度を車両の走行速度とし、この走行速度とシフトポジションとから図４ａの制御マップに従ってエンジンブレーキ力（図ではエンブレ力）推定値又は目標値Ｆeng を求める。また、同時に、自車両の走行速度から図４ｂの制御マップに従って平坦路における走行抵抗Ｆreg を求める。そして、それらの和を平均的な車両重量ＭV で除してエンジンブレーキ減速度推定値αeng を算出する。
【００３６】
次にステップＳ６に移行して、前記ステップＳ４で算出した目標減速度αdemに対し、前記１式のフィードフォワード補償器（位相補償器）ＣFF(s) 処理を施して制動トルク指令値のフィードフォワード項Ｔd-FFを算出する。
次にステップＳ７に移行して、例えば前記ステップＳ１で読込んだマスタシリンダ圧Ｐmcが比較的小さな所定値以上であるか否か等を利用することによってブレーキペダルが踏込まれているブレーキペダルオン（制動操作）状態であるか否かを判定し、ブレーキペダルオン状態である場合にはステップＳ９に移行し、そうでない場合にはステップＳ８に移行する。
【００３７】
前記ステップＳ８では、ブレーキ操作直前減速度α0 及びエンジンブレーキ減速度基準値αeng0を更新してからステップＳ１１に移行する。具体的には、アクセルペダル解除操作、即ちアクセルオフからブレーキ操作、即ちブレーキオンまでの制動開始時間ＴJ を求め、その制動開始時間ＴJ が、例えばエンジンブレーキ力が収束する時間相当の所定値ＴJ0以上であるときには、前記ステップＳ２で算出した車両減速度αV をブレーキ操作直前減速度α0 とすると共に、前記ステップＳ５で算出したエンジンブレーキ減速度推定値αeng をエンジンブレーキ減速度基準値αeng0とする。また、前記制動開始時間ＴJ が前記所定値ＴJ0未満であるときには、前記ステップＳ５で算出したエンジンブレーキ減速度推定値αeng をブレーキ操作直前減速度α0 とすると共に、当該エンジンブレーキ減速度推定値αeng をエンジンブレーキ減速度基準値αeng0とする。即ち、制動開始時間ＴJ がエンジンブレーキ収束所要時間相当の所定値ＴJ0以上であるときには、実際の車両減速度αV をブレーキ操作直前減速度α0 とし、所定値ＴJ0未満であるときには、その後に発生するであろうエンジンブレーキ減速度推定値αeng をブレーキ操作直前減速度α0 とする。
【００３８】
一方、前記ステップＳ９では、前記ステップＳ５で算出したエンジンブレーキ減速度推定値αeng から前記エンジンブレーキ減速度基準値αeng0を減じた値を前記ブレーキ操作直前減速度α0 に和して、前記基準減速度αB を算出してからステップＳ１０に移行する。
前記ステップＳ１０では、前記ステップＳ９で算出した基準減速度αB を用い、前述のように目標減速度αdem に対して前記２式で示す規範モデル特性Ｆref(s) 処理を施して規範減速度αref を算出し、この規範減速度αref から車両減速度αV と基準減速度αB との差（αV −αB ）を減じて減速度のフィードバック差分値Δαを算出し、この減速度のフィードバック差分値Δαに対し、前記３式で示すフィードバック補償器ＣFB(s) 処理を施して制動トルク指令値のフィードバック項Ｔd-FBを算出してからステップＳ１４に移行する。
【００３９】
前記ステップＳ１４では、前記ステップＳ１で読込んだマスタシリンダ圧Ｐmcが所定値Ｐmc0 以上であるか否か、即ち乗員の制動操作量であり、同時に前記目標減速度αdem の大きさが所定値以上であるか否かを判定し、当該マスタシリンダ圧Ｐmcが所定値Ｐmc0 以上である場合にはステップＳ１５に移行し、そうでない場合にはステップＳ１６に移行する。ここで、所定値Ｐmc0は、乗員が制動操作しているときに制動力指令値を変化させて、その乗員が違和感を感じる変化量の最小値とマスタシリンダ圧との関係を検出する実験から定まる値であって、その乗員が違和感を感じる変化量の最小値が、マスタシリンダ圧Ｐmcに応じて変化するようになるしきい値である。
【００４０】
前記ステップＳ１５では、前記ステップＳ６で算出された制動トルク指令値のフィードフォワード項Ｔd-FFに、“１”より小さい係数ＫLU1，ＫLL１を乗じて制動トルク指令値のフィードバック項の上限値Ｔd-FBUL及び下限値Ｔd-FBLLを算出してからステップＳ１７に移行する。ここで、係数ＫLU1，ＫLL１は、検出された車体減速度αVが正しくないときでも、それに基づく制動トルク指令値の変化量を制限することで、乗員の違和感を抑制防止できるように設定する。
【００４１】
一方、前記ステップＳ１６では、前記ステップＳ６で算出された制動トルク指令値のフィードフォワード項Ｔd-FFに、“１”より小さい係数ＫLU2を乗じた乗算値に定数ＣLUを加算して制動トルク指令値のフィードバック項の上限値Ｔd-FBULを算出すると共に、前記制動トルク指令値のフィードフォワード項Ｔd-FFに、“１”より小さい係数ＫLL2を乗じた乗算値に定数ＣLLを加算して制動トルク指令値のフィードバック項の下限値Ｔd-FBLLを算出してからステップＳ１７に移行する。ここで、定数ＣLU，ＣLLは、乗員の制動操作開始時に、正しくない車体減速度αVが検出されたときでも、それに基づく制動トルク指令値の変化量を制限することで、乗員の違和感を抑制防止でき、且つ、ホイールシリンダ５等で発生可能な最小制動トルクより大きくなるように設定する。
【００４２】
また係数ＫLU2，ＫLL2は、マスタシリンダ圧Ｐmcが所定値Ｐmc0になったときに、フィードバック項の上限値Ｔd-FBULが前記制動トルク指令値のフィードフォワード項Ｔd-FFに係数ＫLU1を乗じた値となるように、また前記フィードバック項の下限値Ｔd-FBLLが前記制動トルク指令値のフィードフォワード項Ｔd-FFに係数ＫLL1を乗じた値となるように設定する。
【００４３】
前記ステップＳ１７では、前記ステップＳ１５又はステップＳ１６で設定された制動トルク指令値のフィードバック項の上限値Ｔd-FBUL及び下限値Ｔd-FB-LLで、前記ステップＳ１０で算出された制動トルク指令値のフィードバック項Ｔd-FBを制限してから前記ステップＳ１１に移行する。
前記ステップＳ１１では、前記ステップＳ６で算出した制動トルク指令値のフィードフォワード項Ｔd-FFと前記ステップＳ１０で算出し、或いは前記ステップＳ１７で制限された制動トルクの指令値のフィードバック項Ｔd-FBとの和から制動トルク指令値Ｔd-com を求め、それを制動流体圧制動トルク指令値Ｔb-com と回生制動トルク指令値Ｔm-com とに配分する。ここでは、可及的に燃費を向上するため、前記ステップＳ３で読込んだ最大回生トルクＴmmaxをできるだけ使い切るように配分する。本実施形態の前記モータジェネレータ１５は前輪だけを駆動し、前輪からの路面駆動トルクによって回生制動するものであるから、以下のようにして場合分けを行う。
【００４４】
まず、図５に示す前後輪制動力配分制御マップ（例えば理想制動力配分マップであり制動トルクを絶対値で示す）に従って、前記制動トルク指令値Ｔd-com を前輪制動トルク指令値Ｔd-com-F と後輪制動トルク指令値Ｔd-com-R とに分配する。そして、この前輪制動トルク指令値Ｔd-com-Fの絶対値と後輪制動トルク指令値Ｔd-com-R の絶対値との和、即ち前記制動トルク指令値Ｔd-comの絶対値 が前記最大回生トルクＴmmaxの絶対値未満であるときには回生制動のみとし、前輪制動流体圧制動トルク指令値Ｔb-com-F 及び後輪制動流体圧制動トルク指令値Ｔb-com-R を共に“０”とし、回生制動トルク指令値Ｔm-com を前記制動トルク指令値Ｔd-com に設定する。
【００４５】
また、前記制動トルク指令値Ｔd-comの絶対値が前記最大回生トルクＴmmaxの絶対値以上であり、且つ、前記前輪制動トルク指令値Ｔd-com-Fの絶対値 が前記最大回生トルクＴmmaxの絶対値未満であるときには回生制動と後輪制動流体圧制動とし、前輪制動流体圧制動トルク指令値Ｔb-com-F を“０”とし、後輪制動流体圧制動トルク指令値Ｔb-com-R を、前記制動トルク指令値Ｔd-com から最大回生トルクＴmmaxを減じた値とし、回生制動トルク指令値Ｔm-com を最大回生トルクＴmmaxに設定する。また、前記最大回生トルクＴmmaxの絶対値が“０”近傍の所定値以上であり且つ前記前輪制動トルク指令値Ｔd-com-Fの絶対値 が当該最大回生トルクＴmmaxの絶対値以上であるときには回生制動と前後輪制動流体圧制動とし、前輪制動流体圧制動トルク指令値Ｔb-com-F を、前輪制動トルク指令値Ｔdcom-F から最大回生トルクＴmmaxを減じた値とし、後輪制動流体圧制動トルク指令値Ｔb-com-R を後輪制動トルク指令値Ｔd-com-R とし、回生制動トルク指令値Ｔm-com を最大回生トルクＴmmaxに設定する。また、前記最大回生トルクＴmmaxの絶対値が“０”近傍の所定値未満であるときには制動流体圧制動のみとし、前輪制動流体圧制動トルク指令値Ｔb-com-F を前輪制動トルク指令値Ｔd-com-F とし、後輪制動流体圧制動トルク指令値Ｔb-com-R を後輪制動トルク指令値Ｔd-com-Rとし、回生制動トルク指令値Ｔm-com を“０”に設定する。
【００４６】
次にステップＳ１２に移行して、前記ステップＳ１１で算出した前後輪の制動流体圧制動トルク指令値Ｔb-com-F 、Ｔb-com-R に所定の車両諸元定数Ｋ3 を乗じて前後輪の制動流体圧指令値Ｐb-com-F 、Ｐb-com-R を算出する。
次にステップＳ１３に移行して、前記ステップＳ１１で算出した回生制動トルク指令値Ｔm-com を前記モータコントロールユニット１８に向けて出力すると共に、前記ステップＳ１２で算出した前後輪の制動流体圧指令値Ｐb-com-F 、Ｐb-com-R を前記制動流体圧コントロールユニット１３に向けて出力してからメインプログラムに復帰する。
【００４７】
この演算処理によれば、前記アクセルオフからブレーキオンまでの間には、そのときの車両減速度αV 又はエンジンブレーキ減速度推定値αeng をブレーキ操作直前減速度α0 として、またそのときのエンジンブレーキ減速度推定値αengをエンジンブレーキ減速度基準値αengOとして随時更新しながら、目標減速度αdem に対する制動トルク指令値フィードフォワード項Ｔd-FFが算出される。この状態での制動トルク指令値Ｔd-com は、この制動トルク指令値フィードフォワード項Ｔd-FFのみであるから、本来、エンジンブレーキ力によって車両減速度αVに反映されており、またシフトダウン操作等を行わない限り、ブレーキペダルを踏込んだときの値よりも絶対値では小さいから、当該制動トルク指令値フィードフォワード項Ｔd-FFのみからなる制動トルク指令値Ｔd-comの絶対値が前記最大回生トルクＴmmaxの絶対値未満であるときには、前述のように前輪制動流体圧制動トルク指令値Ｔb-com-F 及び後輪制動流体圧制動トルク指令値Ｔb-com-R を共に“０”とし、回生制動トルク指令値Ｔm-com を前記制動トルク指令値Ｔd-com に設定する。
【００４８】
これに対し、ブレーキペダルの踏込みが行われると、そのときの車両減速度αV 又はエンジンブレーキ減速度推定値αeng がブレーキ操作直前減速度α0 として、またそのときのエンジンブレーキ減速度推定値αeng がエンジンブレーキ減速度基準値αengOとして記憶され、このブレーキ操作直前減速度α0 及びエンジンブレーキ減速度基準値αeng0を用いて、そのときのエンジンブレーキ減速度推定値αeng に応じた基準減速度αB が算出され、この基準減速度αB と実際の車両減速度αV と前記規範減速度αref とから制動トルク指令値フィードバック項Ｔd-FBが算出され、これに前記制動トルク指令値フィードフォワード項Ｔd-FFを和した値が制動トルク指令値Ｔd-com となる。このとき、アクセルオフからブレーキオンまでの時間ＴJ が前記エンジンブレーキ力が収束する時間相当の所定値ＴJ0以上であれば、そのときの車両減速度αV が前記ブレーキ操作直前減速度α0 に設定されている。従って、ブレーキ操作時に、エンジンブレーキ力や登坂路での減速度や、降坂路での加速度が作用していれば、それは車両減速度αV に表れてブレーキ操作直前減速度α0 に反映しているので、その後の基準減速度αBはそれらの加減速度の影響を反映した値となり、この基準減速度αB と車両減速度αV との差に応じた制動トルク指令値フィードバック項Ｔd-FBは、エンジンブレーキトルクの変動のみを反映した値となり、ブレーキペダルの操作量が一定で前記制動トルク指令値フィードフォワード項Ｔd-FFが同等か又はほぼ同等である限り、運転者の意図した減速度を達成することができる。
【００４９】
また、この途中にダウンシフトなどによってエンジンブレーキ力が変化したときにも、そのときのエンジンブレーキ減速度推定値αeng と前記エンジンブレーキ減速度基準値αeng0との差を基準減速度αB に反映することができるので、その後も、基準減速度αB と車両減速度αV との差に応じた制動トルク指令値フィードバック項Ｔd-FBに基づいて、運転者の意図した減速度を達成し続けることができる。
【００５０】
また、アクセルオフからブレーキオンまでの時間ＴJ が前記エンジンブレーキ力が収束する時間相当の所定値ＴJ0未満であるときには、エンジンブレーキ減速度推定値αeng を前記ブレーキ操作直前減速度α0 に設定するので、エンジンブレーキ力が収束してから、運転者の意図した減速度を達成することが可能となる。
【００５１】
図６は、前記図３の演算処理による車両加減速度の経時変化を示したものである。このタイミングチャートでは、平坦路を定速走行中に、時刻ｔ01でアクセルオフ、時刻ｔ02でブレーキオン、時刻ｔ03でダウンシフトを行っており、ブレーキオンからのブレーキペダルの踏込み量、即ちマスタシリンダ圧Ｐmcは一定である。時刻ｔ01でアクセルオフとなると、エンジンブレーキ力によって車両に減速度が発生するが、自車両走行速度の減少に伴って、その減速度の値は次第に増加する（減速度の度合としては小さくなる）。
【００５２】
そして、時刻ｔ02でブレーキオンとなると、そのときの車両減速度αV がブレーキ操作直前減速度α0 に設定され、そのときのエンジンブレーキ減速度推定値αeng がエンジンブレーキ減速度基準値αeng0に設定される。従って、この時刻ｔ02以後、ブレーキペダルの踏込み量に応じた減速度（αV −αeng0 ）が、それまでの減速度αB （＝α0 ）に付加されるが、その後の自車両走行速度の減少に伴ってエンジンブレーキ減速度推定値αengが大きく（減速度の度合としては小さく）なると、このエンジンブレーキ減速度推定値αeng と前記エンジンブレーキ減速度基準値αeng0との差の分だけ減速度基準値αB が大きく（減速度の度合としては小さく）なり、これに伴って前記制動流体圧制御又は回生ブレーキ制御によって発生する車両減速度αVの値はエンジンブレーキトルクの減少分ずつ大きく（減速度の度合としては小さく）なってゆく。
【００５３】
更に、時刻ｔ03でダウンシフトを行うと、その分だけ、エンジンブレーキ減速度推定値αeng が小さく（減速度の度合としては大きく）なり、このエンジンブレーキ減速度推定値αeng と前記エンジンブレーキ減速度基準値αeng0との差の分だけ減速度基準値αB が小さく（減速度の度合としては大きく）なり、これに伴って前記制動流体圧制御又は回生ブレーキ制御によって発生する車両減速度αVの値はエンジンブレーキトルクの増加分だけ小さく（減速度の度合としては大きく）なる。しかし、その後も、走行速度の減少に伴ってエンジンブレーキ力が減少するので、車両減速度αVの値は次第に大きく（減速度の度合としては小さく）なってゆく。
【００５４】
ところで、前記制動トルク指令値のフィードバック項Ｔd-FBは、前記制動トルク指令値のフィードバック項の上限値Ｔd-FBUL及び下限値Ｔd-FBLLで制限される。これに対し、制動トルク指令値のフィードフォワード項Ｔd-FFは制限されないので、当該制動トルク指令値のフィードフォワード項Ｔd-FFと前記制動トルク指令値のフィードバック項Ｔd-FBとの加算値からなる制動トルク指令値Ｔd-com は、制動トルク指令値のフィードフォワード項Ｔd-FFと制動トルク指令値のフィードバック項の上限値Ｔd-FBUL及び下限値Ｔd-FBLLとの加算値で制限されると換言できる。この制動トルク指令値のフィードフォワード項Ｔd-FFと制動トルク指令値のフィードバック項の上限値Ｔd-FBUL及び下限値Ｔd-FBLLとの加算値を制動トルク指令値の上限値Ｔd-comUL 及び下限値Ｔd-comLL とすると、当該制動トルク指令値の上限値Ｔd-comUL 及び下限値Ｔd-comLL は、マスタシリンダ圧Ｐmcに対して、図７のように設定されることになる。なお、図７では制動トルク指令値は絶対値で示している。
【００５５】
即ち、マスタシリンダ圧Ｐmcが前記所定値Ｐmc0 以下の領域では、前記制動トルク指令値のフィードバック項の上限値Ｔd-FBUL及び下限値Ｔd-FBLLが、制動トルク指令値のフィードフォワード項Ｔd-FFに係数ＫLU2，ＫLL2を乗じた乗算値に定数ＣLU，ＣLLを加算した値となるので、マスタシリンダ圧Ｐmc、即ち目標減速度である制動トルク指令値のフィードフォワード項Ｔd-FFの増加に応じて定数ＣLU，ＣLLから増加することになる。一方、マスタシリンダ圧Ｐmcが前記所定値Ｐmc0 以上の領域では、制動トルク指令値のフィードフォワード項Ｔd-FFに係数ＫLU2，ＫLL2を乗じた値となるので、マスタシリンダ圧Ｐmc、即ち目標減速度である制動トルク指令値のフィードフォワード項Ｔd-FFの増加に応じてリニアに増加することになる。
【００５６】
図８は、制動トルク指令値（絶対値で示す）のフィードバック項の上限値Ｔd-FBUL及び下限値Ｔd-FBLLを、常時、制動トルク指令値のフィードフォワード項Ｔd-FFに所定の係数ＫLU2，ＫLL2を乗じた値としたものである。従って、制動トルク指令値の上限値Ｔd-comUL 及び下限値Ｔd-comLL は、制動トルク指令値のフィードフォワード項Ｔd-FFが大きいほど大きくなる。ここでは、時刻ｔ01でブレーキペダルを踏込み、時刻ｔ02でブレーキペダルの踏込みを一定に保持したものとし、その後、時刻ｔ03で路面突起や路面摩擦係数の変動により車体減速度αV が小さく（数値的には大きく）誤検出されたものとする。また、この時刻ｔ03までは、車体減速度αV は前記目標減速度αdem によく一致し、その結果、制動トルク指令値Ｔd-comはほぼ制動トルク指令値Ｔd-FFであったものとする。そして、時刻ｔ03以後は、前記制動トルク指令値のフィードバック項Ｔd-FBによって制動トルク指令値Ｔdcomは小さく補正されているが、制動トルク指令値の下限値Ｔd-comLL によって制限されている。
【００５７】
図から明らかなように、制動トルク指令値のフィードバック項の上限値Ｔd-FBUL及び下限値Ｔd-FBLLを、常時、制動トルク指令値のフィードフォワード項Ｔd-FFに所定の係数ＫLU2，ＫLL2を乗じた値とし、仮に制動トルク指令値Ｔd-com が比較的大きい領域で車体減速度αV が誤検出されたら、不適正な制動トルク指令値が上限値Ｔd-comUL 又は下限値Ｔd-comLL で制限されるように、当該上限値Ｔd-comUL 又は下限値Ｔd-comLLを比較的絶対値の小さな値にしなければならない。このシミュレーションでは、制動トルク指令値Ｔd-com が比較的大きいときに車体減速度αV が誤検出されたために、当該制動トルク指令値Ｔd-com は適正な制動トルク指令値の下限値Ｔd-comLL で制限されているが、仮に制動トルク指令値Ｔd-com が比較的小さいときに、正しく検出された車体減速度αVに基づく前記制動トルク指令値のフィードバック項Ｔd-FBにより制動トルク指令値Ｔdcomが小さく補正されたときには、不適正な制動トルク指令値の上限値Ｔd-comUL 又は下限値Ｔd-comLL で制限され、適正な制動力制御が行えない恐れがある。
【００５８】
図９は、本実施形態のように、マスタシリンダ圧Ｐmcが所定値Ｐmc0 以下、即ち目標減速度αdem が所定値以下のときには、制動トルク指令値（絶対値で示す）のフィードフォワード項Ｔd-FFに所定の係数ＫUL、ＫLL１を乗じた乗算値に定数ＣLU，ＣLLを加算した値を制動トルク指令値のフィードバック項の上限値Ｔd-FBUL及び下限値Ｔd-FBLLとし、マスタシリンダ圧Ｐmcが所定値Ｐmc0 以上、即ち目標減速度αdem が所定値以上のときには、制動トルク指令値のフィードフォワード項Ｔd-FFに係数ＫLU2，ＫLL2を乗じた値を制動トルク指令値のフィードバック項の上限値Ｔd-FBUL及び下限値Ｔd-FBLLとしたものである。このような設定では、例えば制動トルク指令値Ｔd-comが比較的大きい領域で、車体減速度αV が誤検出されたときには、不適正な制動トルク指令値が前記上限値Ｔd-comUL 又は下限値Ｔd-comLL で制限されるように、当該上限値Ｔd-comUL 又は下限値Ｔd-comLLを比較的絶対値の小さな値にしても、制動トルク指令値Ｔd-com が比較的小さいときには、定数ＣLU，ＣLLにより前記制動トルク指令値のフィードバック項の上限値Ｔd-FBUL及び下限値Ｔd-FBLLは比較的絶対値の大きな値となる。このシミュレーションでは、制動トルク指令値Ｔd-com が比較的大きいときに車体減速度αV が誤検出され、当該制動トルク指令値Ｔd-com は適正な制動トルク指令値の下限値Ｔd-comLL で制限されているが、仮に制動トルク指令値Ｔd-com が比較的小さいときに、正しく検出された車体減速度αVによって発生した前記制動トルク指令値のフィードバック項Ｔd-FBによって、制動トルク指令値Ｔdcomが小さく補正されるときには、制動トルク指令値の上限値Ｔd-comUL 又は下限値Ｔd-comLL で制限されることなく、適正な制動力制御を継続して実行することができる。
【００５９】
ちなみに、上記実施形態では、マスタシリンダ圧Ｐmcが所定値Ｐmc0 以下、即ち目標減速度αdem が所定値以下のときに、図７に示すように、制動トルク指令値のフィードフォワード項Ｔd-FFに所定の係数ＫUL2、ＫLL2を乗じた乗算値に定数ＣLU，ＣLLを加算した値を制動トルク指令値のフィードバック項の上限値Ｔd-FBUL及び下限値Ｔd-FBLLとした例を示したが、目標減速度αdem が所定値以下のときの制動トルク指令値のフィードバック項の上限値Ｔd-FBUL及び下限値Ｔd-FBLLは、上記実施形態に限られるものではなく、例えば図１０に示すように、所定の一定値で前記上限値Ｔd-FBUL及び下限値Ｔd-FBLL（いずれも絶対値で示す）を制限するようにしてもよく、図１１に示すように、所定の一定値を前記上限値Ｔd-FBUL及び下限値Ｔd-FBLL（いずれも絶対値で示す）としてもよい。そのようにすれば、検出された車体減速度αVが正しくないときでも、それに基づく制動トルク指令値の変化量を小さく制限して、乗員の違和感を抑制防止することができ、また制動力制御で適切な制動力を発生でき、制動力制御を適正な範囲にすることができる。
【００６０】
以上より、前記図３の演算処理のステップＳ４が本発明の目標減速度設定手段を構成し、以下同様に、前記駆動輪速度センサ２０及び前記図３の演算処理のステップＳ２が減速度検出手段を構成し、前記ポンプ２１、増圧弁８、減圧弁９、ホイールシリンダ５が制動手段を構成し、前記図３の演算処理のステップＳ１４〜ステップＳ１６が制動力指令値上下限値設定手段を構成し、前記図３の演算処理のステップＳ６〜ステップＳ１３、ステップＳ１７が制動制御手段を構成している。
【図面の簡単な説明】
【図１】本発明の制動制御装置の一例を示すシステム概略構成図である。
【図２】回生協調ブレーキ制御コントロールユニットで行われる制動トルク指令値算出のブロック図である。
【図３】図２の制動トルク指令値算出に基づく制動流体圧指令値及び回生トルク指令値算出のための演算処理のフローチャートである。
【図４】図３の演算処理で用いる制御マップである。
【図５】図３の演算処理で用いる制御マップである。
【図６】図３の演算処理による車両減速度の変化を示すタイミングチャートである。
【図７】図３の演算処理で設定される制動トルク指令値とその上限値及び下限値の説明図である。
【図８】車体減速度が誤検出されたときの制動トルク指令値の説明図である。
【図９】図３の演算処理による車体減速度が誤検出されたときの制動トルク指令値の説明図である。
【図１０】図３の演算処理で設定される制動トルク指令値とその上限値及び下限値の変形例の説明図である。
【図１１】図３の演算処理で設定される制動トルク指令値とその上限値及び下限値の変形例の説明図である。
【符号の説明】
１はブレーキペダル
３はマスタシリンダ
５はホイールシリンダ
６はストロークシミュレータ
７はストロークシミュレータ切換弁
８は増圧弁
９は減圧弁
１０は車輪
１１はマスタシリンダ圧センサ
１２はホイールシリンダ圧センサ
１３は制動流体圧コントロールユニット
１５はモータジェネレータ
１８はモータコントロールユニット
１９は回生協調ブレーキ制御コントロールユニット
２４はストロークセンサ[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a braking control device that detects a deceleration acting on a vehicle and controls a braking force based on the detected deceleration.
[0002]
[Prior art]
An example of such a braking control device is disclosed in Japanese Patent Laid-Open No. 56-33254. In this braking control device, a deceleration acting on the vehicle is detected, and so-called feedback control is performed on the braking force based on the detected deceleration.
[0003]
[Problems to be solved by the invention]
However, in the conventional braking control device, since the braking force control is performed by feeding back the deceleration acting on the vehicle, for example, when the vehicle deceleration is calculated from the wheel rotation speed, the wheel rotation speed is the road surface speed. If it changes due to unevenness or fluctuations in the road surface friction coefficient state, the vehicle deceleration will not be detected correctly, and there is a problem that appropriate braking force control cannot be performed.
[0004]
The present invention has been developed to solve these problems, and provides a braking control device capable of executing appropriate braking force control even when vehicle deceleration cannot be correctly detected due to a disturbance. It is intended.
[0005]
[Means for Solving the Problems]
In order to achieve the above object, a braking control apparatus according to claim 1 of the present invention detects a target deceleration setting means for setting a target deceleration from a braking operation amount of an occupant and a deceleration generated in the vehicle. Deceleration detecting means; braking means for applying braking force to each wheel; braking force command value upper and lower limit value setting means for setting upper and lower limits of a braking force command value to the braking means; A braking force command value is set from a reference value corresponding to the target deceleration set by the speed setting means and a correction amount corresponding to the deceleration detected by the deceleration detecting means, and the braking force command value is set to the The braking force command value upper / lower limit value setting means limits the upper limit value and lower limit value of the braking force command value, and the braking force applied to each wheel by the braking means is controlled based on the restricted braking force command value. Braking control means for performing the braking force command The upper and lower limit value setting means, when the target deceleration set by the target deceleration setting means is equal to or greater than a predetermined value, multiplies a reference value according to the target deceleration by a predetermined ratio and sets an upper limit of the correction amount. By setting a value and a lower limit value, an upper limit value and a lower limit value of the braking force command value are set.
[0006]
According to a second aspect of the present invention, there is provided the braking control device according to the second aspect, wherein the braking force command value upper / lower limit value setting means has a target deceleration set by the target deceleration setting means. When it is less than the predetermined value, an upper limit value and a lower limit value of the braking force command value are set by setting a predetermined constant value as an upper limit value and a lower limit value of the correction amount. .
[0007]
Furthermore, the braking control device according to claim 3 of the present invention is the braking control device according to claim 1, wherein the braking force command value upper and lower limit value setting means has a target deceleration set by the target deceleration setting means. When it is less than the predetermined value, an addition value of a multiplication value obtained by multiplying a reference value according to the target deceleration by a predetermined ratio and a predetermined constant value is set as an upper limit value and a lower limit value of the correction amount. The upper limit value and the lower limit value of the braking force command value are set.
[0008]
Still further, the braking control device according to a fourth aspect of the present invention is the braking control device according to the third aspect , wherein the braking force command value upper and lower limit value setting means is a predetermined constant value and an upper limit value and a lower limit value of the addition value. A value is set.
[0009]
【The invention's effect】
Thus, according to the braking control apparatus of the first aspect of the present invention, the target deceleration is set from the occupant's braking operation amount, the deceleration generated in the vehicle is detected, and during the occupant's braking operation, The braking force command value is set from the reference value corresponding to the target deceleration and the correction amount corresponding to the deceleration, and when the target deceleration is equal to or greater than a predetermined value, the reference value corresponding to the target deceleration is set. Since the braking command value is controlled by the upper and lower limit values set by multiplying by a predetermined ratio to control the braking force to each wheel, when the target deceleration is greater than or equal to the predetermined value, the detected deceleration is Even when it is not correct, the braking force command value based on the braking force can be limited, and when the target deceleration is less than the predetermined value, the upper and lower limits of the correction amount are set to be large so that the appropriate braking force can be controlled by the braking force control. And set the braking force control within the proper range. It is possible.
[0010]
Further, according to the braking control device according to claim 2 of the present invention, when the target deceleration is less than the predetermined value, by setting a predetermined constant value to the upper limit value and the lower limit value of the correction amount, Since the upper limit value and the lower limit value of the braking force command value are set, when the target deceleration is less than the predetermined value, the amount of change in the braking force command value based on the detected deceleration is not correct. Can be suppressed to a small extent to prevent the passenger from feeling uncomfortable, and an appropriate braking force can be generated by the braking force control, so that the braking force control can be within an appropriate range.
[0011]
Furthermore, according to the braking control apparatus of the third aspect of the present invention, when the target deceleration is less than the predetermined value, a multiplication value obtained by multiplying a reference value corresponding to the target deceleration by a predetermined ratio and a predetermined value. Since the upper limit value and the lower limit value of the braking force command value are set by setting the addition value with the constant value as the upper limit value and the lower limit value of the correction amount, it is not correct when the braking operation of the occupant is started. Even when the deceleration is detected, the amount of change of the braking force command value based on the deceleration can be limited to a smaller value, and the occupant's uncomfortable feeling can be suppressed and prevented.
[0012]
Furthermore, according to the braking control device according to claim 4 of the present invention, since the upper limit value and the lower limit value of the addition value are set with a predetermined constant value, the target deceleration is less than the predetermined value. Even when the detected deceleration is not correct, the amount of change in the braking force command value based on it can be limited to a small extent to prevent the passenger from feeling uncomfortable, and the braking force control can generate an appropriate braking force. The braking force control can be set within an appropriate range.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic system configuration diagram showing an embodiment of the present invention. Regenerative coordination for efficiently recovering regenerative energy by controlling the brake fluid pressure to be reduced while controlling the regenerative brake torque by an AC synchronous motor. The brake control device of the present invention is applied to a brake control system.
[0014]
In FIG. 1, a brake pedal 1 that is braked by a driver is connected to a master cylinder 3 via a booster 2. The booster 2 is boosted by the pump 21 and boosts the pedal depression force using the high braking fluid pressure accumulated in the accumulator 22 and supplies the pedal depression force to the master cylinder 3. The pump 21 is sequence-controlled by a pressure switch 23. Reference numeral 4 in the figure denotes a brake fluid reservoir.
[0015]
The master cylinder 3 is connected to a wheel cylinder 5 of each wheel 10. A stroke simulator for switching to a stroke simulator 6 having a fluid load equivalent to that of the wheel cylinder 5 is provided in the middle of the brake fluid path. A switching valve 7 is interposed. That is, when the stroke simulator switching valve 7 is not energized, the master cylinder 3 is connected to each wheel cylinder 5, but when the stroke simulator switching valve 7 is energized, the master cylinder 3 is connected to the stroke simulator 6 and each wheel cylinder 5 is connected. Is disconnected from the brake fluid pressure of the master cylinder 3.
[0016]
Along with the operation of the stroke simulator switching valve 7, the output pressure of the pump 21 or the accumulated pressure of the accumulator 22 is supplied to each wheel cylinder 5 to increase the pressure, and the braking fluid pressure of each wheel cylinder 5 is stored in the reservoir. A pressure reducing valve 9 for reducing the pressure to 4 and reducing the pressure is provided. Among these, the pressure increasing valve 8 shuts off each wheel cylinder 5 and the pump 21 or the accumulator 22 when not energized, and connects each wheel cylinder 5 and the pump 21 or the accumulator 22 when energized. The pressure reducing valve 9 shuts off each wheel cylinder 5 and the reservoir 4 when not energized, and connects each wheel cylinder 5 and the reservoir 4 when energized. Therefore, if the pressure increasing valve 8 is energized in a state where each wheel cylinder 5 is disconnected from the master cylinder 3 by the stroke simulator switching valve 7, the braking fluid of each wheel cylinder 5 is separated from the output pressure of the master cylinder 3. The pressure can be increased, and if the pressure reducing valve 9 is energized, the brake fluid pressure of each wheel cylinder 5 can be reduced.
[0017]
Further, in this brake fluid pressure circuit, the master cylinder pressure sensor 11 for detecting the output pressure of the master cylinder 3 and the brake fluid pressure of each wheel cylinder 5 separated from the master cylinder 3 by the stroke simulator switching valve 7 are provided. A wheel cylinder pressure sensor 12 for detection is provided, and the stroke simulator switching valve 7, the pressure increasing valve 8, and the like according to a command from the brake fluid pressure control unit 13 using the brake fluid pressure detected by these pressure sensors 11, 12, The pressure reducing valve 9 is controlled.
[0018]
Among the wheels 10, an AC synchronous motor, so-called motor generator 15, is connected to a front wheel 10 corresponding to a drive wheel via a gear box 14. The motor generator 15 can drive the wheel 10 as an electric motor with electric power supplied from the battery 16, and can store the battery 16 as a generator with a road surface driving torque from the wheel 10. An AC current control circuit, so-called inverter 17, is interposed between the battery 16 and the motor generator 15, and an AC current and a DC current according to a command (three-phase PWM signal) from the motor control unit 18. Thus, the vehicle kinetic energy can be recovered to the battery 16 by the drive torque control of the motor generator 15 and the regenerative brake control.
[0019]
The brake fluid pressure control unit 13 and the motor control unit 18 are connected to a regenerative cooperative brake control control unit 19 via a communication line. Of course, the brake fluid pressure control unit 13 and the motor control unit 18 can individually control the brake fluid pressure of the wheel cylinder 5 and the rotation state of the motor generator 15, respectively. By controlling them according to commands from 19, it becomes possible to more efficiently recover vehicle kinetic energy and improve fuel efficiency.
[0020]
Specifically, the motor control unit 18 controls the regenerative brake torque based on the regenerative brake torque command value received from the regenerative cooperative brake control control unit 19, and at the same time obtains the maximum obtained from the state of charge, temperature, etc. of the battery 16. An allowable regenerative torque value is calculated and transmitted to the regenerative cooperative brake control control unit 19. The brake fluid pressure control unit 13 controls the brake fluid pressure of each wheel cylinder 5 according to the brake fluid pressure command value received from the regenerative cooperative brake control control unit 19, and the master cylinder pressure sensor 11, wheel cylinder The master cylinder pressure and the wheel cylinder pressure detected by the pressure sensor 12 are transmitted to the regenerative cooperative brake control control unit 19. In order to calculate the regenerative braking torque and braking fluid pressure command value in the regenerative cooperative brake control control unit 19, the vehicle has a driving wheel speed for detecting the rotational speed of the wheel (front wheel) 10 corresponding to the driving wheel. A sensor 20 is provided.
[0021]
Each control unit such as the braking fluid pressure control unit 13 and the motor control unit 18 including the regenerative cooperative brake control control unit 19 includes an arithmetic processing unit such as a microcomputer. The motor control unit 18 creates a drive signal and a control signal corresponding to each command value, and outputs them to each actuator described above. On the other hand, the regenerative cooperative brake control control unit 19 calculates a braking fluid pressure command value and a regenerative torque command value with the best vehicle kinetic energy recovery efficiency while obtaining a deceleration that matches the driver's intention. , Output to the brake fluid pressure control unit 13 and the motor control unit 18, respectively.
[0022]
Next, a method of calculating the braking torque command value Td-com from the target deceleration rate αdem for calculating the braking fluid pressure command value and the regenerative torque command value performed in the regenerative cooperative brake control control unit 19 is shown in FIG. This will be described based on the block diagram. For example, when the target deceleration rate αdem is a value proportional to the driver's brake pedal depression amount (braking operation amount), that is, the master cylinder pressure Pmc, a feedforward term corresponding only to the target deceleration rate αdem, A feedback term obtained by feeding back the deceleration actually generated in the vehicle is obtained, and the total value thereof is set as a braking torque command value Td-com.
[0023]
In FIG. 2, the block B4 (response characteristic P (s)) corresponds to the host vehicle. ΑV in the figure is a deceleration achieved or generated by the own vehicle. Here, when the deceleration immediately before the start of braking, for example, deceleration due to engine braking force, deceleration on an uphill road, acceleration on a downhill road, or the like is set as a reference deceleration αB, the deceleration αV generated in the host vehicle is The value obtained by subtracting the reference deceleration αB (αV−αB) is the deceleration to be achieved in the braking control system.
[0024]
In the block diagram of FIG. 2, first, in block B1, in order to make the response characteristic Pm (s) of the subject vehicle model to be controlled coincide with the reference model characteristic Fref (s), the following is applied to the target deceleration rate αdem. A feedforward compensator (phase compensator) CFF (s) shown in Equation 1 is processed to calculate a feedforward term Td-FF of the braking torque command value. In the equation, K2 is a vehicle specification constant for converting the target deceleration rate αdem into a braking torque.
[0025]
[Expression 1]

[0026]
On the other hand, in order to calculate the feedback term Td-FB of the braking torque command value, first, in the block B2, the reference deceleration characteristic αref is subjected to the reference model characteristic Fref (s) processing expressed by the following two expressions for the target deceleration rate αdem. Is calculated.
[0027]
[Expression 2]

[0028]
From the reference deceleration αref calculated in this way, the difference (αV −αB) between the deceleration αV generated by the host vehicle and the reference deceleration αB is subtracted by the adder / subtractor to calculate the feedback difference value Δα of the deceleration. To do. Then, the feedback compensator CFB (s) shown in the following equation 3 is applied to the deceleration feedback difference value Δα to calculate a feedback term Td-FB of the braking torque command value. The feedback compensator CFB (s) is a basic PI (proportional-integral) controller, and the control constants KP and KI in the equation are set in consideration of gain margin and phase margin.
[0029]
[Equation 3]

[0030]
Therefore, the braking torque command value Td-com can be calculated by adding the feedforward term Td-FF of the braking torque command value and the feedback term Td-FB of the braking torque command value with an adder.
Next, a calculation process for calculating the braking fluid pressure command value and the regenerative torque command value performed in the regenerative cooperative brake control control unit 19 will be described with reference to the flowchart of FIG.
[0031]
This calculation process is executed as a timer interrupt process every predetermined time ΔT (for example, 10 msec.). In this flowchart, no particular communication step is provided, but information obtained by calculation is stored as needed, and stored information is read as needed.
In this calculation process, first, in step S 1, the master cylinder pressure Pmc detected by the master cylinder pressure sensor 11 and each wheel cylinder pressure Pwc detected by the wheel cylinder pressure sensor 12 are read from the brake fluid pressure control unit 13. .
[0032]
Next, the process proceeds to step S2, where the driving wheel speed detected by the driving wheel speed sensor 20 is read as the traveling speed of the vehicle, and further the bandpass filter processing indicated by the following four transfer functions Fbpf (s) is performed. Thus, the driving wheel deceleration is obtained, and is set as the vehicle deceleration αV generated in the actual vehicle. In the equation, ω is a natural angular frequency, and ζ is an attenuation constant.
[0033]
[Expression 4]

[0034]
In step S3, the maximum regenerative torque Tmmax available from the motor control unit 18 is read.
In step S4, the master cylinder pressure Pmc read in step S1 is multiplied by a predetermined constant K1, and the negative value is calculated as the target deceleration rate αdem.
[0035]
Next, the process proceeds to step S5, where an estimated value of deceleration due to the engine braking force and an estimated value of engine brake deceleration αeng are calculated. Specifically, first, the driving wheel speed read in step S2 is set as the vehicle traveling speed, and the engine braking force (emblem force in the figure) estimated value or target according to the control map of FIG. 4a from this traveling speed and the shift position. Find the value Feng. At the same time, the running resistance Freg on a flat road is obtained from the running speed of the host vehicle according to the control map of FIG. Then, an engine brake deceleration estimated value αeng is calculated by dividing the sum by the average vehicle weight MV.
[0036]
Next, the process proceeds to step S6, where the target deceleration αdem calculated in step S4 is subjected to the feed forward compensator (phase compensator) CFF (s) process of the above equation 1 to feed forward the braking torque command value. The term Td-FF is calculated.
Next, the process proceeds to step S7, where the brake pedal is turned on (for example, whether or not the master cylinder pressure Pmc read in step S1 is a relatively small predetermined value or more). It is determined whether or not the vehicle is in a braking operation state. If the brake pedal is on, the process proceeds to step S9. If not, the process proceeds to step S8.
[0037]
In step S8, the deceleration α0 immediately before the brake operation and the engine brake deceleration reference value αeng0 are updated, and then the process proceeds to step S11. Specifically, the brake start time TJ from the accelerator pedal release operation, that is, the accelerator off to the brake operation, that is, the brake on is obtained, and the brake start time TJ is equal to or greater than a predetermined value TJ0 corresponding to, for example, the time when the engine braking force converges. In this case, the vehicle deceleration rate αV calculated in step S2 is set as the deceleration immediately before braking operation α0, and the engine brake deceleration estimated value αeng calculated in step S5 is set as the engine brake deceleration reference value αeng0. When the braking start time TJ is less than the predetermined value TJ0, the engine brake deceleration estimated value αeng calculated in step S5 is set as the deceleration immediately before braking operation α0, and the engine brake deceleration estimated value αeng is The engine brake deceleration reference value αeng0. That is, when the braking start time TJ is equal to or greater than the predetermined value TJ0 corresponding to the engine brake convergence time, the actual vehicle deceleration αV is set to the deceleration α0 immediately before the brake operation, and when it is less than the predetermined value TJ0, it occurs thereafter. The estimated engine braking deceleration rate αeng will be the deceleration α0 immediately before the brake operation.
[0038]
On the other hand, in the step S9, a value obtained by subtracting the engine brake deceleration reference value αeng0 from the engine brake deceleration estimated value αeng calculated in the step S5 is added to the deceleration just before the brake operation α0 to obtain the reference deceleration. After αB is calculated, the process proceeds to step S10.
In step S10, using the reference deceleration rate αB calculated in step S9, the reference deceleration rate αref is obtained by subjecting the target deceleration rate αdem to the reference model characteristic Fref (s) processing shown in the above equation (2). The difference between the vehicle deceleration αV and the reference deceleration αB (αV −αB) is calculated from this reference deceleration αref to calculate the deceleration feedback difference value Δα. Then, the feedback compensator CFB (s) shown in the above equation 3 is processed to calculate the feedback term Td-FB of the braking torque command value, and the process proceeds to step S14.
[0039]
In step S14, whether or not the master cylinder pressure Pmc read in step S1 is equal to or greater than a predetermined value Pmc0, that is, a braking operation amount of the occupant, and at the same time, the magnitude of the target deceleration rate αdem is equal to or greater than a predetermined value. If it is determined that the master cylinder pressure Pmc is greater than or equal to the predetermined value Pmc0, the process proceeds to step S15. If not, the process proceeds to step S16. Here, the predetermined value Pmc0 is determined from an experiment in which the braking force command value is changed when the occupant is braking, and the relationship between the minimum value of the change amount that the occupant feels uncomfortable and the master cylinder pressure is detected. This is a threshold value at which the minimum value of the change amount that the passenger feels uncomfortable changes according to the master cylinder pressure Pmc.
[0040]
In step S15, the braking torque command value feedforward term Td-FF calculated in step S6 is multiplied by a coefficient KLU1, KLL1 smaller than “1” to obtain an upper limit value Td-FBUL of the braking torque command value feedback term. And after calculating lower limit Td-FBLL, it transfers to step S17. Here, the coefficients KLU1 and KLL1 are set so that even when the detected vehicle deceleration αV is not correct, the change amount of the braking torque command value based on the detected vehicle deceleration αV is limited to suppress and prevent the passenger from feeling uncomfortable.
[0041]
On the other hand, in step S16, a constant CLU is added to a multiplication value obtained by multiplying the feedforward term Td-FF of the braking torque command value calculated in step S6 by a coefficient KLU2 smaller than “1” to obtain a braking torque command value. And calculating a braking torque command by adding a constant CLL to a multiplication value obtained by multiplying the feedforward term Td-FF of the braking torque command value by a coefficient KLL2 smaller than "1". After the lower limit value Td-FBLL of the value feedback term is calculated, the process proceeds to step S17. Here, the constants CLU and CLL prevent the passenger from feeling uncomfortable by limiting the amount of change in the braking torque command value based on the detected vehicle deceleration αV when an incorrect vehicle deceleration αV is detected at the start of the passenger's braking operation. It is set to be larger than the minimum braking torque that can be generated by the wheel cylinder 5 or the like.
[0042]
The coefficients KLU2 and KLL2 are values obtained by multiplying the upper limit value Td-FBUL of the feedback term by the coefficient KLU1 to the feedforward term Td-FF of the braking torque command value when the master cylinder pressure Pmc reaches the predetermined value Pmc0. In addition, the lower limit value Td-FBLL of the feedback term is set to be a value obtained by multiplying the feedforward term Td-FF of the braking torque command value by a coefficient KLL1.
[0043]
In step S17, the upper limit value Td-FBUL and the lower limit value Td-FB-LL of the feedback term of the braking torque command value set in step S15 or step S16, and the braking torque command value calculated in step S10. After limiting the feedback term Td-FB, the process proceeds to step S11.
In step S11, the feedforward term Td-FF of the braking torque command value calculated in step S6 and the feedback term Td-FB of the command value of braking torque calculated in step S10 or limited in step S17 The braking torque command value Td-com is obtained from the sum of the two, and is distributed to the braking fluid pressure braking torque command value Tb-com and the regenerative braking torque command value Tm-com. Here, in order to improve the fuel consumption as much as possible, the maximum regenerative torque Tmmax read in step S3 is distributed so as to be used as much as possible. Since the motor generator 15 of the present embodiment drives only the front wheels and performs regenerative braking by the road surface driving torque from the front wheels, the case division is performed as follows.
[0044]
First, in accordance with the front and rear wheel braking force distribution control map shown in FIG. 5 (for example, an ideal braking force distribution map indicating the braking torque as an absolute value), the braking torque command value Td-com is changed to the front wheel braking torque command value Td-com-. Distribute to F and rear wheel braking torque command value Td-com-R. The sum of the absolute value of the front wheel braking torque command value Td-com-F and the absolute value of the rear wheel braking torque command value Td-com-R, that is, the absolute value of the braking torque command value Td-com is the maximum value. When the regenerative torque Tmmax is less than the absolute value, only regenerative braking is performed. Both the front wheel braking fluid pressure braking torque command value Tb-com-F and the rear wheel braking fluid pressure braking torque command value Tb-com-R are set to “0”. The regenerative braking torque command value Tm-com is set to the braking torque command value Td-com.
[0045]
Further, the absolute value of the braking torque command value Td-com is not less than the absolute value of the maximum regenerative torque Tmmax, and the absolute value of the front wheel braking torque command value Td-com-F is the absolute value of the maximum regenerative torque Tmmax. If it is less than the value, regenerative braking and rear wheel braking fluid pressure braking are set, the front wheel braking fluid pressure braking torque command value Tb-com-F is set to “0”, and the rear wheel braking fluid pressure braking torque command value Tb-com-R is set. Then, a value obtained by subtracting the maximum regenerative torque Tmmax from the braking torque command value Td-com is set, and the regenerative braking torque command value Tm-com is set to the maximum regenerative torque Tmmax. Further, when the absolute value of the maximum regenerative torque Tmmax is equal to or greater than a predetermined value near “0” and the absolute value of the front wheel braking torque command value Td-com-F is equal to or greater than the absolute value of the maximum regenerative torque Tmmax. The front wheel braking fluid pressure braking torque command value Tb-com-F is set to the value obtained by subtracting the maximum regenerative torque Tmmax from the front wheel braking torque command value Tdcom-F, and the rear wheel braking fluid pressure braking is performed. The torque command value Tb-com-R is set as the rear wheel braking torque command value Td-com-R, and the regenerative braking torque command value Tm-com is set to the maximum regenerative torque Tmmax. When the absolute value of the maximum regenerative torque Tmmax is less than a predetermined value near “0”, only the braking fluid pressure braking is performed, and the front wheel braking fluid pressure braking torque command value Tb-com-F is used as the front wheel braking torque command value Td−. com-F, the rear wheel braking fluid pressure braking torque command value Tb-com-R is set as the rear wheel braking torque command value Td-com-R, and the regenerative braking torque command value Tm-com is set to "0".
[0046]
Next, the process proceeds to step S12, and the front and rear wheel braking fluid pressure braking torque command values Tb-com-F and Tb-com-R calculated in step S11 are multiplied by a predetermined vehicle specification constant K3 to calculate the front and rear wheel. Brake fluid pressure command values Pb-com-F and Pb-com-R are calculated.
Next, the process proceeds to step S13, where the regenerative braking torque command value Tm-com calculated in step S11 is output to the motor control unit 18, and the front and rear wheel braking fluid pressure command values calculated in step S12 are output. After Pb-com-F and Pb-com-R are output to the braking fluid pressure control unit 13, the program returns to the main program.
[0047]
According to this calculation process, the vehicle deceleration αV or the engine brake deceleration estimated value αeng at that time is used as the deceleration α0 immediately before the brake operation between the time when the accelerator is off and the time when the brake is on. While updating the estimated speed value αeng as the engine brake deceleration reference value αengO as needed, the braking torque command value feedforward term Td-FF for the target deceleration rate αdem is calculated. Since the braking torque command value Td-com in this state is only this braking torque command value feedforward term Td-FF, it is originally reflected in the vehicle deceleration αV by the engine braking force, and the downshift operation, etc. Unless the brake pedal is depressed, the absolute value is smaller than the value when the brake pedal is depressed. Therefore, the absolute value of the braking torque command value Td-com including only the braking torque command value feedforward term Td-FF is the maximum regeneration. When the torque Tmmax is less than the absolute value, both the front wheel braking fluid pressure braking torque command value Tb-com-F and the rear wheel braking fluid pressure braking torque command value Tb-com-R are set to “0”, and the regeneration is performed. The braking torque command value Tm-com is set to the braking torque command value Td-com.
[0048]
On the other hand, when the brake pedal is depressed, the vehicle deceleration αV or engine brake deceleration estimated value αeng at that time becomes the deceleration immediately before braking operation α0, and the engine brake deceleration estimated value αeng at that time becomes the engine braking deceleration estimated value αeng. The brake deceleration reference value αengO is stored, and using this deceleration immediately before braking operation α0 and the engine brake deceleration reference value αeng0, a reference deceleration αB corresponding to the estimated engine brake deceleration value αeng at that time is calculated, A braking torque command value feedback term Td-FB is calculated from the reference deceleration αB, the actual vehicle deceleration αV, and the reference deceleration αref, and a value obtained by adding the braking torque command value feedforward term Td-FF to the braking torque command value feedback term Td-FF Becomes the braking torque command value Td-com. At this time, if the time TJ from the accelerator off to the brake on is equal to or greater than a predetermined value TJ0 corresponding to the time when the engine braking force converges, the vehicle deceleration αV at that time is set to the deceleration α0 immediately before the brake operation. Yes. Therefore, if engine braking force, deceleration on an uphill road, or acceleration on a downhill road is acting during braking, it appears in the vehicle deceleration αV and is reflected in the deceleration α0 immediately before braking. Then, the reference deceleration αB becomes a value reflecting the influence of the acceleration and deceleration, and the braking torque command value feedback term Td-FB corresponding to the difference between the reference deceleration αB and the vehicle deceleration αV is the engine brake torque. As long as the amount of operation of the brake pedal is constant and the braking torque command value feedforward term Td-FF is the same or almost the same, the deceleration intended by the driver can be achieved. it can.
[0049]
Also, when the engine braking force changes due to a downshift or the like in the middle, the difference between the estimated engine brake deceleration value αeng and the engine brake deceleration reference value αeng0 at that time should be reflected in the reference deceleration αB. Therefore, the deceleration intended by the driver can be continuously achieved based on the braking torque command value feedback term Td-FB corresponding to the difference between the reference deceleration αB and the vehicle deceleration αV.
[0050]
When the time TJ from the accelerator off to the brake on is less than a predetermined value TJ0 corresponding to the time when the engine braking force converges, the engine brake deceleration estimated value αeng is set to the deceleration α0 immediately before the brake operation. After the engine braking force has converged, the deceleration intended by the driver can be achieved.
[0051]
FIG. 6 shows a change with time of the vehicle acceleration / deceleration by the arithmetic processing of FIG. In this timing chart, while traveling at a constant speed on a flat road, the accelerator is turned off at time t01, the brake is turned on at time t02, and the downshift is performed at time t03. Pmc is constant. When the accelerator is turned off at time t01, deceleration occurs in the vehicle due to the engine braking force, but the deceleration value gradually increases as the host vehicle traveling speed decreases (the degree of deceleration decreases). .
[0052]
When the brake is turned on at time t02, the vehicle deceleration αV at that time is set to the deceleration α0 immediately before the brake operation, and the engine brake deceleration estimated value αeng at that time is set to the engine brake deceleration reference value αeng0. . Therefore, after this time t02, the deceleration (αV−αeng0) corresponding to the amount of depression of the brake pedal is added to the previous deceleration αB (= α0). When the estimated engine brake deceleration value αeng becomes larger (smaller as the degree of deceleration), the deceleration reference value αB becomes equal to the difference between the engine brake deceleration estimated value αeng and the engine brake deceleration reference value αeng0. The vehicle deceleration αV generated by the braking fluid pressure control or the regenerative brake control increases with the decrease of the engine brake torque (the degree of deceleration). It will become smaller).
[0053]
Further, when downshifting is performed at time t03, the engine brake deceleration estimated value αeng becomes smaller (as a degree of deceleration) correspondingly, and this engine brake deceleration estimated value αeng and the engine brake deceleration reference The deceleration reference value αB becomes smaller (larger as the degree of deceleration) by the difference from the value αeng0, and the value of the vehicle deceleration αV generated by the braking fluid pressure control or the regenerative brake control is It becomes smaller by the increase in brake torque (larger as the degree of deceleration). However, since then, the engine braking force decreases as the traveling speed decreases, so that the value of the vehicle deceleration αV gradually increases (the degree of deceleration decreases).
[0054]
Incidentally, the feedback term Td-FB of the braking torque command value is limited by the upper limit value Td-FBUL and the lower limit value Td-FBLL of the feedback term of the braking torque command value. On the other hand, since the feedforward term Td-FF of the braking torque command value is not limited, it consists of an addition value of the feedforward term Td-FF of the braking torque command value and the feedback term Td-FB of the braking torque command value. In other words, the braking torque command value Td-com is limited by an addition value of the feedforward term Td-FF of the braking torque command value and the upper limit value Td-FBUL and the lower limit value Td-FBLL of the feedback term of the braking torque command value. it can. The addition value of the feedforward term Td-FF of the braking torque command value and the upper limit value Td-FBUL and the lower limit value Td-FBLL of the feedback term of the braking torque command value is used as the upper limit value Td-comUL and the lower limit value of the braking torque command value. Assuming Td-comLL, the upper limit value Td-comUL and the lower limit value Td-comLL of the braking torque command value are set as shown in FIG. 7 with respect to the master cylinder pressure Pmc. In FIG. 7, the braking torque command value is shown as an absolute value.
[0055]
That is, in the region where the master cylinder pressure Pmc is equal to or less than the predetermined value Pmc0, the upper limit value Td-FBUL and the lower limit value Td-FBLL of the feedback term of the braking torque command value become the feedforward term Td-FF of the braking torque command value. Since the multiplication value obtained by multiplying the coefficients KLU2 and KLL2 is added to the constants CLU and CLL, the constant is determined according to the increase in the feedforward term Td-FF of the master cylinder pressure Pmc, that is, the braking torque command value that is the target deceleration. It will increase from CLU and CLL. On the other hand, in a region where the master cylinder pressure Pmc is equal to or greater than the predetermined value Pmc0, the value becomes the value obtained by multiplying the feedforward term Td-FF of the braking torque command value by the coefficients KLU2 and KLL2, and therefore the master cylinder pressure Pmc, that is, the target deceleration. As the feedforward term Td-FF of a certain braking torque command value increases, it increases linearly.
[0056]
FIG. 8 shows that the upper limit value Td-FBUL and the lower limit value Td-FBLL of the feedback term of the braking torque command value (shown in absolute value) are always set to the feedforward term Td-FF of the braking torque command value by a predetermined coefficient KLU2, The value is multiplied by KLL2. Accordingly, the upper limit value Td-comUL and the lower limit value Td-comLL of the braking torque command value increase as the feedforward term Td-FF of the braking torque command value increases. Here, it is assumed that the brake pedal is depressed at time t01 and the brake pedal depression is kept constant at time t02, and thereafter, at time t03, the vehicle body deceleration αV is small (numerically due to fluctuations in the road surface protrusion and the road surface friction coefficient). Is large). Until this time t03, the vehicle body deceleration αV is well matched with the target deceleration αdem, and as a result, the braking torque command value Td-com is substantially the braking torque command value Td-FF. After time t03, the braking torque command value Tdcom is corrected to be small by the feedback term Td-FB of the braking torque command value, but is limited by the lower limit value Td-comLL of the braking torque command value.
[0057]
As is apparent from the figure, the upper limit value Td-FBUL and the lower limit value Td-FBLL of the feedback term of the braking torque command value are always multiplied by the predetermined coefficients KLU2 and KLL2 to the feedforward term Td-FF of the braking torque command value. If the vehicle deceleration αV is erroneously detected in a region where the braking torque command value Td-com is relatively large, the inappropriate braking torque command value is limited by the upper limit value Td-comUL or the lower limit value Td-comLL. Thus, the upper limit value Td-comUL or the lower limit value Td-comLL must be a relatively small absolute value. In this simulation, since the vehicle body deceleration αV is erroneously detected when the braking torque command value Td-com is relatively large, the braking torque command value Td-com is an appropriate lower limit value Td-comLL of the braking torque command value. Although it is limited, if the braking torque command value Td-com is relatively small, the braking torque command value Tdcom is small due to the feedback term Td-FB of the braking torque command value based on the vehicle body deceleration αV detected correctly. When corrected, it is limited by the upper limit value Td-comUL or the lower limit value Td-comLL of the improper braking torque command value, and there is a possibility that proper braking force control cannot be performed.
[0058]
FIG. 9 shows a feedforward term Td-FF of the braking torque command value (indicated in absolute value) when the master cylinder pressure Pmc is equal to or smaller than the predetermined value Pmc0, that is, when the target deceleration rate αdem is equal to or smaller than the predetermined value. The value obtained by multiplying the multiplication value obtained by multiplying the predetermined coefficient KUL, KLL1 by the constants CLU, CLL is the upper limit value Td-FBUL and the lower limit value Td-FBLL of the feedback term of the braking torque command value, and the master cylinder pressure Pmc is a predetermined value. When Pmc0 or more, that is, when the target deceleration rate αdem is greater than or equal to a predetermined value, a value obtained by multiplying the feedforward term Td-FF of the braking torque command value by the coefficients KLU2 and KLL2 is the upper limit value Td-FBUL of the feedback term of the braking torque command value and This is the lower limit value Td-FBLL. In such a setting, for example, when the vehicle body deceleration αV is erroneously detected in a region where the braking torque command value Td-com is relatively large, the inappropriate braking torque command value is the upper limit value Td-comUL or the lower limit value Td. Even if the upper limit value Td-comUL or the lower limit value Td-comLL is set to a relatively small absolute value as limited by -comLL, when the braking torque command value Td-com is relatively small, the constants CLU, CLL Thus, the upper limit value Td-FBUL and the lower limit value Td-FBLL of the feedback term of the braking torque command value are relatively large in absolute value. In this simulation, the vehicle body deceleration αV is erroneously detected when the braking torque command value Td-com is relatively large, and the braking torque command value Td-com is limited by the lower limit value Td-comLL of the appropriate braking torque command value. However, if the braking torque command value Td-com is relatively small, the braking torque command value Tdcom is small due to the feedback term Td-FB of the braking torque command value generated by the vehicle body deceleration αV detected correctly. When corrected, appropriate braking force control can be continued without being limited by the upper limit value Td-comUL or the lower limit value Td-comLL of the braking torque command value.
[0059]
Incidentally, in the above embodiment, when the master cylinder pressure Pmc is equal to or smaller than the predetermined value Pmc0, that is, the target deceleration rate αdem is equal to or smaller than the predetermined value, the feedforward term Td-FF of the braking torque command value is predetermined as shown in FIG. Although the values obtained by adding the constants CLU and CLL to the multiplication value multiplied by the coefficients KUL2 and KLL2 are shown as the upper limit value Td-FBUL and lower limit value Td-FBLL of the feedback term of the braking torque command value, the target deceleration is shown. The upper limit value Td-FBUL and the lower limit value Td-FBLL of the feedback term of the braking torque command value when αdem is equal to or smaller than a predetermined value are not limited to the above embodiment, and are, for example, a predetermined constant as shown in FIG. The upper limit value Td-FBUL and the lower limit value Td-FBLL (both are expressed as absolute values) may be limited by values, and as shown in FIG. Lower limit value Td-FBLL (both shown as absolute values It may be. By doing so, even when the detected vehicle deceleration αV is not correct, the amount of change in the braking torque command value based on the detected vehicle deceleration αV can be limited to a small extent, and occupant discomfort can be suppressed and prevented. Appropriate braking force can be generated, and braking force control can be within an appropriate range.
[0060]
From the above, step S4 of the arithmetic processing of FIG. 3 constitutes the target deceleration setting means of the present invention, and similarly, the driving wheel speed sensor 20 and step S2 of the arithmetic processing of FIG. The pump 21, the pressure increasing valve 8, the pressure reducing valve 9, and the wheel cylinder 5 constitute a braking means, and steps S14 to S16 of the arithmetic processing in FIG. 3 constitute a braking force command value upper / lower limit value setting means. In addition, Steps S6 to S13 and Step S17 of the arithmetic processing in FIG. 3 constitute a braking control means.
[Brief description of the drawings]
FIG. 1 is a schematic system configuration diagram showing an example of a braking control device of the present invention.
FIG. 2 is a block diagram of braking torque command value calculation performed by a regenerative cooperative brake control control unit.
FIG. 3 is a flowchart of a calculation process for calculating a braking fluid pressure command value and a regenerative torque command value based on the calculation of the braking torque command value in FIG. 2;
4 is a control map used in the arithmetic processing of FIG.
FIG. 5 is a control map used in the arithmetic processing of FIG.
6 is a timing chart showing changes in vehicle deceleration due to the arithmetic processing in FIG. 3;
7 is an explanatory diagram of a braking torque command value set in the calculation process of FIG. 3 and its upper limit value and lower limit value. FIG.
FIG. 8 is an explanatory diagram of a braking torque command value when a vehicle body deceleration is erroneously detected.
FIG. 9 is an explanatory diagram of a braking torque command value when a vehicle body deceleration is erroneously detected by the calculation process of FIG. 3;
10 is an explanatory diagram of a modified example of a braking torque command value and its upper limit value and lower limit value set in the calculation process of FIG. 3;
11 is an explanatory diagram of a modified example of a braking torque command value and its upper limit value and lower limit value set in the calculation process of FIG. 3;
[Explanation of symbols]
1 is a brake pedal 3 is a master cylinder 5 is a wheel cylinder 6 is a stroke simulator 7 is a stroke simulator switching valve 8 is a pressure increasing valve 9 is a pressure reducing valve 10 is a wheel 11 is a master cylinder pressure sensor 12 is a wheel cylinder pressure sensor 13 is a brake fluid pressure The control unit 15 is a motor generator 18, the motor control unit 19 is a regenerative cooperative brake control control unit 24 is a stroke sensor.

Claims (4)

A target deceleration setting means for setting a target deceleration from a braking operation amount of the occupant, a deceleration detection means for detecting a deceleration generated in the vehicle, a braking means for applying a braking force to each wheel, and the braking means A braking force command value upper / lower limit value setting means for setting an upper limit value and a lower limit value of the braking force command value, a reference value corresponding to the target deceleration set by the target deceleration setting means, and the deceleration detection means The braking force command value is set from the correction amount corresponding to the detected deceleration, and the braking force command value is set to the upper and lower limits of the braking force command value set by the braking force command value upper and lower limit setting means. A braking control means for controlling the braking force applied to each wheel by the braking means based on the restricted braking force command value.
The braking force command value upper / lower limit value setting means multiplies a reference value corresponding to the target deceleration by a predetermined ratio when the target deceleration set by the target deceleration setting means is a predetermined value or more. A braking control device, wherein an upper limit value and a lower limit value of the braking force command value are set by setting an upper limit value and a lower limit value of the correction amount. The braking force command value upper and lower limit value setting means sets a predetermined constant value as the upper limit value and lower limit value of the correction amount when the target deceleration set by the target deceleration setting means is less than the predetermined value. The braking control device according to claim 1, wherein an upper limit value and a lower limit value of the braking force command value are set. The braking force command value upper and lower limit value setting means multiplies a reference value corresponding to the target deceleration by a predetermined ratio when the target deceleration set by the target deceleration setting means is less than the predetermined value. The upper limit value and the lower limit value of the braking force command value are set by setting an addition value of a multiplication value and a predetermined constant value as an upper limit value and a lower limit value of the correction amount. The braking control device described. The braking control device according to claim 3, wherein the braking force command value upper and lower limit value setting means sets an upper limit value and a lower limit value of the addition value at a predetermined constant value.

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