JP2004125001A - Clutch controller for automatic transmission of vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a clutch controller preventing the seizure of a clutch plate by correctly grasping a state of the clutch plate of a friction clutch device in a mechanical automatic transmission. <P>SOLUTION: This clutch controller comprises an energy calculating means for calculating the absorbed energy of the clutch plate in a half-connected state of the clutch plate on the basis of a rotating speed of an engine, an input shaft rotating speed of the mechanical transmission, and the movement of the clutch plate of the friction clutch plate in the half-connected state of the clutch plate (S20), a clutch state determining means for determining the state of the clutch plate by comparing the absorbed energy calculated by the energy calculating means with a specified value, and a seizure preventing means for preventing the seizure of the clutch plate, when the calculated absorbed energy is more than the specified value (S40). <P>COPYRIGHT: (C)2004,JPO

Description

【００３６】
ここで、Ｎｅはエンジン回転速度（ｒｐｍ）、Ｎｃｌはクラッチ板１２の回転速度（ｒｐｍ）である。また、Ｔｃｌはクラッチ板１２の伝達トルク（Ｎｍ）であり、ｔ１は伝達トルクＴｃｌの立ち上がり時の時刻（ｓｅｃ）、ｔ２はエンジン回転速度Ｎｅとクラッチ板１２の回転速度Ｎｃｌとが同期した時の時刻（ｓｅｃ）である。
上述のクラッチ板１２の伝達トルクＴｃｌは、クラッチストロークセンサ１７によるクラッチ板１２のストローク量からマップを用いて算出される。具体的には、このマップは、ＥＣＵ８０内に記憶されており、ストローク量が大きくなるにしたがって伝達トルクＴｃｌが単双曲線的に小さくなる関係を有している。
【００３７】
ところで、クラッチ板１２の半クラッチ状態とは、フライホイール１０とクラッチ板１２とが係合を開始した時点と、フライホイール１０とクラッチ板１２とが完全に係合する直前の時点との間を意味する。
以下、この半クラッチ状態を上述の各パラメータを用いて説明する。
まず、クラッチ板１２がフライホイール１０から最も離れた位置（ストローク量が最大値）においては、エンジン１の出力が変速機４に伝達されていない。一方、クラッチ板１２がエンジン出力軸２に向けて移動し始めると、すなわち、クラッチ板１２のストローク量が減少し始めると、後にフライホイール１０とクラッチ板１２とが係合を開始して、エンジン１の出力が僅かながらも変速機４に伝達されてクラッチ板１２の回転速度Ｎｃｌが立ち上がる。この時刻が伝達トルクの立ち上がり時の時刻ｔ１であり、半クラッチ状態の開始時点である。
【００３８】
そして、クラッチ板１２のストローク量が減少するに伴って、フライホイール１０とクラッチ板１２との係合状態が増すことから、クラッチ板１２の伝達トルクＴｃｌが大きくなり、クラッチ板１２の回転速度Ｎｃｌが上昇するとともに、エンジン回転速度Ｎｅが低下する。
その後、クラッチ板１２のストローク量がさらに減少して、エンジン回転速度Ｎｅとクラッチ板１２の回転速度Ｎｃｌとの差がなくなり、クラッチ板１２の回転速度Ｎｃｌがエンジン回転速度Ｎｅに同期すると、フライホイール１０とクラッチ板１２とが完全に係合する。この時刻がエンジン回転速度とクラッチ板１２の回転速度との同期時の時刻ｔ２であり、半クラッチ状態の終了時点である。
【００３９】
そして、エンジン回転速度Ｎｅとクラッチ板１２の回転速度Ｎｃｌとが同期した後は、クラッチ板１２のストローク量が最小値まで減少される。
このような半クラッチ状態において、フライホイール１０とクラッチ板１２とが係合を開始した半クラッチ状態の開始時点（クラッチ板１２のストローク量が減少を始める時点）では、エンジン回転速度Ｎｅとクラッチ板１２の回転速度Ｎｃｌとの差が大きく、クラッチ板１２の伝達トルクＴｃｌが小さいものの、クラッチ板１２では、フライホイール１０との当接部分を中心とした摩擦負荷により局部的な温度変化が生じる。これに対し、フライホイール１０とクラッチ板１２とが完全に係合する直前の半クラッチ状態の終了時点（ストローク量が最小値に近づき、エンジン回転速度Ｎｅとクラッチ板１２の回転速度Ｎｃｌとが同期した時点）では、エンジン回転速度Ｎｅとクラッチ板１２の回転速度Ｎｃｌとの差がなくなり、クラッチ板１２の伝達トルクＴｃｌが大きくなって摩擦負荷が大きくなり、クラッチ板１２の全体に亘る温度変化が生じる。
【００４０】
すなわち、クラッチ板１２には、クラッチ板１２のストローク量が減少を始める時点からエンジン回転速度Ｎｅとクラッチ板１２の回転速度Ｎｃｌとが同期した時点までの間において、各係合状態に応じた摩擦負荷が継続して与えられてクラッチ板１２を昇温させている。
このことは、エンジン回転速度Ｎｅが大きくなるに連れて、また、クラッチ板１２の回転速度Ｎｃｌが立ち上がってからエンジン回転速度Ｎｅに同期するまでの時間が長くなるに連れて摩擦負荷の継続時間が長くなり、クラッチ板１２に蓄えられる吸収エネルギｅが大きくなり、クラッチ板１２の温度が上昇し、クラッチ板１２の焼けが生じやすいことを意味している。つまり、摩擦負荷の大きさと摩擦負荷の継続時間の長さ、すなわち、クラッチ板１２の吸収エネルギｅがクラッチ板１２の焼けに大きな影響を及ぼしているのである。
【００４１】
以上のことを鑑み、本発明のクラッチ制御装置では、クラッチ板１２のストローク量に基づき半クラッチ状態でのクラッチ板１２の吸収エネルギｅを求め、当該吸収エネルギｅを判定指標としてクラッチ板１２の状態を判定するようにしている。
図２は、本発明の第１実施例におけるクラッチ制御の制御ルーチンを示すフローチャートである。該第１実施例のクラッチ制御装置では、エンジンストールを起こさせてクラッチ板１２の焼けの防止を図っている。
【００４２】
図２のステップＳ１０でクラッチ板１２が半クラッチ状態にある場合に、ステップＳ２０では、エネルギ算出手段にて、エンジン回転センサ８、入力軸回転センサ７７及びクラッチストロークセンサ１７からの各出力信号に基づき、半クラッチ状態におけるクラッチ板１２の吸収エネルギｅを算出しステップＳ３０に進む。
【００４３】
ステップＳ３０では、クラッチ状態判定手段にて、この吸収エネルギｅが規定値以上であるか否かが判定され、吸収エネルギｅが規定値以上である場合、すなわちＹＥＳのときには、ステップＳ４０に進む。一方、吸収エネルギｅが規定値以上ではないときには、ステップＳ２０に進んで吸収エネルギｅの計算を行う。
ステップＳ４０では、クラッチ板１２が焼け状態になり得ることから、焼け防止手段にて電空比例制御弁３１への駆動信号の供給を停止して、エアシリンダユニット１６への作動エアの供給を遮断することにより、クラッチ装置３が半クラッチ状態から接状態とされる。そして、クラッチ接状態に伴ってエンジン１が停止される。そして、このエンジンストール状態で一連の動作を終了する。
【００４４】
これにより、エンジンストールになるものの、焼け状態になり得る現在の半クラッチ状態を終了することができ、クラッチ板１２の焼けを確実に防止することができる。
図３は、本発明の第２実施例におけるクラッチ制御の制御ルーチンを示すフローチャートである。該第２実施例のクラッチ制御装置では、クラッチ板１２を断状態で駆動輪に自動ブレーキを生じさせてクラッチ板１２の焼けの防止を図っている。
【００４５】
図３のステップＳ１０からステップＳ３０までは、第１実施例と同様であり、ステップＳ１０で半クラッチ状態にある場合に、ステップＳ２０で、エネルギ算出手段にて半クラッチ状態における吸収エネルギｅを算出したらステップＳ３０に進み、クラッチ状態判定手段にて、この吸収エネルギｅが規定値以上であるか否かを判定し、吸収エネルギｅが規定値以上であるときにはステップＳ５０に進む。一方、吸収エネルギｅが規定値以上ではないときにはステップＳ２０に進んで吸収エネルギｅの計算を行う。
【００４６】
ステップＳ５０では、クラッチ板１２が焼け状態になり得ることから、焼け防止手段にてクラッチ装置３を半クラッチ状態から断状態にしてステップＳ５１に進み、自動ブレーキをオン、つまり、電磁弁ＭＶＱ４４を自動的に閉弁させてホイールブレーキ４０による制動力を生じさせてステップＳ５２に進む。
ステップＳ５２では、ブレーキペダル５０が踏み込まれているか否かが判定され、ブレーキペダル５０が踏み込まれている場合、すなわちＹＥＳのときには、ステップＳ５３に進んで上述の自動ブレーキをオフにして一連の動作を終了する。一方、ステップＳ５２でブレーキペダル５０が踏み込まれていないときには、ステップＳ５１に進んで自動ブレーキをオンのまま維持する。なお、自動ブレーキを生じさせる場合には、いわゆる坂道発進補助装置を利用することも考えられる。
【００４７】
これにより、現在の半クラッチ状態を終了させてクラッチ板１２の焼けを確実に防止することができるとともに、車輪に自動ブレーキを生じさせているので、登坂路でも車両が後退することなく停止させることができる。さらに、車輪に手動によるブレーキが生じたときには自動ブレーキを解除しており、車両の再発進を可能にすることができる。
【００４８】
図４は、本発明の第３実施例におけるクラッチ制御の制御ルーチンを示すフローチャートである。該第３実施例のクラッチ制御装置では、シフトダウンを行ってクラッチ板１２の焼けの防止を図っている。
図４のステップＳ１０からステップＳ３０までは、第１及び第２実施例と同様であり、ステップＳ１０で半クラッチ状態にある場合に、ステップＳ２０で吸収エネルギｅを算出したらステップＳ３０に進み、吸収エネルギｅが規定値以上であるときにはステップＳ６０に進む。一方、吸収エネルギｅが規定値以上ではないときにはステップＳ２０に進んで吸収エネルギｅの計算を行う。
【００４９】
ステップＳ６０では、クラッチ板１２が焼け状態になり得ることから、焼け防止手段にてクラッチ装置３を半クラッチ状態から断状態にしてステップＳ６１に進み、自動ブレーキをオンにし、ホイールブレーキ４０による制動力を生じさせてステップＳ６２に進む。
ステップＳ６２では、現在の速度段（例えば二速段）を強制的に低速段（例えば一速段）へシフトダウンしてステップＳ６３に進む。ステップＳ６３では、ギヤ位置センサ６８からの出力信号に基づいてシフトダウンが完了しているか否かを判定し、シフトダウンが完了している場合、すなわちＹＥＳのときには、ステップＳ６４に進んで上述の自動ブレーキをオフにしてステップＳ６５に進み、半クラッチ状態にして上記低速段での接続を試み、ステップＳ６６に進んで吸収エネルギｅを計算してステップＳ６７に進む。一方、ステップＳ６３でシフトダウンが完了していないときには、自動ブレーキをオンのまま維持してシフトダウンを継続する。
【００５０】
ステップＳ６７では、クラッチ状態判定手段にて、シフトダウン後の半クラッチ状態の吸収エネルギｅが規定値以上であるか否かを判定し、吸収エネルギｅが規定値以上である場合、すなわちＹＥＳのときには、ステップＳ５０に進む。一方、吸収エネルギｅが規定値以上ではないときには、ステップＳ６６に進んで吸収エネルギｅの計算を行う。
【００５１】
ステップＳ６７で吸収エネルギｅが規定値以上であるとき以降は、第２実施例と同様であり、ステップＳ５０では、焼け防止手段にてクラッチ装置３を半クラッチ状態から断状態にしてステップＳ５１に進み、自動ブレーキをオンにしてホイールブレーキ４０による制動力を生じさせてステップＳ５２に進む。ステップＳ５２では、ブレーキペダル５０が踏み込まれているか否かを判定し、ブレーキペダル５０が踏み込まれているときには、ステップＳ５３に進んで上述の自動ブレーキをオフにして一連の動作を終了する。一方、ステップＳ５２でブレーキペダル５０が踏み込まれていないと判定されたときには、ステップＳ５１に進んで自動ブレーキをオンのまま維持する。
【００５２】
これにより、伝達トルクを低減して摩擦負荷を減少させるようにし、焼け状態になり得る現在の半クラッチ状態を終了させてクラッチ板１２の焼けを確実に防止することができ、さらに、車輪に自動ブレーキを生じさせているので、登坂路でも車両が後退することなく停止させることができる。しかも、ドライバが意図する速度段よりもシフトダウンさせていることから、クラッチ板１２への負担を減らすことからもクラッチ板１２の焼けを確実に防止することができるとともに、車両の再発進を容易することができる。また、シフトダウンさせた後に、万一、吸収エネルギｅが規定値以上であるときには、クラッチ板１２を再び断状態にしてから自動ブレーキを再び生じさせているので、クラッチ板１２の焼けをより一層確実に防止することができる。
【００５３】
なお、ステップＳ６２のシフトダウンを実行する際に、ステップＳ６１により自動ブレーキをオンにして制動力を生じさせているが、車両が後退するおそれがない状態にある等の場合には、自動ブレーキをオンにすることなく、図中に破線で示すように、ステップＳ６０でクラッチ装置３を断状態にした後にステップＳ６２に進み、シフトダウンを実行するようにしても良い。
【００５４】
図５は、本発明の第４実施例におけるクラッチ制御の制御ルーチンを示すフローチャートである。該第４実施例のクラッチ制御装置では、ドライバにクラッチ板１２を手動で断状態にさせてクラッチ板１２の焼けの防止を図っている。
図５のステップＳ１０からステップＳ３０までは、第１から第３実施例と同様であり、ステップＳ１０で半クラッチ状態にある場合に、ステップＳ２０で吸収エネルギｅを算出したらステップＳ３０に進み、吸収エネルギｅが規定値以上であるときにはステップＳ６０に進む。一方、吸収エネルギｅが規定値以上ではないときにはステップＳ２０に進んで吸収エネルギｅの計算を行う。
【００５５】
ステップＳ７０では、クラッチ板１２が焼け状態になり得ることから、焼け防止手段にて警告手段９０を介してドライバに警告を開始してステップＳ７１に進む。この警告には、例えば、ブザーを鳴らしたり、警告ランプを点灯させたり、クラッチ手動操作部７６のクラッチペダルを振動させてドライバに伝えること等が考えられる。
【００５６】
ステップＳ７１では、上述のクラッチペダルが踏み込まれて、クラッチ板１２が断状態にあるか否かを判定し、クラッチペダルが踏み込まれている場合、すなわちＹＥＳのときには、ステップＳ７２に進んで警告を終了させ、ステップＳ７３でクラッチ装置３の操作を自動モードから手動モードに変更して一連の動作を終了する。一方、ステップＳ７１でクラッチペダルが踏み込まれていないときには、ステップＳ７０に進んでドライバへの警告を維持する。
【００５７】
これにより、やはり現在の半クラッチ状態を終了させて、クラッチ板１２の焼けを確実に防止することができる。なお、本実施形態の焼け防止手段は、ドライバが手動でクラッチペダルを踏み込むまでは半クラッチ状態を継続し得る。よって、ステップＳ３０の規定値は、上述の第１から第３実施例の規定値よりも低めの値であることが望ましい。
【００５８】
このように、本発明の車両用自動変速機のクラッチ制御装置では、エネルギ算出手段においてクラッチ板１２のストローク量から半クラッチ状態におけるクラッチ板１２に蓄えられる吸収エネルギｅを算出し、これをクラッチ板１２の状態の判定指標としているので、継続した摩擦負荷が生じているクラッチ板の状態を正確に把握することができる。これにより、特に、トルクコンバータ付き乗用車に慣れたドライバ及び二速発進を基本とする大型車のドライバが登坂路で半クラッチ状態を継続させて車両を停止させる操作を行うときのクラッチ板１２の焼けを防止することができる。
【００５９】
以上で本発明の一実施形態についての説明を終えるが、本発明は上記実施形態に限定されるものではなく、本発明の趣旨を逸脱しない範囲で種々の変更ができるものである。
例えば、上記第３実施例では、シフトダウンさせた後に、万一、吸収エネルギｅが規定値以上であるときには、クラッチ板１２を再び断状態にしてから自動ブレーキを再び生じさせているが、この形態に限られるものではなく、例えば、第１実施例と同様に、シフトダウンさせた後に、万一、吸収エネルギｅが規定値以上であるときには、クラッチ装置３を接状態にしてエンジンストールを起こさせても良く、この場合にも、上記と同様にクラッチ板１２の焼けをより一層確実に防ぐことができるとの効果を奏するものである。
【００６０】
また、クラッチ板１２の半クラッチ状態とは、フライホイール１０とクラッチ板１２とが係合を開始した時点と、フライホイール１０とクラッチ板１２とが完全に係合する直前の時点との間であれば、上記実施形態の如くフライホイール１０とクラッチ板１２とが係合を開始した時点から始まり、フライホイール１０とクラッチ板１２とが完全に係合する直前の時点を終わりとすることに限定されるものではなく、その始まりの時点と終わりの時点とが反対の場合であっても良く、この場合にも上記と同様に吸収エネルギｅをクラッチ板１２の状態の判定指標とすることができる。
【００６１】
【発明の効果】
以上の説明から理解できるように、請求項１記載の本発明の車両用自動変速機のクラッチ制御装置によれば、クラッチ板の状態を判定するにあたり、クラッチ板の移動量に基づく半接状態におけるクラッチ板の吸収エネルギを判定指標として採用しているので、クラッチ板の状態を正確に把握することができる。これにより、クラッチ板が焼けてその後の車両走行が困難になる状態を回避し、路上故障の減少を図ることができる。
【００６２】
また、請求項２記載の発明によれば、焼け防止手段がクラッチ板を強制的に半接状態から接状態にしてエンジンを停止させているので、現在の半接状態の継続によるクラッチ板の焼けを確実に防止することができる。
さらに、請求項３記載の発明によれば、焼け防止手段がクラッチ板を強制的に半接状態から断状態にするとともに、車輪に対して自動的な制動力を生じさせているので、現在の半接状態の継続によるクラッチ板の焼けを確実に防止することができるほか、登坂路における車両の後退をも防止することができる。
【００６３】
さらにまた、請求項４記載の発明によれば、焼け防止手段が変速機を強制的にシフトダウンさせているので、現在の半接状態の継続によるクラッチ板の焼けを確実に防止することができるほか、車両の再発進を容易にすることができる。
また、請求項５記載の発明によれば、焼け防止手段がクラッチ板を手動にて半接状態から断状態にさせているので、この場合にも、現在の半接状態の継続によるクラッチ板の焼けを確実に防止することができる。
【図面の簡単な説明】
【図１】本発明の一実施形態に係る車両用自動変速機のクラッチ制御装置が適用される車両の駆動系の全体構成図である。
【図２】本発明の第１実施例におけるクラッチ制御の制御ルーチンを示すフローチャートである。
【図３】本発明の第２実施例におけるクラッチ制御の制御ルーチンを示すフローチャートである。
【図４】本発明の第３実施例におけるクラッチ制御の制御ルーチンを示すフローチャートである。
【図５】本発明の第４実施例におけるクラッチ制御の制御ルーチンを示すフローチャートである。
【符号の説明】
１　エンジン
３　クラッチ装置
４　機械式の変速機
８　エンジン回転センサ
１０　フライホイール
１２　クラッチ板
１７　ストロークセンサ
７６　クラッチ手動操作部
７７　入力軸回転センサ
８０　ＥＣＵ（電子コントロールユニット）
９０　警告手段[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a clutch control device for an automatic transmission for a vehicle, and more particularly, to a technology for preventing scorching of a clutch plate of a friction clutch device capable of automatically connecting and disconnecting a connection between an engine and a mechanical transmission. About.
[0002]
[Prior art]
2. Description of the Related Art Generally, an automatic transmission in which a shift operation is automated is used as a vehicle transmission. In the case of a small vehicle, the automatic transmission is often a fluid type transmission employing a torque converter. On the other hand, in the case of a large vehicle such as a bus or a truck, the transmission amount of the driving torque is large, so that it is difficult for the torque converter to sufficiently transmit the driving torque. Therefore, in the case of a large vehicle, a mechanical transmission is used.
[0003]
This mechanical transmission includes a mechanical automatic transmission equipped with a friction type clutch device that can automatically connect and disconnect the connection between the engine and the transmission. The clutch plate is automatically controlled according to the shift timing. In addition, a large drive torque is transmitted by the automatic transmission. Also, when the vehicle is stopped, the clutch plate is automatically controlled, thereby preventing engine stall.
[0004]
Here, in the above-mentioned mechanical automatic transmission, it is possible to perform a gearshift without depressing the accelerator pedal and keeping the accelerator pedal depressed. Further, depending on the depression operation of the accelerator pedal, the clutch plate may be exposed to the half-contact state (half-clutch state) for a long time. For example, when stopping the vehicle on an uphill road, it is conceivable to slightly depress the accelerator pedal without depressing the brake pedal. This operation is particularly common for drivers who are used to passenger cars with a torque converter. Further, in large vehicles such as trucks, many drivers start at the second speed, so it is conceivable that the vehicle runs at a low speed while using a half clutch at the second speed on an uphill road.
[0005]
However, when the state of the half clutch continues for a long time, there is a problem that the clutch plate generates heat due to friction between the engine output shaft (flywheel) and the clutch plate, and the clutch plate is burnt. This clutch burn makes it difficult to drive the vehicle thereafter.
In order to solve this problem, a technique of an automatic clutch control device configured to calculate the temperature of the clutch plate by simulation and forcibly terminate the half-clutch state when the temperature exceeds a predetermined temperature is proposed. It has been proposed (for example, see Patent Document 1).
[0006]
[Patent Document 1]
JP-A-6-56526 (paragraphs 0007 to 0010, FIG. 2 and the like)
[0007]
[Problems to be solved by the invention]
By the way, the automatic clutch control device disclosed in the above publication is configured to calculate the temperature of the clutch plate in the half-clutch state based on the engine rotation speed and the rotation speed of the transmission without using the temperature sensor, The state of the clutch plate is determined with an inexpensive configuration.
[0008]
However, it is not always appropriate to determine the state of the clutch plate based on the temperature generated in the clutch plate. This is because at a time immediately before the flywheel and the clutch plate, which is one mode of the half-clutch state, are completely engaged, the frictional load is large due to the large transmission torque of the clutch plate, and the temperature change occurs over the entire clutch plate. On the other hand, when the flywheel and the clutch plate, which are also in a half-clutch state, start to engage with each other, although the transmission torque of the clutch plate is small, the portion of the clutch plate in contact with the flywheel. This is because a local temperature change may occur due to a frictional load centered on. In other words, this local temperature change is difficult to be transmitted to the entire clutch plate and is hardly determined as the state of the clutch plate, but causes a burn of the clutch plate in the corresponding portion. In addition, since the inner peripheral side and the outer peripheral side of the clutch plate have different peripheral speeds and different temperatures, it is considered difficult to accurately grasp the state of the clutch plate based on the temperature generated in the clutch plate.
[0009]
That is, even if the temperature of the clutch plate is calculated based on the engine rotation speed, the rotation speed of the transmission, and the like, there is a problem that the state of the clutch plate cannot be accurately grasped.
The present invention has been made in view of such a problem, and in a mechanical automatic transmission, a clutch control device capable of accurately grasping a state of a clutch plate of a friction clutch device and preventing a scorch of the clutch plate. The purpose is to provide.
[0010]
[Means for Solving the Problems]
In order to achieve the above object, a clutch control device for an automatic transmission for a vehicle according to the present invention according to the first aspect of the present invention includes: an engine speed, an input shaft speed of a mechanical transmission, and an output of the engine. Based on the amount of movement of the clutch plate of the friction clutch device capable of automatically connecting and disconnecting the engine and the transmission to transmit to the drive wheels, the absorbed energy in the half-contact state of the clutch plate is calculated. Energy calculating means, clutch state determining means for comparing the absorbed energy calculated by the energy calculating means with a specified value to determine the state of the clutch plate, and the calculated absorbed energy by the clutch state determining means. When it is determined that the value is equal to or more than the specified value, a scoring prevention means for preventing scorching of the clutch plate is provided.
[0011]
Here, the present invention has been made based on the knowledge that it is necessary to consider the absorbed energy of the clutch plate in the half-contact state in determining the state of the clutch plate. That is, the clutch plate has a frictional load corresponding to each engagement state as described above, and furthermore, the time when the engine output shaft (flywheel) and the clutch plate start engaging, and the time when the flywheel and the clutch plate And a friction load that is continuous between immediately before and when the clutch plate is completely engaged. The absorbed energy of the clutch plate stored in the clutch plate due to the continuation of the friction load determines the state of the clutch plate. We think that it is appropriate as an indicator. For this purpose, it is necessary to particularly consider the amount of movement of the clutch plate, which indicates the engagement relationship between the flywheel and the clutch plate.
[0012]
Therefore, in determining the state of the clutch plate, the absorbed energy is calculated in consideration of the amount of movement of the clutch plate, and the state of the clutch plate is accurately grasped. As a result, it is possible to avoid a difficult state in which the vehicle travels thereafter due to the scorching of the clutch plate, and to reduce road failures.
Further, in the invention according to claim 2, the burn prevention means stops the engine by changing the clutch plate from the semi-contact state to the contact state, that is, when the engine stop is induced, The feature is to prevent burning. As a result, the current half-contact state of the clutch plate is terminated, and burning of the clutch plate due to the continuation of the half-contact state is reliably prevented.
[0013]
Further, in the invention according to claim 3, the scoring prevention means prevents the scoring of the clutch plate by setting the clutch plate from the semi-contacted state to the disconnected state, and automatically prevents the clutch plate from burning. It is characterized by generating a realistic braking force. As a result, the current half-contact state ends, and the scorching of the clutch plate is reliably prevented. In addition, since an automatic braking force is generated on the driving wheels, the vehicle does not move backward even on an uphill road.
[0014]
It is preferable that the burn prevention means releases the automatic braking force when a manual braking force is separately applied to the drive wheels, and prepares for the restart of the vehicle.
The invention according to claim 4 is characterized in that the burn prevention means prevents the clutch plate from burning by shifting down the transmission. This also terminates the half-contact state at the current gear position and shifts to a lower gear speed than the speed gear intended by the driver, thereby reducing the load on the clutch plate and preventing the clutch plate from burning. This makes it possible to restart the vehicle easily.
[0015]
Preferably, the anti-burn means shifts down the transmission in a state where the clutch plate is shifted from the semi-contact state to the disconnected state when shifting down the transmission, and after the shift-down is completed, the clutch plate is again shifted. It is better to be in a semi-contact state. Then, after the clutch plate is shifted to the half-contact state again, if the absorbed energy exceeds the specified value, the clutch plate is brought into the contact state and the engine is stopped, or the clutch plate is again disconnected. In addition, it is preferable to prevent the clutch plate from burning by generating the automatic braking force again.
[0016]
Further, in the invention according to claim 5, the clutch device can be further manually connected and disconnected, and the burn prevention means issues a warning when the calculated absorbed energy is equal to or more than the specified value. In response to the warning, it is urged that the clutch plate is manually disengaged to prevent burning of the clutch plate. This also terminates the current half-contacted state and prevents the clutch plate from burning.
[0017]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 shows an entire configuration of a drive system of a vehicle to which a clutch control device for a vehicle automatic transmission according to the present invention is applied. Hereinafter, the configuration of the clutch control device of the automatic transmission for a vehicle will be described with reference to FIG.
[0018]
As shown in FIG. 1, a diesel engine (hereinafter, referred to as an engine) 1 is provided with a fuel injection pump unit (hereinafter, referred to as an injection pump) 6 for supplying fuel. The injection pump 6 is a device that operates the pump by the output of the engine 1 transmitted via a pump input shaft (not shown) to inject fuel. The injection pump 6 is provided with a control rack (not shown) for adjusting a fuel injection amount, and further provided with a rack position sensor 9 for detecting a rack position of the control rack. In the vicinity of the pump input shaft, an engine rotation sensor 8 for detecting the rotation speed of the pump input shaft and detecting the rotation speed of the engine output shaft 2, that is, the engine rotation speed Ne, based on the rotation speed is provided. .
[0019]
An engine output shaft 2 extends from the engine 1. The engine output shaft 2 is connected to an input shaft 20 of a mechanical transmission (hereinafter simply referred to as a transmission) 4 having a gear mechanism via a clutch device 3. It is connected. As a result, the output of the engine 1 is transmitted to the transmission 4 via the clutch device 3, and the transmission 4 shifts. The transmission 4 is a mechanical automatic transmission having, for example, five forward gears (first gear to fifth gear) in addition to the reverse gear, and is configured to be capable of manual gear shifting as well as automatic gear shifting. ing. The clutch device 3 is configured to be automatically connected and disconnected when the transmission 4 is automatically shifted and when the vehicle stops and starts.
[0020]
In the clutch device 3, the clutch plate 12 is brought into pressure contact with the flywheel 10 by the pressure spring 11 to bring the clutch plate 12 into a connected state (contact state), while the clutch plate 12 is separated from the flywheel 10 to bring it into a disconnected state (disconnected state). This is a clutch device capable of automatically performing such an operation of a normal mechanical friction clutch. That is, the clutch plate 12 can be automatically operated by the clutch actuator for clutch connection / disconnection, that is, the air cylinder unit 16 via the outer lever 12a.
[0021]
Specifically, an air tank 34 is connected to the air cylinder unit 16 via an air passage 30. Therefore, when the working air is supplied from the air tank 34 through the air passage 30, the air cylinder unit 16 automatically operates. As a result, the clutch plate 12 moves, and the clutch device 3 is automatically connected / disconnected.
[0022]
Actually, the air passage 30 is provided with an electro-pneumatic proportional control valve 31 which is driven in accordance with a signal from an ECU (electronic control unit) 80 to perform the flow and cutoff of the working air. When supplied from the ECU 80 to the electropneumatic proportional control valve 31, working air is supplied from the air tank 34 to the air cylinder unit 16 via the electropneumatic proportional control valve 31 to operate, and the clutch device 3 is disengaged. On the other hand, when the supply of the drive signal is stopped, the supply of the working air from the air tank 34 to the air cylinder unit 16 is cut off, and the working air in the air cylinder unit 16 is discharged into the atmosphere, and the pressure of the pressure spring 11 is reduced. The clutch device 3 is brought into the connected state by the action.
[0023]
Although the air cylinder unit 16 is used as the clutch actuator, the present invention is not limited to this configuration. For example, the clutch actuator is configured by an electric actuator such as a hydraulic actuator or an electric motor. May be configured to be automatically connected and disconnected. As described above, the clutch device 3 mainly operates to automatically connect and disconnect the clutch plate 12. However, in order to allow the clutch plate 12 to be manually connected and disconnected as needed. , A manual clutch operating section 76.
[0024]
A clutch stroke sensor 17 that detects the amount of movement of the clutch plate 12 relative to the position of the flywheel 10, that is, the amount of stroke of the clutch plate 12, is attached to the air cylinder unit 16. The clutch stroke sensor 17 is electrically connected to the ECU 80. It is connected to the.
An air passage 39 branches from the air passage 30 and extends. An air master 42 is connected to the tip of the air passage 39. The air master 42 is an actuator for generating a braking force on the driving wheels by operating the wheel brake 40. The air master 42 is driven by the supply of the operating air from the air tank 34 through the air passage 39, and is controlled by the wheel brake 40. Generate power. Although only one wheel brake 40 and one air master 42 are shown here, these wheel brakes 40 and air master 42 are provided for each wheel.
[0025]
Actually, an electromagnetic valve MVQ44 driven by a signal from the ECU 80 is interposed in the air passage 39, and the air supplied from the air tank 34 to the air master 42 from the air tank 34 according to the operation / non-operation of the electromagnetic valve MVQ44. The switching between the cutoff and the communication is controlled. When the solenoid valve MVQ44 operates to shut off the air, a braking force by the wheel brake 40 is generated.
[0026]
Specifically, when the brake pedal 50 is depressed, a brake sensor 52 that outputs an ON signal to the ECU 80 is electrically connected, and the solenoid valve MVQ44 closes in response to the ON signal of the brake sensor 52. This manual operation generates a braking force by the wheel brake 40. On the other hand, the solenoid valve MVQ44 automatically closes when the absorbed energy of the clutch plate 12, which will be described later, becomes equal to or more than a specified value, and the clutch plate 12 ends the half-contact state (half-clutch state). As a result, the braking force by the wheel brake 40 is automatically generated.
[0027]
The change lever 60 is a select lever of the transmission 4 and is provided with an N (neutral) range, an R (reverse) range, and a D (drive) range corresponding to an automatic shift mode. The change lever 60 is provided with a select position sensor 62 for detecting each range position, and the select position sensor 62 is connected to the ECU 80. On the other hand, the ECU 80 is connected to a gear shift unit 64 for meshing gears of the transmission 4, that is, switching gear positions. Therefore, when a position signal is supplied from the select position sensor 62 to the ECU 80, a drive signal is output from the ECU 80 to the gear shift unit 64 in accordance with the position signal, whereby the gear shift unit 64 is operated and the transmission The gear position of No. 4 is switched to the selected desired select range. Although not described in detail, when the select position is in the D range, the automatic shift control is performed according to the driving state of the vehicle, and the gear position is switched based on the automatic shift control. .
[0028]
The gear shift unit 64 has an electromagnetic valve 66 that is activated by an activation signal from the ECU 80 and a power cylinder (not shown) that activates a shift fork (not shown) in the transmission 4. The power cylinder is connected to the air passage 30 via the electromagnetic valve 66 and the air passage 67. That is, when an operation signal is given from the ECU 80 to the electromagnetic valve 66, the electromagnetic valve 66 opens and closes in accordance with the operation signal, and the power cylinder is operated by supplying operating air from the air tank 34. Thereby, the meshing state of the gears of the transmission 4 is appropriately changed. Although only one solenoid valve 66 is shown here, a plurality of shift forks is actually provided, and a plurality of power cylinders are provided corresponding to the plurality of shift forks. Are provided in correspondence with the power cylinders.
[0029]
In the vicinity of the gear shift unit 64 of the transmission 4, a gear position sensor 68 for detecting each gear position is attached, and is electrically connected to the ECU 80. The gear position sensor 68 outputs the current gear position toward the ECU 80. A signal, that is, a gear position signal is output.
The accelerator pedal 70 is provided with an accelerator opening sensor 72, and is electrically connected to the ECU 80. The accelerator opening sensor 72 outputs the amount of depression of the accelerator pedal 70, that is, accelerator opening information.
[0030]
The input shaft 20 of the transmission 4 is provided with an input shaft rotation sensor 77 for detecting the rotation speed of the input shaft 20, in other words, the rotation speed Ncl of the clutch plate 12 integrated with the input shaft 20. The input shaft rotation sensor 77 is electrically connected to the ECU 80. Further, the output shaft 5 of the transmission 4 is provided with a vehicle speed sensor 78 for detecting and outputting the vehicle speed. The vehicle speed sensor 78 is also electrically connected to the ECU 80.
[0031]
Reference numeral 82 in FIG. 1 indicates an engine control unit provided separately from the ECU 80. The engine control unit 82 is a device that supplies a signal from the ECU 80 according to information from each sensor and accelerator opening information to an electronic governor (not shown) in the injection pump 6, and drives the engine 1. The control is performed. That is, when a command signal is supplied from the engine control unit 82 to the electronic governor, the control rack operates to perform an operation to increase or decrease the fuel, thereby controlling an increase or decrease in the engine rotation speed Ne. The detection information from the rack position sensor 9 and the engine rotation sensor 8 is supplied to the ECU 80 via the engine control unit 82.
[0032]
The ECU 80 includes a microcomputer (CPU), a memory, and an interface for performing input / output signal processing. The input side interface of the ECU 80 includes the above-described clutch stroke sensor 17, input shaft rotation sensor 77, engine The control unit 82, the brake sensor 52, the select position sensor 62, the gear position sensor 68, various sensors such as the accelerator opening sensor 72 and the vehicle speed sensor 78, and the clutch manual operation unit 76 are connected to each other. On the other hand, various devices such as the air cylinder unit 16, the solenoid valve MVQ44, the engine control unit 82, the solenoid valve 66, and the warning means 90 are connected to the output interface of the ECU 80. The warning means 90 informs the driver that the energy absorbed by the clutch plate 12 has exceeded a specified value, as will be described later.
[0033]
Then, the ECU 80 calculates energy absorbed by the clutch plate 12 to perform an appropriate connection / disconnection operation for the continuation of the half-clutch state of the clutch plate 12, and a clutch state for determining the state of the clutch plate 12. It is provided with a judging means and a burn preventing means for preventing the clutch plate 12 from burning.
More specifically, the energy calculating means calculates the absorbed energy of the clutch plate 12 in the half-clutch state of the clutch plate 12 based on the output signals from the engine rotation sensor 8, the input shaft rotation sensor 77, and the clutch stroke sensor 17. The clutch state determining means is configured to compare the calculated absorbed energy with a specified value to determine the state of the clutch plate 12, and the anti-burn means determines that the calculated absorbed energy is equal to the specified value. In the case described above, the half-clutch state is terminated to prevent the clutch plate 12 from burning.
[0034]
The absorbed energy is the energy stored in the clutch plate 12 due to the continued frictional load in the half-clutch state, and is an index for determining whether the clutch is burned based on the stroke amount of the clutch plate 12 with respect to the position of the flywheel 10. The absorbed energy e of the clutch plate 12 is obtained as in the following equation (1).
[0035]
(Equation 1)

[0036]
Here, Ne is the engine rotation speed (rpm), and Ncl is the rotation speed (rpm) of the clutch plate 12. Tcl is the transmission torque (Nm) of the clutch plate 12, t1 is the time (sec) when the transmission torque Tcl rises, and t2 is the time when the engine speed Ne and the rotation speed Ncl of the clutch plate 12 are synchronized. It is time (sec).
The transmission torque Tcl of the clutch plate 12 described above is calculated from the stroke amount of the clutch plate 12 by the clutch stroke sensor 17 using a map. More specifically, this map is stored in the ECU 80, and has a relationship in which the transmission torque Tcl decreases in a single hyperbolic manner as the stroke amount increases.
[0037]
By the way, the half-clutch state of the clutch plate 12 is defined between the time when the flywheel 10 and the clutch plate 12 start engaging and the time immediately before the flywheel 10 and the clutch plate 12 completely engage. means.
Hereinafter, this half-clutch state will be described using the above-described parameters.
First, at the position where the clutch plate 12 is farthest from the flywheel 10 (the stroke amount is the maximum value), the output of the engine 1 is not transmitted to the transmission 4. On the other hand, when the clutch plate 12 starts to move toward the engine output shaft 2, that is, when the stroke amount of the clutch plate 12 starts to decrease, the flywheel 10 and the clutch plate 12 start engaging later, and the engine 1 is transmitted to the transmission 4 to a small extent, and the rotational speed Ncl of the clutch plate 12 rises. This time is the time t1 when the transmission torque rises, and is the start time of the half-clutch state.
[0038]
Then, as the stroke of the clutch plate 12 decreases, the engagement state between the flywheel 10 and the clutch plate 12 increases, so that the transmission torque Tcl of the clutch plate 12 increases, and the rotation speed Ncl of the clutch plate 12 increases. Increases, and the engine rotation speed Ne decreases.
Thereafter, when the stroke amount of the clutch plate 12 further decreases and the difference between the engine rotation speed Ne and the rotation speed Ncl of the clutch plate 12 disappears, and the rotation speed Ncl of the clutch plate 12 is synchronized with the engine rotation speed Ne, the flywheel 10 and the clutch plate 12 are completely engaged. This time is time t2 at the time of synchronization between the engine rotation speed and the rotation speed of the clutch plate 12, and is the end point of the half-clutch state.
[0039]
After the engine rotation speed Ne and the rotation speed Ncl of the clutch plate 12 are synchronized, the stroke amount of the clutch plate 12 is reduced to the minimum value.
In such a half-clutch state, at the start of the half-clutch state in which the flywheel 10 and the clutch plate 12 have started engaging (when the stroke amount of the clutch plate 12 starts to decrease), the engine rotation speed Ne and the clutch plate Although the difference from the rotational speed Ncl of the clutch plate 12 is large and the transmission torque Tcl of the clutch plate 12 is small, a local temperature change occurs in the clutch plate 12 due to a friction load centered on a contact portion with the flywheel 10. On the other hand, at the end point of the half-clutch state immediately before the flywheel 10 and the clutch plate 12 are completely engaged (the stroke amount approaches the minimum value, and the engine rotation speed Ne and the rotation speed Ncl of the clutch plate 12 are synchronized. At this time, the difference between the engine rotation speed Ne and the rotation speed Ncl of the clutch plate 12 disappears, the transmission torque Tcl of the clutch plate 12 increases, the friction load increases, and the temperature change over the entire clutch plate 12 decreases. Occurs.
[0040]
That is, the friction corresponding to each engagement state is applied to the clutch plate 12 from the time when the stroke amount of the clutch plate 12 starts to decrease to the time when the engine rotation speed Ne and the rotation speed Ncl of the clutch plate 12 are synchronized. The load is continuously applied to raise the temperature of the clutch plate 12.
This means that the duration of the friction load increases as the engine rotation speed Ne increases and as the time from when the rotation speed Ncl of the clutch plate 12 rises to when the rotation speed Ncl synchronizes with the engine rotation speed Ne increases. The length of the clutch plate 12 becomes longer, the absorbed energy e stored in the clutch plate 12 increases, and the temperature of the clutch plate 12 increases, which means that the clutch plate 12 is easily burnt. That is, the magnitude of the friction load and the length of the duration of the friction load, that is, the absorbed energy e of the clutch plate 12 has a great effect on the scorching of the clutch plate 12.
[0041]
In view of the above, in the clutch control device of the present invention, the absorbed energy e of the clutch plate 12 in the half-clutch state is obtained based on the stroke amount of the clutch plate 12, and the state of the clutch plate 12 is determined using the absorbed energy e as a determination index. Is determined.
FIG. 2 is a flowchart showing a control routine of clutch control according to the first embodiment of the present invention. In the clutch control device of the first embodiment, engine stall is caused to prevent the clutch plate 12 from burning.
[0042]
When the clutch plate 12 is in the half-clutch state in step S10 in FIG. 2, in step S20, the energy calculating means is based on the output signals from the engine rotation sensor 8, the input shaft rotation sensor 77, and the clutch stroke sensor 17. Then, the absorbed energy e of the clutch plate 12 in the half-clutch state is calculated, and the routine proceeds to step S30.
[0043]
In step S30, the clutch state determining means determines whether or not the absorbed energy e is equal to or greater than a specified value. If the absorbed energy e is equal to or greater than the specified value, that is, if YES, the process proceeds to step S40. On the other hand, if the absorbed energy e is not equal to or greater than the specified value, the process proceeds to step S20, where the absorbed energy e is calculated.
In step S40, since the clutch plate 12 may be in a burn state, the supply of the drive signal to the electropneumatic proportional control valve 31 is stopped by the burn prevention means, and the supply of the working air to the air cylinder unit 16 is cut off. By doing so, the clutch device 3 is changed from the half-clutch state to the contact state. Then, the engine 1 is stopped according to the clutch engagement state. Then, a series of operations is ended in the engine stall state.
[0044]
As a result, the current half-clutch state in which the engine is stalled but may be in a scorched state can be ended, and the scorching of the clutch plate 12 can be reliably prevented.
FIG. 3 is a flowchart showing a control routine of clutch control according to the second embodiment of the present invention. In the clutch control device according to the second embodiment, the automatic braking is applied to the drive wheels when the clutch plate 12 is disconnected to prevent the clutch plate 12 from burning.
[0045]
Steps S10 to S30 in FIG. 3 are the same as those in the first embodiment. If the half-clutch state is calculated in step S10 and the energy calculation means calculates the absorbed energy e in the half-clutch state in step S20. Proceeding to step S30, the clutch state determining means determines whether or not the absorbed energy e is equal to or greater than a specified value. If the absorbed energy e is equal to or greater than the specified value, the flow proceeds to step S50. On the other hand, when the absorbed energy e is not equal to or more than the specified value, the process proceeds to step S20 to calculate the absorbed energy e.
[0046]
In step S50, since the clutch plate 12 may be in a scorched state, the clutch device 3 is changed from the half-clutched state to the disengaged state by the scorch preventing means, and the process proceeds to step S51. The valve is closed to generate a braking force by the wheel brake 40, and the process proceeds to step S52.
In step S52, it is determined whether or not the brake pedal 50 is depressed. If the brake pedal 50 is depressed, that is, if YES, the process proceeds to step S53 to turn off the above-described automatic brake and perform a series of operations. finish. On the other hand, when the brake pedal 50 is not depressed in step S52, the process proceeds to step S51, and the automatic brake is kept on. When an automatic brake is generated, a so-called slope start assist device may be used.
[0047]
As a result, the current half-clutch state can be ended to reliably prevent the scorching of the clutch plate 12, and the wheels can be automatically braked, so that the vehicle can be stopped on an uphill road without retreating. Can be. Further, when the brake is manually applied to the wheel, the automatic brake is released, so that the vehicle can be restarted.
[0048]
FIG. 4 is a flowchart showing a control routine of clutch control according to the third embodiment of the present invention. In the clutch control device of the third embodiment, downshifting is performed to prevent the clutch plate 12 from burning.
Steps S10 to S30 in FIG. 4 are the same as those in the first and second embodiments. When the half-clutch state is obtained in step S10 and the absorbed energy e is calculated in step S20, the process proceeds to step S30. When e is equal to or greater than the specified value, the process proceeds to step S60. On the other hand, when the absorbed energy e is not equal to or more than the specified value, the process proceeds to step S20 to calculate the absorbed energy e.
[0049]
In step S60, since the clutch plate 12 can be in a scorched state, the clutch device 3 is changed from the half-clutched state to the disengaged state by the scorch preventing means, and the process proceeds to step S61. And the process proceeds to step S62.
In step S62, the current speed stage (for example, the second speed stage) is forcibly downshifted to the low speed stage (for example, the first speed stage), and the process proceeds to step S63. In step S63, it is determined whether or not the downshift is completed based on the output signal from the gear position sensor 68. If the downshift is completed, that is, if YES, the process proceeds to step S64, and the above-described automatic operation is performed. The brake is turned off and the process proceeds to step S65, the half-clutch state is established, and the connection at the low speed is attempted. The process proceeds to step S66 to calculate the absorbed energy e, and the process proceeds to step S67. On the other hand, when the downshift is not completed in step S63, the downshift is continued while the automatic brake is kept on.
[0050]
In step S67, the clutch state determining means determines whether or not the absorbed energy e in the half-clutch state after downshifting is equal to or more than a specified value. If the absorbed energy e is equal to or more than the specified value, that is, if YES, The process proceeds to step S50. On the other hand, when the absorbed energy e is not equal to or more than the specified value, the process proceeds to step S66 to calculate the absorbed energy e.
[0051]
After the time when the absorbed energy e is equal to or more than the specified value in step S67, the process is the same as in the second embodiment. Then, the automatic brake is turned on to generate a braking force by the wheel brake 40, and the process proceeds to step S52. In step S52, it is determined whether or not the brake pedal 50 is depressed. If the brake pedal 50 is depressed, the process proceeds to step S53, where the above-described automatic brake is turned off, and a series of operations is terminated. On the other hand, when it is determined in step S52 that the brake pedal 50 has not been depressed, the process proceeds to step S51, and the automatic brake is kept on.
[0052]
As a result, the transmission torque is reduced to reduce the frictional load, and the current half-clutch state, which may be in a scorched state, is terminated to reliably prevent the clutch plate 12 from being scorched. Since the brake is generated, the vehicle can be stopped without going backward even on an uphill road. In addition, since the gear is shifted down from the speed stage intended by the driver, the load on the clutch plate 12 is reduced, so that the scorch of the clutch plate 12 can be reliably prevented, and the vehicle can be easily restarted. can do. Also, if the absorbed energy e is equal to or more than the specified value after the shift down, the clutch plate 12 is again disengaged and the automatic braking is re-established. It can be reliably prevented.
[0053]
In performing the downshift in step S62, the automatic brake is turned on in step S61 to generate a braking force. However, in a case where the vehicle is not likely to retreat, for example, the automatic brake is turned off. Instead of being turned on, as shown by the broken line in the figure, the clutch device 3 may be disengaged in step S60, and then the process may proceed to step S62 to execute the downshift.
[0054]
FIG. 5 is a flowchart showing a control routine of clutch control according to the fourth embodiment of the present invention. In the clutch control device of the fourth embodiment, the driver manually puts the clutch plate 12 into the disconnected state to prevent the clutch plate 12 from burning.
Steps S10 to S30 in FIG. 5 are the same as those in the first to third embodiments. If the absorbed energy e is calculated in step S20 when the clutch is half-engaged in step S10, the process proceeds to step S30. When e is equal to or greater than the specified value, the process proceeds to step S60. On the other hand, when the absorbed energy e is not equal to or more than the specified value, the process proceeds to step S20 to calculate the absorbed energy e.
[0055]
In step S70, since the clutch plate 12 may be in a burning state, a warning is started to the driver via the warning means 90 by the burning prevention means, and the process proceeds to step S71. The warning may include, for example, sounding a buzzer, turning on a warning lamp, or vibrating the clutch pedal of the clutch manual operation unit 76 to inform the driver.
[0056]
In step S71, it is determined whether or not the clutch pedal is depressed and the clutch plate 12 is in a disconnected state. If the clutch pedal is depressed, that is, if YES, the process proceeds to step S72 to end the warning. Then, in step S73, the operation of the clutch device 3 is changed from the automatic mode to the manual mode, and the series of operations ends. On the other hand, if the clutch pedal has not been depressed in step S71, the process proceeds to step S70 to maintain a warning to the driver.
[0057]
As a result, the current half-clutch state is also ended, and the scorching of the clutch plate 12 can be reliably prevented. It should be noted that the anti-burn means of this embodiment can maintain the half-clutch state until the driver manually depresses the clutch pedal. Therefore, it is desirable that the prescribed value of step S30 is a value lower than the prescribed values of the above-described first to third embodiments.
[0058]
As described above, in the clutch control device of the automatic transmission for a vehicle according to the present invention, the energy calculating means calculates the absorbed energy e stored in the clutch plate 12 in the half-clutch state from the stroke amount of the clutch plate 12, and calculates the absorbed energy e. Since it is used as the determination index for the state of No. 12, it is possible to accurately grasp the state of the clutch plate where the continuous frictional load occurs. Accordingly, the burnt of the clutch plate 12 particularly when a driver accustomed to a passenger vehicle with a torque converter and a driver of a large vehicle based on the second speed start perform an operation to stop the vehicle by continuing the half-clutch state on an uphill road. Can be prevented.
[0059]
The description of one embodiment of the present invention is finished above, but the present invention is not limited to the above embodiment, and various changes can be made without departing from the spirit of the present invention.
For example, in the third embodiment, if the absorbed energy e is equal to or more than the specified value after the shift down, the clutch plate 12 is again disengaged and the automatic braking is caused again. The present invention is not limited to the embodiment. For example, similarly to the first embodiment, if the absorbed energy e is equal to or more than the specified value after downshifting, the clutch device 3 is brought into the contact state to cause engine stall. In this case as well, there is an effect that the burn of the clutch plate 12 can be more reliably prevented as in the above case.
[0060]
The half-clutch state of the clutch plate 12 is defined between the time when the flywheel 10 and the clutch plate 12 start to be engaged and the time immediately before the flywheel 10 and the clutch plate 12 are completely engaged. If so, it is limited to starting from the time when the flywheel 10 and the clutch plate 12 start engaging as in the above embodiment and ending at the time immediately before the flywheel 10 and the clutch plate 12 completely engage. However, the start time and the end time may be opposite to each other. In this case as well, the absorbed energy e can be used as a determination index of the state of the clutch plate 12 in the same manner as described above. .
[0061]
【The invention's effect】
As can be understood from the above description, according to the clutch control device for an automatic transmission for a vehicle according to the first aspect of the present invention, when determining the state of the clutch plate, the state of the semi-contact state based on the movement amount of the clutch plate is determined. Since the absorbed energy of the clutch plate is used as the determination index, the state of the clutch plate can be accurately grasped. As a result, it is possible to avoid a situation in which the clutch plate is burnt and the vehicle becomes difficult to travel thereafter, thereby reducing road failures.
[0062]
According to the second aspect of the present invention, since the scorch preventing means forcibly sets the clutch plate from the semi-contact state to the contact state and stops the engine, the scorch of the clutch plate due to the continuation of the current semi-contact state. Can be reliably prevented.
Further, according to the third aspect of the present invention, the scorch preventing means forcibly switches the clutch plate from the semi-contact state to the disconnected state and generates an automatic braking force on the wheels. The burn of the clutch plate due to the continuation of the semi-contact state can be reliably prevented, and the retreat of the vehicle on an uphill road can also be prevented.
[0063]
Furthermore, according to the fourth aspect of the present invention, since the burn prevention means forcibly downshifts the transmission, it is possible to reliably prevent the clutch plate from being burned due to the continuation of the current half-contact state. In addition, the vehicle can be easily restarted.
According to the fifth aspect of the present invention, the scorch preventing means manually sets the clutch plate from the semi-contact state to the disconnected state. Burn can be reliably prevented.
[Brief description of the drawings]
FIG. 1 is an overall configuration diagram of a drive system of a vehicle to which a clutch control device for a vehicle automatic transmission according to an embodiment of the present invention is applied.
FIG. 2 is a flowchart showing a control routine of clutch control according to the first embodiment of the present invention.
FIG. 3 is a flowchart illustrating a control routine of clutch control according to a second embodiment of the present invention.
FIG. 4 is a flowchart illustrating a control routine of clutch control according to a third embodiment of the present invention.
FIG. 5 is a flowchart illustrating a control routine of clutch control according to a fourth embodiment of the present invention.
[Explanation of symbols]
1 engine
3 Clutch device
4 Mechanical transmission
8 Engine rotation sensor
10 Flywheel
12 Clutch plate
17 Stroke sensor
76 Clutch manual operation unit
77 Input shaft rotation sensor
80 ECU (Electronic Control Unit)
90 Warning means

Claims (5)

A friction clutch device capable of automatically connecting and disconnecting the connection between the engine and the transmission to transmit the rotation speed of the engine, the rotation speed of the input shaft of the mechanical transmission, and the output of the engine to drive wheels. Energy calculating means for calculating the absorbed energy of the clutch plate in a semi-contact state based on the amount of movement of the clutch plate,
Clutch state determining means for comparing the absorbed energy calculated by the energy calculating means with a specified value to determine the state of the clutch plate;
An automatic transmission for a vehicle, comprising: a scoring prevention means for preventing scorching of the clutch plate when the clutch state determining means determines that the calculated absorbed energy is equal to or greater than the specified value. Clutch control device. 2. The automatic transmission for a vehicle according to claim 1, wherein said burn prevention means prevents said clutch plate from burning by bringing said clutch plate into said contact state from said half contact state and stopping said engine. Machine clutch control device. The burn preventing means prevents the clutch plate from burning by causing the clutch plate to be in the disconnected state from the half-contact state, and generates an automatic braking force on the drive wheels. The clutch control device for a vehicle automatic transmission according to claim 1, wherein The clutch control device for an automatic transmission for a vehicle according to claim 1, wherein the burn prevention means prevents the clutch plate from burning by shifting down the transmission. The clutch device can be further manually connected and disconnected,
The burn prevention means issues a warning when the calculated absorbed energy is equal to or greater than the specified value, and the clutch plate is manually disconnected in response to the warning to prevent the burn of the clutch plate. The clutch control device for an automatic transmission for a vehicle according to claim 1, wherein:

Images