JPS633191B2 - - Google Patents
Info
- Publication number
- JPS633191B2 JPS633191B2 JP12879582A JP12879582A JPS633191B2 JP S633191 B2 JPS633191 B2 JP S633191B2 JP 12879582 A JP12879582 A JP 12879582A JP 12879582 A JP12879582 A JP 12879582A JP S633191 B2 JPS633191 B2 JP S633191B2
- Authority
- JP
- Japan
- Prior art keywords
- oil
- hydraulic
- pulley half
- driven
- spool valve
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired
Links
- 230000005540 biological transmission Effects 0.000 claims description 30
- 230000007246 mechanism Effects 0.000 claims description 16
- 239000003921 oil Substances 0.000 description 119
- 230000001105 regulatory effect Effects 0.000 description 9
- 238000001816 cooling Methods 0.000 description 8
- 239000010720 hydraulic oil Substances 0.000 description 5
- 230000009467 reduction Effects 0.000 description 5
- 230000004044 response Effects 0.000 description 4
- 230000004043 responsiveness Effects 0.000 description 3
- 230000008859 change Effects 0.000 description 2
- 238000002955 isolation Methods 0.000 description 2
- 230000007935 neutral effect Effects 0.000 description 1
- 238000005192 partition Methods 0.000 description 1
- 230000002093 peripheral effect Effects 0.000 description 1
- 239000007787 solid Substances 0.000 description 1
- 238000003466 welding Methods 0.000 description 1
Classifications
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16H—GEARING
- F16H55/00—Elements with teeth or friction surfaces for conveying motion; Worms, pulleys or sheaves for gearing mechanisms
- F16H55/32—Friction members
- F16H55/52—Pulleys or friction discs of adjustable construction
- F16H55/56—Pulleys or friction discs of adjustable construction of which the bearing parts are relatively axially adjustable
Landscapes
- Engineering & Computer Science (AREA)
- General Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Control Of Transmission Device (AREA)
- Transmissions By Endless Flexible Members (AREA)
Description
【発明の詳細な説明】
本発明はベルト式無段変速機の作動制御装置に
関する。DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an operation control device for a belt type continuously variable transmission.
従来、この種無段変速機として、プーリ軸上に
固定プーリ半体と可動プーリ半体を設け、その可
動プーリ半体を油圧作動機構により固定プーリ半
体に対して進退させることにより有効半径を調節
し得るVプーリを備えたものが知られている。 Conventionally, in this type of continuously variable transmission, a fixed pulley half and a movable pulley half are provided on the pulley shaft, and the movable pulley half is moved forward and backward with respect to the fixed pulley half by a hydraulic actuation mechanism to adjust the effective radius. Those with adjustable V-pulleys are known.
本発明はこの種無段変速機において、可動プー
リ半体の前進及び後退を軽快に行うと共に可動プ
ーリ半体を任意位置で確実に停止させることがで
き、その上装置全体を小型化した、前記作動制御
装置を提供することを目的とする。 The present invention provides a continuously variable transmission of this type, which can easily move the movable pulley half forward and backward, and can reliably stop the movable pulley half at any position, and furthermore, the entire device is miniaturized. The object of the present invention is to provide an actuation control device.
以下、図面により本発明を自動二輪車に採用し
た一実施例について説明すると、先ず第1図にお
いて、自動二輪車のパワーユニツトPuは、エン
ジンE、発進クラツチSc、ベルト式無段変速機
Tm及び歯車式補助変速機Taよりなり、これら
は図示しない車体に支持されるケーシングC内に
構成される。 Hereinafter, an embodiment in which the present invention is applied to a motorcycle will be explained with reference to the drawings. First, in FIG. 1, a power unit Pu of the motorcycle includes an engine E, a starting clutch Sc, and a belt-type continuously variable transmission.
It consists of a gear type auxiliary transmission Tm and a gear type auxiliary transmission Ta, and these are constructed in a casing C supported by a vehicle body (not shown).
ケーシングCは第2図に示すように、エンジン
Eのクランク軸1のクランク部及び補助変速機
Taを収容する主ケースC1と、無段変速機Tmを
収容する補助ケースC2と、その補助ケースC2の
外側面を閉鎖するカバーC3とに分割されている。
また、クランク軸1その他、パワーユニツトPu
中の各種回転軸は、パワーユニツトPuの後方で
図示しない車体に軸支される後輪Wrの軸線とす
べて平行に配置され、パワーユニツトPuの出力
軸、即ち補助変速機Taの出力軸141がチエン
伝動装置Mを介して後輪Wrを駆動するようにな
つている。 As shown in FIG.
The main case C1 houses the continuously variable transmission Tm, the auxiliary case C2 houses the continuously variable transmission Tm, and the cover C3 closes the outer surface of the auxiliary case C2 .
In addition, crankshaft 1 and other parts, power unit Pu
The various rotating shafts inside are all arranged parallel to the axis of the rear wheel Wr which is supported by the vehicle body (not shown) behind the power unit Pu, and the output shaft of the power unit Pu, that is, the output shaft 141 of the auxiliary transmission Ta is The rear wheels Wr are driven through a chain transmission M.
発進クラツチSc及び無段変速機Tmはいずれも
油圧作動式に構成される。それらに作動油を供給
するために、クラツチ弁Vcより延出した制御油
路Lcが発進クラツチScに、またエンジンEに駆
動される油圧ポンプPから延出した第1,第2給
油路L1,L2が無段変速機Tmの駆動、従動部にそ
れぞれ接続される。 The starting clutch Sc and the continuously variable transmission Tm are both hydraulically operated. In order to supply hydraulic oil to them, a control oil passage Lc extending from the clutch valve Vc is connected to the starting clutch Sc, and first and second oil supply passages L1 extending from the hydraulic pump P driven by the engine E are connected to each other. , L2 are respectively connected to the drive and driven parts of the continuously variable transmission Tm.
尚、第1図中、Vrは油圧ポンプPのリリーフ
弁、RはケーシングCの底部に形成される油溜で
ある。 In FIG. 1, Vr is a relief valve of the hydraulic pump P, and R is an oil reservoir formed at the bottom of the casing C.
パワーユニツトPuの各部の構成を第2,3図
により順次説明する。 The configuration of each part of the power unit Pu will be sequentially explained with reference to FIGS. 2 and 3.
先ず、発進クラツチScであるが、それはクラ
ンク軸1を支承する最右側の軸受2の外側に隣接
してクランク軸1上に設けられる。この発進クラ
ツチScはクランク軸1にスプライン結合3され
たクラツチアウタ4と、後述する駆動Vプーリ4
0の固定プーリ半体44と一体に形成されたクラ
ツチインナ5とを有し、これらクラツチアウタ及
びインナ4,5間には、クラツチアウタ4に摺動
自在にスプライン嵌合される複数枚の駆動摩擦板
6と、クラツチインナ5に摺動自在にスプライン
嵌合される複数枚の被動摩擦板7とが各板交互に
重合して介装されると共に、最外側位置の駆動摩
擦板6の外方移動を拘束する受圧環8がクラツチ
アウタ4に係止される。この受圧環8と反対側で
クラツチアウタ4には油圧シリンダ9が形成され
ており、このシリンダ9には最内側位置の駆動摩
擦板6に皿状の緩衝ばね10を挾んで対向するピ
ストン11が摺合されている。このピストン11
は、クラツチインナ5の内側に配置された戻しば
ね12により後退方向、即ち摩擦板6,7群から
離れる方向に弾圧される。油圧シリンダ9の油圧
室13には前記制御油路Lcからクランク軸1に
形成した油路14を通して作動油が供給されるよ
うになつている。 First, the starting clutch Sc is provided on the crankshaft 1 adjacent to the outside of the rightmost bearing 2 that supports the crankshaft 1. This starting clutch Sc includes a clutch outer 4 spline-coupled to the crankshaft 1 and a drive V pulley 4 to be described later.
A clutch inner 5 is integrally formed with a fixed pulley half 44 of 0, and a plurality of drive friction plates 6 are slidably spline-fitted to the clutch outer 4 between the clutch outer and inner clutch 4 and 5. and a plurality of driven friction plates 7 which are slidably spline-fitted into the clutch inner 5 and are interposed by alternately overlapping each other, and restrain the outward movement of the driving friction plate 6 located at the outermost position. A pressure receiving ring 8 is locked to the clutch outer 4. A hydraulic cylinder 9 is formed in the clutch outer 4 on the opposite side from the pressure receiving ring 8, and a piston 11 that faces the driving friction plate 6 at the innermost position with a dish-shaped buffer spring 10 in between slides into the cylinder 9. has been done. This piston 11
is pressed in the backward direction, that is, in the direction away from the group of friction plates 6 and 7, by a return spring 12 arranged inside the clutch inner 5. Hydraulic oil is supplied to the hydraulic chamber 13 of the hydraulic cylinder 9 from the control oil passage Lc through an oil passage 14 formed in the crankshaft 1.
而して、油圧室13に高圧の作動油を供給すれ
ば、ピストン11はその油圧を受けて戻しばね1
2を圧縮しながら前進し、駆動及び被動摩擦板
6,7群を受圧環8に対して押圧することにより
両摩擦板6,7間を半クラツチ状態を経て摩擦連
結することができる。このクラツチ接続状態で
は、クランク軸1からクラツチアウタ4に伝達さ
れる動力は両摩擦板6,7群を介してクラツチイ
ンナ5に伝達し、そして次段の無段変速機Tmへ
と伝達する。また、油圧シリンダ9内の作動油を
排出すれば、ピストン11は戻しばね12の弾圧
力により後退するので、両摩擦板6,7間の摩擦
連結は解かれ(クラツチ遮断状態)、上記の動力
伝達は休止する。 When high-pressure hydraulic oil is supplied to the hydraulic chamber 13, the piston 11 receives the hydraulic pressure and returns to the spring 1.
By moving forward while compressing the drive and driven friction plates 6 and 7 against the pressure receiving ring 8, the friction plates 6 and 7 can be frictionally connected through a half-clutch state. In this clutch connected state, the power transmitted from the crankshaft 1 to the clutch outer 4 is transmitted to the clutch inner 5 via both friction plates 6 and 7, and then to the next continuously variable transmission Tm. Furthermore, when the hydraulic oil in the hydraulic cylinder 9 is discharged, the piston 11 moves back due to the elastic force of the return spring 12, so the frictional connection between the two friction plates 6 and 7 is released (clutch disconnected state), and the above-mentioned power is released. Transmission pauses.
発進クラツチScは両摩擦板6,7を作動油に
より冷却する湿式を採用している。ところで、両
摩擦板6,7に供給する冷却油が過多であれば、
クラツチ遮断時には冷却油の粘性に起因した両摩
擦板6,7間の引摺り現象を起こし、またクラツ
チ接続時には両摩擦板6,7間に滑りが生じ易く
なる。反対に冷却油が過少であれば、摩擦熱を多
量に発する半クラツチ時に各摩擦板6,7が過熱
する嫌いがある。したがつて、冷却油の供給量
は、クラツチ遮断時及び接続時には零若しくは僅
少に、また半クラツチ時には多量にそれぞれ制御
することが要求され、そのような制御のために流
量調節弁15が設けられる。 The starting clutch Sc employs a wet type in which both friction plates 6 and 7 are cooled with hydraulic oil. By the way, if too much cooling oil is supplied to both friction plates 6 and 7,
When the clutch is disengaged, a dragging phenomenon occurs between the friction plates 6 and 7 due to the viscosity of the cooling oil, and when the clutch is engaged, the friction plates 6 and 7 tend to slip. On the other hand, if there is too little cooling oil, each friction plate 6, 7 tends to overheat when the clutch is half-engaged, which generates a large amount of frictional heat. Therefore, the amount of cooling oil supplied must be controlled to zero or a small amount when the clutch is disconnected and engaged, and to a large amount when the clutch is half-engaged, and a flow rate control valve 15 is provided for such control. .
流量調節弁15は円筒形をなしていて、クラン
ク軸1の前記油路14内に摺合され、該弁15の
左端面には油路14の油圧が、また右端面には大
気圧と戻しばね16の弾発力とがそれぞれ作用す
るようになつている。流量調節弁15は油路14
と連通する弁孔17を有し、該弁15が所定の右
動位置に移動したとき上記弁孔17と連通する、
オリフイス18付油孔19がクランク軸1に穿設
され、またその油孔19をスプライン結合3を介
してクラツチインナ5の内側に常時連通させる油
孔20がクラツチアウタ4に穿設される。 The flow rate regulating valve 15 has a cylindrical shape and is slid into the oil passage 14 of the crankshaft 1. The left end face of the valve 15 receives the oil pressure of the oil passage 14, and the right end face receives atmospheric pressure and a return spring. 16 elastic forces act on each of them. The flow control valve 15 is connected to the oil passage 14
having a valve hole 17 that communicates with the valve hole 17, and communicates with the valve hole 17 when the valve 15 moves to a predetermined rightward movement position;
An oil hole 19 with an orifice 18 is formed in the crankshaft 1, and an oil hole 20 is formed in the clutch outer 4 to constantly communicate the oil hole 19 with the inside of the clutch inner 5 via the spline connection 3.
而して、油路14内が低圧のクラツチ遮断時に
は調節弁15は戻しばね16の力で左動限に保持
されるので、弁孔17と油孔19とは図示のよう
に連通を断たれ、若しくはその連通を適当に絞ら
れ、これにより油路14から発進クラツチScへ
の冷却油の供給量は零若しくは僅少に調節され
る。油路14内の油圧が半クラツチ状態をもたら
すまでに上昇すると、その油圧を受けて調節弁1
5は戻しばね16を圧縮しながら右動し、弁孔1
7を油孔19に連通させ、これにより油路14か
ら弁孔17、油孔19,20を通して発進クラツ
チScに冷却油が充分に供給される。このときの
冷却油の最大流量はオリフイス18により規制さ
れる。さらに、油路14内の油圧がクラツチ接続
状態をもたらすまでに上昇して調節弁15が更に
右動すると、弁孔17と油孔19とは再び連通を
断たれ、若しくはその連通を適当に絞られ、これ
により冷却油の供給量は再び零若しくは僅少に調
節される。 When the pressure in the oil passage 14 is low and the clutch is shut off, the control valve 15 is held at the leftmost limit of movement by the force of the return spring 16, so that the valve hole 17 and the oil hole 19 are disconnected from each other as shown in the figure. , or the communication thereof is appropriately throttled, whereby the amount of cooling oil supplied from the oil passage 14 to the starting clutch Sc is adjusted to zero or a small amount. When the oil pressure in the oil passage 14 rises to a level that brings about a half-clutch state, the control valve 1 is activated in response to the oil pressure.
5 moves to the right while compressing the return spring 16 and closes the valve hole 1.
7 is communicated with the oil hole 19, whereby cooling oil is sufficiently supplied from the oil passage 14 to the starting clutch Sc through the valve hole 17 and the oil holes 19, 20. The maximum flow rate of the cooling oil at this time is regulated by the orifice 18. Furthermore, when the oil pressure in the oil passage 14 rises to the point where the clutch is engaged and the control valve 15 moves further to the right, the valve hole 17 and the oil hole 19 are again disconnected from each other, or the communication is appropriately throttled. As a result, the amount of cooling oil supplied is again adjusted to zero or a small amount.
第1図において、上記発進クラツチScを操作
するためのクラツチ弁Vcについて説明すると、
一端が閉塞されたシリンダ状の弁函25には戻し
ばね26、スプール弁27、調圧ばね28及び押
圧板29が順次挿入され、最外側の押圧板29に
は、固定の支軸30に中央部を支持させた作動レ
バー31の一端が連接され、その他端には操向ハ
ンドルHに付設されたクラツチレバー32に連な
る操作ワイヤ33と作動ばね34とが接続され
る。その作動ばね34は前記調圧ばね28よりば
ね力が強く、クラツチレバー32の解放に従い作
動レバー31及び押圧板29を介して調圧ばね2
8を押圧し、そのセツト荷重を増加させることが
できる。 In FIG. 1, the clutch valve Vc for operating the starting clutch Sc will be explained as follows.
A return spring 26, a spool valve 27, a pressure regulating spring 28, and a pressing plate 29 are sequentially inserted into the cylindrical valve box 25 with one end closed. One end of the actuating lever 31 is connected to the other end, and an operating wire 33 connected to a clutch lever 32 attached to the steering handle H and an actuating spring 34 are connected to the other end. The operating spring 34 has a stronger spring force than the pressure regulating spring 28, and as the clutch lever 32 is released, the pressure regulating spring 2
8 to increase the set load.
弁函25は、調圧ばね28側から並んでその内
壁に開口する第1〜第4ポート351〜354を有
し、第1ポート351は油溜Rと連通し、第2ポ
ート352から制御油路Lcが延出され、第3ポー
ト353は油圧ポンプPと連通し、また第4ポー
ト354はオリフイス36を介して制御油路Lcと
連通すると共に、弁函25内の戻しばね26を収
容する反力油圧室38と連通する。他方、スプー
ル弁27は、前記第2ポート352と第1ポート
351または第3ポート353との連通を切換え得
る環状溝39を有する。 The valve box 25 has first to fourth ports 35 1 to 35 4 that are lined up from the pressure regulating spring 28 side and open to its inner wall, the first port 35 1 communicates with the oil reservoir R, and the second port 35 A control oil passage Lc extends from 2 , a third port 35 3 communicates with the hydraulic pump P, and a fourth port 35 4 communicates with the control oil passage Lc via an orifice 36 . It communicates with a reaction force hydraulic chamber 38 that houses the return spring 26 . On the other hand, the spool valve 27 has an annular groove 39 that can switch communication between the second port 35 2 and the first port 35 1 or the third port 35 3 .
而して、第1図の状態のように、クラツチレバ
ー32を操向ハンドルH側に引き寄せることによ
り、作動ばね34の力に抗して作動レバー31を
押圧板29から充分に後退させれば、スプール弁
27は戻しばね26により右動されて、第3ポー
ト353を閉じると共に第1及び第2ポート35
1,352間を連通させる。その結果、発進クラツ
チScの油圧シリンダ9内の圧力は油溜Rに解放
されるので、発進クラツチScは遮断状態となる。 1, by pulling the clutch lever 32 toward the steering handle H side, the actuating lever 31 is sufficiently retreated from the pressing plate 29 against the force of the actuating spring 34. , the spool valve 27 is moved to the right by the return spring 26 to close the third port 353 and close the first and second ports 35.
1 , 35 2 to communicate with each other. As a result, the pressure in the hydraulic cylinder 9 of the starting clutch Sc is released to the oil reservoir R, so that the starting clutch Sc becomes in a disconnected state.
クラツチレバー32の操作力を徐々に解放して
いき、押圧板29が作動ばね34の力により調圧
ばね28を押圧していくと、スプール弁27は左
動して第1ポート351を閉じると共に第2及び
第3ポート352,353間を連通させるので、油
圧ポンプPの吐出油が制御油路Lcに供給される。
これに伴い制御油路Lcの油圧が上昇すると、そ
の油圧はオリフイス36を経て反力油圧室38に
導入されるため、その油圧による押圧力と調圧ば
ね28のセツト荷重とが平衡するところまでスプ
ール弁27は右方へ押し戻される。したがつて、
クラツチレバー32の戻し動作に伴う調圧ばね2
8のセツト荷重の増加に応じて制御油路Lcの油
圧、即ち発進クラツチScの接続油圧を上昇させ
ることができる。 When the operating force of the clutch lever 32 is gradually released and the pressing plate 29 presses the pressure regulating spring 28 by the force of the operating spring 34, the spool valve 27 moves to the left and closes the first port 351. At the same time, the second and third ports 35 2 and 35 3 are communicated with each other, so that the oil discharged from the hydraulic pump P is supplied to the control oil path Lc.
When the oil pressure in the control oil passage Lc increases accordingly, that oil pressure is introduced into the reaction pressure oil pressure chamber 38 through the orifice 36, so that the pressing force due to the oil pressure and the set load of the pressure regulating spring 28 are balanced. The spool valve 27 is pushed back to the right. Therefore,
The pressure regulating spring 2 accompanying the return operation of the clutch lever 32
According to the increase in the set load of 8, the oil pressure of the control oil passage Lc, that is, the connection oil pressure of the starting clutch Sc can be increased.
このようなクラツチ弁Vcを用いると、クラツ
チレバー32の操作力を軽く設定しても、それに
殆ど関係なく発進クラツチScの接続油圧を充分
に大きく設定することができ、これにより発進ク
ラツチScの小型化が可能となり、また前述のよ
うに、発進クラツチScを、パワーユニツトPu中、
最も回転数が高くてトルクの低いクランク軸1上
に設けることにより、その小型化は更に促進され
る。 By using such a clutch valve Vc, even if the operating force of the clutch lever 32 is set lightly, the connection hydraulic pressure of the starting clutch Sc can be set sufficiently large regardless of the operating force of the clutch lever 32. Also, as mentioned above, the starting clutch Sc can be moved during the power unit Pu.
By providing the crankshaft 1 on the crankshaft 1, which has the highest rotational speed and the lowest torque, its size can be further reduced.
次に無段変速機Tmについて説明する。 Next, the continuously variable transmission Tm will be explained.
この変速機Tmは、発進クラツチScの右側に隣
接してクランク軸1上に設けた駆動Vプーリ4
0、その後方に隣接配置した従動Vプーリ41、
及び両Vプーリ40,41間に懸張したVベルト
42を主要素としている。 This transmission Tm consists of a drive V pulley 4 provided on the crankshaft 1 adjacent to the right side of the starting clutch Sc.
0, a driven V pulley 41 arranged adjacent to the rear thereof,
The main element is a V-belt 42 stretched between both V-pulleys 40 and 41.
駆動Vプーリ40は、クランク軸1の右端部に
ベアリング43を介して回転自在に支承される固
定プーリ半体44と、この固定プーリ半体44と
一体の筒状駆動プーリ軸45に2個のボールキー
46を介して摺動可能に連結される可動プーリ半
体47とより構成され、この可動プーリ半体47
はその背面にねじ48で固着されたピストン49
を備え、このピストン49を収容する油圧シリン
ダ50の後壁板50aがケーシングCにボールベ
アリング51を介して支承されると共に、駆動プ
ーリ軸45に止環52により連結される。ピスト
ン49は油圧シリンダ50内をVベルト42側の
第1油圧室501と、それと反対側の第2油圧室
502とに区画し、ピストン49の受圧面は、第
1油圧室501側が第2油圧室502側より狭くな
るように形成される。かくして、ピストン49及
び油圧シリンダ50は可動プーリ半体47の油圧
作動機構を構成する。 The drive V pulley 40 includes a fixed pulley half 44 that is rotatably supported on the right end of the crankshaft 1 via a bearing 43, and a cylindrical drive pulley shaft 45 that is integral with the fixed pulley half 44. The movable pulley half 47 is slidably connected to the movable pulley half 47 via a ball key 46.
is a piston 49 fixed to its back surface with a screw 48.
A rear wall plate 50a of a hydraulic cylinder 50 that accommodates the piston 49 is supported by the casing C via a ball bearing 51 and connected to the drive pulley shaft 45 by a stop ring 52. The piston 49 divides the inside of the hydraulic cylinder 50 into a first hydraulic chamber 50 1 on the V-belt 42 side and a second hydraulic chamber 50 2 on the opposite side. The second hydraulic chamber 502 is formed to be narrower than the second hydraulic chamber 502 side. Thus, the piston 49 and the hydraulic cylinder 50 constitute a hydraulic actuation mechanism for the movable pulley half 47.
上記構成において、両油圧室501,502に同
圧の油圧を導入すると、ピストン49は左右の受
圧面積の差による差動油圧を受けて左方へ移動し
て可動プーリ半体47を固定プーリ半体44に近
付け、駆動Vプーリ40の有効半径、即ちVベル
ト42との接触半経を拡大させることができる。
また、第1油圧室501に油圧をかけた状態で第
2油圧室502の油圧を解放すれば、ピストン4
9は第1油圧室501の油圧により右動して可動
プーリ半体47を固定プーリ半体44より遠ざ
け、駆動Vプーリ40の有効半径を縮小すること
ができる。このようなピストン49の油圧作動の
ために第1制御弁V1が駆動プーリ軸45内に設
けられるが、その詳細は後述する。 In the above configuration, when the same hydraulic pressure is introduced into both hydraulic chambers 50 1 and 50 2 , the piston 49 receives the differential hydraulic pressure due to the difference in the pressure receiving areas on the left and right sides, moves to the left, and fixes the movable pulley half 47 By bringing the drive V-pulley 40 closer to the pulley half 44, the effective radius of the drive V-pulley 40, that is, the half diameter of its contact with the V-belt 42 can be expanded.
Furthermore, if the hydraulic pressure in the second hydraulic chamber 502 is released while applying hydraulic pressure in the first hydraulic chamber 501 , the piston 4
9 is moved to the right by the hydraulic pressure in the first hydraulic chamber 50 1 to move the movable pulley half 47 away from the fixed pulley half 44, thereby reducing the effective radius of the drive V-pulley 40. A first control valve V 1 is provided within the drive pulley shaft 45 for hydraulically operating the piston 49, the details of which will be described later.
油圧シリンダ50は、前述のようにその後壁板
50aを駆動プーリ軸45に止環52を介して連
結したので、固定プーリ半体44とも一体的な連
結関係に置かれる。このようにすると、ピストン
49の油圧作動に伴い固定プーリ半体44と油圧
シリンダ50間に作用するスラスト荷重を駆動プ
ーリ軸45に伝達、支承させることができ、その
結果、油圧シリンダ50を回転自在に支承するボ
ールベアリング51の負荷が軽減される。 Since the rear wall plate 50a of the hydraulic cylinder 50 is connected to the drive pulley shaft 45 via the stop ring 52 as described above, the hydraulic cylinder 50 is also placed in an integral connection relationship with the fixed pulley half 44. In this way, the thrust load acting between the stationary pulley half 44 and the hydraulic cylinder 50 due to the hydraulic operation of the piston 49 can be transmitted to and supported by the drive pulley shaft 45, and as a result, the hydraulic cylinder 50 can be freely rotated. The load on the ball bearing 51 supported by the ball bearing 51 is reduced.
従動Vプーリ41は、従動プーリ軸56と一体
に形された固定プーリ半体57と、従動プーリ軸
56に3個のボールキー58を介して軸方向摺動
可能に連結される可動プーリ半体59とより構成
され、そして固定プーリ半体57は駆動Vプーリ
40の可動プーリ半体47の後方に、また可動プ
ーリ半体59は固プーリ半体44の後方に、それ
ぞれ隣接して配置される。可動プーリ半体59は
その背面にねじ60で固着されたピストン61を
備え、このピストン61を収容する油圧シリンダ
62の後壁板62aが従動プーリ軸56に止環6
3を介して連結される。ピストン61は油圧シリ
ンダ62内をVベルト42側の第1油圧室621
と、それと反対側の第2油圧室622とに区画し、
ピストン61の受圧面は、第1油圧室621側が
第2油圧室622側より狭くなるように形成され
る。かくして、ピストン61及び油圧シリンダ6
2は可動プーリ半体59の油圧作動機構を構成す
る。 The driven V-pulley 41 includes a fixed pulley half 57 integrally formed with the driven pulley shaft 56 and a movable pulley half connected to the driven pulley shaft 56 so as to be slidable in the axial direction via three ball keys 58. 59, and the fixed pulley half 57 is arranged adjacent to the rear of the movable pulley half 47 of the driving V-pulley 40, and the movable pulley half 59 is arranged behind the solid pulley half 44, respectively. . The movable pulley half 59 is provided with a piston 61 fixed to its back surface with a screw 60, and a rear wall plate 62a of a hydraulic cylinder 62 that accommodates the piston 61 is attached to the driven pulley shaft 56 with a stop ring 6.
Connected via 3. The piston 61 moves inside the hydraulic cylinder 62 into a first hydraulic chamber 62 1 on the V-belt 42 side.
and a second hydraulic chamber 622 on the opposite side,
The pressure receiving surface of the piston 61 is formed such that the first hydraulic chamber 62 1 side is narrower than the second hydraulic chamber 62 2 side. Thus, the piston 61 and the hydraulic cylinder 6
2 constitutes a hydraulic operating mechanism for the movable pulley half 59.
上記構成において、両油圧室621,622に同
圧の油圧を導入すると、ピストン61は左右の受
圧面積の差による差動油圧を受けて右方に移動し
て可動プーリ半体59を固定プーリ半体57に近
付け、従動Vプーリ41の有効半径を拡大させる
ことができる。また、第1油圧室621に油圧を
かけた状態で第2油圧室622の油圧を解放すれ
ば、ピストン61は第1油圧室621の油圧によ
り左動して可動プーリ半体59を固定プーリ半体
57より遠ざけ、従動Vプーリ41の有効半径を
縮小することができる。このようなピストン61
の油圧作動のために第2制御弁V2が従動プーリ
軸56内に設けられるが、その詳細は後述する。 In the above configuration, when the same hydraulic pressure is introduced into both hydraulic chambers 62 1 and 62 2 , the piston 61 receives the differential hydraulic pressure due to the difference in the left and right pressure receiving areas, moves to the right, and fixes the movable pulley half 59. By bringing it closer to the pulley half 57, the effective radius of the driven V-pulley 41 can be expanded. Furthermore, if the hydraulic pressure in the second hydraulic chamber 62 2 is released with hydraulic pressure applied to the first hydraulic chamber 62 1 , the piston 61 moves to the left by the hydraulic pressure in the first hydraulic chamber 62 1 and moves the movable pulley half 59 . By moving it away from the fixed pulley half 57, the effective radius of the driven V-pulley 41 can be reduced. Such a piston 61
A second control valve V 2 is provided within the driven pulley shaft 56 for hydraulic operation of the second control valve V 2 , the details of which will be described later.
従動プーリ軸56は左右両端部及び中央部の3
個所をベアリング64,65,66を介してケー
シングCに支承される。そして、中央のベアリン
グ65と右端部のベアリング66の間において油
圧シリンダ62は、止環63及び従動プーリ軸5
6を介して固定プーリ半体57と一体的な連結関
係に置かれる。このようにすると、ピストン61
の油圧作動に伴い固定プーリ半体57と油圧シリ
ンダ62間に作用するスラスト荷重を従動プーリ
軸56に伝達、支承させることができ、その結
果、ベアリング65,66の負荷が軽減される。 The driven pulley shaft 56 has three shafts at both left and right ends and at the center.
These parts are supported by the casing C via bearings 64, 65, and 66. Between the center bearing 65 and the right end bearing 66, the hydraulic cylinder 62 is connected to the stop ring 63 and the driven pulley shaft 5.
6, it is placed in integral connection with the fixed pulley half 57. In this way, the piston 61
The thrust load acting between the stationary pulley half 57 and the hydraulic cylinder 62 due to the hydraulic operation can be transmitted to and supported by the driven pulley shaft 56, and as a result, the load on the bearings 65 and 66 is reduced.
さて、第1,第2制御弁V1,V2並びにその周
囲の油路に説明を移す。 Now, the explanation will shift to the first and second control valves V 1 and V 2 and the oil passages around them.
第1制御弁V1は中空の駆動プーリ軸45内に
摺合された筒状の従動スプール弁71と、この従
動スプール弁71内に摺合された筒状の主動スプ
ール弁70とよりなり、主動スプール弁70内に
内、外2重に嵌合した内側連絡管72及び外側連
絡管73が挿入される。内側連絡管72は主動ス
プール弁70を左右に貫通して、ケーシングCの
カバーC3に設けた前記制御油路Lcと発進クラツ
チScの油圧室13に連なる油路14との間を連
通する。 The first control valve V 1 consists of a cylindrical driven spool valve 71 slidably fitted within the hollow driving pulley shaft 45 and a cylindrical main driving spool valve 70 slidably fitted within the driven spool valve 71. An inner communicating pipe 72 and an outer communicating pipe 73, which are fitted in a double-fitted manner inside and out, are inserted into the valve 70. The inner communication pipe 72 passes through the main drive spool valve 70 from side to side, and communicates between the control oil passage Lc provided in the cover C3 of the casing C and the oil passage 14 connected to the hydraulic chamber 13 of the starting clutch Sc.
また、内側連絡管72は主動スプール弁70の
内側に筒状油路74を画成し、この油路74は外
側連絡管73を介してカバーC3に設けた前記第
1給油路L1に連通される。 Further, the inner communication pipe 72 defines a cylindrical oil passage 74 inside the main drive spool valve 70, and this oil passage 74 is connected to the first oil supply passage L1 provided in the cover C3 via the outer communication pipe 73. communicated.
両連絡管72,73は、外側連絡管73の右端
を絞つて内側連絡管72の外周面に溶接すること
により連結しており、また、外側連絡管73の外
周には取付フランジ75が溶接してある。この取
付フランジ75はカバーC3の内壁に形成した段
付取付凹部76の大径部に弾性シールリング77
を介して嵌装され、止環78により抜止めされ
る。段付取付凹部76の小径部には内側連絡管7
2の右方突出部が弾性シールリング79を介して
嵌装される。かくして、2重連絡管72,73は
カバーC3にフローテイング支持され、クランク
軸1及び駆動プーリ軸45の心振れにも追従する
ことができる。尚、80はカバーC3の第1給油
路L1と外側連絡管73の内側とを連通させるた
めに、該連絡管73の周壁に穿設した透孔であ
る。 Both communication pipes 72 and 73 are connected by squeezing the right end of the outer communication pipe 73 and welding it to the outer circumferential surface of the inner communication pipe 72, and a mounting flange 75 is welded to the outer circumference of the outer communication pipe 73. There is. This mounting flange 75 has an elastic seal ring 77 attached to the large diameter part of a stepped mounting recess 76 formed on the inner wall of the cover C3 .
, and is prevented from coming off by a retaining ring 78. The inner connecting pipe 7 is installed in the small diameter part of the stepped mounting recess 76.
The right protrusion of No. 2 is fitted through an elastic seal ring 79. In this way, the double communication pipes 72 and 73 are floatingly supported by the cover C 3 and can follow the eccentricity of the crankshaft 1 and the drive pulley shaft 45. Incidentally, reference numeral 80 denotes a through hole bored in the peripheral wall of the outer communication pipe 73 in order to communicate the first oil supply path L 1 of the cover C 3 with the inside of the outer communication pipe 73 .
主動スプール弁70は外周に左右一対の環状給
油溝81,82と1条の環状排油溝83とを有
し、給油溝81,82は透孔84,85を介して
主動スプール弁70内の筒状油路74と連通して
いる。また、従動スプール弁71は外周に左右一
対の環状油溝86,87を有し、その左側油溝8
6は、透孔88を介して主動スプール弁70の左
側給油溝81と常時連通する一方、透孔89、環
状油路90及び油路91を介して油圧シリンダ5
0の第1油圧室501とも常時連通している。右
側油溝87は、透孔92を介して主動スプール弁
70の排油溝83と常時連通する一方、透孔93
を介して油圧シリンダ50の第2油圧室502と
も常時連通している。また、従動スプール弁71
には、その右側油溝87と主動スプール弁70の
右側給油溝82との間の連通、遮断を制御する透
孔94と、主動スプール弁70の排油溝83とケ
ーシングC内部との連通、遮断を制御する切欠状
の排油口95が設けられている。さらに、従動ス
プール弁71は、駆動プーリ軸45を半径方向に
貫通する連動ピン96を介して可動プーリ半体4
7に連結されて、それと共に左右動するようにな
つている。駆動プーリ軸45の連動ピン96に貫
通される部分は、連動ピン96の左右動を妨げな
いように長孔97になつている。 The main drive spool valve 70 has a pair of left and right annular oil supply grooves 81, 82 and a single annular oil drain groove 83 on the outer periphery. It communicates with the cylindrical oil passage 74 . Further, the driven spool valve 71 has a pair of left and right annular oil grooves 86 and 87 on the outer periphery, and the left oil groove 8
6 constantly communicates with the left oil supply groove 81 of the main drive spool valve 70 through a through hole 88, and is connected to the hydraulic cylinder 5 through a through hole 89, an annular oil passage 90, and an oil passage 91.
It is also in constant communication with the first hydraulic chamber 50 1 of No. 0 . The right oil groove 87 is always in communication with the oil drain groove 83 of the main drive spool valve 70 via the through hole 92 , and
It is also in constant communication with the second hydraulic chamber 502 of the hydraulic cylinder 50 via. In addition, the driven spool valve 71
, a through hole 94 that controls communication and isolation between the right oil groove 87 and the right oil supply groove 82 of the main drive spool valve 70, and a communication between the oil drain groove 83 of the main drive spool valve 70 and the inside of the casing C; A cutout-shaped oil drain port 95 is provided to control shutoff. Furthermore, the driven spool valve 71 is connected to the movable pulley half 4 through an interlocking pin 96 that radially passes through the drive pulley shaft 45.
7, so that it can move left and right along with it. The portion of the drive pulley shaft 45 that is penetrated by the interlocking pin 96 is formed into a long hole 97 so as not to hinder the left and right movement of the interlocking pin 96.
第2制御弁V2は中空の従動プーリ軸56内に
摺合された筒状の従動スプール弁101と、この
従動スプール弁101内に摺合された主動スプー
ル弁100とよりなる。主動スプール弁100の
中心部には隔壁102により互いに隔離される給
油路103及び排油路104が形成されており、
給油路103は、それに挿入された連絡管105
を介してカバーC3に形成した前記第2給油路L2
と連通し、排油路104は、ケーシングC内部と
連通する従動プーリ軸56の中空部に開口する。 The second control valve V 2 consists of a cylindrical driven spool valve 101 slidably fitted within the hollow driven pulley shaft 56 and a main driven spool valve 100 slidably fitted within the driven spool valve 101 . An oil supply passage 103 and an oil drainage passage 104 are formed in the center of the active spool valve 100 and are separated from each other by a partition wall 102.
The oil supply path 103 has a communication pipe 105 inserted therein.
The second oil supply path L 2 formed in the cover C 3 via the
The oil drain passage 104 opens into a hollow portion of the driven pulley shaft 56 that communicates with the inside of the casing C.
連絡管105の外周に溶接した取付フランジ1
06はカバーC3の内壁に形成した取付凹部10
7に弾性シールリング108を介して嵌装され、
止環109により抜止めされる。かくして、連絡
管105はカバーC3にフローテイング支持され、
従動プーリ軸56の心振れに追従することができ
る。 Mounting flange 1 welded to the outer periphery of the connecting pipe 105
06 is a mounting recess 10 formed on the inner wall of the cover C3
7 through an elastic seal ring 108,
It is prevented from coming off by a retaining ring 109. In this way, the communication pipe 105 is floatingly supported by the cover C3 ,
It is possible to follow the runout of the driven pulley shaft 56.
また、主動スプール弁100は外周に左右一対
の環状給油溝110,111と1条の環状排油溝
112とを有し、給油溝110,111は透孔1
13,114を介していずれも前記給油路103
と連通し、排油溝112は透孔115を介して前
記排油路104と連通している。また、従動スプ
ール弁101は外周に左右一対の環状油溝11
6,117を有し、その右側油溝117は透孔1
18を介して主動スプール弁100の右側給油溝
111と常時連通する一方、透孔119、環状油
路120及び油路121を介して油圧シリンダ6
2の第1油圧室621とも常時連通し、左側油溝
116は透孔122を介して油圧シリンダ62の
第2油圧室622と常時連通している。また、従
動スプール弁101には、その左側油溝116
と、主動スプール弁100の左側給油溝110及
び排油溝112との各間の連通、遮断を制御する
透孔123,124が設けられている。さらに、
従動スプール弁101は、従動プーリ軸56を半
径方向に貫通する連動ピン125を介して可動プ
ーリ半体59に連結されて、それと共に左右動す
るようになつている。従動プーリ軸56の連動ピ
ン125に貫通される部分は、連動ピン56の左
右動を妨げないように長孔126になつている。 Moreover, the main drive spool valve 100 has a pair of left and right annular oil supply grooves 110, 111 and a single annular oil drain groove 112 on the outer periphery.
13 and 114, both of which are connected to the oil supply path 103.
The oil drain groove 112 communicates with the oil drain passage 104 via the through hole 115. Further, the driven spool valve 101 has a pair of left and right annular oil grooves 11 on the outer periphery.
6,117, and its right oil groove 117 is through hole 1.
18 , it is constantly in communication with the right side oil supply groove 111 of the main drive spool valve 100 , and is connected to the hydraulic cylinder 6 through the through hole 119 , the annular oil passage 120 , and the oil passage 121 .
The left oil groove 116 is always in communication with the second hydraulic chamber 62 2 of the hydraulic cylinder 62 via the through hole 122 . The driven spool valve 101 also has a left oil groove 116.
Through holes 123 and 124 are provided to control communication and isolation between the main drive spool valve 100 and the left oil supply groove 110 and the left oil drain groove 112 of the active spool valve 100, respectively. moreover,
The driven spool valve 101 is connected to the movable pulley half 59 via an interlocking pin 125 passing through the driven pulley shaft 56 in the radial direction, and is configured to move laterally together with the movable pulley half body 59. The portion of the driven pulley shaft 56 that is penetrated by the interlocking pin 125 is formed into a long hole 126 so as not to hinder the left-right movement of the interlocking pin 56.
第1、第2両制御弁V1,V2は、駆動側の可動
プーリ半体47と従動側の可動プーリ半体59と
を同期作動させるために、連動機構130により
連結される。連動機構130は、両制御弁V1,
V2の中間でケーシングCに両制御弁V1,V2と平
行に設けた支軸131と、この支軸131に摺動
自在に支承されたシフタ132と、このシフタ1
32に中間部を固着されると共に両制御弁V1,
V2の主動スプール弁70,100に両端を連結
した連動棒133とよりなり、前記シフタ132
はケーシングCに軸支したシフトレバー134の
回動により作動され、またそのシフトレバー13
4は第1図の操向ハンドルHの左グリツプHgの
回動により操作されるようになつている。 Both the first and second control valves V 1 and V 2 are connected by an interlocking mechanism 130 in order to synchronously operate the movable pulley half 47 on the driving side and the movable pulley half 59 on the driven side. The interlocking mechanism 130 includes both control valves V 1 ,
A support shaft 131 provided in the casing C in parallel with both control valves V 1 and V 2 in the middle of V 2 , a shifter 132 slidably supported on this support shaft 131 , and a shifter 132 that is slidably supported on this support shaft 131 .
32, and both control valves V 1 ,
It consists of an interlocking rod 133 whose both ends are connected to the main drive spool valves 70 and 100 of V2 , and the shifter 132
is operated by rotation of a shift lever 134 pivotally supported on the casing C, and the shift lever 13
4 is adapted to be operated by rotating the left grip Hg of the steering handle H shown in FIG.
ここで、両制御弁V1,V2の作用を説明すると、
第3図に示すように、シフタ132がカバーC3
に当接した右動限に位置する場合は、第1制御弁
V1では透孔94が主動スプール弁70により閉
じられて右側給油溝82と右側油溝87との間が
遮断されると共に、排油溝83と排油口95とが
連通し、一方、左側給油溝81と左側油溝86間
は常時連通状態にあるので、第1油圧室501に
は筒状油路74に待機する作動油圧が油溝81,
86等を通して導入され、第2油圧室502は油
溝82,87等を介して排油口95に開放され
る。したがつて、ピストン11は第1油圧室50
1の油圧を受けて右動して可動プーリ半体47を
後退限に保持する。 Here, to explain the actions of both control valves V 1 and V 2 ,
As shown in FIG. 3, shifter 132 is connected to cover C 3
If the valve is located at the right end of movement, the first control valve
In V 1 , the through hole 94 is closed by the active spool valve 70, and the right side oil supply groove 82 and the right side oil groove 87 are cut off, and the oil drain groove 83 and the oil drain port 95 are communicated with each other. Since the oil supply groove 81 and the left oil groove 86 are always in communication, the hydraulic pressure waiting in the cylindrical oil passage 74 is transferred to the oil groove 81 and the left oil groove 86 in the first hydraulic chamber 501 .
86 etc., and the second hydraulic chamber 50 2 is opened to the oil drain port 95 via oil grooves 82, 87, etc. Therefore, the piston 11 is in the first hydraulic chamber 50
The movable pulley half 47 is moved to the right in response to the hydraulic pressure of 1 and held at the backward limit.
また、この場合、第2制御弁V2では、左側給
油溝110が透孔123を介して左側油溝116
と連通すると共に、透孔124が主動スプール弁
100に閉じられて排油溝112と左側油溝11
6間が遮断される。一方、右側給油溝111と右
側油孔117間は常時連通状態にあるので、給油
路103に待機する作動油圧が油圧シリンダ62
の第1,第2両油圧室621,622に導入され、
したがつてピストン61は前述のように差動油圧
を受けて右方へ移動して可動プーリ半体59を前
進限に保持する。 Furthermore, in this case, in the second control valve V 2 , the left oil supply groove 110 is connected to the left oil groove 116 through the through hole 123 .
At the same time, the through hole 124 is closed by the main drive spool valve 100 and the oil drain groove 112 and the left oil groove 11 are connected to each other.
6 is cut off. On the other hand, since the right oil supply groove 111 and the right oil hole 117 are always in communication, the hydraulic pressure waiting in the oil supply path 103 is transferred to the hydraulic cylinder 62.
introduced into both the first and second hydraulic chambers 62 1 , 62 2 ,
Therefore, as described above, the piston 61 receives the differential oil pressure and moves to the right to hold the movable pulley half 59 at the forward limit.
このようにして、駆動Vプーリ40の有効半径
は最小に、また従動Vプーリ41の有効半径は最
大に制御されるので、駆動Vプーリ40は最大の
減速比を以て従動Vプーリ41を駆動することが
できる。 In this way, the effective radius of the driving V-pulley 40 is controlled to the minimum and the effective radius of the driven V-pulley 41 is controlled to the maximum, so that the driving V-pulley 40 drives the driven V-pulley 41 with the maximum reduction ratio. Can be done.
次に、シフタ132を左動すれば、連動棒13
3により両主動スプール弁70,100は同時に
左動される。そして、主動スプール弁70の左動
により透孔94が開いて右側給油溝82と右側油
溝87間が連通すると共に排油口95が主動スプ
ール弁70により閉じられると、筒状油路74の
作動油圧が第2油圧室502にも導入されるため、
ピストン49は前述のように差動油圧を受けて左
動を開始し、可動プーリ半体47を前進させる。
すると、この可動プーリ半体47の前進は連動ピ
ン96を介して従動スプール弁71に伝達される
ので、該スプール弁71も同時に移動して主動ス
プール弁70を追跡し、その追跡により透孔94
及び排油口95が主動スプール弁70に閉じられ
て、第2油圧室502が筒状油路74及び排油口
95のいずれとも遮断されたとき、ピストン49
したがつて可動プーリ半体47の移動は停止す
る。即ち、可動プーリ半体47は主動スプール弁
70の左動に応じて前進することができる。 Next, if you move the shifter 132 to the left, the interlocking rod 13
3, both main driven spool valves 70, 100 are simultaneously moved to the left. When the main drive spool valve 70 moves to the left, the through hole 94 opens and the right oil supply groove 82 and the right oil groove 87 communicate with each other, and when the oil drain port 95 is closed by the main drive spool valve 70, the cylindrical oil passage 74 Since the working hydraulic pressure is also introduced into the second hydraulic chamber 502 ,
As described above, the piston 49 receives the differential oil pressure and starts moving to the left, causing the movable pulley half 47 to move forward.
Then, the forward movement of the movable pulley half 47 is transmitted to the driven spool valve 71 via the interlocking pin 96, so the spool valve 71 also moves at the same time and tracks the driving spool valve 70, and as a result of the tracking, the through hole 94
When the oil drain port 95 is closed by the active spool valve 70 and the second hydraulic chamber 50 2 is cut off from both the cylindrical oil passage 74 and the oil drain port 95, the piston 49
Therefore, the movement of the movable pulley half 47 is stopped. That is, the movable pulley half 47 can move forward in response to leftward movement of the main drive spool valve 70.
また、主動スプール弁100の左動によれば、
透孔123が主動スプール弁100に閉じられる
と共に、透孔124が開かれて排油溝112と左
側油溝116間が連通するので、第2油圧室62
2の油圧が排油路104に解放される。このため、
ピストン61は第1油圧室621の油圧により左
動を開始し、可動プーリ半体59を後退させる。
すると、この可動プーリ半体59の後退は連動ピ
ン125を介して従動スプール弁101に伝動さ
れるので、該スプール弁101も同時に移動して
主動スプール弁100を追跡し、その追跡により
両透孔113,114が主動スプール弁100に
閉じられて、第2油圧室622が給油路103及
び排油路104のいずれとも遮断されたとき、ピ
ストン61したがつて可動プーリ半体59の移動
は停止する。即ち、可動プーリ半体59は主動ス
プール弁100の左動に応じて後退することがで
きる。 Furthermore, according to the leftward movement of the main drive spool valve 100,
The through hole 123 is closed to the active spool valve 100 and the through hole 124 is opened to communicate between the oil drain groove 112 and the left oil groove 116, so that the second hydraulic chamber 62
2 hydraulic pressure is released to the oil drain path 104. For this reason,
The piston 61 starts moving to the left due to the hydraulic pressure in the first hydraulic chamber 62 1 and moves the movable pulley half 59 backward.
Then, the retreat of the movable pulley half 59 is transmitted to the driven spool valve 101 via the interlocking pin 125, so the spool valve 101 also moves at the same time and tracks the driving spool valve 100, and as a result of the tracking, both through-holes are moved. 113 and 114 are closed by the active spool valve 100, and the second hydraulic chamber 622 is cut off from both the oil supply path 103 and the oil drain path 104, the movement of the piston 61 and therefore the movable pulley half 59 is stopped. do. That is, the movable pulley half 59 can move backward in response to leftward movement of the main drive spool valve 100.
このようにして、駆動Vプーリ40の可動プー
リ半体47の前進と、従動Vプーリ41の可動プ
ーリ半体59の後退とが同期して行われるため、
Vベルト42に過度の張力を与えることなく駆動
Vプーリ40の有効半径の縮小と従動Vプーリ4
1の有効半径の拡大とを同時に達成し、両Vプー
リ40,41間の減速比を的確に減じることがで
きる。 In this way, the advancement of the movable pulley half 47 of the driving V-pulley 40 and the retreat of the movable pulley half 59 of the driven V-pulley 41 are performed in synchronization.
The effective radius of the driving V pulley 40 and the driven V pulley 4 can be reduced without applying excessive tension to the V belt 42.
It is possible to simultaneously achieve the expansion of the effective radius of 1, and to accurately reduce the reduction ratio between both V-pulleys 40 and 41.
以上において、駆動Vプーリ40の油圧シリン
ダ50は従動Vプーリ41の油圧シリンダ62よ
りも大径に形成される。これによれば、同油圧下
においても、駆動側のピストン49が受ける油圧
作動力を従動側のピストン61が受ける油圧作動
力よりも常に大きくすることができ、変速の応答
性を向上させる上に有効である。 In the above, the hydraulic cylinder 50 of the driving V-pulley 40 is formed to have a larger diameter than the hydraulic cylinder 62 of the driven V-pulley 41. According to this, even under the same hydraulic pressure, the hydraulic actuation force received by the driving side piston 49 can always be made larger than the hydraulic actuation force applied by the driven side piston 61, which not only improves the responsiveness of shifting, but also improves the responsiveness of shifting. It is valid.
また、駆動Vプーリ40のピストン49におい
ては、それの第1油圧室501側の受圧面積を
A1、第2油圧室502側の受圧面積をA2とする
と、
A2−A1>A1
上式が成立し、また従動Vプーリ41のピストン
61においては、それの第1油圧室621側の受
圧面積をB1、第2油圧室622側の受圧面積をB2
とすると、
B2−B1>B1
上式が成立している。したがつて、各可動プーリ
半体47,59の油圧による前進力をそれぞれの
後退力よりも常に大きくすることができ、これに
よつても変速応答性の向上がもたらされる。 In addition, in the piston 49 of the drive V pulley 40, the pressure receiving area on the first hydraulic chamber 501 side is
A 1 , and if the pressure receiving area on the second hydraulic chamber 50 2 side is A 2 , then A 2 −A 1 >A 1 The above formula holds true, and in the piston 61 of the driven V pulley 41, the pressure receiving area on the second hydraulic chamber 50 2 side is A 2 . The pressure receiving area on the 62 1 side is B 1 , and the pressure receiving area on the 2nd hydraulic chamber 62 2 side is B 2
Then, B 2 −B 1 >B 1The above formula holds true. Therefore, the hydraulic forward force of each of the movable pulley halves 47, 59 can always be made larger than the respective backward force, and this also improves the speed change responsiveness.
更に、油圧シリンダ50,62には可動プーリ
半体47,59をそれぞれ前進方向に弾圧するば
ね53,67が縮設される。これらのばね53,
67は各油圧シリンダ50,62内に未だ油圧が
導入されていないとき、Vベルト42に予張力を
与えてその弛みを除去するように機能する。 Further, the hydraulic cylinders 50 and 62 are compressed with springs 53 and 67 that respectively press the movable pulley halves 47 and 59 in the forward direction. These springs 53,
67 functions to apply pretension to the V-belt 42 to remove slack when hydraulic pressure is not yet introduced into each hydraulic cylinder 50, 62.
補助ケースC2において、駆動Vプーリ40の
油圧シリンダ50は前方外側に、従動Vプーリ4
1の油圧シリンダ62は後方内側にそれぞれ配置
され、したがつて従動Vプーリ41の固定プーリ
半体57は後方外側に配置される。この固定プー
リ半体57は油圧シリンダ62のような付属部品
を持たないので、固定プーリ半体57の背面側の
ケーシングCの右外側面後部に凹所135を形成
することができ、第1図に示すように、この凹所
135を利用してブレーキペダルBpが設置され
る。このようにすると、ブレーキペダルBpの外
方突出を無くし、若しくはその突出量を小さくす
ることができる。尚、図中Stはステツプである。 In the auxiliary case C 2 , the hydraulic cylinder 50 of the driving V-pulley 40 is located on the front outside, and the driven V-pulley 4
The one hydraulic cylinder 62 is arranged on the rear inner side, and therefore the fixed pulley half 57 of the driven V-pulley 41 is arranged on the rear outer side. Since this fixed pulley half 57 does not have an attached part such as a hydraulic cylinder 62, a recess 135 can be formed in the rear right outer surface of the casing C on the back side of the fixed pulley half 57, as shown in FIG. As shown in the figure, the brake pedal Bp is installed using this recess 135. In this way, the outward protrusion of the brake pedal Bp can be eliminated or the amount of protrusion can be reduced. In addition, St in the figure is a step.
また、両油圧シリンダ50,62を両Vプーリ
40,41の対角線上に配置することは、両Vプ
ーリ40,41の近接配置の場合でも、各油圧シ
リンダ50,62の外径を他方の油圧シリンダ6
2,50に干渉されずに自由に設定し得るので好
都合である。 Further, by arranging both the hydraulic cylinders 50 and 62 on the diagonal line of both the V-pulleys 40 and 41, even when both the V-pulleys 40 and 41 are arranged close to each other, the outer diameter of each hydraulic cylinder 50 and 62 can be adjusted to the other hydraulic pressure. cylinder 6
This is advantageous because it can be freely set without being interfered with by the numbers 2 and 50.
次に、補助変速機Taの説明をする。 Next, the auxiliary transmission Ta will be explained.
第1及び第2図に示すように、ベアリング6
4,65の間で従動プーリ軸56上にニードルベ
アリング137を介して支承される入力軸138
と、その後方で主ケースC1にニードルベアリン
グ139及びボールベアリング140を介して両
端部を支承される出力軸141とを有し、入力軸
138は減速歯車列142を介して従動プーリ軸
56と連結される一方、低速及び高速歯車列14
3,144を介して出力軸141とも連結され
る。 As shown in FIGS. 1 and 2, the bearing 6
An input shaft 138 is supported between 4 and 65 on the driven pulley shaft 56 via a needle bearing 137.
and an output shaft 141 supported at both ends by the main case C 1 through a needle bearing 139 and a ball bearing 140 behind it, and an input shaft 138 connected to a driven pulley shaft 56 through a reduction gear train 142. While coupled, low speed and high speed gear train 14
It is also connected to the output shaft 141 via 3,144.
減速歯車列142は、従動プーリ軸56にスプ
ライン結合した第1小歯車145、この小歯車1
45より中間歯車146を介して駆動される第1
大歯車147、この大歯車147と一体に回転す
る第2小歯車148及びこの小歯車148より駆
動される第2大歯車149より構成され、一体の
第1大歯車147及び第2小歯車148はニード
ルベアリング150を介して出力軸141上に支
承され、第2大歯車149は入力軸138の一端
に一体に形成される。したがつて、従動プーリ軸
56の回転は第1歯車145,147により1段
階減速し、また第2歯車148,149によりも
う1段階減速して入力軸138に伝達することが
できる。 The reduction gear train 142 includes a first small gear 145 spline-coupled to the driven pulley shaft 56, and this small gear 1.
45 via an intermediate gear 146.
It is composed of a large gear 147, a second small gear 148 that rotates together with this large gear 147, and a second large gear 149 that is driven by this small gear 148. The second large gear 149 is supported on the output shaft 141 via a needle bearing 150 and is integrally formed at one end of the input shaft 138 . Therefore, the rotation of the driven pulley shaft 56 can be reduced by one step by the first gears 145 and 147, and by another step by the second gears 148 and 149, and then transmitted to the input shaft 138.
低速歯車列143は入力軸138に一体に形成
された駆動歯車151と、出力軸141に回転自
在に支承されて上記歯車151より駆動される被
動歯車152とより構成され、また高速歯車列1
44も同じく入力軸138に一体に形成された駆
動歯車153と、出力軸141に回転自在に支承
されて上記歯車153より駆動される被動歯車1
54とより構成され、そして減速比は、低速歯車
列143の方を高速歯車列144の方より当然に
大きく設定される。また、出力軸141には両被
動歯車152,154に交互にドツグ結合し得る
シフタ155が摺動自在にスプライン嵌合156
されており、したがつて、シフタ155は、被動
歯車152と結合する低速位置「Lo」と、被動
歯車154と結合する高速位置「Hi」との2つ
切換位置を持つが、その外に両被動歯車152,
154のいずれとも結合しない中立位置「N」を
もとり得るものであり、このシフタ155の切換
操作はシフトフオーク157により行われる。か
くして、シフタ155を「Lo」または「Hi」の
位置に切換えれば、低速歯車列143または高速
歯車列144が作動状態となるので、入、出力軸
138,141間に高低二段の変速比を与えるこ
とができる。 The low-speed gear train 143 includes a driving gear 151 integrally formed with the input shaft 138 and a driven gear 152 rotatably supported by the output shaft 141 and driven by the gear 151.
44 also includes a drive gear 153 formed integrally with the input shaft 138, and a driven gear 1 rotatably supported by the output shaft 141 and driven by the gear 153.
54, and the reduction ratio of the low-speed gear train 143 is naturally set larger than that of the high-speed gear train 144. Further, a shifter 155 that can be dog-coupled alternately to both driven gears 152 and 154 is slidably spline-fitted 156 to the output shaft 141.
Therefore, the shifter 155 has two switching positions: a low speed position "Lo" where it is coupled with the driven gear 152, and a high speed position "Hi" where it is coupled with the driven gear 154. driven gear 152,
The shifter 155 can be switched to a neutral position "N" in which it is not coupled to any of the shifters 154 and 154, and this switching operation of the shifter 155 is performed by a shift fork 157. In this way, when the shifter 155 is switched to the "Lo" or "Hi" position, the low speed gear train 143 or the high speed gear train 144 is put into operation, so that two high and low gear ratios are established between the input and output shafts 138 and 141. can be given.
この補助変速機Taは、前記無段変速機Tmの
不足する変速比幅を補うものであり、換言すれば
補助変速機Taの併設により、無段変速機Tmの
駆動及び従動Vプーリ40,41の軸間距離を可
及的に狭ばめてこれらをパワーユニツトPuのケ
ーシングC内にコンパクトに収めることが可能と
なり、それに伴う無段変速機Tmの変速比幅の多
少の犠性が許容される。 This auxiliary transmission Ta compensates for the gear ratio width that the continuously variable transmission Tm lacks.In other words, by providing the auxiliary transmission Ta, it drives the continuously variable transmission Tm and drives the driven V pulleys 40, 41. By narrowing the distance between the shafts as much as possible, it is possible to compactly fit them into the casing C of the power unit Pu, and some sacrifice in the gear ratio width of the continuously variable transmission Tm is allowed. Ru.
以上のように本発明によれば、プーリ軸上に固
定プーリ半体と可動プーリ半体を設け、可動プー
リ半体を油圧作動機構により固定プーリ半体に対
して進退させることにより有効半径を調節し得る
Vプーリを備えたベルト式無段変速機において、
プーリ軸を中空に形成して、それの内部に油圧作
動機構への作動油圧を制御する制御弁を嵌入し、
その制御弁を、一方向への摺動により可動プーリ
半体を前進させ、また他方向への摺動により可動
プーリ半体を後退させ得るように油圧作動機構へ
の作動油圧を制御する主動スプール弁と、主動ス
プール弁の外周に摺合され、可動プーリ半体と一
体に摺動してその可動プーリ半体を主動スプール
弁の摺動量に応じた位置で停止させ得るように油
圧作動機構への作動油圧を制御する従動スプール
弁とより構成したので、制御弁をプーリ軸内に収
めて装置全体の小型化を図り、また可動プーリ半
体の前進及び後退を主動スプール弁と従動スプー
ル弁の摺動により軽快に行うと共に可動プーリ半
体を任意位置で確実に停止させることができ、し
たがつて変速操作を正確に行うことができる。 As described above, according to the present invention, a fixed pulley half and a movable pulley half are provided on the pulley shaft, and the effective radius is adjusted by moving the movable pulley half forward and backward with respect to the fixed pulley half using a hydraulic actuation mechanism. In a belt type continuously variable transmission equipped with a V-pulley that can
The pulley shaft is formed hollow, and a control valve that controls the hydraulic pressure to the hydraulic operating mechanism is fitted inside it.
The control valve is connected to a drive spool that controls the hydraulic pressure to the hydraulic operating mechanism so that the movable pulley half can be moved forward by sliding in one direction, and the movable pulley half can be moved backward by sliding in the other direction. A hydraulic actuating mechanism that is slidable on the outer periphery of the valve and the drive spool valve, slides together with the movable pulley half, and stops the movable pulley half at a position corresponding to the amount of sliding of the drive spool valve. Since it is composed of a driven spool valve that controls the working oil pressure, the control valve is housed within the pulley shaft to reduce the size of the entire device, and the movement of the movable pulley half is moved forward and backward by the sliding movement of the driving spool valve and the driven spool valve. This allows the movable pulley half to be reliably stopped at any position, and therefore allows for accurate speed change operations.
図面は本発明の一実施例を示すもので、第1図
は自動二輪車の動力伝達系の概略平面図、第2図
はその動力伝達系内のパワーユニツトの要部縦断
平面図、第3図はそのパワーユニツト内のベルト
式無段変速機の拡大縦断平面図である。
Tm…ベルト式無段変速機、V1,V2…第1、
第2制御弁、40…駆動Vプーリ、41…従動V
プーリ、44,57…固定プーリ半体、45…駆
動プーリ軸、47,59…可動プーリ半体、4
9,50…油圧作動機構を構成するピストン、油
圧シリンダ、56…従動プーリ軸、61,62…
油圧作動機構を構成するピストン、油圧シリン
ダ、70,100…主動スプール弁、71,10
1…従動スプール弁。
The drawings show one embodiment of the present invention, and FIG. 1 is a schematic plan view of a power transmission system of a motorcycle, FIG. 2 is a vertical sectional plan view of a main part of a power unit in the power transmission system, and FIG. is an enlarged vertical sectional plan view of the belt type continuously variable transmission in the power unit. Tm…belt type continuously variable transmission, V 1 , V 2 … 1st,
2nd control valve, 40... Drive V pulley, 41... Driven V
Pulley, 44, 57... Fixed pulley half, 45... Driving pulley shaft, 47, 59... Movable pulley half, 4
9, 50... Piston and hydraulic cylinder constituting the hydraulic operating mechanism, 56... Driven pulley shaft, 61, 62...
A piston, a hydraulic cylinder, 70, 100, which constitutes a hydraulic operating mechanism, a driving spool valve, 71, 10
1...Followed spool valve.
Claims (1)
体を設け、該可動プーリ半体を油圧作動機構によ
り前記固定プーリ半体に対して進退させることに
より有効半径を調節し得るVプーリを備えたベル
ト式無段変速機において、前記プーリ軸を中空に
形成して、それの内部に前記油圧作動機構への作
動油圧を制御する制御弁を嵌入し、該制御弁を、
一方向への摺動により前記可動プーリ半体を前進
させ、また他方向への摺動により前記可動プーリ
半体を後退させ得るように前記油圧作動機構への
作動油圧を制御する主動スプール弁と、該主動ス
プール弁の外周に摺合され、前記可動プーリ半体
と一体に摺動して該可動プーリ半体を前記主動ス
プール弁の摺動量に応じた位置で停止させ得るよ
うに前記油圧作動機構への作動油圧を制御する従
動スプール弁とより構成した、ベルト式無段変速
機の作動制御装置。 2 特許請求の範囲第1項記載のものにおいて、
前記Vプーリは駆動Vプーリ及び従動Vプーリで
あり、両Vプーリにそれぞれ前記制御弁を設け、
駆動側の前記可動プーリ半体と従動側の前記可動
プーリ半体とを同期作動させるように両制御弁を
連動機構により連結した、ベルト式無段変速機の
作動制御装置。[Claims] 1. A fixed pulley half and a movable pulley half are provided on a pulley shaft, and the effective radius is adjusted by moving the movable pulley half forward and backward with respect to the fixed pulley half using a hydraulic actuation mechanism. In a belt-type continuously variable transmission equipped with a V-pulley, the pulley shaft is formed hollow, and a control valve for controlling the hydraulic pressure to the hydraulic operating mechanism is fitted inside the pulley shaft, and the control valve is
a main drive spool valve that controls hydraulic pressure to the hydraulic operating mechanism so that the movable pulley half moves forward by sliding in one direction, and moves backward by sliding in the other direction; , the hydraulic actuation mechanism is slidable on the outer periphery of the driven spool valve, and is configured to slide integrally with the movable pulley half to stop the movable pulley half at a position corresponding to the sliding amount of the driven spool valve. An operation control device for a belt-type continuously variable transmission consisting of a driven spool valve that controls hydraulic pressure to the belt. 2. In what is stated in claim 1,
The V-pulleys are a driving V-pulley and a driven V-pulley, and both V-pulleys are each provided with the control valve,
An operation control device for a belt-type continuously variable transmission, in which both control valves are connected by an interlocking mechanism so that the movable pulley half on the driving side and the movable pulley half on the driven side operate synchronously.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP12879582A JPS58102857A (en) | 1982-07-23 | 1982-07-23 | Control device for operation of belt type stepless change gear |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP12879582A JPS58102857A (en) | 1982-07-23 | 1982-07-23 | Control device for operation of belt type stepless change gear |
Related Parent Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
JP56198796A Division JPS5899548A (en) | 1981-12-10 | 1981-12-10 | Belt type infinitely variable gear |
Publications (2)
Publication Number | Publication Date |
---|---|
JPS58102857A JPS58102857A (en) | 1983-06-18 |
JPS633191B2 true JPS633191B2 (en) | 1988-01-22 |
Family
ID=14993625
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
JP12879582A Granted JPS58102857A (en) | 1982-07-23 | 1982-07-23 | Control device for operation of belt type stepless change gear |
Country Status (1)
Country | Link |
---|---|
JP (1) | JPS58102857A (en) |
Families Citing this family (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS6030855A (en) * | 1983-07-30 | 1985-02-16 | Mazda Motor Corp | Controller for continuously variable transmission |
JPS6179055U (en) * | 1984-10-30 | 1986-05-27 | ||
JP2008087606A (en) * | 2006-09-29 | 2008-04-17 | Honda Motor Co Ltd | Transmission |
-
1982
- 1982-07-23 JP JP12879582A patent/JPS58102857A/en active Granted
Also Published As
Publication number | Publication date |
---|---|
JPS58102857A (en) | 1983-06-18 |
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