US2436388A - Servomotor - Google Patents

Description

Feb. 24,1948. T, |AvE| ET AL 2,436,388

SERVO-MOTOR Filed Nov. 28, 1940 4 Sheets-Sheet 1 Feb. 24, 1948. T- |AVE| ET AL 2,436,388

sERvoMoToR Filed NOV. 28, 1940 4 Sheets-Sheet 2 Feb. 24, 1948. T. IAVELLI ETAI.

SERVO-MOTOR 4 Sheets-Sheet I5 Filed Nov. 28, 1940 ATTORNEY5- T. IAVELLI E1- AL l SERvo -MOTOR 4 Sheets-Sheet 4 Filed Nov. 28, 1940 N3 .Mq n. #Hdl Feb. 24, 1948.

Patented Feb. 24, 1948 SERVOMOTOR Teno Iavelli, Detroit, and Victor E. Matulaitis, Highland Park, Mich., assignors to Chrysler Corporation, Highland Park, Mich., a corporation of Delaware Application November 28, 1940, Serial No. 367,584

22 claims. l

This invention relates to motor vehicles and refers more particularly to power transmission and control mechanism therefor.

Our invention has particular reference to transmission systems in which the torque load is relieved as by momentary interruption of the engine ignition or by other suitable `means in order to unload positively engageable drive control elements so as to facilitate disengagement of such elements. One example of such a transmission is described and claimed in the copending application of Carl A. Neracher et al., Serial No. 335,310, iiled May 15, 1940.

One object of our invention is to provide improved and simplied means for controlling the torque-relieving or torque reversing means.

Another object is to provide a transmission control which is more fool-proof in its operation and in the general drive functions of the vehicle.

A further object is to provide improved control means for the torque-relieving means whereby the torque relief is brought about only as an incident to the one desired direction of movement of the actuating means for the movable or shiftvable drive control element and not during the return direction of movement of this actuating means.

Another object is to provide an improved servo-motor assembly for controlling shift of the shiftable drive control element.

An additional object is to provide an improved servo-motor which is very compact and which takes up relatively little room.

Another object is to provide an improved servo-motor prima-mover of the vacuum operated electromagnetically controlled type in which the parts are advantageously arranged for low cost, simplified manufacture, novel subassembly of the electromagnet structure, and for so telescoping certain of the parts as to greatly reduce the overall length, weight and cost of the motor.

-We have retained in this application claims directed to our servo-motor. The subject matter of our transmission control including our switch control mechanism has been made the subject of our copending divisional application Serial No. 421,558 filed December 4, 1941.

Further objects and advantages of our invention reside in the novel combination and arrangement of parts more particularly hereinafter described and claimed, reference being had to the accompanying drawings in which:

Fig. 1 is a side elevational view showing the motor vehicle engine and power transmission.

Fig. 2 is a longitudinal sectional elevational view through the main clutching mechanism.

Fig. 3 is a similar view through the change speed transmission.

Fig. 4 is a detail enlarged view of the blocker clutch as seen in Fig. 3.

Fig. 5 is a sectional plan view illustrated as a development according to line 5-5 of Fig. 4, the automatic clutching sleeve being released.

Fig. 6 is a similar view showing the automatic clutching sleeve in its intermediate shift position during the drive blocking condition.

Fig. 7 is a similar view showing the automatic clutching sleeve in its coasting relationship for the Fig. 6 showing, the clutching sleeve being unblocked during coast for its clutching movement.

Fig. 8 is a similar view showing the automatic clutching sleeve in full clutching engagement.

Fig. 9 is a View similar to Fig. 5 but showing the automatic clutching sleeve in its other intermediate shift position during the coast blocking condition.

Fig. 10 is a sectional elevational View taken approximately as indicated by line lll-I0 in Fig. 3 but showing only the upper portion of the transmission mechanism and particularly the lever operating mechanism for the automatic clutching sleeve.

Fig. 1l is a diagrammatic view of the control mechanism for the automatic clutching sleeve, the latter being shown in its released position.

Fig. 12 is a similar view of the Fig. 11 mechanism corresponding to engaged position of the automatic clutching sleeve.

Fig. 13 is a detail sectional view oi.' one of the terminal connections for the coil of the electromagnet.

Fig. 14 is a detail sectional view showing the venting system for the pressure fluid motor, the view being taken approximately as indicated by line l 4l 4 of Fig. 12.

Fig. 15 is a detail view taken as indicated b line l5-l5 of Fig. 12. Y A

While our control may be employed in conjunction with various types and arrangements of motor vehicle transmissions, especially where a pair of relatively movable positively engageable drive control elements are employed, in order to illustrate one driving system we have shown our invention in connection with certain parts of the aforesaid Neracher et al. application.

In the drawings A represents the internal combustion engine which drives through fluid coupling B and conventional type of friction main clutch C to the speed ratio transmission D whence the drive passes from output shaft to drive the rear vehicle wheels in the usual manner.

The engine crankshaft 2l carries the vaned fluid coupling impeller 22 which in the well known manner drives the vaned runner 23 whence the drive passes through' hub 24 to clutch driving member 25. This member then transmits the drive, when clutch C is engaged as in Fig. 2, through driven member 26 to the transmission driving shaft 21 carrying the main drive pinion 28. A clutch pedal 29 controls clutch C such that when the driver depresses this pedal. collar 39 is thrust forward to cause levers 3| to release the clutch driving pressure plate 32 against springs 33 thereby releasing the drive between runner 23 and shaft 21. The primary function of the main clutch C is to enable the driver to make manual shifts in transmission D.

Referring to the transmission, pinion 28 is in constant mesh with gear 34 which drives countershaft 35 through an overrunning clutch E of the usual type such that when shaft 21 drives in its usual clockwise direction (looking from front to rear) then clutch E will engage to lock gear 34 to countershaft 35 whenever the gear 34 tends to drive faster than the countershaft. However,

. whenever this gear 34 tends to rotate slower than the countershaft then clutch E will automatically release whereby shaft 21, under certain conditions. may readily drop its speed while countershaft 35 continues to revolve.

Countershaft 35 comprises cluster gears 36, 31 and 38 which respectively provide drives in first, third and reverse. Freely rotatable on shaft 20 are the first and third driven gears 39 and 40 respectively in constant mesh with countershaft gears 36 and 31. A hub 4I is splined on shaft 20 and carries therewith a manually shiftable sleeve 42 adapted to shift from the Fig. 3 neutral position either rearwardly to clutch with teeth 43 of gear 39 or else forwardly to clutch with teeth 44 of gear 40. Sleeve 42 is operably connected to shift rail 45 adapted for operation by any suitable means under shifting control of the vehicle driver.

Shaft 20 also carries reverse driven gear 46 fixed thereto. A reverse idler gear 41 is suitably mounted so that when reverse drive is desired, idler 41 is shifted into mesh with gears 38 and 45.

First, third and reverse speed ratio drives and neutral are under manual shift control of the vehicle driver, the main clutch C being released by depressing pedal 29 in shifting into any one of these drives.

First is obtained by shifting sleeve 42 to clutch with teeth 43, the drive passing from engine A, through fluid coupling B, clutch C and shaft 21 to pinion 28, thence through gear 34 and clutch E to countershaft 35. From the countershaft the drive is through gears 36, 39 and sleeve 42 to shaft 20.

Third is obtained by shifting sleeve 42 to clutch with teeth 44, the drive passing from the engine to the countershaft 35 as before, thence through gears 31, and sleeve 42 to shaft 20.

Reverse is obtained by shifting idler into mesh with gears 38, 46, sleeve 42 being in neutral, the reverse drive passing from the engine to the countershaft 35 as before, thence through gears 38, 41 and 46 to shaft 20.

Slidably splined on teeth 48 carried by gear 40 4 certain conditions, is adapted to shift forwardly to clutch with teeth 49 carried by pinion 28 thereby positively'to clutch shaft 21 directly to gear 40. The sleeve F is adapted to step-up the speed ratio drive from rst to second and from third to fourth which is a direct drive speed ratio. Control means is provided which limits clutching of sleeve F to approximate synchronism with teeth 49 and also to a condition of engine coast, sleeve F being prevented from clutching during that condition known as engine drive as when the engine is being speeded up under power.

When driving in rst, second is obtained by the driver releasing the usual accelerator pedal 50' thereby allowing spring 5l)EL to close the engine throttle valve and cause the engine to rapidly coast down. When this occurs, the engine along with shaft 21, pinion 28 and gear 34 all slow down while shaft 20 along with gears 39 and 38 continue their speeds-by accommodation of clutch E which now overruns. The engine slows down until teeth 49 are brought to approximate synchronism with sleeve F which thereupon automatically shifts to clutch with teeth 49 resulting in a two-way drive for second as follows: pinion 28 through sleeve F to gear 40 thence through gears 31, 36 and 39 to sleeve 42 and shaft 20, the clutch E overrunning.

When driving in third, fourth or direct is obtained just as for second by driver release of the accelerator pedal and resulting shift of sleeve F to clutch with teeth 49 when these parts are synchronized by reason of the engine coasting down from the drive in third. The direct drive is a two-way drive as follows: pinion 28 through sleeve F to gear 40 thence directly through sleeve 42 to shaft 20, clutch E overrunning as before.

Referring to Figs. 4 to 9 there is shown the blocking means for controlling clutching shift of sleeve F so as to limit clutching thereof to engine' short teeth 50, 5I certain of which may be bridged or joined together. A blocker ring 52 is provided with blocking teeth 53 which either lie in the path of forward shift of teeth 50 or 5| or else between these teeth to allow clutching shift of sleeve F. Thus, blocker 52 has, at suitable locations, a drive lug 54 engaged in a slot 55 of gear 40. The blocker is urged under light energizing pressure of spring 58 into constant frictional engagement at 51 with pinion 28 so that the blocker tends to rotate with pinion 28 within the limits afforded by the travel of lug 54 circumferentially in slot 55.

During drive in rst and third, the speed of shaft 21 exceeds the speed of gear 40 so that, if sleeve F is fully released, the parts will be positioned as in Fig. 5 wherein the blocker teeth 53 are axially in alignment with the short teeth 5l. If now the sleeve F is urged forwardly it will move to the Fig. 6 position of drive blocking and will remain in this blocked position as long as the engine drives the carin first or third.

If now the driver releases the accelerator pedal so that the engine may coast down under accommodation of overrunning clutch E, while sleeve F is urged forwardly, then when pinion 28 is reduced in speed to that of sleeve F slight further drop in speed of pinion 28 for a fraction of a revolution below the speed of sleeve F will cause blocker 52 to rotate slightly relative to sleeve F 1s the automatic clutching sleeve F Whh, Bilder 75 until blocker teeth 53 strike the adjacent Sides of long teeth 58 as in Fig. '1 thereby limiting fur ther reduction in speed of the blocker relative to sleeve F. At this time the sleeve Fis free to complete its forward clutching shift with teeth 48, as in Fig. 8, the blocker teeth 53 passing between adjacent long and short teeth 50, 5|. With the sleeve F thus clutched during engine coast, a two-way drive is established in second or fourth depending on whether the manually shifta-ble'.

sleeve F was set for first or third just prior to the clutching shift of sleeve F.

In the event that sleeve F is urged forwardly from its Fig. 5 position at a time when the gear 48 is rotating faster than pinion 28, then the blocker 52 will lag behind the sleeve and will be blocked by engagement of long teeth 58 with the blocker teeth 53 as shown in Fig. 9. This is referred to as the coast blocking condition. If now the engine is speeded up by the driver depressing the accelerator pedal in the usual manner, then the engine and blocker 52 rotate forwardly and blocker teeth 53 move over to the Fig- 6 drive blocking position thereby jumping the gap between teeth 58 and 5l This is the primary reason for providing the long and short teeth whereby sleeve F clutches only from the drive blocking condition followed by engine coast which protects the teeth and avoids harsh clutching effects on the passengers and transmission mechanism. On accelerating the engine from the Fig. 9 coast blocking condition, the engine comes up to a speed limited by engagement of the overrunning clutch E for drive in either rst or third depending on the setting of the manual shiftable sleeve 42. Then on releasing the accelerator pedal the sleeve F will synchronously clutch with teeth 49 during coast to step-up the drive to either second or fourth as aforesaid.

The transmission is provided with our im proved prime mover means for controlling shift of sleeve F along with several control means. Referring particularly to Figs. l1 and l2, there is illustrated a pressure fluid operated motor G utilizing air pressure for its operation. For convenience this motor is arranged to operate by the vacuum in the intake manifold system of the engine under control of electromagnetic means.

Forward shift of sleeve F is effected, under control of motor G, by reason of a spring 58 having its upper end fixed by engaging the outboard portion of a transverse shaft 59 xcd in the housing of transmission D. Mounted to freely rock on shaft 59 is a shift yoke El) which engages the shift groove 8| of sleeve F, this yoke having one of its arms provided with a forwardly extending lever 62 carrying a lateral pin 63 which engage-.a the yoke portion 84 of an upstanding lever 85. This lever G5 is fixed to the inboard end of a rockshaft 86 the outboard end of which has fixed thereto a bell-crank follower lever member having lever arms Gland 68. The end of lever B8 is connected -to the lower end of spring 58 and lever 61 carries an adjustable abutment 69 for taking up any play in the linkage mechanism.

Spring 58 acts to yieldingly urge engagement of sleeve F, acting through lever 88, shaft 65 and lever 85, to cause pin 63 to swing yoke 88 forwardly on its shaft 59 until, when sleeve F is fully engaged, a stop pin 1| engages the forward flat face 12 of lever 62. This limits rearward swing of lever 61.

The motor G comprises a central body casting 13 to which is secured the rear body casting 14 and the forward closure 15. A piston preferably of the diaphragm type 16 has its outer end fixed between closure 15 and body 13 while its inner or central portion is secured tothe rear portion of a hollow reciprocatory leader member or piston rod 18. Theforward end of this piston rod carries a closure abutment member 11 fixed thereto and arranged toengage abutment 69 during its arcuate swing about the axis of shaft 68. The rear end of rod 18' is open and telescopically receives the guldeaod 18 of a unitary assembly H for the coil 1,8 of the electromagnet.

The assembly H comprises an outer ferrous electromagnet cylinder 88 having a rear outwardly extending flange 8| and an inner ferrous electromagnet cylinder 82 disposed concentrically within cylinder 88 and receiving the coil 18 therebetween. The cylinders 88, 82 are the main flux-directing elements of the electromagnet for forming the flux 'path when magnetically activated by coil 19. A non-ferrous annulus 83 is disposed between'cylinders 88, 82 at the rear ends thereof and a isecond non-ferrous annulus 84 is disposed between the rear end of cylinder 82 and the rear end of'guide rod 18 which is bored out at 85 to slidably receive a guide plunger 88 urged rearwardly by spring 81. The rear faces of annuli 83, 84 are flush with the rear faces of cylinders 88, 82. A ferrous annulus 88 is seated around cylinder 82 at'the front end of coil 19, this annulus having a gap within the cylinder 88 and having its'forward face spaced rearwardly from the flush front-faces of cylinders 88, 82 to form a shunt flux path as will be presently apparent. The assembly H comprising cylinders 88, 82, rod 18 and annuli 83, 84, 88 are hydrogen welded or brazed so as to forma permanent unitary assembly in conjunction with coil 18, The assembly H is formed in this unitary fashion and then assembled as a, unit fixed in the motor G. the cylinder 88 slidably fitting within a cylindrical bracket 89 which is formed as a part of body 13. The flange 8| is secured between bodies 13, 14 as illustrated and the guide rod 18 slidably guides reciprocatory movement of piston rod 16' as piston 16 moves between its Fig. 11 and Fig. 12 positions.

Thrusting forwardly on piston 18 is a spring 88 of much greater force than that of spring 58 so that spring 98 can act to release sleeve F as in Fig. 11. In order to releasably hold the piston in its Fig. 12 position we provide a plate armature 9| fixed with respect to piston 18 and rod 18 and adapted for engagement with the front faces of cylinders 88, 82 as in Fig. 12.

At the rear of the unit H there is provided a second plate armature 82 engageable as in Fig. 12 with the rear faces of cylinders 88, 82 and fixed to a pin 93 which is secured to plunger 88 and projects rearwardly therefrom and terminates in a head 94. This pin 93 loosely mounts a valve member 85, a spring 86 acting between head 94 and the valve to urge the latter forwardly against a spacer sleeve 91 disposed between armature 92 and the valve.

The body 14 is formed with a valve seat 98 cooperable with valve 95 to control supply of vacuum from pipe 99 to the body passage |88 which extends by passage |8| ln body 13 for communication with the working chamber |82 at the rear face of piston 18. Pipe 99 extends through flexible pipe .99' to the engine intake manifold J. Body 14 hasfa second valve seat |83 spaced around sleeve 91 and also cooperable with valve 95 to control venting communication between passage |88 and a venting chamber |84 within 7,. which the armature 92" moves. Chamber |04 communicates with a vent (Fig, 14) which leads to the atmosphere and which may be equipped with a conventional air cleaner (not shown).

In Fig. 13 we have illustrated one oi the leads |06 for the coil 19, this lead extending rearwardly from the coil through an opening in annulus 83 and then outwardly in a slot |01 milled in the rear face of this annulus for connection with terminal |08 insulated with respect to body 14. A

i sealing grommet |09 is disposed in a recess in annulus 83 around lead |06 so as to prevent leakage between `chamber |02 and the atmosphere by way of chamber |04 and vent |05. The other lead for coil 19 extends in similar manner to its terminal just as in Fig. 13 for controlling energization of the coil.

We also provide means which functions to relieve the thrust-application between the teeth of sleeve F and the teeth 49 thereby facilitating movement of the drive control sleeve element F from its Fig. 12 position of engaging relationship into its Fig. 11 position of disengaging relationship with respect to teeth 49, This relief means, in the present embodiment of our invention, is in the form of a system of grounding the primary terminalof the usual distributor of the engine ignition system whereby the engine ignition may be momentarily rendered inoperative thereby unloading the torque at sleeve F suil'iciently to insure its release by spring 90.

The interrupting system is under control of a pair of interrupter switches K and L which function to momentarily interrupt the ignition. These switches K and L are mounted in a switch casing H0. Switch K comprises a xed contact which is connected by conductor ||2 to a ground at H3. Contact Ill' is carried by a bracket ||4 loosely mounted on a ilxed rod 5 and yieldingly urged into its Fig. 12 switch open position by a spring ||6 (Fig. l5).

yieldingly urged to its Fig. 1l switch open position by a spring I9.

Engaging the bracket I4 is a pin |20 slidable in body 14 and adapted to be urged rearwardly by a plunger |2| acting through a spring |22. The front face of the plunger |2| is in contact with th'e rear face of armature 92, the arrangement being such .that when the armature moves rearwardly from its Fig. 12 position to its Fig. 11 position, plunger 2| compresses spring |22 and causes contact l I to swing against the action of spring I6 to close switch K as in Fig. 11. Likewise when armature 92 moves back to its Fig. l2 position the spring l I6 restores the parts to their Fig. 12 positions.

Engaging bracket H8 is a generally similar When piston 16..moves. forwardly to its Fig. 11

position spring |24,4 will hold switch L closed until near the end of the piston travel at which time the force of spring I.24.4is so'reduced that spring ||9 then acts to swing bracket `||8 forwardly along with pin |23 thereby opening switch L as in Fig. l2. Contact ||1 extends by conductor |21 to the primary terminal |26 of .distributer |29.

Switch L likewise com-` prises a stationary contact I |1 and a contact I |1' carried by a bracket H8 loose on rod H5 and- Contacts and ||1'are electrically connected with.- each other through their brackets ||4, ||8, and rod |I5 and terminals and ||1 are of course electrically insulated from casing H0.

, Likewise pins |20 and |23 are either insulated with respect to brackets ||4 and ||8 or made of non-conducting material.

It is deemed preferable to provide a speed control on the energization of the electromagnetic coil 19 so as to insure automatic release of sleeve F below a predetermined car speed and to accommodate automatic engagement of sleeve F above a predetermined car speed. Whenever the car is in forward driving condition the manual sleeve 42 is either shifted rearwardly to the low range or forwardly to the high range so that by driving a governor from the countershaft 35 it is possible to provide a speed control operated proportionate to the speed of travel of the car. Driven from countershaft gear |30 is a governor M of any suitable type, this governor operating a sleeve |3| outwardly along its drive shaft |32 as the car speed reaches a predetermined point, the break-away being under control of a detent |33 if desired.

The sleeve |3| has a shoulder |34 engaged by the swinging switch piece |35 of the governorj switch N. When the car is stationary the detent |33 is engaged and switch N is open. As the car accelerates the governor eventually. reaches its critical speed and detent |33 releases thereby causing switch N to close. As the car slows down, the governor spring |36 restores the parts to the Fig. 11 position and by proportioning the various parts it is obvious that switch N may be made to function at desired speeds proportionate to car travel. As an example of one arrangement of governor operation and gearing arrangement, the governor may be made to close switch N during car acceleration in iirst and third respectively at approximately '1 and 15 M. P. H. (miles per hour), the switch N opening on stopping the car in direct and second at approximately 7 and 3 M. P.H. respectively.

The driver operated ignition switch is designated at O and comprises a conductor |31 which, in the Fig. l1 position showing the switch on or closed, electrically connects contacts |38 and |39. Contact |38 extends by conductor |40 to ammeter |4| and thence by conductor |42 to the usual storage battery |43 and thence to ground |44. Contact |39 has a conductor |45 extending by conductor |46 branching therefrom to the engine ignition system herein shown in part as comprising coil |41 and distributer |29 having the aforesaid primary terminal |28.

A second conductor |48 branches from conductor |45 to one of the terminals |08 of coil 19 and thence by the other terminal to conductor.

|49 to the kick-down switch P and then by conductor |50 through switch N and ground |5i. The switch P is normally closed and is opened preferably by a full depression of accelerator pedal 50' acting through link |52 and a bellcrank lever |53 pivotally mounted at |54. Lever |53 actuates a link |55 which extends forwardly to adjust the engine throttle valve lever |56. When pedal 50 is thus depressed, the lever |56 is positioned to fully open the throttle valve |51 and as the throttle valve is adjusted in its wideopen range the lever |53 opens switch P to effect a step-down inthe transmission from fourth to third gr from second to first by ie-energizing the coil 1 Switches P and N are in series so as to form a governor kick-down circuit as follows: ground |44 to battery |43 thence by conductor |42 to ammeter |4| and by conductor |40 to ignition switch O. From switch O this .circuit extends through conductors |45 and |48 to coil I9 and thence by conductor |49, switch P, conductor |50 and switch N to ground |5|.

In the operation ,of the mechanism, the car at standstill and with ignition switch O closed and the engine idling will cause governor switch N to remain open as in Fig. 11 thereby breaking the governor kick-down circuit and de-energizing coil 19 even though the kick-down switch P is closed at this time. The parts are then in their Fig. 11 positions with valve 95 seated at 98 so that vacuum at pipe 99 is shut off from passage |00 and chamber |02 while this passage and chamber are open through seat |03 to chamber |04 and vent |05 thereby allowing spring S0 to hold piston 16 and rod 16' forwardly projected and sleeve F disengaged. Armature 9| is thus positioned forwardly away from coil 19 and armature 92 is positioned rearwardly from the coil but not so far but that it will respond to energization of the coil. Spring 8l acting through plunger 86, armature 92 and sleeve Bl is now acting to hold valve 95 against seat 98 as well to position armature 92 as in Fig. 11. With the armature moved rearwardly switch K is thereby closed and with piston 16 moved forwardly switch L is thereby open so that the ignition system may operate normally without being grounded.

The driver now shifts sleeve 42 to either the high or low range and accelerates the car, ordinarily above the critical speed of governor M thereby causing switch N to close and establish the governor kick-down circuit. When this occurs the coil 'I9 is energized and armature 92 moves electromagnetically to its Fig. l2 position of magnetic attraction to the electromagnet means 19, 80, 82, the annulus 88 constituting a gap shunt for the electromagnetic circuit at this time.

When armature 92 moves forwardly, valve 95 is caused to seat at |03 by spring 96, this spring insuring proper seating of the valve and compensating for an otherwise diilicult problem of seating armature 92 at the cylinders 80, 82 of the electromagnetic circuit at the same time of seating the valve 95. Spring 96 thus provides seating for the Valve independently of seating the armature. The vent chamber |04 is now shut off from passage |00, the latter being open to the vacuum in manifold J through pipes 99, 90. At the same time, forward movement of armature 92 unloads spring |22 and spring H6 then acts to open switch K.

As the vacuum in manifold J is now open to chamber |02, piston 16 moves rearwardly to its Fig. l2 position bringing armature 9| in a position of electromagnetic attraction with respect to cylinders 80, 82 where it is electromagnetically held independently of the presence of vacuum in chamber |02. Rearward movement of piston 'l5 acts through pins |25, |23 and spring |24 to close switch L, switch K being open. Rod 1S moves rearwardly, leaving lever 6l because the blocker 52 prevents engagement of sleeve F. As soon as the driver allows the engine to coast, sleeve F will engage teeth 49 synchronously under action of spring 58, to step-up the drive to either second or fourth although the step-up will be delayed by the blocker 52 until engine coast thereby 75 enabling drive in the slower driving ratio of rst or third as long as desired.

If the car is initially accelerated in rst above the governor critical speed and the engine allowed to coast, then second will automatically become operative. Then if the driver shifts sleeve 42 forwardly to the high range, third will of course be skipped and fourth will be obtained because sleeve F will remain engaged. Ordinarily, especially where the car is equipped with a liuid coupling B, the sleeve 42 may be left in its high range and all starts and stops made without iurther shifting. This is possible owing to slippage in the fluid coupling when stopping the car for a traic light and is practicable because the fluid coupling allows high engine torque for favorable car acceleration and because governor M directs a downshift on bringing the car to rest. Thus there is automatically provided a favorable torque-multiplying gear for starting, as in third.

On bringing tne car to a stop when sleeve F is clutched as in fourth, for example, the governor M opens the switch N to allow spring to release sleeve F which it can do as the car is brought to a stop because of the low coasting torque at the teetn of sleeve F. 'lhe interruption of the ignition system at this time does not relieve or reverse the torque at the teeth of tne sleeve unless the governor is arranged to open on coast down at a car speed below engine idle and such may be readily provided although by providing a spring 90 of proper strength the sleeve F will, in any event, release'on car coast to a stop.

Whenever the car is driving in lourth or second above the governor critical speed, a full depression of the accelerator pedal will cause the transmission to step-down to third or first, the transmission step-up back to fourth or second taking place on release of the accelerator pedal with attendant synchronization of sleeve F with teeth 49.

When the accelerator pedal is thus fully depressed for the kickdown, switch P opens thereby de-energizing coil 19. Armature 9| and piston 16 cannot move forwardly to release sleeve F because the latter is under torque load by reason of the engine driving under open throttle. However, armature 92 immediately moves to its Fig. position by spring 8l thereby causing valve 95 to shut off the vacuum supply to chamber |02 and to vent this chamber as aforesaid. Also. at this time the rearward armature movement -acts through spring |22 and pin |20 to close switch K. Switch L being closed at this time, the ignition interrupting circuit is established to ground the ignition system at l|3 and this causes the engine to unload the torque at sleeve F whereupon spring 90 acts through rod 76' and the sleeve linkage to disengage sleeve F. As the piston com pletes its forward stroke spring |24 unloads allowing switch L to open thereby restoring the engine ignition and allowing the engine to rapidly speed up to pick up the drive in third or rst at the overrunning clutch E. Springs ||9 and |24 may be arranged to open switch L and restore the ignition appreciably prior to disengagement of sleeve F in which case when switch L closes as aforesaid a torque reversal occurs at the teeth of sleeve F facilitating its full disengagement by change from coast load imposed by closing of switch K so that if sleeve F does not fully release when switch K closes, a second reversal of torque will facilitate the sleeve release when switch L opens. Ordinarily sleeve F will always 11 dsengage in response to closing of switch K so that switch L may be arranged to open during the last travel of sleeve F rearwardly but either relationship of springs |24 and ||9 may be employed.

When the driver releases the accelerator pedal, assuming governor switch N to be closed, coil 'I9 is energized to cause armature 92 to move to its Fig. 12 position opening switch K and moving valve 95 to supply vacuum to chamber |02. This causes piston 1B to move rearwardly and thereby close switch L but as switch K was previously closed the ignition is not interrupted during this stroke of the piston. As soon as the engine slows down to synchronize the teeth 49 with sleeve F, the latter will then shift forwardly by spring 58 to restore direct drive from pinion 28 to gear 4U.

By slidably guiding rod 16 telescopically on the stationary guide rod 'i8 of unit H we have greatly shortened the necessary length of the motor as a whole. The unit H lends itself to economical quantity production and provides a sub-assembly which is easily handled and installed during assembly of the motor. The unit H is firmly mounted in the bracket 89 so as to support the cantilever guide rod 18.

The unit H functions as an electromagnetic holding device as it serves, when the vacuum retracts piston 16 from the Fig. l1 position to the Fig. 12 position, to releasably hold the piston independently of the continuance of vacuum in chamber |02 so that the kickdown or releasing spring 9|) cannot project the piston back to its Fig. 11 position until coil 19 is de-energized.

Our arrangement of eld coil 19 and flux-directing or flux-carrying eld core portions 8U, 82 is such that the magnetic loading or tension at the gaps closed by the armature 9| is in the general direction of movement of the armature and piston 16. Such arrangement is greatly more ecient as a holding device than solenoid devices wherein eld core portions magnetically load the gap or gaps which are closed by a plunger-type of armature in a. direction normal to the direction of armature movement, such solenoid devices being ordinarily employed where pulling or pushing of the armature is the prime consideration.

In our device we provide non-magnetic means such as differential pressure fluid to retract the piston 16 against the force of spring 90 and a coil 19 arranged to provide magnetic holding flux to hold the piston retracted independently of the continuance of differential pressure fluid such as vacuum.

Electromagnets in general embody at least two gaps in forming a magnetic circuit between the field core and armature, our arrangement being such as to utilize both of these gaps for magnetically loading or tensioning the armature in the general direction of its movement. At the time that the piston 'I6 is retracted by vacuum, the eld core portions 80, 82 are magnetically connected or bridged by armature 92 which at such time functions as part of the core means so that, in effect, there are at this time two gaps in the magnetic circuit at the forward ends of field portions 80 and 82 respectively. These gaps are closed by armature 9| such that the magnetic loading is in the direction of movement of the armature or axially of the travel of piston 16.

We claim:

l. In a motor for controlling a Vehicle power transmission; a casing structure; an electromagnet assembly fixed within said casing and having a rod-supporting portion; a rod xed at one end thereof to said rod-supporting portion of said assembly and having a guide portion projecting as a cantilever therefrom; a tubular rod slidably mounted on said cantilever guide portion and adapted for reciprocation relative to said guide portion for controlling operation of said transmission; a pressure fluid operated member operably connected to said tubular rod; and means controlled in part by said electromagnet assembly for effecting operation of said piston.

2. In a motor for controlling a vehicle power transmission; a casing structure; electromagnet means supported within said casing structure; a rod xed with respect to said electromagnet means and having a cantilever guide portion projecting therefrom; a tubular rod slidably mounted on said cantilever guideportion and adapted for reciprocation relative to said guide portion between two positions thereof for controlling operation of said transmission; a pressure fluid operated member operably connected to said tubular rod; and an armature operably connected to said member and tubular rod and adapted for magnetic association with respect to said electromagnet means for holding said tubular rod in one of its said positions.

3. In a motor for controlling a vehicle power transmission; a casing structure; electromagnet means supported within said casing structure; an annular support member carried by said electromagnet means; a rod having a hollow end portion xed within said annular support member and having a cantilever guide portion projecting therefrom; a tubular rod slidably mounted on said cantilever guide portion and adapted for reciprocation relative to said guide portion for controlling operation of said transmission; a pressure fluid operated member operably connected to said tubular rod; valving means slidably supported in the aforesaid hollow end portion of said rod for movement to control pressure fluid application to said member; and an armature movable relative to said member and magnetically associated with said electromagnet means for controlling movement of said valving means.

4. In a motor for controlling a vehicle power transmission; a casing structure; electromagnet means supported within said casing structure; a rod xed with respect to said electromagnet means and having a cantilever guide portion projecting therefrom; a tubular rod slidably mounted on said cantilever guide portion and adapted for reciprocation relative to said guide portion between two positions thereof for controlling operation of said transmission; a pressure fluid operated member operably connected to said tubular rod; valving means for controlling pressure fluid application to said member; an armature operably connected to said member and tubular rod and adapted for magnetic association with respect to said electromagnet means for holding said tubular rod in one of its said positions; and a second armature movable relative to said piston and magnetically associated with said electromagnet means for controlling said valving means.

5. In a motor for controlling a vehicle power transmission; a casing structure; an electromagnet stationarily mounted in said casing structure; a reciprocatory pressure fluid operated member disposed in said casing structure adjacent one end of said electromagnet, said member being adapted for movement from a first position to a second position thereof for controlling operation of said transmission; an armature operably connected to said vmember and adapted for magnetic attraction relationship with one end of said electromagnet for holding said member in its said first position; a spring yieldingly urging movement of said member to its said second position; a stationarily mounted rod disposed within said casing structure and having a cantilever guide portion; and a hollow rod slidable on said cantilever portion for guiding reciprocation of said member.

6. In a motor for controlling a vehicle power transmission; a casing structure; an electromagnet stationarily mounted in said casing structure; a reciprocatory pressure fluid operated member disposed in said casing structure adjacent one end of said electromagnet, said member being adapted for movement from a first position to a4 second position thereof for controlling operation of said transmission; an armature operably connected to said member and adapted for magnetic attraction relationship with one end of said electromagnet for holding said member in its said` first position; said casing structure having an annular support bracket disposed therewithin, said electromagnet having an annular bounding member fitting within said annular bracket for supporting said electromagnet; a spring surrounding said annular support bracket and yieldingly urging said member to its said second position; a stationan'ly mounted rod disposed Within said casing structure and having a cantilever guide portion; and a hollow rod slidable on said cantilever portion for guiding reciprocation of said member.

7. In a motor for controlling a vehicle power transmission; a casing structure; magnet stationarily mounted in said casing structure; a reciprocatory pressure fluid operated member disposed in said casing structure adjacent one end of said electromagnet, said member being adapted for movement from a rst position to a second position thereof for controlling operation of said transmission; an armature operably connected to said member and adapted for magnetic attraction relationship with one end of said electromagnet for holding said member in its said rst position; a spring yieldingly urging movement of said member to its said second position; a stationarily mounted rod disposed within said casing structure and having a cantilever guide portion; a hollow rod slidable on said cantilever portion for guiding reciprocation of said member; valving means for controlling pressure fluid application to said member; and a second armature adapted for magnetic attraction relationship with the other end of said electromagnet for controlling said valving means.

8. In a motor for controlling a vehicle power transmission; a casing structure; an electromagnet stationarily mounted in said casing structure; a reciprocatory pressure uid operated member disposed in said casing structure adjacent one end of said electromagnet, said member being adapted for movement from a iirst position to a second position thereof for controlling operation of said transmission; an armature operably connected to said member and adapted for magnetic attraction relationship with one end of said electromagnet for holding said member in its said rst position;

,said casing structure having an annular support bracket disposed therewithin; said electromagnet having an annular bounding member fitting within said annular bracket for supporting said electromagnet; a spring surrounding `said annular an electrosupport bracket and yieldingly urging said member to its said second position; a stationarily mounted rod disposed within said casing structure and having a cantilever guide portion; a hollow rod slidable on said cantilever portion for guiding reciprocation of said member; valving means for controlling pressure fluid application to said member; and a second armature adapted for magnetic attraction relationship with the other end of said electromagnet for controlling said valving means.

9. In a motor for controlling a vehicle power transmission; a casing structure; an electromagnet stationarily mounted in said casing structure; a reciprocatory pressure fluid operated member disposed in said casing structure adjacent one end of said electromagnet, said member being adapted for movement from a iirst position to a second position thereof for controlling operation of said transmission; an armature operably connected to said member and adapted for magnetic attraction relationship with one end of said electromagnet for holding said member in its said rst position;

a spring yieldingly urging movement of said mem- I ber to its said second position; a stationarily mounted rod disposed within said casing structure and having a cantilever guide portion; a hollow rod slidable on said cantilever portion for guiding reciprocation of said member; valving means for controlling pressure iluid application to said member; a second armature adapted for magnetic attraction relationship with the other end of said electromagnet; a reciprocatory plunger slidably supported by said stationarily mounted rod and operably connected with said second armature and with said valving means; and a second spring acting on said plunger to yieldingly urge said second armature away from said electromagnet.

10. In a motor for controlling a vehicle power transmission; a casing structure; an electromagnet stationarily mounted in said casing structure; a reciprocatory pressure fluid operated member disposed in said casing structure adjacent one lend of said electromagnet, said member being adapted for movement from a first position to a'second position thereof for controlling operation of said transmission; an armature operably connected to said member and adapted for magnetic attraction relationship with one end of said electromagnet for holding said member in its said ilrst position;

said casing structure having an annular support bracket disposed therewithin; said electromagnet having an annular 'bounding member fitting within said annular bracket for supporting said electromagnet; a spring surrounding said annular support bracket and yieldingly urging said member to its said second position; a stationarily mounted rod disposed within said casing structure and having a. cantilever guide portion; a hollow rod slidable on said cantilever portion for guiding reciprocation of said member; valving means for controlling pressure fluid application to said member; a second armature adapted :for magnetic attraction relationship with the other end of said electromagnet; said stationarily mounted rod having a bore in one end thereof; a reciprocatory plunger slidably disposed in said bore; means operably connecting said second armature and said valving means with said plunger; and a second spring disposed in said -bore and acting on said plunger to yieldingly urge said second armature away from said electromagnet.

1l. In a. motor for controlling a vehicle power transmission; a casing structure; a reciprocatory pressure fluid operated member disposed in said au casing structure for controlling operation of said transmissiom an electromagnet stationarily valving means for controlling pressure iluid application to said-memben a second armature mounted in said casing; said casing structure providing a chamber for saidimembere'adapted for selective communication with'a source -of vac? lnum and with the atmosphere-for controlling. operation of said member; said casing structure :having a rst passageway leading from said yacnum 'source to said chamber and aseco'nd passageway communicating with saidiirst passage- -,way and opening to the atmosphere-:La valve adapted for magnetic attraction relationship with the other end of said electromagnet; a'nd means operably connecting said second amature and saidv'alving means. i

14.- In a motor for controlling a vehicle power transmission; a casing structure having a supmember movable from a first position wherein it closes the iirst passageway to a secondfiposition opening the first passageway to said .chamber andblocking communication of the first passagewaylwith the second passageway by `"seating on saidfsecond passageway; a platearmature adapted for movement from a iirsteposition to a sec -ond-position in magnetic association withand seating' on said electromagnet; means-for moving said valve member from-its saidsecond position to its said-nrst position; a=pin-carried by said amature and slidably mounting -said valve member; and yielding means acting. between said pin and valve member for moving said valve member from its said rst position to its'sai'd second position in response to movement of said armature from its-said rst position to its said second psition, said yieldingvmeans allowing -said valve member to seat as aforesaid. independently of said seating of saidarmature.`

12. In a motor for controlling a vehicle power transmission; a casing structure;a reciprocatory piston structure disposed in said casing :structure for controlling operation of Saidtransmission; an

electromagnet stationarily `mounted insaidcasc ing; said casing structure providing-a chamber for said piston adapted for selective communication with a source of vacuum and. with the atmosphere for controlling operation 'of said piston; .said casing structure having-a first passageway leading from saidivacuum source to said chamber and a second passageway communicating with said first passageway and openingto the atmosphere; a valve member movable from a iirst position to a second position of blocking communication between the rst and second passageways by seating' on said second passageway; a plate armature movable from a iii-st..- position to a second position' in magnetic association with and seating on said electromagnet; a pin carried-by said armature and slidably-monnting said valve member; and ayielding thrust-transmitting connection between said pin and valvernember for moving said valve member from its said rst position to its said second posltionfin response to movement of said armature from its said first position to its .said second'position. thereby to allow said valve member jto seat as aforesaid independently of said seating of Asaid armature.

13. In a motor for controlling a vehicle power transmission; a casing structure; an electromagnet stationarily mounted in said casingstructure; a reciprocatory pressure uid operated member disposed in said casing-structure adjacent one end of said electromagnet, said member-being adapted for movement from a rst position to a second position thereof for controlling operation of said transmission; an armature operably connected to said member and adapted for magnetic attraction relationship with-'one end of said electromagnet for holding saidmemberin its, said rst position; a spring yieldingly urging movement of said member to itssaidsecond position;

port; a pressure fluid operated member reciprocable in said casing structure and having a rod operable to control operation of said transmission; and means for controlling operation of said member comprising an electromagnet, said electromagnet having va pair of concentrically arranged inner and outer linx-directing ferrous annulif and a'n electrical current-conducting coil interposed between said annuli, a non-ferrous ring'disposed between said annuli adjacent one endA thereof and being'permanently bonded to said annuli, a guide-support having a cantilever portion slidably supporting said rod, a second non-'ferrous ring disposed between and permanently bonded to the inner ferrous annulus and said guide support, said annuli, rings and guidesupport forming a. unitary assembly fixed to the aforesaid support of said casing structure.

15. In a motor for controlling a vehicle power transmission; a casing structure having a support; a pressure iluid operated member reciprocable in said casing structure and having a rod operable to control operation of said transmission;-and means foi controlling operation of said member comprising an electromagnet, said electromagnet having a pair of concentrically ar'- ranged inner and outer linx-directing ferrous annulll and an electrical current-conducting coil interposed between said annuli, a non-ferrous ring disposed between said annuli adjacent one end' thereof, a guide-support having a portion thereof slidably supporting said rod, said annuli. ring and guide-support forming a unitary assembly 'iixed to the aforesaid support of said casing structure.

16. -In a-motor for controlling a vehicle power transmission; a reciprocatory element adapted for movement from a iirst position to a second position thereof for controlling said transmission-:servo-motor means operable to move said element as aforesaid; electromagnetic holding means comprising, a field core having core portions arranged one within the other, and a field coil disposed between said core portions; a platelike armature operably connected to said element so as to move therewith and adapted for magnetic holding relationship with end portions of said core portions for holding said element in its said iirst position; and means forA coincidentally controlling said operation of said servo-motor means as aforesaid and energization of said eld coil.

17. In a motor for controlling a vehicle power transmission; a reciprocatory pressure iiuid operated member adapted for movement from a first position to a second position thereof for controlling said transmission; electromagnetic. holding means comprising, a eld core having core portions arranged one within the other and eachpresenting an armature-engaging end surface,land a field coil disposed between said core portions; chamber-forming means for subjecting said member to differential pressure fluid for effecting operation thereof to its said first position; a plate-like armature carried with said member and having a face portion thereof engageable in magnetic holding relationship with the armature-engaging surfaces of said core portions for holding said member in its said first position; and means operable to bias said member to its said second position.

18. In a servo-motor having a chamber; a pressure diierential operated member within said chamber and adapted to be moved in one direction by vacuum and in the opposite direction by spring pressure; an operating element connected with said member for movement thereby; and electromagnetic means operable to hold said operating element in the position to which it is adapted to be moved by vacuum movement of said member whereby said operating element is retained in its aforesaid position independently of said vacuum; said electromagnetic means comprising, a field core having core portions arranged one within the other and each presenting an armature-engaging end surface, a field coil disposed between said core portions, and a plate-like armature connected with said operating element and adapted for magnetic holding relationship with the armature-engaging surfaces of said core portions.

19. In a motor for controlling a vehicle power transmission; a reciprocatory pressure fluid operated member adapted for movement from a rst position to a second position thereof for controlling said transmission; electromagnetic means operable to hold said member in its said first position, comprising, a flux-generating eld coil, iield core means disposed in flux-directing relationship with respect to said coil, and an armature operably connected to said member so as to move therewith and adapted for magnetic holding relationship with said core means, said core means having relatively spaced portions thereof presenting a pair of magnetic circuit gaps adapted to be magnetically closed by said armature when said member is in its said rst position thereby to provide a magnetic circuit through said core means and armature, the relatively spaced portions of said core means being so constructed and arranged in relation to said armature that magnetic force at each of said gaps operates in the general direction of movement of said member when the latter moves from its said second position to its said first position; chamber-forming means for subjecting said member to differential pressure uid for effecting operation thereof to its said first position; and means operable to bias said member to its said second position.

20. In a servo-motor having a chamber-forming means; a pressure uid operated member operably associated with said chamber for movement in one direction by vacuum and in the opposite direction by spring pressure; an operating element connected with said member for movement thereby; and electromagnetic means operable to hold said operating element in the position to which it is adapted to be moved by vacuum movement of said member whereby said operating element is retained in its aforesaid position independently of said vacuum; said electromagnetic means comprising, a flux-generating field coil, field core means disposed in flux-directing relationship with respect to said coil, and an armature operably connected to said operating element so as to move therewith and adapted for magnetic holding relationship with said core means, 'said core means having relatively spaced portions thereof presenting a pair of magnetic circuit gaps adapted to be magnetically closed ,by said armature when said operating element is in its aforesaid position thereby to provide a magnetic circuit through said core means and armature, the relatively spaced portions of said core means being so constructed and arranged in relation tosaid armature that magnetic force at each of said gaps operates in the general direction of movement of said operating element.

21. In an electromagnet, a, pair of concentrically arranged inner and outer flux-directing ferrous annuli, an electrical current-conducting coil interposed between said annuli, a non-ferrous ring disposed adjacent one end of said coil and between said annuli in permanently bonded relationship therewith, a ferrous ring disposed adjacent the other end of said coil and between said annuli in permanently bonded relationship with only one of said annuli such that said ferrous ring is spaced from the other of said annuli, a rod-supporting ring disposed within said inner annulus and permanently bonded thereto, and a rod co-axlal with said annuli and having an end portion permanently bonded to said rod-supporting ring, said rod having an armature-guide portion at its opposite end projecting cantilever-like from said rod-supporting ring so as to lie axially beyond said annuli.

22. In a uid servo-motor device, a casing structure providing a working chamber, a. pressure fluid operated member operably disposed in said chamber for movement in a predetermined path, a plate-like armature attached to said member, an electromagnet disposed within said casing structure and comprising inner and outer flux-directors and an electrical current-conducting coil interposed between said directors, said armature being engageable in one position of said member with said directors in magnetic holding relationship therewith, a spring biasing said member in opposition to said holding relationship, and connecting means between said member and said inner director adapted to constrain said member for eifecting its said movement along said ath. p TENO IAVELLI.

VICTOR E. MATULAITIS.

REFERENCES CITED The following references are of Yrecord in the file of this patent:

UNITED STATES PATENTS Number Name Date 293,116 'Iimmis Feb. 5, 1884 1,227,341 Stratton May 22, 1917 1,414,835 Spohrer May 2, 1922 1,497,469 Ames June 10, 1924 1,871,110 Campbell Aug. 9,V 1932 2,078,174 Brewer Apr. 20, 1937 2,102,761 Strobel Dec. 21, 1937 2,164,694 Betz July 4, 1939 2,209,844 Otto July 30, 1940 2,218,797 Linde Oct. 22, 1940 2,225,493 Barnes Dec. 17, 1940 2,231,876 Beltz Feb. 1'8, 1941 2,269,345 Nickle Jan. 6, 1942 2,275,839 Boehne Mar. 10, 1942 2.300.263 McLeod Oct. 27, 1942

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