FR2478760A2 - Hydraulic torque converter bridging control device - automatically suppresses bridging prior to transmission ratio change by controlling piston being moved out of its seating (PT 12.12.80) - Google Patents

Abstract

Bridging is accomplished by a moving valve with a return spring operating to uncover an opening whereby hydraulic fluid is admitted to a release chamber. A controlling piston is thus moved out of contact with its seating to suppress the bridging between the input impeller and output turbine. The bridging control is performed by an electrohydraulic transducer acted upon by an electronic device (as in EP--21258) as a function of the input and output shaft speeds which are measured by independent sensors. Bridging is obtainable for all values of transmission ratio with transitory suppression at the moment of changeover.

Description

Bridging control device for a hydrodynamic torque converter.

 The present invention relates to a bridging control device allowing the slip-free coupling between the input shaft and the output shaft of a hydrodynamic torque converter and in particular of a converter used in an automatic transmission with several transmission reports with torque shift for a motor vehicle.

 The invention complements the invention already described in the main patent application. The main patent application has described a bridging control device for a hydrodynamic torque converter comprising a clutch provided with a control piston and which comprises a hydraulic valve disposed in the hydraulic fluid supply circuit of the 'enclosure of the converter and controlled by the pressure prevailing in said enclosure so as to selectively supply either the enclosure of the converter, or a chamber for loosening the control piston.

 According to the present invention, the hydraulic valve comprises a movable element subjected to a return spring and to the differential pressure between the supply of hydraulic fluid which takes place at constant pressure and the release chamber. The movement of the movable element allows the hydraulic supply fluid to pass to the converter enclosure through a passage duct. The hydraulic valve further comprises a restriction allowing the passage of the hydraulic supply fluid to the release chamber regardless of the position of the movable element.

The movable element is preferably constituted by a drawer moving in a housing and capable of masking or clearing the passage duct towards the enclosure of the converter. The upstream face of the slide valve is subjected to the constant pressure of the hydraulic supply fluid while the downstream face is subjected on the one hand to the pressure prevailing in the release chamber and on the other hand to the action of the return spring compression.

As in the embodiments described in the main patent application, the hydraulic valve is preferably housed at the end of the hub of the converter, the supply of hydraulic fluid at constant pressure being by a central hollow drive shaft.

 The control device of the invention further comprises an electrohydraulic translator which can be, for example, in the form of a solenoid valve placed in the hydraulic circuit downstream of the converter.

 In a first embodiment, the electrohydraulic translator is constituted by a three-way and two-position solenoid valve mounted so as to close in a first position the circuit of the enclosure of the converter and to close in a second position the circuit of the loosening chamber. A restriction is advantageously mounted in the circuit between the converter enclosure and the solenoid valve. In this way, when the solenoid valve occupies the second position in which the loosening chamber circuit is closed, the pressure which builds up in the enclosure of the converter between the first restriction of the hydraulic control valve and this second restriction is an intermediate pressure lower than the supply pressure of the hydraulic fluid and which also prevails in the loosening chamber.

 In an alternative embodiment, the electrohydraulic translator consists of a simple shutter valve, a second restriction being arranged in a secondary conduit returning to the fluid reservoir. In this variant, the converter enclosure does not have an outlet orifice and it is the loosening chamber which is connected to the hydraulic fluid reservoir via the shutter valve of the solenoid valve and of the second restriction.

 As in the embodiments of the main patent application, the control device of the present invention preferably comprises an electronic control device receiving signals corresponding respectively to the speed of rotation of the input shaft and of the converter output shaft so as to control the electrohydraulic translator as soon as the ratio of these speeds reaches a predetermined value corresponding to the theoretical coupling point of the converter.

 The electronic device preferably comprises a timing circuit receiving signals for shifting the gear ratios of the transmission making it possible to interrupt the bridging each gear shift by corresponding action on the electrohydraulic translator.

The invention will be better understood on studying the detailed description of two embodiments taken. The title of examples in no way limiting and illustrated by the appended drawings, in which
fig. 1 is a schematic longitudinal section view of a hydrodynamic torque converter, and
fig. 2 is a schematic longitudinal section view of a variant of the converter of FIG. 1.

 As shown in fig. 1, the converter 1 comprises an input element 2 also called a pump or impeller, mechanically connected the input shaft or motor shaft 3 secured to the drive motor not shown in the figure by means of a cylindrical bell 5 having a substantially frontal wall 6 provided with a conical recess 6a. The impeller 2 rotates relative to the frame 7 of the converter 1 with the interposition of a seal 8 and a ring 9.

 The output element 10 of the converter 1 also called turbine is connected to an output shaft 11 by means of the turbine hub 11a. The output shaft 11 can rotate relative to a central transmission shaft 12. The converter 1 is completed by the reactor or stator 14 interposed between the impeller 2 and the turbine 10 and which is mounted on a shaft 15 via of the freewheel device 16 which therefore makes it possible in a direction of rotation to make the reactor 14 integral with the shaft 15 fixed to the casing 7.

A control piston 17 in the form of a substantially radial flange provided with a conical portion 17a, has on its peripheral portion 18 a friction lining 19 which is capable of coming into contact with the corresponding internal front face 6 of the bell 5 so as to make integral in rotation said bell 5 and the control piston 17. The latter is also integral with the turbine 10 by means of a damping system 20 comprising a plurality of helical springs 21 and friction washers 21a so as to dampen torsional vibrations. The damping system 20 is fixed directly to the periphery of the control piston 17 and is made integral with the hub 11a of the turbine 10. The control piston 17 is capable of moving in axial translation inside the bell 5 of the converter , the seal being ensured by contact between its bore and a seal IIb mounted in an annular groove of the hub IIa of the turbine.

A loosening chamber 56 is defined between the front wall 6 and the opposite face of the control piston 17 which constitutes a movable wall of the loosening chamber 56.

 Inside the hub 57 of the converter secured to the end of the central transmission shaft 12 is disposed a hydraulic valve comprising a cylindrical slide 58 movable inside a housing 59 opening into a distribution chamber 60 which communicates with the end of the hollow shaft 12. The drawer 58 is subjected to the action of a compression return spring 61, the axial movement of the drawer 58 under the action of the spring 61 being limited by a ring stop 62.

The hydraulic valve of the hub 57 further comprises a substantially axial passage 63 provided with a restriction 64 making the distribution chamber 60 communicate with the loosening chamber 56 via a substantially radial passage 65. The passage 65 passes through the housing 59 of drawer 58 and also communicates with a substantially axial passage 66 connected to the annular space 67 remaining between the transmission shaft 12 and the output shaft 11, the sealing of the annular space 67 being ensured by the sealing ring 68.

Furthermore, the hydraulic valve of the hub 57 also comprises substantially radial passages 69 which can make the enclosure 70 of the converter communicate via a passage 71 formed in the hub 11a of the turbine with the housing 59 and the chamber distribution 60 when the movable drawer 58 is moved against the compression force of the spring 61.

 The outlet of the hydraulic fluid from the enclosure 70 of the converter takes place via the outlet orifices 72 communicating with the annular space 73 remaining between the fixed shaft 15 and the outlet shaft 11 and the sealing of which is ensured by the rings 73a and 73b.

 The annular space 73 is connected to a pipe 74 comprising a restriction 75 and leading to one of the orifices 80 of a three-way and two-position control solenoid valve 76 which in the example illustrated comprises two electromagnets 77a, 77b and a shutter ball 78.

The annular space 67 connected to the loosening chamber 56 also communicates with a pipe 79 leading to the second orifice 80a of the solenoid valve 76 which is also connected by an outlet pipe 81 to the hydraulic fluid tank at zero pressure.

 It will of course be understood that the solenoid valve 76 could be replaced by an equivalent bridging control device comprising for example a distribution slide controlled by an electromagnet.

In the illustrated embodiment, the solenoid valve 76 is mounted so as to open the outlet port 80 of the pipe 74 when it receives an electrical signal while closing the port 80a of the pipe 79.

 The operation of the converter and its bridging control device is as follows. The hydraulic fluid is supplied to the converter at constant pressure and unidirectional flow through the hollow drive shaft 12 and the distribution chamber 60. When the solenoid valve 76 for bridging control is in the state shown in in the figure, the sealing ball 78 closing the orifice 80a of the pipe 79, no flow is established in the annular space 67. The hydraulic fluid coming from the distribution chamber 60 passes through the conduit 63, the restriction 64 and the passage 65, thus supplying the loosening chamber 56. The fluid then passes into the enclosure 70 of the converter which communicates with the loosening chamber 56 by the interval existing between the front face 6 of the bell 5 and the lining 19 of the peripheral end 18 of the control piston 17. It will be noted that the hydraulic fluid also passes between the periphery of the control piston 17 and the internal cylindrical surface of the bell 5 or an appropriate interval remains housework. The hydraulic fluid returns to the reservoir which is at zero pressure through the outlet orifices 72, the annular space 73, the pipe 74 and the restriction 75 by passing through the orifice 80 of the solenoid valve 76 which is then opened by the ball. 78. It is established in the enclosure 70 of the converter, between the calibrated orifices playing the role of restrictions 64 and 75 of the hydraulic circuit, a pressure P1 determined by the passage sections of these calibrated and lower orifices. at the supply pressure P. This intermediate pressure P1 also prevails in the loosening chamber 56 and in the housing 59. It therefore acts on the downstream face 58a of the movable slide 58 and adds the action of the spring of compression 61. The action of the pressure P1 and of the spring 61 is such that the drawer 58 is held in abutment on the stop ring 62 despite the action of the supply pressure P on the upstream face 58b of the drawer 58 on the side of the distribution chamber 60. In this position, the drawer 58 closes the passages 69 preventing any supply of the enclosure 70 of the converter by these passages. The enclosure 70 of the converter is therefore only supplied by the loosening chamber 56. The control piston 17 is therefore kept away from the front face 6 of the shell 5. The assembly operates as a torque converter.

 When the solenoid valve 76 is controlled so that the shutter ball 78 is placed in the reverse position, closing the orifice 80 and releasing the orifice 8Oa, the hydraulic fluid coming from the loosening chamber 56 can return to the reserve hydraulic fluid through the passages 65 and 66 of the hub 57, the annular space 67 and the pipe 79 connected to the solenoid valve 76 and released by the ball 78. The pressure in the release chamber 56 therefore drops. The movable slide 58 is no longer subjected on its downstream face to the action of the compression spring 61. The supply pressure always equal to the pressure P thanks to the existence of the calibrated orifice 64 which limits the leakage flow therefore has a predominant action on the upstream face 58b of the movable drawer 58 on the side of the distribution chamber 60. The movable drawer 58 is therefore pushed into abutment on the side of the front face 6 of the shell 5 by compressing the spring 61 and by clearing the orifices of the passages 69. The enclosure 70 of the converter is then supplied by the passages 69 and 71. The release chamber 56 being at zero pressure, the supply pressure P prevailing in the enclosure 70 acts on the control piston 17 which moves up! that the gasket 19 comes into frictional contact with the front face 6 of the shell 5.A clutch effect is achieved thanks to the existence of this gasket 19 which is also preferably produced so as to ensure at the same time contact sealing. The pressure of the hydraulic fluid prevailing in the enclosure 70 of the converter is such that the force transmitted to the control piston 17 is capable of ensuring the transmission of the torque to the output shaft 11 through the piston 17 and the torsional vibration damper system 20. The sliding between the impeller 2 and the turbine 10 is eliminated. The converter is bridged. It will be noted that in this configuration the flow rate of the hydraulic fluid returning to the reservoir is limited by the calibrated orifice 64. This fluid return takes place through the passages 65, the structure of the drawer 58 and of its housing 59 being such that the communication remains established between the passage 63 provided with the restriction 64 and the passage 66 via the passages 65.

 It can be seen that the bridging control can be easily achieved by the combination of the movable drawer 58 and the restriction 64. The drawer 58 opens or closes the supply circuit constituted by the passages 69 communicating with the enclosure 70 of the converter. Furthermore, the restriction 64 allows the bridging phase to establish the pressure of the hydraulic fluid in the enclosure 70 and to obtain in the release chamber 56 a pressure lower than that prevailing in the enclosure 70 of the converter allowing direct transmission of the torque without slipping.

The embodiment illustrated in FIG. 2 where similar parts have the same references only differs from the embodiment of FIG. 1 by the fact that the enclosure 70 of the converter is here closed by construction, the return of the hydraulic fluid to the reservoir taking place through the loosening chamber 56.

Furthermore, in this embodiment, the solenoid valve 82 is constituted by a simple shutter valve comprising a ball 83 and an electromagnet 84. The ball 83 is capable of closing an outlet orifice 85 of a pipe. 86 connected to the annular space 67 communicating through the passages 66 and -65 with the loosening chamber 56 as we have seen previously for the embodiment of FIG. 1. A secondary return duct 87 is also connected to the pipe 86 and has a restriction 88 which is therefore mounted in parallel with respect to the solenoid valve 82. The secondary return duct 87 is connected to the hydraulic fluid reservoir 9 at zero pressure .

The operation of this second embodiment is as follows. The hydraulic fluid is supplied to the converter as before at constant pressure and unidirectional flow rate through the transmission shaft 12 and the distribution chamber 60. When the solenoid valve 82 for bypass control is in the state shown in FIG. . 2, the ball 83 closing the outlet 85 of the pipe 86, the return of the hydraulic fluid to the reservoir takes place only through the secondary return conduit 87 and the restriction 88. The hydraulic fluid coming from the distribution chamber 60 passes through the passage 63 and the restriction 64 before entering the loosening chamber 56 by the passages 65. The return to the hydraulic fluid reservoir is made by the passage 65 passing through the housing 59 then by the passage 66 and the annular space 67 connected as it has just been said to the pipe 86 and to the secondary outlet conduit 87. I1 is established between the calibrated orifices playing the role of restrictions 64 and 88 a pressure P1 determined by the passage sections of these calibrated orifices and less than the supply pressure P. As before, this intermediate pressure P1 prevailing in the housing 59 is added to the action of the compression spring 61 and keeps the drawer 58 in abutment on the stop ring 62. The drawer 58 therefore closes the passages 69 preventing any direct supply of the enclosure 70 of the converter. The enclosure 70 of the converter is therefore only supplied by the passages 65 and the release chamber 56. The control piston 17 is held moves away from the front face 6 of the bell 5 of the converter which therefore operates as a torque converter.

 When the solenoid valve 82 is in the reverse position, the ball 83 opening the orifice 85 of the channel 86, the return of the hydraulic fluid to the reservoir takes place both through the pipe 86 and the secondary return conduit 87 which results in a larger hydraulic fluid passage section.

The pressure drops in the loosening chamber 56 and in the housing 59 which are both connected to the pipeline 86 by the annular space 67 and the passages 66. The drawer 58 which is no longer subjected on its downstream face 58a only at the action of the compression spring 61 moves under the action of the supply pressure P prevailing in the distribution chamber 60 and releases the orifices of the passages 69. The supply pressure always equal to the pressure P thanks to the presence of the calibrated orifice 64 playing the role of restriction which limits the leakage rate therefore has a predominant action on the spool 58. The enclosure 70. of the converter is supplied with the pressure P. Considering the fact that the loosening chamber 56 is at a substantially zero pressure, the control piston 17 is displaced until the lining 19 comes into friction contact with the front face 6 thus playing a clutch role as in the mode from previous realization so as to real to bypass the bypass. It will be noted that in this configuration, the flow rate of the hydraulic fluid returning to the reservoir is limited by the calibrated orifice 64.

 Ultimately, in the embodiment of FIG. 2, the bridging control is therefore obtained by means of the same combination of the movable drawer 58 and the restriction 64. In this embodiment, however, the structure of the converter is simpler and it is possible to remove the outlet pipe 74 of the embodiment of FIG. 1 as well as the sealing ring 73a since the annular spaces 67 and 73 are here both in communication with the single outlet pipe 86.

 The electrical control of the solenoid valves 76 and 82 is preferably done as described in the main patent application by means of an electronic device receiving signals corresponding respectively to the speed of rotation of the input shaft 12 and the shaft output 11 so as to control bridging as soon as the ratio of these speeds reaches a predetermined value corresponding to the theoretical coupling of the converter. As in the main patent application, there is also preferably provided a time delay circuit receiving signals corresponding to the shifting of the gear ratios so as to interrupt the bridging at each gear shift during the duration of the shift.

Claims (9)

 1. Bridging control device according to any one of claims 1 to 3, of main patent application No. 79 15191, characterized in that the hydraulic valve comprises a movable element (58) subjected to a return spring ( 61) and at the differential pressure between the supply of hydraulic fluid and the loosening chamber (56), the displacement of the movable element allowing the passage of the hydraulic supply fluid to the enclosure of the converter through a conduit ( 69).  2. Bridging control device according to claim 1, characterized in that the hydraulic valve further comprises a restriction (64) allowing the passage of the hydraulic supply fluid to the release chamber (56) whatever the position. of the movable element (58). 3. Bridging control device according to claims 1 or 2, characterized in that the movable element comprises a drawer (58) moving in a housing (59) and capable of masking or clearing a passage orifice (69 ) towards the converter enclosure, the upstream face (58b) of the slide (58) being subjected to the constant pressure of the hydraulic supply fluid and the downstream face (58a) being subjected on the one hand to the pressure prevailing in the loosening chamber and on the other hand to the action of the compression return spring (61).  4. Control device according to any one of the preceding claims, characterized in that the hydraulic valve is housed at the end of the hub (57) of the converter, the supply of hydraulic fluid at constant pressure being by a shaft central hollow transmission (12). 5. Bridging control device according to any one of the preceding claims, characterized in that it further comprises an electrohydraulic translator constituted by a three-way solenoid valve (76) and two positions mounted so as to close in a first position the converter enclosure circuit and in a second position to close the loosening chamber circuit.  6. Control device according to claim 5, characterized in that a restriction (75) is mounted in the circuit between the enclosure (70) of the converter and the solenoid valve (76).  7. Bridging control device according to any one of claims 1 to 4, characterized in that it further comprises an electrohydraulic translator constituted by a simple shutter valve (82) electrically controlled, a second restriction (88 ) being disposed in a secondary conduit (87) returning to the fluid reservoir and the enclosure (70) of the converter being closed by construction.  8. Bridging control device according to any one of the preceding claims, characterized in that it comprises an electronic control device receiving signals corresponding respectively to the speed of rotation of the input shaft and the converter output shaft so as to control the electrohydraulic translator as soon as the ratio of these speeds reaches a predetermined value.  9. Bridging control device according to the preceding claim, applied to the bridging control of the converter of an automatic transmission of a motor vehicle with several transmission ratios under torque transmission characterized in that it further comprises an electric circuit timer receiving signals corresponding to the shift of gear ratios and acting on the aforementioned electronic control device to interrupt the bridging at each shift.