DE102008012257B4 - Hydraulic control circuit for a multi-speed transmission - Google Patents

Abstract

A hydraulic control circuit for a transmission, comprising: a first solenoid valve (150) receiving a first pressurized fluid flow; a second solenoid valve (152) receiving a second pressurized fluid flow; a first valve assembly (160) connected to the first solenoid valve (150) in FIG Communicating to selectively receive the first pressurized fluid flow and communicating with the second solenoid valve (152) to selectively receive the second pressurized fluid flow; a second valve assembly (162) in communication with the first valve assembly (160); selectively receiving the first or second pressurized fluid flow; a third valve assembly (164) in communication with the first valve assembly (160) for selectively receiving the first or second pressurized fluid flow; a first actuator (180) communicating with the second valve assembly (162) is in communication to selectively receive the first or the second pressure fluid flow to a translation of an e a second actuator (182) in communication with the second valve assembly (162) for selectively receiving the first or second pressure fluid flow to initiate a translation of a second pair of the plurality of translations; a third one Actuator (184) in communication with the third valve assembly (164) for selectively receiving the first or second pressure fluid flow to initiate a translation of a third pair of the plurality of translations; and a fourth actuator (186) in communication with the third valve assembly (164) for selectively receiving the first or second pressure fluid flow to initiate a translation of a fourth pair of the plurality of transmissions, the first solenoid valve (150) serving therefor selectively transferring the first pressurized fluid flow to the first valve assembly (160), the second solenoid valve (152) selectively communicating the second pressurized fluid flow to the first valve assembly (160), the first valve assembly (160) selectively operating the first valve assembly (160) and transferring the second pressure fluid flow to the second and third valve assemblies (162, 164), the second valve assembly (162) selectively communicating the first and second pressure fluid flow to the first and second actuators (180, 182), and the third valve assembly (164) is for selectively communicating the first and second pressurized fluid flow to the third and fourth actuators (184, 186) transfer.

Description

TECHNICAL AREA

The invention relates to a hydraulic control circuit for a multi-speed transmission and in particular to a hydraulic control circuit with a plurality of solenoid valves and valves, which serve to actuate a plurality of actuators in the multi-speed transmission.

BACKGROUND

A typical multi-speed dual clutch transmission employs a combination of two friction clutches and multiple dog clutch / synchronizers to achieve "under power" or dynamic shifting by switching between one friction clutch and the other, prior to actually performing the dynamic shifting, the synchronizers be "selected" for the upcoming relationship. "Switching under power" means that the torque flow from the engine need not be interrupted before performing the shift. This concept typically uses countershaft transmissions with a different dedicated gear pair or gear set to achieve each forward gear ratio. Typically, an electronically controlled hydraulic control circuit or an electronically controlled control system is used to control solenoid valves and valve assemblies. The solenoid valve and valve assemblies operate clutches and synchronizers to achieve the forward and reverse gear ratios.

Although prior hydraulic control systems are meaningful for their intended purpose, the need for new and improved hydraulic control system configurations in transmissions that are more powerful, especially from the point of view of efficiency, responsiveness, and smoothness, remains substantially constant.

The invention is therefore based on the object to provide an improved, inexpensive hydraulic control circuit for use in a transmission.

SUMMARY

This object is achieved with a hydraulic control circuit having the features of claim 1 or claim 19.

The present invention provides a hydraulic control circuit for a transmission. The hydraulic control circuit includes a plurality of solenoid valves and valves that are in fluid communication with a plurality of actuators. The actuators serve to actuate multiple torque transmitting devices. The selective actuation of the solenoid valves allows a pressure fluid flow to actuate at least one of the actuators to shift the transmission to a desired gear ratio.

An embodiment of the hydraulic control circuit of the present invention includes a first solenoid valve receiving a first pressurized fluid flow, a second solenoid valve receiving a second pressurized fluid flow, a first valve assembly in communication with the first solenoid valve to selectively receive the first pressurized fluid flow, and communicating with the second solenoid valve to selectively receive the second pressurized fluid flow, a second valve assembly in communication with the first valve assembly to selectively receive the first or second pressurized fluid flow, and a third valve assembly coupled to the first valve assembly is in communication to selectively receive the first or second pressure fluid flow. A first actuator communicates with the second valve assembly to selectively receive the first or second pressurized fluid flow to initiate a translation of a first pair of a plurality of transmissions, a second actuator is in communication with the second valve assembly to selectively connect the first or second pressurized fluid receiving a second pressurized fluid flow to initiate a translation of a second pair of the plurality of translations; a third actuator communicating with the third valve assembly to selectively receive the first or second pressurized fluid flow to initiate a translation of a third pair of the plurality of translations The fourth actuator is in communication with the third valve assembly to selectively receive the first or second pressure fluid flow to initiate a translation of a fourth pair of the plurality of translations. The first solenoid valve is operable to selectively communicate the first pressurized fluid flow to the first valve assembly, the second solenoid valve is operable to selectively communicate the second pressurized fluid flow to the first valve assembly, the first valving arrangement selectively serves the first and second pressurized fluid flow to the second valve assembly and the third valve assembly, the second valve assembly operable to selectively communicate the first and second pressurized fluid flow to the first and second actuators, and the third valve assembly selectively selects the first and second pressurized fluid flow to the third and fourth actuators Actuator to transfer.

In one aspect of the present invention, the first solenoid valve has a first solenoid fluid port in communication with the first valve assembly, and has the second solenoid valve has a second solenoid valve fluid port in communication with the first valve assembly.

In another aspect of the present invention, the first valve assembly includes a first fluid port in communication with the first solenoid fluid port and a second fluid port in communication with the second solenoid fluid port.

In yet another aspect of the present invention, the first valve assembly includes a third fluid port and a fourth fluid port that are in selective communication with the first fluid port and a fifth fluid port and a sixth fluid port that are in selective communication with the second fluid port wherein the third and fifth fluid ports communicate with the second valve assembly and the fourth and sixth fluid ports communicate with the third valve assembly.

In yet another aspect of the present invention, the second valve assembly includes a seventh fluid port in communication with the fourth fluid port and an eighth fluid port in communication with the sixth fluid port.

In yet another aspect of the present invention, the second valve assembly includes a ninth fluid port and a tenth fluid port, which are in selective communication with the seventh fluid port, and an eleventh fluid port and a twelfth fluid port that are in selective communication with the eighth fluid port, wherein the tenth and twelfth fluid ports communicate with the first actuator and the ninth and eleventh fluid ports communicate with the second actuator.

In yet another aspect of the present invention, the third valve assembly includes a thirteenth fluid port in communication with the third fluid port and a fourteenth fluid port in communication with the fifth fluid port.

In yet another aspect of the present invention, the third valve assembly includes a fifteenth fluid port and a sixteenth fluid port in communication with the thirteenth fluid port and a seventeenth fluid port and eighteenth fluid port in communication with the fourteenth fluid port the fifteenth and seventeenth fluid ports are in communication with the third actuator and the sixteenth and eighteenth fluid ports are in communication with the fourth actuator.

In yet another aspect of the present invention, the first valve assembly includes an adjustable valve or slider that serves to permit fluid communication between the first fluid port and the third fluid port when in a first position to permit fluid communication between the first fluid port and the fourth fluid port when in a second position to allow fluid communication between the second fluid port and the fifth fluid port when in the first position and fluid communication between the second fluid port and the sixth fluid port when in the second position.

In yet another aspect of the present invention, the valve is adjustable between the first and second positions by a first solenoid valve assembly in fluid communication with the first valve assembly.

In yet another aspect of the present invention, the second valve assembly includes an adjustable second valve that serves to permit fluid communication between the seventh fluid port and the ninth fluid port when in a first position is to permit fluid communication between the seventh fluid port and the tenth fluid port when in a second position to allow fluid communication between the eighth fluid port and the eleventh fluid port when in the first position and fluid communication between the eighth Fluid port and the twelfth fluid port when it is in the second position.

In yet another aspect of the present invention, the valve is adjustable between the first and second positions by a second valve solenoid valve assembly in fluid communication with the second valve assembly.

In yet another aspect of the present invention, the third valve assembly includes an adjustable third valve or actuator that serves to provide fluid communication between the thirteenth fluid port and the fifteenth fluid port, when in a first position to allow fluid communication between the thirteenth fluid port and the sixteenth fluid port when in a second position, fluid communication between the fourteenth fluid port and the seventeenth fluid port when in the first position and allowing fluid communication between the fourteenth fluid port and the eighteenth fluid port when in the second position.

In yet another aspect of the present invention, the third valve is adjustable between the first and second positions by a third valve solenoid valve assembly in fluid communication with the third valve assembly.

In yet another aspect of the present invention, the first, second, third, and fourth actuators are tri-recessed piston assemblies each engaging a torque transmitting device.

In yet another aspect of the present invention, the first and second pressure fluid flows into contact with pistons in the first, second, third and fourth actuators to actuate the torque transmitting devices.

Another embodiment of the hydraulic control circuit of the present invention includes a first solenoid valve that receives a first pressurized fluid flow, a second solenoid valve that receives a second pressurized fluid flow, a first valve assembly that communicates with the first solenoid valve to selectively receive the first pressurized fluid flow, and communicating with the second solenoid valve to selectively receive the second pressurized fluid flow, a first valve solenoid in communication with the first valve assembly to selectively actuate the first valve assembly, a second valve assembly in communication with the first valve assembly to selectively receive the first or second pressure fluid flow, a second valve solenoid in communication with the second valve assembly for selectively actuating the second valve assembly, a third valve assembly communicating with the first valve assembly in communication tion to selectively receive the first or second pressure fluid flow, and a third valve solenoid in communication with the third valve assembly to selectively actuate the third valve assembly. A first actuator is in communication with the second valve assembly to selectively receive the first or second pressure fluid flow to initiate a translation of a first pair of a plurality of transmissions, a second actuator is in communication with the second valve assembly to selectively connect the first or second pressure fluid receiving a second pressurized fluid flow to initiate a translation of a second pair of the plurality of translations; a third actuator communicating with the third valve assembly to selectively receive the first or second pressurized fluid flow to initiate a translation of a third pair of the plurality of translations, and a fourth actuator communicates with the third valve assembly to selectively receive the first or second pressure fluid flow to initiate a translation of a fourth pair of the plurality of translations. The first solenoid valve is operable to selectively communicate the first pressurized fluid flow to the first valve assembly, the second solenoid valve is operable to selectively communicate the second pressurized fluid flow to the first valve assembly, the first valving arrangement selectively serves the first and second pressurized fluid flow to the second valve assembly and the third valve assembly, the second valve assembly operable to selectively communicate the first and second pressurized fluid flows to the first and second actuators, and the third valve assembly selectively selects the first and second pressurized fluid flow to the third and fourth actuators Actuator to transfer

In one aspect of the present invention, the first valve assembly includes an adjustable first valve operable to permit fluid communication between a plurality of first fluid ports in the first valve assembly, the first valve being operable by a third pressurized fluid flow selectively transmitted from the first valve solenoid ,

In another aspect of the present invention, the second valve assembly includes an adjustable second valve operable to permit fluid communication between a plurality of second fluid ports in the second valve assembly, the second valve being operable by a fourth pressurized fluid flow selectively transmitting from the second valve solenoid becomes.

In yet another aspect of the present invention, the third valve assembly includes an adjustable third valve operable to permit fluid communication between a plurality of third fluid ports in the third valve assembly, and wherein the third valve is operable by a fifth pressure fluid flow, optionally from the third Valve solenoid is transmitted.

Other objects, features and advantages of the present invention will become apparent by reference to the following description and the accompanying drawings in which: FIG Reference symbols refer to the same component, the same element or the same feature.

list of figures

• 1 eine schematische Darstellung einer Ausführungsform eines hydraulischen Steuersystems für ein Doppelkupplungsgetriebe mit einem Aktorsteuerungs-Subsystem gemäß den Prinzipien der vorliegenden Erfindung;
• 2 eine schematische Darstellung einer Ausführungsform eines Aktorsteuerungs-Subsystem gemäß den Prinzipien der vorliegenden Erfindung;
• 3A eine schematische Querschnittsansicht eines Paars beispielhafter Kolben einer Dreibereichskolbenanordnung, die durch das Aktorsteuerungs-Subsystem der vorliegenden Erfindung gesteuert wird;
• 3B eine schematische Querschnittsansicht einer beispielhaften Dreibereichskolbenanordnung in einer ersten Stellung;
• 3C eine schematische Querschnittsansicht einer beispielhaften Dreibereichskolbenanordnung in einer zweiten Stellung; und
• 3C eine schematische Querschnittsansicht einer beispielhaften Dreibereichskolbenanordnung in einer dritten Stellung.

The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way. In the drawings are:

• 1 a schematic representation of an embodiment of a hydraulic control system for a dual-clutch transmission with an actuator control subsystem according to the principles of the present invention;
• 2 a schematic representation of an embodiment of an actuator control subsystem according to the principles of the present invention;
• 3A FIG. 2 is a schematic cross-sectional view of a pair of exemplary pistons of a tri-range piston assembly controlled by the actuator control subsystem of the present invention; FIG.
• 3B a schematic cross-sectional view of an exemplary Dreiereichskolbenanordnung in a first position;
• 3C a schematic cross-sectional view of an exemplary three-stroke piston assembly in a second position; and
• 3C a schematic cross-sectional view of an exemplary Dreiereichskolbenanordnung in a third position.

DESCRIPTION

In 1 is a generally by the reference numeral 10 shown hydraulic control system for use in a dual-clutch transmission in a motor vehicle shown schematically. The hydraulic control system 10 includes several subsystems, which is a line pressure subsystem 12 , a torque converter clutch (TCC) control subsystem 14, a lubrication control subsystem 16 , an electronic limited slip differential (ELSD) 17 subsystem, a clutch control subsystem 18 , an electronic transmission range selection (ETRS) subsystem 19 and an actuator control subsystem 20 include. The hydraulic control system 10 serves to control the dual-clutch transmission, as will be described in more detail below. In addition, the hydraulic control system 10 Various other subsystems include, without departing from the scope of the present invention.

The line pressure subsystem 12 serves to the hydraulic control system 10 to provide pressurized hydraulic fluid such as oil and to regulate it throughout. Accordingly, the line pressure subsystem 12 various components (not shown) such as a hydraulic pump, a fluid source, a line pressure relief valve, a line pressure control valve and / or a filter include. In the example given, the line pressure subsystem includes 12 one by the reference numeral 28 specified fluid communication channel or line connection passage, the pressurized hydraulic fluid directly to the TCC control subsystem 14 and the clutch control subsystem 18 and the actuator control subsystem 20 supplies. The line connection 28 is in 1 shown schematically as a plurality of separate lines, but it should be noted that the line connecting passage 28 may be a single uninterrupted passageway or may correspond to a plurality of consecutive or adjacent coupled passageways without departing from the scope of the present invention.

The TCC control subsystem 14 controls the operation of a torque converter (not shown) in the dual clutch transmission. The TCC control subsystem 16 is through a fluid connection passage 30 in direct hydraulic communication with the lubrication control subsystem 16 , The fluid connection passage 30 may be a single passageway or may correspond to a plurality of serially connected or adjacent coupled passageways without departing from the scope of the present invention.

The lubrication control subsystem 16 provides lubrication and cooling for a variety of components throughout the dual-clutch transmission. For example, the lubrication control subsystem 16 Supply hydraulic fluid through multiple fluid communication passages (not shown) to heat generating components.

The electronic limited slip differential (ELSD) subsystem 17 serves to an axle coupling 31 , which is arranged in a differential gear (not shown) of the motor vehicle to control. The axle coupling 31 is with a pair of half-axes 33 coupled, in turn, with a pair of wheel assemblies 35 are coupled. The axle coupling 31 Controls the speed difference between the pairs of half-axles 33 and wheel assemblies 35 to eliminate the difference (or "slip") between them. An exemplary ELSD control subsystem is described in commonly assigned US patent application US 2008/0 220 923 A1 disclosed.

The clutch control subsystem 18 serves a double clutch assembly, which is a first clutch 32 and a second clutch 34 includes, to control. The couplings 32 . 34 may be used to engage one or more input shafts or countershafts (not shown) in the dual clutch transmission and through between the clutches 32 . 34 alternating engagement and the actuator control subsystem 20 to enable a dynamic switching or "switching under power".

The Electronic Transmission Range Selection Subsystem (ETRS) 19 receives the switching command from the vehicle operator and, in the present embodiment, is a shift-by-wire system. The ETRS subsystem 19 serves a parking system 37 to control the reception of electronic control signals. The parking system 37 serves to provide at least two transmission modes including a first mode or non-park mode and a second mode or park mode. In parking mode, the parking system prevents 37 in that the transmission moves the vehicle by preferably locking an output shaft (not shown) of the transmission. In the non-parking mode is the parking system 37 and the transmission can move the vehicle by engaging any of the forward or reverse transmission ratios. An exemplary ETRS control subsystem is described in commonly assigned US patent application US 2008/0 220 939 A1 disclosed.

In order to 2 The actuator control subsystem controls 20 actuating a plurality of synchronizers, clutches and / or brakes to selectively engage a plurality of gear sets (not shown) in the dual clutch transmission to provide a plurality of forward and reverse gear ratios and a neutral state. The actuator control subsystem 24 includes two solenoid valves with variable force 150 . 152 , an odd / even actuator safety valve 160 , an even actuator safety valve 162 , an odd actuator safety valve 164 , three switching solenoid valves 170 . 172 and 174 and four tri-piston actuators 180 . 182 . 184 and 186 ,

The solenoid valve 150 has a fluid connection 195 that with the line connection 28 is in communication, and a fluid connection 197 that with a fluid communication connection 200 in communication, up. The fluid communication connection 200 stands with the odd / even actuator safety valve 160 in fluid communication. The solenoid valve 150 serves to pressurize the hydraulic fluid from the line connecting passage 28 to translate the 2nd, 3rd, 6th and 7th transmissions of the dual clutch transmission, as will be described in more detail below.

The solenoid valve 152 has a fluid connection 199 that with the line connection 28 is in communication, and a fluid connection 210 that with a fluid communication connection 202 in communication, up. The fluid communication connection 202 stands with the odd / even actuator safety valve 160 in fluid communication. The solenoid valve 152 serves to pressurize the hydraulic fluid from the line connecting passage 28 to translate the 1st, 4th, and 5th gear ratios as well as the reverse ratio of the dual clutch transmission, as described in more detail below.

The odd / even actuator safety valve 160 serves to pressurize the hydraulic fluid from one of the solenoid valves 150 . 152 to the odd actuator safety valve 162 or the even actuator safety valve 164 transferred to. More specifically, the odd / even actuator safety valve 160 a fluid connection 203 connected to the fluid communication link 200 is in communication, and a fluid connection 205 connected to the fluid communication link 202 is in communication, to the pressurized hydraulic fluid from one of the solenoid valves 150 . 152 to recieve. The odd / even actuator safety valve 160 also has a fluid connection 207 that with a fluid communication connection 208 is in communication, a fluid connection 210 that with a fluid communication connection 212 is in communication, a fluid connection 214 that with a fluid communication connection 216 is in communication, and a fluid connection 218 that with a fluid communication connection 220 in communication, up. The fluid communication links 212 and 220 stand with the even-numbered actuator safety valve 162 in communication while the fluid communication links 208 and 216 with the odd-numbered actuator safety valve 164 communicate. The odd / even actuator safety valve 160 includes a valve or a slider 222 which is slidably disposed therein. The valve 222 is adjustable between two positions to selectively communicate the pressurized hydraulic fluid from the fluid port 203 to the fluid port 207 if it is in a first Position, and to the fluid port 210 when in a second position, and selectively communicating the hydraulic fluid from the fluid port 205 to the fluid port 214 when in the first position and to the fluid port 218 if it is in the second position to admit. The position of the valve 222 is activated by actuation of the solenoid valve 170 controlled.

The even-numbered actuator safety valve 162 serves to supply the pressurized hydraulic fluid from the odd / even actuator safety valve 160 to the actors 180 and 182 to transfer one of the even-numbered translations (ie, the 2nd, 4th, and 6th ratios and the reverse ratio) of the dual-clutch transmission. More specifically, the even-numbered actuator safety valve 162 a fluid connection 230 connected to the fluid communication link 212 is in communication, and a fluid connection 232 connected to the fluid communication link 220 is in communication to the pressurized hydraulic fluid from the odd / even actuator safety valve 160 to recieve. The even-numbered actuator safety valve 162 also has a fluid connection 238 that with a fluid communication connection 240 is in communication, a fluid connection 242 that with a fluid communication connection 244 is in communication, a fluid connection 246 that with a fluid communication connection 248 is in communication, and a fluid connection 250 that with a fluid communication connection 252 in communication, up. The fluid communication links 244 and 252 stand with the actor 180 in communication while the fluid communication links 240 and 248 with the actor 182 communicate. The even-numbered actuator safety valve 162 includes a valve or a slider 254 which is slidably disposed therein. The valve 254 is adjustable between two positions to selectively communicate the pressurized hydraulic fluid from the fluid port 232 to the fluid port 238 when in a first position and to the fluid port 242 when in a second position, and selectively communicating the pressurized hydraulic fluid from the fluid port 230 to the fluid port 246 when in the first position and to the fluid port 250 if it is in the second position to admit. The position of the valve 252 is activated by actuation of the solenoid valve 172 controlled.

The odd actuator safety valve 164 serves to supply the pressurized hydraulic fluid from the odd / even actuator safety valve 160 to the actors 184 and 186 to translate one of the odd-numbered translations (ie, the 1st, 3rd, 5th, and 7th ratios) of the dual-clutch transmission. Specifically, the odd-numbered actuator safety valve 164 a fluid connection 260 connected to the fluid communication link 208 is in communication, and a fluid connection 262 connected to the fluid communication link 216 is in communication to the pressurized hydraulic fluid from the odd / even actuator safety valve 160 to recieve. The odd actuator safety valve 164 also has a fluid connection 264 that with a fluid communication connection 266 is in communication, a fluid connection 268 that with a fluid communication connection 270 is in communication, a fluid connection 272 that with a fluid communication connection 274 is in communication, and a fluid connection 276 that with a fluid communication connection 278 in communication, up. The fluid communication links 266 and 274 stand with the actor 184 in communication while the fluid communication links 270 and 278 with the actor 186 communicate. The odd actuator safety valve 164 includes a valve or a slider 280 which is slidably disposed therein. The valve 280 is adjustable between two positions to selectively communicate the pressurized hydraulic fluid from the fluid port 260 to the fluid port 264 when in a first position and to the fluid port 268 when in a second position, and selectively communicating the hydraulic fluid from the fluid port 262 to the fluid port 272 when in the first position and to the fluid port 276 if it is in the second position to admit. The position of the valve 280 is activated by actuation of the solenoid valve 174 controlled.

The actors 180 . 182 . 184 and 186 Preferably, three-piston piston assemblies which serve to respectively engage a torque transmitting member. With reference to the 3A-D becomes the actor 180 described in more detail, it being mentioned that the actuators 182 . 184 and 168 essentially the same as the actuator 180 are and therefore have corresponding components. The actor 180 includes a first piston 286 and a second piston 288 , as in 3A best seen. The pistons 286 . 288 are sliding in a piston housing or piston cylinder 290 arranged as in the 3B-D best seen. The pistons 286 . 288 have three separate areas 292 . 294 and 296 on. The area 292 is disposed on the first piston while the areas 294 and 296 on the second piston 288 are arranged. Every area 292 . 296 and 298 has a different size or lateral surface. The pistons 286 . 288 are with a drag lever 300 a synchronizer assembly (not shown). The actor 180 has a fluid connection 302 who deals with the areas 292 and 294 The piston 268 . 288 communicates, and a fluid connection 304 that with the area 296 of the piston 288 communicates, on. The fluid connection 320 communicates with the fluid communication channel 252 in communication while the fluid connection 304 with the fluid communication channel 244 is in communication. Accordingly, the pressurized hydraulic fluid may be supplied by the even-numbered actuator safety valve 162 through one of the fluid ports 302 . 304 in the actor 180 penetrate and with one of the areas 292 . 294 . 296 The piston 268 . 288 get in contact to move them between different positions. Each position in turn corresponds to a position of the finger lever 300 the synchronizing arrangement. For example, shows 3B the actor 180 in a neutral position while 3C shows that pressurized fluid from the fluid port 302 the piston 288 moved to the right to trigger a 6. 4. translation, and 3D shows that pressurized fluid from the fluid port 304 the piston 288 moved to the left to trigger a 4th translation.

In 2 instructs the actor 182 a fluid connection 306 connected to the fluid communication channel 240 is in fluid communication, and a fluid port 308 connected to the fluid communication channel 248 in fluid communication. Pressurized hydraulic fluid coming from the fluid port 306 to the actor 182 is used to engage the reverse gear during pressurized hydraulic fluid coming from the fluid port 308 to the actor 182 is used to engage the 2nd translation.

The actor 184 has a fluid connection 310 connected to the fluid communication channel 266 is in communication, and a fluid connection 312 connected to the fluid communication channel 274 in communication, up. Pressurized hydraulic fluid coming from the fluid port 310 to the actor 184 is used to engage the 7th gear during pressurized hydraulic fluid coming from the fluid port 312 to the actor 184 to serve the 5th translation.

The actor 186 has a fluid connection 314 connected to the fluid communication channel 278 is in communication, and a fluid connection 316 connected to the fluid communication channel 270 in communication, up. Pressurized hydraulic fluid coming from the fluid port 314 to the actor 186 serves to engage the 1st gear, while pressurized hydraulic fluid coming from the fluid port 316 to the actor 186 is used to engage the 3rd translation. Although specific translations for the dual-clutch gearbox specific actuators 180 . 182 . 184 . 186 have been assigned in the specified embodiment, it should be noted that by the actuators 180 . 182 . 184 . 186 may be different, without departing from the scope of the present invention, and controlling which specific synchronizers with the actuators 180 . 182 . 184 . 186 be coupled.

Claims (22)

A hydraulic control circuit for a transmission, comprising: a first solenoid valve (150) receiving a first pressurized fluid flow; a second solenoid valve (152) receiving a second pressure fluid flow; a first valve assembly (160) in communication with the first solenoid valve (150) for selectively receiving the first pressurized fluid flow and in communication with the second solenoid valve (152) to selectively receive the second pressurized fluid flow; a second valve assembly (162) in communication with the first valve assembly (160) for selectively receiving the first or second pressure fluid flow; a third valve assembly (164) in communication with the first valve assembly (160) for selectively receiving the first or second pressure fluid flow; a first actuator (180) in communication with the second valve assembly (162) for selectively receiving the first or second pressure fluid flow to initiate a translation of a first pair of multiple translations; a second actuator (182) in communication with the second valve assembly (162) for selectively receiving the first or second pressure fluid flow to initiate a translation of a second pair of the plurality of translations; a third actuator (184) in communication with the third valve assembly (164) for selectively receiving the first or second pressure fluid flow to initiate a translation of a third pair of the plurality of translations; and a fourth actuator (186) in communication with the third valve assembly (164) for selectively receiving the first or second pressurized fluid flow to initiate a translation of a fourth pair of the plurality of translations, the first solenoid valve (150) therefor is operable to selectively communicate the first pressurized fluid flow to the first valve assembly (160), the second solenoid valve (152) selectively communicating the second pressurized fluid flow to the first valve assembly (160), the first valve assembly (160) serving to selectively dispose the second pressurized fluid flow first and second Transferring pressurized fluid flow to the second and third valve assemblies (162, 164), the second valve assembly (162) operable to selectively communicate the first and second pressurized fluid flow to the first and second actuators (180, 182), and the third Valve assembly (164) serves to selectively transfer the first and second pressurized fluid flow to the third and fourth actuators (184, 186). Hydraulic control circuit to Claim 1 wherein the first solenoid valve (150) has a first solenoid fluid port in communication with the first valve assembly (160) and the second solenoid valve (152) has a second solenoid fluid port associated with the first valve assembly (160) in FIG Communication stands. Hydraulic control circuit to Claim 2 wherein the first valve assembly (160) has a first fluid port in communication with the first solenoid fluid port and a second fluid port in communication with the second solenoid fluid port. Hydraulic control circuit to Claim 3 wherein the first valve assembly (160) includes a third fluid port and a fourth fluid port that are in selective communication with the first fluid port and a fifth fluid port and a sixth fluid port that are in selective communication with the second fluid port, the third one and the fifth fluid port communicates with the second valve assembly (162) and the fourth and sixth fluid ports communicate with the third valve assembly (164). Hydraulic control circuit to Claim 4 wherein the second valve assembly (162) includes a seventh fluid port in communication with the fourth fluid port and an eighth fluid port in communication with the sixth fluid port. Hydraulic control circuit to Claim 5 wherein the second valve assembly (162) includes a ninth fluid port and a tenth fluid port in selective communication with the seventh fluid port, and an eleventh fluid port and a twelfth fluid port in selective communication with the eighth fluid port, the tenth and the twelfth fluid port communicates with the first actuator (180) and the ninth and eleventh fluid ports communicate with the second actuator (182). Hydraulic control circuit to Claim 6 wherein the third valve assembly (164) includes a thirteenth fluid port in communication with the third fluid port and a fourteenth fluid port in communication with the fifth fluid port. Hydraulic control circuit to Claim 7 wherein the third valve assembly (164) has a fifteenth fluid port and a sixteenth fluid port that are in selective communication with the thirteenth fluid port, and a seventeenth fluid port and an eighteenth fluid port that are in selective communication with the fourteenth fluid port, wherein the fifteenth and the seventeenth fluid port is in communication with the third actuator (184) and the sixteenth and eighteenth fluid ports are in communication with the fourth actuator (186). Hydraulic control circuit to Claim 8 wherein the first valve assembly (160) includes an adjustable first valve (222) or an adjustable first spool that serves to permit fluid communication between the first fluid port and the third fluid port when in a first position Allow fluid communication between the first fluid port and the fourth fluid port when in a second position to allow fluid communication between the second fluid port and the fifth fluid port when in the first position and fluid communication between the second fluid port and the first fluid port sixth fluid port when it is in the second position. Hydraulic control circuit to Claim 9 wherein the valve (222) is adjustable between the first and second positions by a first solenoid valve assembly (170) in fluid communication with the first valve assembly (160). Hydraulic control circuit to Claim 8 wherein the second valve assembly (162) includes an adjustable second valve (254) or an adjustable second spool that serves to permit fluid communication between the seventh fluid port and the ninth fluid port when in a first position Allow fluid communication between the seventh fluid port and the tenth fluid port when in a second position to allow fluid communication between the eighth fluid port and the eleventh fluid port when in the first position and fluid communication between the eighth fluid port and the eighth fluid port 12th fluid connection when it is in the second position. Hydraulic control circuit to Claim 11 wherein the second valve (254) is adjustable between the first and second positions by a solenoid valve assembly (172) in fluid communication with the second valve assembly (162). Hydraulic control circuit to Claim 8 wherein the third valve assembly (164) includes an adjustable third valve (280) or a third adjustable spool that serves to permit fluid communication between the thirteenth fluid port and the fifteenth fluid port when in a first position Allow fluid communication between the thirteenth fluid port and the sixteenth fluid port when in a second position to allow fluid communication between the fourteenth fluid port and the seventeenth fluid port when in the first position and fluid communication between the fourteenth fluid port and the second fluid port eighteenth fluid port when in the second position. Hydraulic control circuit to Claim 13 wherein the third valve (280) is adjustable between the first and second positions by a solenoid valve assembly (174) in fluid communication with the third valve assembly (164). Hydraulic control circuit to Claim 1 wherein the first, second, third and fourth actuators (180, 182, 184, 186) are tristate piston assemblies each engaging a torque transmitting device. Hydraulic control circuit to Claim 15 wherein the first and second pressure fluid flows into contact with pistons in the first, second, third and fourth actuators (180, 182, 184, 186) to actuate the torque transmitting devices. Hydraulic control circuit to Claim 1 further comprising a first control subsystem in fluid communication with the first and second pressure fluid flows, the first control subsystem operable to control a clutch disposed in a differential gear coupled to an output of the transmission. Hydraulic control circuit to Claim 1 further comprising a second control subsystem in fluid communication with the first and second pressure fluid flows, the second control subsystem operable to control a parking system for initiating a parking mode and a non-parking mode in the transmission. A hydraulic control circuit for a transmission, comprising: a first solenoid valve (150) receiving a first pressurized fluid flow; a second solenoid valve (152) receiving a second pressure fluid flow; a first valve assembly (160) in communication with the first solenoid valve (150) for selectively receiving the first pressurized fluid flow and in communication with the second solenoid valve (152) to selectively receive the second pressurized fluid flow; a first valve solenoid (170) in communication with the first valve assembly (160) for selectively actuating the first valve assembly (160); a second valve assembly (162) in communication with the first valve assembly (160) for selectively receiving the first or second pressure fluid flow; a second valve solenoid (172) in communication with the second valve assembly (162) for selectively actuating the second valve assembly (162); a third valve assembly (164) in communication with the first valve assembly (160) for selectively receiving the first or second pressure fluid flow; a third valve solenoid (174) in communication with the third valve assembly (164) for selectively actuating the third valve assembly (164); a first actuator (180) in communication with the second valve assembly (162) for selectively receiving the first or second pressure fluid flow to initiate a translation of a first pair of multiple translations; a second actuator (182) in communication with the second valve assembly (162) for selectively receiving the first or second pressure fluid flow to initiate a translation of a second pair of the plurality of translations; a third actuator (184) in communication with the third valve assembly (164) for selectively receiving the first or second pressure fluid flow to initiate a translation of a third pair of the plurality of translations; and a fourth actuator (186) in communication with the third valve assembly (164) for selectively receiving the first or second pressurized fluid flow to initiate a translation of a fourth pair of the plurality of translations, the first solenoid valve (150) therefor is operable to selectively communicate the first pressurized fluid flow to the first valve assembly (160), the second solenoid valve (152) selectively communicating the second pressurized fluid flow to the first valve assembly (160), the first valve assembly (160) serving to selectively dispose the second pressurized fluid flow first and second pressure fluid flow to the second and the third Valve assembly (162, 164), the second valve assembly (162) is operable to selectively communicate the first and second pressurized fluid flow to the first and second actuators (180, 182), and the third valve assembly (164) serves to optionally, transferring the first and second pressurized fluid flow to the third and fourth actuators (184, 186). Hydraulic control circuit to Claim 19 wherein the first valve assembly (160) includes an adjustable first valve (222) operable to permit fluid communication between a plurality of first fluid ports in the first valve assembly (160), and wherein the first valve (222) is operable by a third pressurized fluid flow which is selectively transmitted from the first valve solenoid (170). Hydraulic control circuit to Claim 20 wherein the second valve assembly (162) includes an adjustable second valve (254) for permitting fluid communication between a plurality of second fluid ports in the second valve assembly (162), and wherein the second valve (254) is actuatable by a fourth pressurized fluid flow which is selectively transmitted from the second valve solenoid (172). Hydraulic control circuit to Claim 21 wherein the third valve assembly (164) includes an adjustable third valve (280) operable to permit fluid communication between a plurality of third fluid ports in the third valve assembly (164), and wherein the third valve (280) is operable by a fifth pressure fluid flow which is selectively transmitted from the third valve solenoid (174).

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