CN111425590A

CN111425590A - Automatic transmission hydraulic control oil way with electronic gear shifting function

Info

Publication number: CN111425590A
Application number: CN202010213170.3A
Authority: CN
Inventors: 李洪岩; 马静; 关崴; 姚书涛; 柴召朋; 周章遐; 苏俊元; 赵彦辉; 杨林; 李宾龙; 宋名; 张晓冬; 刘晓宁
Original assignee: Harbin Dongan Automotive Engine Manufacturing Co Ltd
Current assignee: Harbin Dongan Automotive Engine Manufacturing Co Ltd
Priority date: 2020-03-24
Filing date: 2020-03-24
Publication date: 2020-07-17
Anticipated expiration: 2040-03-24
Also published as: CN111425590B

Abstract

the invention relates to an automatic transmission hydraulic control oil circuit with an electronic gear shifting function, which belongs to the technical field of transmission hydraulic control oil circuits and aims to solve the problems of long gear shifting time, slow gear shifting response and poor oil saving capability of the traditional transmission hydraulic oil circuit.

Description

Automatic transmission hydraulic control oil way with electronic gear shifting function

Technical Field

The invention relates to a control oil way, in particular to an automatic transmission hydraulic control oil way with an electronic gear shifting function, and belongs to the technical field of transmission hydraulic control oil ways.

Background

The new energy automobile technology is undoubtedly one of important technologies for solving global energy and environmental problems, and the challenges and the urgent nature of technical innovation faced by China as a major automobile consumption country are stronger. Over a longer period of time, various forms of hybrid technology will be important transition routes. According to whether the technology is upgraded based on the traditional power, the hybrid power technology can be divided into P-frame hybrid power and power split hybrid power, the P-frame hybrid power technology is upgraded based on the traditional power, the development period is short, the industrialization cost is low, but the efficiency and the oil saving capability of the whole machine are limited; the power-split hybrid power is a brand-new developed special electrically-driven transmission for hybrid power, has obvious advantages in cost, arrangement space, efficiency and oil saving capability, and is widely considered to be the hybrid power technology closest to the pure electric technology.

Disclosure of Invention

The invention aims to provide a hydraulic control oil way of an automatic transmission with an electronic gear shifting function, and aims to solve the problems of long gear shifting time, slow gear shifting response and poor oil saving capability of a traditional hydraulic oil way of the automatic transmission.

A hydraulic control oil circuit of an automatic transmission with an electronic gear shifting function comprises a mechanical oil pump, a main pressure regulating valve, a pressure limiting valve, a TC regulating valve, a cooler bypass valve, a DCC valve, a parking logic valve, a start-stop control valve, a limp selection valve, a switch valve, a gear shifting safety valve A, a gear shifting safety valve B, an oil supply valve core, a solenoid valve S L, a solenoid valve S L TC, a solenoid valve S L C1, a solenoid valve S L C2, a solenoid valve S L C3, a solenoid valve S L C4, a solenoid valve S B1, a solenoid valve S L B2, a solenoid valve S1, a solenoid valve S2, a solenoid valve S3, a solenoid valve S4, a solenoid valve S5;

the mechanical oil pump is respectively communicated with a main pressure regulating valve, a pressure limiting valve, a TC regulating valve, a parking logic valve, a start-stop control valve, a shift safety valve B, a solenoid valve S L TC, a solenoid valve S B2 and a start-stop plunger pump through oil passages, the main pressure regulating valve is respectively communicated with a DCC valve and a solenoid valve S L0, the pressure limiting valve is respectively communicated with a solenoid valve S L1, a solenoid valve S1, a solenoid valve S2, a solenoid valve S3, a solenoid valve S4 and a solenoid valve S5, the TC regulating valve is respectively communicated with a DCC valve, a parking logic valve and a solenoid valve S L2 TC, the cooler bypass valve is respectively communicated with a DCC valve, a limp select valve and a solenoid valve S3, the DCC valve is respectively communicated with a parking logic valve, a limp select valve, a switch valve A, an oil supply spool, a 3C 3, a 363C valve, a 3, a 36c valve B, a 3, a 36c valve C valve is respectively communicated with a 3, a 36c valve C, a 3, a 36c 72, a 36c 72, a 36c 72C 72, a 36c 3C, a 36c 3C, a 36c 72, a 36c 3C, a 36c 3C, a 36c and a 36c 3C, a 36c B, a 36c 3C B, a 36c 72C, a 36c 72C 3C 72C, a 36c B, a 36c 72C, a 36c 72C.

Preferably: and a start-stop relief valve is arranged between the start-stop control valve and the start-stop plunger pump.

Compared with the existing product, the invention has the following effects:

The inlet of the electromagnetic valve is directly supplied with oil by the main oil pressure or the mechanical valve core communicated with the main oil pressure, and oil supply is not needed through switching on and off of a switch valve and switching of the mechanical valve core, so that the gear shifting time is greatly shortened, and the gear shifting responsiveness is improved. The oil way is started and stopped in the design, and an electromagnetic pump is designed at an oil return port of a mechanical oil pump and used for replacing the oil pump to keep the oil pressure of a D1 gear clutch C1 in the idle stop stage, so that the oil consumption of an engine under the condition of low rotating speed (low efficiency region) is saved. An electronic gear shifting structure is designed, an electromagnetic valve and a mechanical valve core are utilized to replace an original manual valve, the on-off of the electromagnetic valve is controlled through the on-off of an electric control signal, the switching of the mechanical valve core is further controlled, and the switching between non-P gears (R/D/N) is realized. An electronic parking control oil way is designed, the traditional stay wire control is cancelled, the piston motion control parking execution element action is realized by controlling oil filling of a piston cavity through an electromagnetic valve, and the switching between a P gear and a non-P gear is realized. The parking piston is mechanically limited by controlling the parking locking electromagnetic valve at the P gear and the non-P gear, so that the function safety protection effect is realized; and the electromagnetic valve of the clutch is controlled in a non-P gear, so that control of other gear modes (R/N/D), namely electronic gear shifting, is realized.

The built-in electronic gear shifting, electronic parking and electronic starting and stopping are realized, the structural arrangement is compact, the middle position space is saved, the driving is convenient, and the energy conservation and emission reduction are realized.

Drawings

Fig. 1 is a schematic structural diagram of a hydraulic control oil circuit of an automatic transmission with an electronic gear shifting function.

in the figure, 1-mechanical oil pump, 2-main pressure regulating valve, 3-pressure limiting valve, 4-TC regulating valve, 5-cooler bypass valve, 6-DCC valve, 7-parking logic valve, 8-start-stop control valve, 9-limp selection valve, 10-switch valve, 11-shift safety valve A, 12-shift safety valve B, 13-oil supply valve core, 14-solenoid valve S L, 15-solenoid valve S L TC, 16-solenoid valve S L C1, 17-solenoid valve S L C2, 18-solenoid valve S L C3, 19-solenoid valve S L C4, 20-solenoid valve S L B1, 21-solenoid valve S L B2, 22-solenoid valve S1, 23-solenoid valve S2, 24-solenoid valve S3, 25-solenoid valve S425, 26-solenoid valve S526, 27-start-stop plunger pump and 28-start-stop valve.

Detailed Description

Preferred embodiments of the present invention are explained in detail below with reference to the accompanying drawings.

as shown in fig. 1, the hydraulic control oil circuit of the automatic transmission with the electronic gear shifting function according to the present invention includes a mechanical oil pump 1, a main pressure regulating valve 2, a pressure limiting valve 3, a TC regulating valve 4, a cooler bypass valve 5, a DCC valve 6, a parking logic valve 7, a start-stop control valve 8, a limp-home valve 9, a switching valve 10, a gear-shifting safety valve a11, a gear-shifting safety valve B12, an oil supply spool 13, a solenoid valve S L14, a solenoid valve S L TC 15, a solenoid valve S L C116, a solenoid valve S L C217, a solenoid valve S L C318, a solenoid valve S L C419, a solenoid valve S L B120, a solenoid valve S L B221, a solenoid valve S122, a solenoid valve S223, a solenoid valve S324, a solenoid valve S425, a;

the mechanical oil pump 1 is respectively communicated with a main pressure regulating valve 2, a pressure limiting valve 3, a TC regulating valve 4, a parking logic valve 7, a start-stop control valve 8, a shift safety valve B, a solenoid valve S L TC 15, a solenoid valve S L B221 and a start-stop plunger pump 27 through oil passages, the main pressure regulating valve 2 is respectively communicated with a DCC valve 6 and a solenoid valve 014, the pressure limiting valve 3 is respectively communicated with a solenoid valve 114, a solenoid valve S122, a solenoid valve S223, a solenoid valve S324, a solenoid valve S425 and a solenoid valve S526, the TC regulating valve 4 is respectively communicated with a DCC valve 6, a parking logic valve 7 and a solenoid valve 2TC 15, the Cooler bypass valve 5 is respectively communicated with a DCC oil supply valve 6, a limp selection valve 9 and a solenoid valve S324, the DCC valve 6, the DCC valve 526 is respectively communicated with a parking logic valve 7, a limp selection valve 9, a switching valve 10, a shift safety valve A526, an oil supply spool 13, a solenoid valve C3C 217, a 3C 3, a solenoid valve C3, a 120, a C324, a C3, a C324, a C3, a C324, a C3C, a C3.

Further: a start-stop relief valve 28 is arranged between the start-stop control valve 8 and the start-stop plunger pump 27.

the hydraulic control system comprises a hydraulic torque converter, a main pressure regulating valve, a resolver, a controller, a mechanical oil pump, an input shaft, an engine, a hydraulic torque converter, a main pressure regulating valve, a pressure limiting valve, a TC regulating valve, a resolver bypass valve, a DCC valve, a parking logic valve, a mechanical valve core, a limp valve, a combined valve core, a safety valve and a shift logic valve, wherein the mechanical oil pump is used for 1, the input shaft is connected with the engine and the hydraulic torque converter, the main pressure regulating valve is used for regulating the system pressure to be constant pressure and supplies oil to all VFS solenoid valves, the pressure limiting valve is used for regulating the main oil pressure and supplies oil to all electromagnetic switch valves, the TC regulating valve is used for regulating the DA oil pressure of the hydraulic torque converter, the resolver bypass valve is used for regulating the flow of the resolver, the DCC valve is used for regulating the direct/non-direct junction and slip states of;

the hydraulic control valve comprises a valve core 13 for ensuring oil supply of D/R gears of a C3 clutch and a C4 clutch, a solenoid valve S L, a solenoid valve SLTC, a solenoid valve SL 1, a solenoid valve SLC 2, a solenoid valve SLC 3, a solenoid valve SLC 4, a solenoid valve SLB 1, a solenoid valve SLB 2, a solenoid valve S1, a solenoid valve S2, a solenoid valve S3, a solenoid valve S4, a solenoid valve S5, a start-stop plunger pump 27 and a start-stop relief valve 28, wherein the solenoid valve S S L, the solenoid valve SLC 1, the solenoid valve S L C3, the solenoid valve S L4, the solenoid valve S1, the solenoid valve.

The working principle of the invention is as follows:

1) Electronic gear shifting

According to the invention, a manual valve mechanism in an automatic transmission is cancelled, two switch electromagnetic valves are designed to respectively control two groups of two-position three-way mechanical valve cores, and the two groups of two-position three-way mechanical valve cores are used for realizing switching of a P/R/N/D gear oil circuit, and the specific strategy is as follows:

1. S1 is not electrified, S2 is not electrified

The oil supply end of the clutch is filled with oil, the oil drain state is at the oil way of the N/P gear, the oil supply state is not at the R gear, and the oil is supplied at the D gear;

2. S1 is not electrified, S2 is electrified

The oil supply end of the D-gear clutch is cut off, the oil drainage state is realized at the oil way of the P-gear, and the oil supply state is not realized at the oil way of the R-gear, so that the oil supply way of the N-gear is realized;

3. S1 is electrified, S2 is not electrified

The oil supply of the D-gear clutch is cut off, the parking logic valve enables the oil supply of the parking piston to be cut off forcibly, and at the moment, the electromagnetic valve is cut off to realize a P-gear oil supply oil way;

4. S1 power-on, S2 power-on

The oil supply ends of the C3 and C4 clutches are independently filled with oil, and a reverse gear oil circuit is realized by combining the independent oil supply of B2; the two combined power flows can realize reverse gear, so that two-gear reverse gear can be realized;

2) Oil supply for electromagnetic valve direct clutch

In the forward gear, the power supply is kept at S1, the power supply is kept at S2, the oil pressure is built up by the pump of the mechanical pump 1, and the ATF supplies oil to the inlets of the electromagnetic valves through the 1# oil way, the gear-shifting safety valve B, the 23# oil way and the 25# oil way.

in the invention, each clutch is controlled by an independent electromagnetic valve, namely 6 friction transmission assemblies are controlled by the same 6N L VFS electromagnetic valves, and oil supply of each gear electromagnetic valve inlet is not required to be switched by matching of a switch valve and a mechanical valve core when each gear of a D gear is switched, so that the gear shifting time is greatly shortened, and the gear shifting responsiveness is improved.

3) Electronic start-stop

The invention adopts an internal plunger pump to start and stop to replace the original external electronic pump, the plunger pump and the pressure release valve are arranged on the mechanical pump, the start-stop oil path consists of the plunger pump, a start-stop pressure release electromagnetic valve, a start-stop control valve component and an oil supply oil path, and the working principle is as follows: under the urban working condition, idling is stopped, an engine is shut down, a mechanical pump stops rotating, the start-stop plunger pump is controlled to work at the moment, oil pressure enters a C1 control oil path through a start-stop valve, a C1 clutch is compressed, a clutch piston is pushed to complete the stroke, and the oil pressure of a C1 clutch is kept above a KP point. When the engine is restarted, the mechanical pump works again after the engine reaches a certain rotating speed, and the oil pressure of the main oil way continuously rises. Under the pressure of the main oil way, the start-stop valve moves leftwards to push the steel ball to cut off the oil supply oil way of the plunger pump, and at the moment, the start-stop valve is withdrawn. After the plunger pump is stopped from starting and stopping, an oil drainage oil way is not provided for the plunger pump, oil drainage needs to be forced, and the pressure relief solenoid valve is started and stopped at a certain frequency to switch on and off, so that pressure relief is completed.

4) Electronic parking

the parking mechanical valve assembly comprises a switch valve and a feedback valve, wherein the parking electromagnetic valve is a locking electromagnetic valve, the force required by the action of a locking pin is less than 30N when the parking mechanical valve assembly is powered on, and the force required by the action of the locking pin is greater than 80N when the parking mechanical valve assembly is not powered on, the parking mechanical valve assembly is controlled by the switch valve S4.

And (3) P discharging process: the shifting safety valve and the shifting logic are controlled by switching on and off the switch valves S1 and S2, the main oil circuit is controlled to supply oil to the D-gear oil circuit, and the main oil circuit is cut off to supply oil to the P-gear oil circuit. And electrifying the switch valve S4, moving a switch valve spool leftwards under the control of the oil pressure at an outlet of the switch valve S4, filling oil into the hydraulic cylinder by the main oil line, pushing a piston of the hydraulic cylinder to move downwards after the hydraulic cylinder is filled with the oil, pushing the control shaft to enter a non-P gear, and releasing the P gear locking.

When the vehicle enters a non-P gear, S4 is powered off, the feedback valve in the parking mechanical valve component moves rightwards, and oil drainage is carried out on the oil pressure of the hydraulic cylinder. However, the parking piston (parking control shaft) is locked at the non-P-range position by the parking lock solenoid valve.

Entering P process (non-P gear): and the shifting safety valve and the shifting logic are controlled by switching on and off the switching valves S1 and S2, the main oil circuit is controlled to supply oil to the P-gear oil circuit, and the main oil circuit is cut off to supply oil to the non-P-gear oil circuit. Meanwhile, the parking electromagnetic valve is electrified, the force required by the action of the locking pin is smaller than 30N, the parking piston enters the P gear position under the action of the return spring force, then the parking electromagnetic valve is powered off, and the parking piston is locked at the P gear position.

The application does not relate to the improvement of other gear oil passages except for the P/R/N/D gear oil passage, so that the other gear oil passages except for the P/R/N/D gear oil passage are consistent with the traditional working oil passage switching method.

This embodiment is only illustrative of the patent and does not limit the scope of protection thereof, and those skilled in the art can make modifications to its part without departing from the spirit of the patent.

Claims

1. the hydraulic control oil circuit with the electronic gear shifting function for the automatic transmission is characterized by comprising a mechanical oil pump (1), a main pressure regulating valve (2), a pressure limiting valve (3), a TC regulating valve (4), a cooler bypass valve (5), a DCC valve (6), a parking logic valve (7), a start-stop control valve (8), a limp-home selection valve (9), a switch valve (10), a gear shifting safety valve A (11), a gear shifting safety valve B (12), an oil supply valve core (13), a solenoid valve S L (14), a solenoid valve S L TC (15), a solenoid valve S L C1(16), a solenoid valve S L C2(17), a solenoid valve S L C3(18), a solenoid valve S L C4(19), a solenoid valve S L B1(20), a solenoid valve S L B2(21), a solenoid valve S1(22), a solenoid valve S2(23), a solenoid valve S3), a solenoid valve S4(25), a solenoid valve S5(26) and a plunger;

the mechanical oil pump (1) is respectively communicated with a main pressure regulating valve (2), a pressure limiting valve (3), a TC regulating valve (4), a parking logic valve (7), a start-stop control valve (8), a shift safety valve B (12), a solenoid valve S L TC (15), a solenoid valve S L B (21) and a start-stop plunger pump (27) through oil passages, the main pressure regulating valve (2) is respectively communicated with a DCC valve (6) and a solenoid valve 0(14), the pressure limiting valve (3) is respectively communicated with a solenoid valve 1(14), a solenoid valve S (22), a solenoid valve S (23), a solenoid valve S (24), a solenoid valve S (25) and a solenoid valve S (26), the TC regulating valve (4) is respectively communicated with the DCC valve (6), the parking logic valve (7) and the solenoid valve TC2 (15), a coolor bypass valve (5) is respectively communicated with a valve (6), a limp selection valve (9) and a solenoid valve S (24), the DCC (9) and a solenoid valve core C (24), the clutch solenoid valve C (6) is respectively communicated with a clutch solenoid valve C24), the oil supply solenoid valve S24), the clutch solenoid valve (10), the clutch solenoid valve C24) is respectively communicated with a clutch solenoid valve C24, the oil supply solenoid valve S (17) and the oil supply solenoid valve (17), the oil supply solenoid valve (17) and the oil supply solenoid valve (17), the oil supply solenoid valve (17) 20), the oil supply solenoid valve S (17) 20, the oil supply solenoid valve S (17) and the oil supply solenoid valve S (17) 20, the safety valve S (17) are respectively communicated with the safety valve S (17) and the oil supply solenoid valve S (17, the safety valve S (17) and the oil supply solenoid valve S (17), the oil supply solenoid valve S (17) and the oil solenoid valve S (17) 20, the safety valve S (17) 20, the oil supply solenoid valve S (17) 20, the safety valve S (17) and the oil supply solenoid valve S (17) 20, the safety valve S (17) 20), the safety valve S (17) 20, the safety valve S (17) and the safety valve S (17) 20, the safety valve S (17) 20) and the oil supply solenoid valve S (17) 20, the safety valve S (17) are respectively, the safety valve S (17) 20, the safety valve S (17) and the safety valve S (17) 20, the safety valve S (17) and the safety valve S (17) 14.

2. The automatic transmission hydraulic control oil circuit with the electronic gear shifting function according to claim 1, characterized in that: and a start-stop relief valve (28) is arranged between the start-stop control valve (8) and the start-stop plunger pump (27).