CN206983966U - Double-rotor machine line traffic control brake fluid system - Google Patents

Abstract

The utility model discloses double-rotor machine line traffic control brake fluid system, during to overcome the braking pressure regulation of existing line traffic control brake fluid system due to time lag, braking response caused by motor positive and inverse switching slowly with during brake system non-functional the problem of stability difference, the system includes motor (A), brake unit (B) and ECU (C)；Motor (A) includes the first electromagnet (3), the second electromagnet (16), and motor (A) is realized by the brake master cylinder piston bar (29) of feed screw nut therein (8) and brake unit (B) and the connection of brake unit (B)；ECU (C) includes electronic control unit (56), electric machine controller (57) and solenoid valve controller (58).Terminals on electric machine controller (57) electrically connect with the first electromagnet (3), the second electromagnet (16) with the terminals of stator (13) respectively.ECU (C) and motor (A) are connected with brake unit (B) electric wire.

Description

Double-rotor machine line traffic control brake fluid system

Technical field

The utility model creates a kind of brake apparatus for belonging to brake system of car technical field.More specifically, this reality It is related to a kind of double-rotor machine line traffic control brake fluid system with new.

Background technology

Developing rapidly along with automobile industry at present, brake system of car are important as one in automobile chassis system Part also develops rapidly therewith.From traditional brake system of car using vacuum booster unit, gradually develop at present It can be applied to the line control brake system of electric car and intelligent vehicle.And line control brake system can be divided into mechanical brake-by-wire system System and fluid pressure type line control brake system.Wherein fluid pressure type line control brake system On-line Control is moved in system using relatively broad, its One braking motor of generally use realizes braking procedure in structure, and its advantage is can to realize master cylinder using braking motor braking Accurate increase and decrease pressure.But because braking motor needs itself generation rotating to switch when master cylinder increase and decrease crush-cutting changes, and motor Rotating has time interval when switching, sluggish so as to produce the regular hour when can make master cylinder increase and decrease pressure, causes braking procedure The loss of middle time, adds braking distance during braking, at the same motor positive and inverse switching the service life of motor is influenceed compared with Greatly, the service life of motor is made reduce.

Such as China Patent Publication No. CN104359099A, data of publication of application on January 28th, 2015, patented invention-creation Entitled " a kind of EHB ", the patent of invention disclose a kind of motor-driven EHB, The system contains the composition such as pedal simulator, ECU, automatically controlled Linear Moving Module, master cylinder, secondary master cylinder.This is System can realize the fast run-up pressure of master cylinder by the use of motor as power source, but due to having one when motor positive and inverse switches Fixed time interval, it can make to produce regular hour sluggishness during master cylinder increase and decrease pressure, add braking distance during braking, Er Qie electricity Machine can reduce life-span of motor in the state of being often operated in switching rotating, it can be seen that, some defects be present in the system.

The content of the invention

Technical problem to be solved in the utility model is to overcome the braking pressure regulation in existing line traffic control brake fluid system When due to time lag, braking response caused by motor positive and inverse switching it is slow, during brake system non-functional the problem of stability difference, if A kind of special double-rotor machine of line traffic control brake fluid system is counted, there is provided a kind of double-rotor machine line traffic control Hydraulic braking system System.

In order to solve the above technical problems, the utility model adopts the following technical scheme that realization：

Described double-rotor machine line traffic control brake fluid system includes motor, brake unit and ECU；

Described motor includes motor casing, the first fixing axle, the first electromagnet, the first shaft housing, the first rotor, the first star Wheel, the first outer ring, leading screw screw rod, ball, feed screw nut, the second outer ring, the second star-wheel, stator, the second rotor, the second axle housing Body, the second electromagnet, the second fixing axle, the first star-wheel spring, the first star-wheel fore-set, the first roller, the second star-wheel spring, second Star-wheel fore-set and the second roller；

Described stator is arranged in motor casing, to be fixedly connected between stator and motor casing, the first rotor, the first star Wheel, the first outer ring, leading screw screw rod, ball, feed screw nut, the second outer ring, the second star-wheel and the second rotor are sequentially arranged at stator Interior, the first rotor is located in the high order end of stator, and the right-hand member of the first rotor is fixedly connected with the left end of the first star-wheel, the first star-wheel Right-hand member be sleeved on feed screw nut left end and insert the first outer ring left end in, the right-hand member of the first outer ring is sleeved on feed screw nut Left end and be fixedly connected with feed screw nut, leading screw screw rod be arranged on feed screw nut in, ball is arranged on feed screw nut and leading screw Screw rod it is combined into spiral rolling track in, the right-hand member of the first shaft housing is fixedly connected with the left end of the first rotor, the first electromagnet It is sleeved on the first shaft housing, the right-hand member of the first fixing axle is arranged in the cylindrical groove of the first shaft housing, the first fixing axle Gap filling magnetic between the cylindrical groove of right-hand member and the first shaft housing, the left end of the first fixing axle with motor casing left side wall Side wall is fixedly connected at center, and the second outer ring, the second star-wheel and the second rotor are symmetrically mounted in the right-hand member of stator, the second axle Housing, the second electromagnet and the second fixing axle are symmetrically mounted at the right-hand member in motor casing, and the right-hand member of leading screw screw rod and braking are single The left end of brake master cylinder piston bar is fixedly connected in master cylinder in member；ECU and motor connect with brake unit electric wire Connect.

The rotation conllinear of stator (13) and motor casing described in technical scheme；First fixing axle, the first electromagnet, First shaft housing, the first rotor, the first star-wheel, the first outer ring, leading screw screw rod, feed screw nut, the second outer ring, the second star-wheel, Two rotors, the second shaft housing, the second electromagnet, the rotation conllinear of the second fixing axle and stator.

The second outer ring, the second star-wheel and the second rotor described in technical scheme are symmetrically mounted in the right-hand member of stator, The right-hand member that second shaft housing, the second electromagnet are symmetrically mounted at the second fixing axle in motor casing refers to：

The second described rotor is located in the low order end of stator, and the right-hand member of bitrochanteric left end and the second star-wheel, which is fixed, to be connected Connect, the left end of the second star-wheel is sleeved on the right-hand member of feed screw nut and inserted in the right-hand member of the second outer ring, the left end set of the second outer ring Mounted in feed screw nut right-hand member and be fixedly connected with feed screw nut；The left end of second shaft housing and bitrochanteric right-hand member are fixed and connected Connecing, on the second shaft housing, the left end of the second fixing axle is arranged in the cylindrical groove of the second shaft housing the second electromagnet sleeve, Gap filling magnetic between the cylindrical groove of the left end of second fixing axle and the second shaft housing, right-hand member and the electricity of the second fixing axle It is fixedly connected at the medial center of casing right side wall, the right-hand member of the second star-wheel, the second rotor, the second shaft housing and the second fixing axle On the brake master cylinder piston bar for the master cylinder being sleeved in brake unit.

Brake master cylinder piston bar in master cylinder in the right-hand member and brake unit of leading screw screw rod described in technical scheme Left end be fixedly connected and refer to：Axially disposed at described leading screw screw rod right-hand member center to have a blind round hole, the circle is blind Hole is equal with the cylindrical lip diameter of the brake master cylinder piston bar left end in master cylinder, the cylinder of brake master cylinder piston bar left end Flange is fitted into the blind round hole of leading screw screw rod right-hand member, between the two to be fixedly connected.

Brake unit described in technical scheme also includes brake pedal, pedal displacement sensor, pedal simulation cylinder, oil It is case, the first check valve, the second check valve, the first normally closed solenoid valve, the second normally closed solenoid valve, the first normally open solenoid valve, second normal It is open electromagnetic valve, the 3rd normally open solenoid valve, the 4th normally open solenoid valve, the 5th normally open solenoid valve, the 6th normally open solenoid valve, the 3rd normally closed Magnetic valve, the 4th normally closed solenoid valve, the 5th normally closed solenoid valve, the 6th normally closed solenoid valve, first pressure sensor, second pressure pass Sensor, the 3rd pressure sensor, the 4th pressure sensor, left front wheel cylinder, left back wheel cylinder, off-front wheel cylinder and off hind wheel cylinder.

The described oil inlet of master cylinder first is connected with the oil-out of the first check valve using fluid pressure line, braking master The oil inlet of cylinder second is connected with the oil-out of the second check valve using fluid pressure line, and oil inlet and the fuel tank of the first check valve are adopted It is connected with fluid pressure line, the oil inlet of the second check valve is connected with fuel tank using fluid pressure line；The oil-out of master cylinder first with The Single port of first normally closed solenoid valve is connected using fluid pressure line；The oil-out of master cylinder second and the second normally closed solenoid valve Single port is connected using fluid pressure line；The another port of first normally closed solenoid valve and the another port of the first normally open solenoid valve, Fluid pressure line connection is respectively adopted in the Single port of three normally open solenoid valves, the Single port of the 4th normally open solenoid valve；Second normally closed electromagnetism The another port of valve and the another port of the second normally open solenoid valve, the Single port of the 5th normally open solenoid valve, the 6th normally open solenoid valve Single port fluid pressure line be respectively adopted be connected；The Single port of first normally open solenoid valve, the second normally open solenoid valve Single port and Pedal simulation cylinder oil-out on pedal simulation cylinder is connected using fluid pressure line；The another port and the 3rd of 3rd normally open solenoid valve The Single port of normally closed solenoid valve, left front wheel cylinder are respectively adopted fluid pressure line and are connected；The another port of 4th normally open solenoid valve and The Single port of four normally closed solenoid valves, left back wheel cylinder are respectively adopted fluid pressure line and are connected；The another port of 5th normally open solenoid valve and Single port, the off-front wheel cylinder of 5th normally closed solenoid valve are respectively adopted fluid pressure line and are connected；The other end of 6th normally open solenoid valve Mouth is respectively adopted fluid pressure line with Single port, the off hind wheel cylinder of the 6th normally closed solenoid valve and is connected；The 3rd described normally closed solenoid valve Another port, the another port of the 4th normally closed solenoid valve, another port and the 6th normally closed solenoid valve of the 5th normally closed solenoid valve Another port fluid pressure line be respectively adopted be connected with fuel tank.

Described first pressure sensor is arranged in the fluid pressure line between the 3rd normally open solenoid valve and left front wheel cylinder, the Two pressure sensors are arranged in the fluid pressure line between the 4th normally open solenoid valve and left back wheel cylinder, the installation of the 3rd pressure sensor In fluid pressure line between the 5th normally open solenoid valve and off-front wheel cylinder, the 4th pressure sensor is arranged on the 6th normally open solenoid valve In fluid pressure line between off hind wheel cylinder.

Pedal simulation cylinder described in technical scheme includes pedal simulation cylinder piston rod, pedal simulation cylinder cylinder body, pedal mould Intend cylinder first piston, pedal simulation cylinder second piston and pedal simulation cylinder groups of springs.Described pedal simulation cylinder first piston with Pedal simulation cylinder second piston is arranged in pedal simulation cylinder cylinder body, and pedal simulation cylinder first piston is located at pedal simulation cylinder second The right side of piston, pedal simulation cylinder first piston, pedal simulation cylinder second piston and the axis of rotation of pedal simulation cylinder cylinder body are total to Line, the pedal simulation cylinder second piston that pedal simulation cylinder is located therein are divided into I from left to right with pedal simulation cylinder first piston Chamber, II chamber, III chamber, I chamber and III chamber of master cylinder be do not contain hydraulic oil without sap cavity, II chamber contains hydraulic oil for inside There is sap cavity, pedal simulation cylinder groups of springs is located at I intracavitary of pedal simulation cylinder, and the left end of pedal simulation cylinder groups of springs is simulated with pedal It is fixedly connected at the left side wall medial center of cylinder cylinder body, the right-hand member and pedal simulation cylinder second piston of pedal simulation cylinder groups of springs are left Connection is contacted at side wall center；A pedal simulation cylinder oil-out is provided with pedal simulation cylinder cylinder body in pedal simulation cylinder, Pedal is simulated cylinder oil-out and connected with II chamber of pedal simulation cylinder.

Pedal simulation cylinder groups of springs described in technical scheme is made up of the spring of three different lengths and different-stiffness, institute There is spring left end to be fixedly connected with pedal simulation cylinder cylinder body left side wall medial center.

Master cylinder described in technical scheme also includes master cylinder body, master cylinder first piston, master cylinder First spring, master cylinder second piston and master cylinder second spring；Described master cylinder first piston, master cylinder One spring, master cylinder second piston and master cylinder second spring are arranged in master cylinder body from left to right successively, Master cylinder first piston, the spring of master cylinder first, master cylinder second piston, master cylinder second spring and master cylinder The rotation conllinear of cylinder body, master cylinder first piston that master cylinder is located therein and master cylinder second piston are from a left side It is divided into I chamber, II chamber, III chamber to the right side, I chamber of master cylinder is not contain containing without sap cavity, II chamber, III chamber for intracavitary portion for hydraulic oil There is hydraulic oil to have sap cavity；

The right-hand member of described brake master cylinder piston bar is made with being fixedly connected at the left side center of master cylinder first piston One end of the dynamic spring of master cylinder first at the right side center of master cylinder first piston with being fixedly connected, the spring of master cylinder first The other end with being fixedly connected at the left side center of master cylinder second piston, one end of master cylinder second spring and braking It is fixedly connected at the right side center of master cylinder second piston, the other end at master cylinder body right side wall medial surface center with fixing Connection.

Be provided with master cylinder body described in technical scheme the two oil inlets i.e. oil inlet of master cylinder first with The oil inlet of master cylinder second, the oil inlet of master cylinder first connect with II chamber of master cylinder, the oil inlet of master cylinder second Connected with III chamber of master cylinder；The two oil-outs i.e. oil-out of master cylinder first and braking are provided with master cylinder body The oil-out of master cylinder second, the oil-out of master cylinder first connect with II chamber of master cylinder；The oil-out of master cylinder second and system The III chamber connection of dynamic master cylinder.

The beneficial effects of the utility model are compared with prior art：

1. the motor part of double-rotor machine line traffic control brake fluid system described in the utility model turns using single stator is double Minor structure, when motor rotates forward, forward current is connected to stator, locked second rotor, makes the first rotor externally export power, Only need to be to stator turn-on reversal electric current when motor commutation, while locked the first rotor makes the second rotor start working externally defeated Go out power, the motor in the system is not present time lag caused by rotor rotating switching, therefore the braking response of the system Property is higher, and braking time greatly shortens.

2. the motor part of double-rotor machine line traffic control brake fluid system described in the utility model eliminates conventional motor The structure of additional multiple clutches needed for commutation, the reversing work of motor is realized by the effect of different parts in motor internal Can, its integration is higher and small volume.

3. double-rotor machine line traffic control brake fluid system described in the utility model is not waited firm by using three Length discrepancies The spring of degree, simulated with this to produce good pedal sense, therefore it can bring the good pedal sense feedback of driver.

4. double-rotor machine line traffic control brake fluid system described in the utility model is powered by using normally open solenoid valve and closed Close to realize the full decoupling of brake pedal and four wheel cylinders, so that caused hydraulic pressure fluctuation of the wheel in braking procedure It will not be transferred to impact at driver, comfortableness and stability of the lifting driver in braking procedure.

5. double-rotor machine line traffic control brake fluid system described in the utility model can pass through electronic control unit (ECU) instructed to electric machine controller transmission, electric machine controller is carried out accuracy controlling to motor, realize to the accurate of brake pressure Control.

6. double-rotor machine line traffic control brake fluid system described in the utility model disclosure satisfy that existing conventional brake, Full wheel under the various workings such as ABS, TCS, ESC, ACC, AEB is braked simultaneously and the requirement of single-wheel braking, and its application is very Extensively, prospect is preferable.

7. double-rotor machine line traffic control brake fluid system described in the utility model is when its brakes power-off failure, energy Brake pedal is stepped on by driver to realize automobile brake, therefore the stability of this brakes is preferable.

Brief description of the drawings

The utility model is further described below in conjunction with the accompanying drawings：

Fig. 1 is the schematic block diagram of double-rotor machine line traffic control brake fluid system structure composition described in the utility model；

Fig. 2 is the ECU structure employed in double-rotor machine line traffic control brake fluid system described in the utility model The schematic block diagram of composition；

Fig. 3 is the electric machine structure composition employed in double-rotor machine line traffic control brake fluid system described in the utility model Front view；

Fig. 4-1 is the sectional view at D-D in Fig. 3；

Fig. 4-2 is the partial enlarged view at I in Fig. 4-1；

Fig. 5-1 is the sectional view at E-E in Fig. 3；

Fig. 5-2 is the partial enlarged view at II in Fig. 5-1；

Fig. 6 is boost fluid under the conventional brake operating mode of double-rotor machine line traffic control brake fluid system described in the utility model Lu Tu；

Fig. 7 is to depressurize liquid under the conventional brake operating mode of double-rotor machine line traffic control brake fluid system described in the utility model Lu Tu；

Fig. 8 is to be pressurized fluid path figure under the ABS operating modes of double-rotor machine line traffic control brake fluid system described in the utility model；

Fig. 9 is pressurize fluid path figure under the ABS operating modes of double-rotor machine line traffic control brake fluid system described in the utility model；

Figure 10 is to depressurize fluid path under the ABS operating modes of double-rotor machine line traffic control brake fluid system described in the utility model Figure；

Figure 11 is the near front wheel single-wheel under the TCS operating modes of double-rotor machine line traffic control brake fluid system described in the utility model It is pressurized fluid path figure；

Figure 12 is the near front wheel single-wheel under the TCS operating modes of double-rotor machine line traffic control brake fluid system described in the utility model Depressurize fluid path figure；

Figure 13 is the increasing under the power-off failure pattern of double-rotor machine line traffic control brake fluid system described in the utility model Hydraulic fluid road figure；

Figure 14 is subtracting under the power-off failure pattern of double-rotor machine line traffic control brake fluid system described in the utility model Hydraulic fluid road figure.

In figure：1. motor casing, 2. first fixing axles, 3. first electromagnet, 4. first shaft housings, 5. the first rotors, 6. One star-wheel, 7. first outer rings, 8. leading screw screw rods, 9. balls, 10. feed screw nuts, 11. second outer rings, 12. second star-wheels, 13. is fixed Son, 14. second rotors, 15. second shaft housings, 16. second electromagnet, 17. second fixing axles, 18. brake pedals, 19. pedals Displacement transducer, 20. pedals simulation cylinder piston rod, 21. pedals simulation cylinder cylinder body, 22. pedals simulation cylinder first piston, 23. step on Template die plan cylinder, 24. pedals simulation cylinder second piston, 25. pedals simulation cylinder groups of springs, 26. fuel tanks, 27. first check valves, 28. Second check valve, 29. brake master cylinder piston bars, 30. master cylinders, 31. master cylinder bodies, 32. master cylinders first are lived Plug, 33. the first springs of master cylinder, 34. master cylinder second pistons, 35. master cylinder second springs, 36. first normally closed electricity Magnet valve, 37. second normally closed solenoid valves, 38. first normally open solenoid valves, 39. second normally open solenoid valves, 40. the 3rd normally opened electromagnetism Valve, 41. the 4th normally open solenoid valves, 42. the 5th normally open solenoid valves, 43. the 6th normally open solenoid valves, 44. the 3rd normally closed solenoid valves, 45. the 4th normally closed solenoid valve, 46. the 5th normally closed solenoid valves, 47. the 6th normally closed solenoid valves, 48. first pressure sensors, 49. Second pressure sensor, 50. the 3rd pressure sensors, 51. the 4th pressure sensors, 52. left front wheel cylinders, 53. left back wheel cylinders, 54. off-front wheel cylinder, 55. off hind wheel cylinders, 56. electronic control units (ECU), 57. electric machine controllers, 58. solenoid valve controllers, 59. the first star-wheel spring, 60. first star-wheel fore-sets, 61. first rollers, 62. second star-wheel springs, 63. second star-wheel fore-sets, 64. the second roller, 65. the first oil inlets of master cylinder, 66. the second oil inlets of master cylinder, 67. master cylinders first are fuel-displaced Mouthful, 68. the second oil-outs of master cylinder, 69. pedals simulation cylinder oil-out, A. motors, B. brake units, C. ECUs.

Embodiment

The utility model is explained in detail below in conjunction with the accompanying drawings：

Refering to Fig. 1, double-rotor machine line traffic control brake fluid system described in the utility model includes motor A, brake unit B With ECU C.

Refering to Fig. 3, described motor A includes motor casing 1, the first fixing axle 2, the first electromagnet 3, the first shaft housing 4, the One rotor 5, the first star-wheel 6, the first outer ring 7, leading screw screw rod 8, ball 9, feed screw nut 10, the second outer ring 11, the second star-wheel 12, Stator 13, the second rotor 14, the second shaft housing 15, the second electromagnet 16, the second fixing axle 17, the first star-wheel spring 59, first Star-wheel fore-set 60, the first roller 61, the second star-wheel spring 62, the second star-wheel fore-set 63 and the second roller 64.

Described motor casing 1 is a cylindrical housings, and motor casing 1 is fixedly connected with automobile frame, ensures that it works in motor A Middle position immobilizes.

The first described fixing axle 2 is two sections of multi-diameter shafts, and the diameter of its right section of axle is more than the diameter of left section of axle；First fixes The inner surface of the left end of axle 2 and the left side wall of motor casing 1 is fixedly connected with, and ensures that it immobilizes position in motor A work.

The first described shaft housing 4 is a circular shell, and a cylindrical groove is machined with the center of the first shaft housing 4, circle Left cell wall through hole is provided with the center of the left cell wall of cylindrical groove, left cell wall through-hole diameter is more than left section of axle in the first fixing axle 2 Diameter, cylindrical groove diameter is more than the diameter of right section of axle of the first fixing axle 1, and the width of cylindrical groove is more than the first fixing axle The width of right section of axle in 1.Right section of axle of the first fixing axle 1 is arranged in the cylindrical groove of the first shaft housing 4, and the first shaft housing 4 and first fixing axle 1 rotation conllinear, between right section of axle of the first fixing axle 1 and the cylindrical groove of the first shaft housing 4 Magnetic is filled in gap (as shown in grid lines in Fig. 3).External splines is machined with the right-hand member outer circumference surface of first shaft housing 4, the Connected between the right-hand member external splines of one shaft housing 4 and the left end internal spline of the first rotor 5 using spline, to ensure therebetween Enough passing powers.

The first described electromagnet 3 is enclosed on the periphery of the first shaft housing 4, and is connected with the first shaft housing 4.

The inside of described the first rotor 5 is machined with internal spline, the right-hand member internal spline of the first rotor 5 and the first star-wheel 6 Connected between left end external splines using spline, therebetween being capable of passing power with guarantee.

Refering to Fig. 4-1 and Fig. 4-2, the structure sectional view of the first described star-wheel 6 is as shown in figure 4, the left end of the first star-wheel 6 External splines is machined with outer circumference surface, four wedge-shaped slots are evenly equipped with the first star-wheel 6, each wedge-shaped trench bottom is provided with a circle Groove, a first star-wheel spring 59 is placed with circular groove, its one end is connected with the first star-wheel 6, the other end and the first star Take turns fore-set 60 to be connected, first roller 61 is disposed between each first star-wheel fore-set 60 and the first outer ring 7.

The effect of the first described star-wheel spring 59 is when being rotated backward in 6 relative first outer ring 7 of the first star-wheel, to pass through pressure First roller 61 is pressed into narrower one end of wedge shape space between the first star-wheel 6 and the first outer ring 7 by tight first star-wheel fore-set 60, makes When first star-wheel 6 and the first outer ring 7 can realize that 6 relative first outer ring 7 of the first star-wheel rotates backward by the first roller 61 Power transmission.When 6 relative first outer ring 7 of the first star-wheel rotates forward, the first roller 61 is compressed by the first star-wheel fore-set 60 First star-wheel spring 59, so that the wedge shape space that the first roller 61 enters between the first star-wheel 6 and the first outer ring 7 is wider by one End, makes the first star-wheel 6, the first outer ring 7 no longer be contacted with the first roller 61, realizes that 6 relative first outer ring 7 of the first star-wheel is positive and turns The first star-wheel 6 when dynamic separates with the motion of the first outer ring 7.So as to realize that one-way movement transmission acts on.

The first described outer ring 7 is connected with the left end of feed screw nut 10, and connected mode can use key connection or spline to connect Connect, therebetween being capable of passing power with guarantee.

The described inner surface of feed screw nut 10 is machined with circular arc helicla flute, and the outer surface of leading screw screw rod 8 is machined with circular arc Shape helicla flute.Feed screw nut 10 is set in together the spiral rolling track to form circle cross-section with leading screw screw rod 8.

Described ball 9 is arranged in the spiral rolling track of the circle cross-section between feed screw nut 10 and leading screw screw rod 8, and edge The spiral rolling track for circle cross-section rolls.

Described feed screw nut 10 cooperatively forms ball guide screw nat by ball 9 and leading screw screw rod 8.Pass through the ball Screw pair, the straight line that the rotary motion of feed screw nut 10 can be converted to leading screw screw rod 8 by the rolling of ball 9 are transported It is dynamic, realize the conversion of power form and the transmission of power.

The right-hand member of described leading screw screw rod 8 is connected with the left end of brake master cylinder piston bar 29, and connected mode is leading screw screw rod 8 A blind round hole, the blind round hole and the left end of brake master cylinder piston bar 29 in master cylinder 30 are provided with right-hand member center Cylindrical lip is engaged connected, allows leading screw screw rod 8 to promote brake master cylinder piston bar 29 to move right, realizes the biography of power Pass.

The second described fixing axle 17 is two sections of multi-diameter shafts, and the diameter of its left section of axle is more than the diameter of right section of axle；Second is solid The inner surface of the right-hand member of dead axle 17 and the right side wall of motor casing 1 is fixedly connected with, and ensures that it immobilizes position in motor work.

The second described shaft housing 15 is a circular shell, and a cylindrical groove is machined with the center of the second shaft housing 15, Right cell wall through hole is provided with the center of the right cell wall of cylindrical groove, right cell wall through-hole diameter is more than in the second fixing axle 17 right section The diameter of axle, cylindrical groove diameter are more than the diameter of left section of axle of the second fixing axle 17, and the width of cylindrical groove is more than second and consolidated The width of left section of axle in dead axle 17.Left section of axle of the second fixing axle 17 is arranged in the cylindrical groove of the second shaft housing 15, and the The rotation conllinear of two shaft housings 15 and the second fixing axle 17, left section of axle of the second fixing axle 17 and the second shaft housing 15 Magnetic is filled in gap between cylindrical groove (as shown in grid lines in Fig. 3).On the left end outer circumference surface of second shaft housing 15 External splines is machined with, is connected between the left end external splines of the second shaft housing 15 and the right-hand member internal spline of the second rotor 14 using spline Connect, therebetween being capable of passing power with guarantee.

The second described electromagnet 16 is enclosed on the periphery of the second shaft housing 15, and passes through interference fit with the second shaft housing 15 It is connected.

The inside of the second described rotor 14 is machined with internal spline, the left end internal spline of the second rotor 14 and the second star-wheel 12 Right-hand member external splines between use spline connection so that ensure therebetween being capable of passing power.

Refering to Fig. 5-1 and Fig. 5-2, the structure sectional view figure of the second described star-wheel 12 as shown in FIG., the second star-wheel 12 Right-hand member outer circumference surface on be machined with external splines, four wedge-shaped slots are evenly equipped with the second star-wheel 12, each wedge-shaped trench bottom is provided with One circular groove, a second star-wheel spring 62 is placed with circular groove, its one end is connected with the second star-wheel 12, the other end It is connected with the second star-wheel fore-set 63, second roller is disposed between each second star-wheel fore-set 63 and the second outer ring 11 64。

The effect of the second described star-wheel spring 62 is when being rotated forward in 12 relative second outer ring 11 of the second star-wheel, to pass through It is narrower by one to compress the wedge shape space that the second roller 64 is pressed between the second star-wheel 12 and the second outer ring 11 by the second star-wheel fore-set 63 End, the second star-wheel 12 and the second outer ring 11 is set to realize that 12 relative second outer ring 11 of the second star-wheel is positive by the second roller 64 Power transmission during rotation.When 12 relative second outer ring 11 of the second star-wheel rotates backward.Second roller 64 passes through the second star-wheel Fore-set 63 compresses the second star-wheel spring 62, so that the wedge that the second roller 64 enters between the second star-wheel 12 and the second outer ring 11 The wider one end in shape space, the second star-wheel 12, the second outer ring 11 is no longer contacted with the second roller 64, realize that the second star-wheel 12 is relative The second star-wheel 12 when second outer ring 11 rotates backward separates with the motion of the second outer ring 11.Make so as to realize that one-way movement is transmitted With.

The second described outer ring 11 is connected with the right-hand member of feed screw nut 10, and connected mode can use key connection or spline to connect Connect, therebetween being capable of passing power with guarantee.

Motor A operation principle is：

When electronic control unit (ECU) 56 sends rotor to motor A rotates forward instruction, now electric machine controller 57 is controlled Stator 13 in motor A processed, which produces, makes the positive magnetic field that rotor rotates forward；The first electromagnet 3, which is powered, simultaneously makes the first fixing axle The magnetic filled in gap between the cylindrical groove of 1 right-hand member and the first shaft housing 4 is made due to the magnetic field of the first electromagnet 3 Among being covered with gap under, make the first fixing axle 1 synchronous with the motion of the first shaft housing 4, because the position of the first fixing axle 1 is fixed Motionless, so the locked and then coupled the first rotor 5 of the first shaft housing 4 can not be rotated by locked, now motor A is another Second rotor 14 of one end can be rotated forward because the second electromagnet 16 is not powered, and second is driven by the second rotor 14 Star-wheel 12 is rotated, and due to the single-direction transmission effect between the second star-wheel 12 and the second outer ring 11, the second star-wheel 12 is driven outside second Circle 11 rotates forward, and the second outer ring 11 drives feed screw nut 10 to rotate forward, and by the transmission of ball 9, makes leading screw screw rod 8 to the right It is mobile, there is provided for the power of master cylinder supercharging.

When electronic control unit (ECU) 56 sends rotor to motor A rotates backward instruction, now electric machine controller 57 is controlled Stator 13 in motor A processed produces the opposing magnetic field for reversely rotating rotor；The second electromagnet 16, which is powered, simultaneously makes the second fixation The magnetic filled in gap between the cylindrical groove of the left end of axle 17 and the second shaft housing 15 is due to the second electromagnet 16 It is covered with magnetic fields among gap, makes the second fixing axle 17 synchronous with the motion of the second shaft housing 15, due to the second fixing axle 17 positions are fixed, so locked and then coupled the second rotor 14 of the second shaft housing 15 is gradually slowed down by locked To stopping, now the first electromagnet 3 power-off of the motor other end makes the first rotor 5 affranchise state, and the first rotor 5 is due to fixed Start to reversely rotate in the presence of the opposing magnetic field of son 13, drive the first star-wheel 6 to rotate by the first rotor 5, due to the first star Single-direction transmission effect between the outer ring 7 of wheel 6 and first, the first star-wheel 6 drive the first outer ring 7 to reversely rotate, the band of the first outer ring 7 Dynamic feed screw nut 10 reversely rotates, and by the transmission of ball 9, is moved to the left leading screw screw rod 8, there is provided for master cylinder decompression Power.

Described brake unit B includes brake pedal 18, pedal displacement sensor 19, pedal simulation cylinder 23, fuel tank 26, the One check valve 27, the second check valve 28, master cylinder 30, the first normally closed solenoid valve 36, the second normally closed solenoid valve 37, first are normally opened Magnetic valve 38, the second normally open solenoid valve 39, the 3rd normally open solenoid valve 40, the 4th normally open solenoid valve 41, the 5th normally open solenoid valve 42nd, the 6th normally open solenoid valve 43, the 3rd normally closed solenoid valve 44, the 4th normally closed solenoid valve 45, the 5th normally closed solenoid valve the 46, the 6th are normal Close magnetic valve 47, first pressure sensor 48, second pressure sensor 49, the 3rd pressure sensor 50, the 4th pressure sensor 51st, left front wheel cylinder 52, left back wheel cylinder 53, off-front wheel cylinder 54 and off hind wheel cylinder 55.

The right-hand member of described brake pedal 18 and pedal simulation cylinder piston rod 20 is fixedly connected with, and pedal displacement sensor 19 is installed On pedal simulation cylinder piston rod 20, the function of pedal displacement sensor 19 monitors the shift value of brake pedal 18 in real time, and will The displacement signal of brake pedal 18 passes to electronic control unit (ECU) 56.

Described pedal simulation cylinder 23 includes pedal simulation cylinder piston rod 20, pedal simulation cylinder cylinder body 21, pedal simulation cylinder First piston 22, pedal simulation cylinder second piston 24 and pedal simulation cylinder groups of springs 25.

Described pedal simulation cylinder first piston 22 is arranged on pedal simulation cylinder cylinder body with pedal simulation cylinder second piston 24 In 21, pedal simulation cylinder first piston 22 positioned at the right side of pedal simulation cylinder second piston 24, pedal simulation cylinder first piston 22, Pedal simulation cylinder second piston 24 and the rotation conllinear of pedal simulation cylinder cylinder body 21, pedal simulation cylinder 23 are located therein Pedal simulation cylinder first piston 22 and pedal simulation cylinder second piston 24 are divided into I chamber, II chamber, III chamber from left to right.Master cylinder 30 I chamber and III chamber are without sap cavity, do not contain hydraulic oil；For II chamber to there is sap cavity, hydraulic oil is contained in inside.Pedal simulates cylinder spring Group 25 is positioned at I intracavitary of pedal simulation cylinder 23, left end and the left side wall of pedal simulation cylinder cylinder body 21 of pedal simulation cylinder groups of springs 25 It is fixedly connected at medial center, the right-hand member of pedal simulation cylinder groups of springs 25 at the Left-side center of pedal simulation cylinder second piston 24 with connecing Touch connection.

Described pedal simulation cylinder groups of springs 25 is made up of the spring of three different lengths and different-stiffness, and all springs are left End is fixedly connected with the left side wall medial center of pedal simulation cylinder cylinder body 21, and the length and rigidity of each spring are by be realized Pedal sense simulation strategy select, it act as：When driver steps on drive pedal 18, due to pedal simulation cylinder 23 II intracavitary has liquid closing wherein, can only the pedal simulation cylinder groups of springs 25 of I intracavitary of compression pedal simulation cylinder 23 realize fortune Dynamic, pedal simulation cylinder groups of springs 25 produces elastic resistance due to producing elastic deformation by compression, and the elastic resistance feeds back to braking Realize that pedal sense is simulated on pedal 18, simultaneously because the length and rigidity of three springs in pedal simulation cylinder groups of springs 25 are not Deng, it is possible to achieve brake pedal 18 is in the asynchronous different resistance feedbacks of displacement, the validity of increase pedal sense simulation.

There is an oil-out, i.e. pedal simulation cylinder goes out on pedal simulation cylinder cylinder body 21 in described pedal simulation cylinder 23 Hydraulic fluid port 69.Pedal simulation cylinder oil-out 69 connects with II chamber of pedal simulation cylinder 23.It is normal that pedal simulates cylinder oil-out 69 and first One end of open electromagnetic valve 38, one end of the second normally open solenoid valve 39 are connected by fluid pressure line.

Described master cylinder 30 includes brake master cylinder piston bar 29, master cylinder body 31, master cylinder first piston 32nd, the first spring of master cylinder 33, master cylinder second piston 34 and master cylinder second spring 35.

Described master cylinder first piston 32, the first spring of master cylinder 33, master cylinder second piston 34 and braking Master cylinder second spring 35 is arranged in master cylinder body 31 from left to right successively, master cylinder first piston 32, braking master The first spring of cylinder 33, master cylinder second piston 34, master cylinder second spring 35 and the axis of rotation of master cylinder body 31 Collinearly, the master cylinder first piston 32 that master cylinder 30 is located therein is divided into from left to right with master cylinder second piston 34 I chamber, II chamber, III chamber.I chamber of master cylinder 30 is not contain hydraulic oil without sap cavity, i.e. I chamber；II chamber, III chamber is have sap cavity, i.e., Hydraulic oil is contained in II chamber and III chamber intracavitary portion.

The right-hand member of described brake master cylinder piston bar 29 with being connected at the left side center of master cylinder first piston 32, Connected mode can use the conventional machinery attachment structures such as flange connection or threaded connection.One end of the first spring of master cylinder 33 with It is fixedly connected at the right side center of master cylinder first piston 32, in the left side of the other end and master cylinder second piston 34 It is fixedly connected at the heart.One end of master cylinder second spring 35 and the company of fixation at the right side center of master cylinder second piston 34 Connect, the other end at the right side wall medial surface center of master cylinder body 31 with being fixedly connected.

Two oil inlets i.e. the first oil inlet of master cylinder 65 is provided with described master cylinder body 31 to lead with braking The second oil inlet of cylinder 66, the first oil inlet of master cylinder 65 connect with II chamber of master cylinder 30；The oil inlet of master cylinder second 66 connect with III chamber of master cylinder 30.The two oil-outs i.e. oil-out of master cylinder first is provided with master cylinder body 31 67 connect with the second oil-out of master cylinder 68, the first oil-out of master cylinder 67 with II chamber of master cylinder 30；Master cylinder Second oil-out 68 connects with III chamber of master cylinder 30.

Described the first oil inlet of master cylinder 65 is connected with the oil-out of the first check valve 27 using fluid pressure line, system The second oil inlet of dynamic master cylinder 66 is connected with the oil-out of the second check valve 28 using fluid pressure line, the oil-feed of the first check valve 27 Mouth is connected with fuel tank 26 using fluid pressure line, and the oil inlet of the second check valve 28 is connected with fuel tank 26 using fluid pressure line.Braking The first oil-out of master cylinder 67 is connected with the Single port of the first normally closed solenoid valve 36 using fluid pressure line；Master cylinder second is fuel-displaced Mouth 68 is connected with the Single port of the second normally closed solenoid valve 37 using fluid pressure line；The another port of first normally closed solenoid valve 36 and the The another port of one normally open solenoid valve 38, the Single port of the 3rd normally open solenoid valve 40, the Single port point of the 4th normally open solenoid valve 41 Cai Yong not fluid pressure line connection；The another port of the another port of second normally closed solenoid valve 37 and the second normally open solenoid valve 39, the Single port, the Single port of the 6th normally open solenoid valve 43 of five normally open solenoid valves 42 are respectively adopted fluid pressure line and are connected, and first is normally opened Pedal simulation cylinder oil-out 69 on the Single port of magnetic valve 38, the Single port of the second normally open solenoid valve 39 and pedal simulation cylinder 23 Connected using fluid pressure line；The another port of 3rd normally open solenoid valve 40 and Single port, the near front wheel of the 3rd normally closed solenoid valve 44 Cylinder 52 is respectively adopted fluid pressure line and is connected.The another port of 4th normally open solenoid valve 41 and one end of the 4th normally closed solenoid valve 45 Mouth, left back wheel cylinder 53 are respectively adopted fluid pressure line and are connected.The another port of 5th normally open solenoid valve 42 and the 5th normally closed solenoid valve 46 Single port, off-front wheel cylinder 54 are respectively adopted fluid pressure line and are connected.The another port and the 6th of 6th normally open solenoid valve 43 Single port, the off hind wheel cylinder 55 of normally closed solenoid valve 47 are respectively adopted fluid pressure line and are connected.The 3rd described normally closed solenoid valve 44 Another port, the another port of the 4th normally closed solenoid valve 45, another port and the 6th normally closed electromagnetism of the 5th normally closed solenoid valve 46 The another port of valve 47 is respectively adopted fluid pressure line and is connected with fuel tank 26.

Described first pressure sensor 48 is arranged on the hydraulic tube between the 3rd normally open solenoid valve 40 and left front wheel cylinder 52 Lu Zhong, it is the pressure value for monitoring left front wheel cylinder 52 in real time that it, which is acted on, it is ensured that brake pressure precision.Described second pressure sensor 49 are arranged in the fluid pressure line between the 4th normally open solenoid valve 41 and left back wheel cylinder 53, and its effect is to monitor left back wheel cylinder in real time 53 pressure value, it is ensured that brake pressure precision.The 3rd described pressure sensor 50 is arranged on the 5th normally open solenoid valve 42 and the right side In fluid pressure line between preceding wheel cylinder 54, it is the real-time pressure value for monitoring off-front wheel cylinder 54 that it, which is acted on, it is ensured that brake pressure precision. The 4th described pressure sensor 51 is arranged in the fluid pressure line between the 6th normally open solenoid valve 43 and off hind wheel cylinder 55, and it is made With the pressure value for being real-time monitoring off hind wheel cylinder 55, it is ensured that brake pressure precision.

Refering to Fig. 2, described ECU C includes electronic control unit (ECU) 56, electric machine controller 57 and magnetic valve Controller 58.Corresponding terminals on electronic control unit (ECU) 56 sense with pedal displacement sensor 19, first pressure respectively Device 48, second pressure sensor 49, the 3rd pressure sensor 50, the 4th pressure sensor 51, electric machine controller 57 and magnetic valve Respective terminal electrical connection on controller 58.Corresponding terminals on solenoid valve controller 58 respectively with the first normally closed solenoid valve 36th, the second normally closed solenoid valve 37, the 3rd normally closed solenoid valve 44, the 4th normally closed solenoid valve 45, the 5th normally closed solenoid valve the 46, the 6th Normally closed solenoid valve 47, the first normally open solenoid valve 38, the second normally open solenoid valve 39, the 3rd normally open solenoid valve 40, the 4th normally opened electromagnetism Valve 41, the 5th normally open solenoid valve 42 electrically connect with the respective terminal of electromagnet on the 6th normally open solenoid valve 43.Electric machine controller Corresponding terminals on 57 electrically connect with the first electromagnet 3, the second electromagnet 16 with the respective terminal on stator 13 respectively. Electrical connection is as shown in short dash line in Fig. 2.

Principle and the course of work of the present utility model are as follows：

1. pressurization under conventional brake operating mode：

Refering to Fig. 6, when driver steps on brake pedal 18, the pedal position on brake pedal simulation cylinder piston rod 20 Displacement sensor 19 detects the shift value of brake pedal 18, and sends displacement signal to electronic control unit (ECU) 56, electronics Control unit (ECU) 56 sends control command by calculating with analyzing to electric machine controller 57 and solenoid valve controller 58.

Solenoid valve controller 58 controls the first normally closed solenoid valve 36, the second normally closed solenoid valve 37 to be powered and opened；Control first Normally open solenoid valve 38, the second normally open solenoid valve 39, which are powered, closes；Remaining magnetic valve powers off valve element and is in initial position.Motor control Device 57 processed controls the first electromagnet 3 to be powered, and control stator 13, which produces, makes the conversion magnetic field that two rotors rotate forward.

II chamber of now pedal simulation cylinder 23 is closed due to the first normally open solenoid valve 38 and the power-off of the second normally open solenoid valve 39 Make its closing, so pedal force is transferred to I intracavitary of simulation cylinder pedal simulation cylinder 23, the pedal simulation cylinder spring of I intracavitary of compression Group 25, so as to produce pedal sense simulation true to nature.

Meanwhile the first rotor 5 is due to the energization of the first electromagnet 3, its moved with the first fixing axle 2 it is synchronous, due to first Fixing axle 2 is fixed, so the first rotor 5 can not be rotated by locked；Magnetic fields of second rotor 14 in stator 13 Under, start to rotate forward, so as to which the second rotor 14 drives the second star-wheel 12 to rotate, due to the second star-wheel 12 and the second outer ring 11 it Between single-direction transmission effect, the second star-wheel 12 drive the second outer ring 11 rotate forward, the second outer ring 11 drive feed screw nut 10 just To rotation, by the transmission of ball 9, leading screw screw rod 8 is set to move right, so as to promote brake master cylinder piston bar 29 to move right. Brake master cylinder piston bar 29 promotes master cylinder first piston 32 to move right, so that the II of master cylinder 30, III liang of chamber pressure Power is raised, and the hydraulic oil of II intracavitary is entered in left front wheel cylinder 52 by the first normally closed solenoid valve 36, the 3rd normally open solenoid valve 40, real The braking supercharging of existing the near front wheel；The hydraulic oil of II intracavitary is entered left by the first normally closed solenoid valve 36, the 4th normally open solenoid valve 42 In rear wheel cylinder 53, the braking supercharging of left rear wheel is realized；The hydraulic oil of III intracavitary passes through the second normally closed solenoid valve 37, the 5th normally opened electricity Magnet valve 43 enters in off-front wheel cylinder 54, realizes the braking supercharging of off-front wheel；The hydraulic oil of III intracavitary passes through the second normally closed solenoid valve 37th, the 6th normally open solenoid valve 44 enters in off hind wheel cylinder 55, realizes the braking supercharging of off hind wheel.So as to complete pressurization.

Specific flow of pressurized is as shown in heavy line in Fig. 6.

2. decompression process under conventional brake operating mode:

Refering to Fig. 7, when driver loosen the brake 18 when, the pedal position on brake pedal simulation cylinder piston rod 20 Displacement sensor 19 detects the shift value of brake pedal 18, and sends displacement signal to electronic control unit (ECU) 57, electronics Control unit (ECU) 57 sends control command by calculating with analyzing to electric machine controller 57 and solenoid valve controller 58.

Solenoid valve controller 58 controls the first normally closed solenoid valve 36, the second normally closed solenoid valve 37 to be powered and opened；Control first Normally open solenoid valve 38, the second normally open solenoid valve 39, which are powered, closes；Remaining magnetic valve powers off valve element and is in initial position.Motor control Device 57 processed controls the second electromagnet 16 to be powered, and control stator 13, which produces, makes the counter-rotational conversion magnetic field of two rotors.

Now, the second rotor 14 is due to the energization of the second electromagnet 16, its moved with the second fixing axle 17 it is synchronous, due to Two fixing axles 17 are fixed, so the second rotor 14 can not be rotated by locked；Magnetic fields of the first rotor 5 in stator 13 Under, start to rotate backward, so as to which the first rotor 5 drives the first star-wheel 6 to rotate, due between the first star-wheel 6 and the first outer ring 7 Single-direction transmission effect, the first star-wheel 6 drive the first outer ring 7 reversely rotate, the first outer ring 7 drive feed screw nut 10 reversely revolve Turn, by the transmission of ball 9, be moved to the left leading screw screw rod 8, so as to promote brake master cylinder piston bar 29 to be moved to the left.Braking Main cylinder piston-rod 29 pulls master cylinder first piston 32 to be moved to the left, so that the II of master cylinder 30, III liang of cavity pressure drop Low, the hydraulic oil in left front wheel cylinder 52 enters master cylinder 30 by the first normally closed solenoid valve 36, the 3rd normally open solenoid valve 40 In II chamber, the braking compression release of the near front wheel is realized；Hydraulic oil in left back wheel cylinder 53 is normally opened by the first normally closed solenoid valve the 36, the 4th Magnetic valve 42 enters in II chamber of master cylinder 30, realizes the braking compression release of left rear wheel；Hydraulic oil in off-front wheel cylinder 54 passes through Second normally closed solenoid valve 37, the 5th normally open solenoid valve 43 enter in III chamber of master cylinder 30, realize the braking compression release of off-front wheel； Hydraulic oil in off hind wheel cylinder 55 enters III chamber of master cylinder 30 by the second normally closed solenoid valve 37, the 6th normally open solenoid valve 44 In, realize the braking compression release of off hind wheel.So as to complete decompression process.

Specific flow of pressurized is as shown in heavy line in Fig. 7.

Pressurization under 3.ABS operating modes：

It is no longer superfluous herein because pressurization is identical with pressurization under conventional brake operating mode under ABS operating modes refering to Fig. 8 State.Specific flow of pressurized is as shown in thick line in Fig. 8.

Pressure maintaining period under 4.ABS operating modes：

Refering to Fig. 9, when needing pressurize under ABS operating modes, solenoid valve controller 58 controls the first normally open solenoid valve 38, and second Normally open solenoid valve 39, the 3rd normally open solenoid valve 40, the 4th normally open solenoid valve 41, the 5th normally open solenoid valve 42, the 6th normally opened electromagnetism Valve 43, which is powered, closes.So that left front wheel cylinder 52, left back wheel cylinder 53, off-front wheel cylinder 54, the brake fluid in off hind wheel cylinder 55 is in Closed state, realize four-wheel pressurize.Specific flow of pressurized is as shown in thick line in Fig. 9.

Decompression process under 5.ABS operating modes：

It is no longer superfluous herein because decompression process is identical with decompression process under conventional brake operating mode under ABS operating modes refering to Figure 10 State.Specific flow of pressurized is as shown in thick line in Figure 10.

The near front wheel single-wheel pressurization under 6.TCS operating modes：

Refering to Figure 11, when needing the near front wheel single-wheel to be pressurized, electronic control unit (ECU) 57 is by calculating and analyzing to electricity Machine controller 57 and solenoid valve controller 58 send control command.

Solenoid valve controller 58 controls the first normally closed solenoid valve 36, the second normally closed solenoid valve 37 to be powered and opened；Control first Normally open solenoid valve 38, the second normally open solenoid valve 39, which are powered, closes；Remaining magnetic valve powers off valve element and is in initial position.Motor control Device 57 processed controls the first electromagnet 3 to be powered, and control stator 13, which produces, makes the conversion magnetic field that two rotors rotate forward.

Meanwhile the first rotor 5 is due to the energization of the first electromagnet 3, its moved with the first fixing axle 2 it is synchronous, due to first Fixing axle 2 is fixed, so the first rotor 5 can not be rotated by locked；Magnetic fields of second rotor 14 in stator 13 Under, start to rotate forward, so as to which the second rotor 14 drives the second star-wheel 12 to rotate, due to the second star-wheel 12 and the second outer ring 11 it Between single-direction transmission effect, the second star-wheel 12 drive the second outer ring 11 rotate forward, the second outer ring 11 drive feed screw nut 10 just To rotation, by the transmission of ball 9, leading screw screw rod 8 is set to move right, so as to promote brake master cylinder piston bar 29 to move right. Brake master cylinder piston bar 29 promotes master cylinder first piston 32 to move right, so that the II of master cylinder 30, cavity pressure liter Height, the hydraulic oil of II intracavitary are entered in left front wheel cylinder 52 by the first normally closed solenoid valve 36, the 3rd normally open solenoid valve 40, realized left The single-wheel braking supercharging of front-wheel.

Specific flow of pressurized is as shown in thick line in Figure 11.

The near front wheel single-wheel decompression process under 7.TCS operating modes：

Refering to Figure 12, when needing the near front wheel single-wheel to depressurize, electronic control unit (ECU) 57 is by calculating and analyzing to electricity Machine controller 57 and solenoid valve controller 58 send control command.Solenoid valve controller 58 controls the first normally closed solenoid valve 36, the Two normally closed solenoid valves 37, the 3rd normally closed solenoid valve 44, which are powered, to be opened；Control the first normally open solenoid valve 38, the second normally open solenoid valve 39th, the 3rd normally open solenoid valve 40, which is powered, closes.

Brake fluid in left front wheel cylinder 52 enters in fuel tank 26 by the 3rd normally closed solenoid valve 44, realizes left front wheel cylinder 52 Single-wheel is depressurized.

Specific flow of pressurized is as shown in thick line in Figure 12.

8. the pressurization under power-off failure pattern：

Refering to Figure 13, when brakes power-off failure, all magnetic valve power-off valve elements are in initial position.Now, drive The person of sailing steps on brake pedal 18, and brake pedal 18 promotes pedal simulation cylinder piston rod 20 to be moved to the left, so as to promote pedal to simulate Cylinder first piston 22 is moved to the left, so that the II cavity pressure rise of pedal simulation cylinder 23, II intracavitary of pedal simulation cylinder 23 Brake fluid enters in left front wheel cylinder 52 by the first normally open solenoid valve 38, the 3rd normally open solenoid valve 40, realizes the supercharging of the near front wheel； The brake fluid of II intracavitary of pedal simulation cylinder 23 enters left back wheel cylinder by the first normally open solenoid valve 38, the 4th normally open solenoid valve 41 In 53, the supercharging of left rear wheel is realized；The brake fluid of II intracavitary of pedal simulation cylinder 23 is by the second normally open solenoid valve 39,5 constant virtues Open electromagnetic valve 42 enters in off-front wheel cylinder 54, realizes the supercharging of off-front wheel；The brake fluid of II intracavitary of pedal simulation cylinder 23 passes through Second normally open solenoid valve 39, the 6th normally open solenoid valve 43 enter in off hind wheel cylinder 53, realize the supercharging of off hind wheel.Increase so as to realize Press through journey.

Specific flow of pressurized is as shown in thick line in Figure 13.

9. the decompression process under power-off failure pattern：

Refering to Figure 14, when brakes power-off failure, all magnetic valve power-off valve elements are in initial position.Now, drive The person of sailing loosens the brake 18, because the high pressure effect of brake fluid promotes pedal simulation cylinder first piston 22 to move right, so as to Make II cavity pressure of pedal simulation cylinder 23 reduce, the brake fluid in left front wheel cylinder 52 is normal by the first normally open solenoid valve the 38, the 3rd Open electromagnetic valve 40 enters II intracavitary of pedal simulation cylinder 23, realizes the decompression of the near front wheel；Brake fluid in left back wheel cylinder 53 passes through First normally open solenoid valve 38, the 4th normally open solenoid valve 41 enter II intracavitary of pedal simulation cylinder 23, realize the decompression of left rear wheel；It is right Brake fluid in preceding wheel cylinder 54 enters II chamber of pedal simulation cylinder 23 by the second normally open solenoid valve 39, the 5th normally open solenoid valve 42 It is interior, realize the decompression of off-front wheel；Brake fluid in off hind wheel cylinder 53 is by the second normally open solenoid valve 39, the 6th normally open solenoid valve 43 Into II intracavitary of pedal simulation cylinder 23, the decompression of off hind wheel is realized.So as to realize decompression process.

Specific flow of pressurized is as shown in thick line in Figure 14.

Claims (9)

1. A kind of 1. double-rotor machine line traffic control brake fluid system, it is characterised in that described double-rotor machine line traffic control hydraulic braking System includes motor (A), brake unit (B) and ECU (C)；

   Described motor (A) includes motor casing (1), the first fixing axle (2), the first electromagnet (3), the first shaft housing (4), first Rotor (5), the first star-wheel (6), the first outer ring (7), leading screw screw rod (8), ball (9), feed screw nut (10), the second outer ring (11), the second star-wheel (12), stator (13), the second rotor (14), the second shaft housing (15), the second electromagnet (16), second are consolidated Dead axle (17), the first star-wheel spring (59), the first star-wheel fore-set (60), the first roller (61), the second star-wheel spring (62), second Star-wheel fore-set (63) and the second roller (64)；

   Described stator (13) is arranged in motor casing (1), to be fixedly connected between stator (13) and motor casing (1), first turn Sub (5), the first star-wheel (6), the first outer ring (7), leading screw screw rod (8), ball (9), feed screw nut (10), the second outer ring (11), Second star-wheel (12) is sequentially arranged in stator (13) with the second rotor (14), and the first rotor (5) is located at the most left of stator (13) In end, the right-hand member of the first rotor (5) is fixedly connected with the left end of the first star-wheel (6), and the right-hand member of the first star-wheel (6) is sleeved on leading screw The left end of nut (10) is simultaneously inserted in the left end of the first outer ring (7), and the right-hand member of the first outer ring (7) is sleeved on feed screw nut (10) Left end is simultaneously fixedly connected with feed screw nut (10), and leading screw screw rod (8) is arranged in feed screw nut (10), and ball (9) is arranged on silk Thick stick nut (10) and leading screw screw rod (8) it is combined into spiral rolling track in, right-hand member and the first rotor (5) of the first shaft housing (4) Left end be fixedly connected, the first electromagnet (3) is sleeved on the first shaft housing (4), and the right-hand member of the first fixing axle (2) is arranged on the In the cylindrical groove of one shaft housing (4), between the right-hand member of the first fixing axle (2) and the cylindrical groove of the first shaft housing (4) between Gap fills magnetic, and the left end of the first fixing axle (2) at motor casing (1) left side wall madial wall center with being fixedly connected, the second outer ring (11), the second star-wheel (12) and the second rotor (14) are symmetrically mounted in the right-hand member of stator (13), the second shaft housing (15), the Two electromagnet (16) and the second fixing axle (17) are symmetrically mounted at the right-hand member in motor casing (1), the right-hand member of leading screw screw rod (8) with The left end of brake master cylinder piston bar (29) is fixedly connected in master cylinder (30) in brake unit (B)；ECU (C) and electricity Machine (A) is connected with brake unit (B) electric wire.
2. 2. according to the double-rotor machine line traffic control brake fluid system described in claim 1, it is characterised in that described stator (13) With the rotation conllinear of motor casing (1)；

   First fixing axle (2), the first electromagnet (3), the first shaft housing (4), the first rotor (5), the first star-wheel (6), outside first Enclose (7), leading screw screw rod (8), feed screw nut (10), the second outer ring (11), the second star-wheel (12), the second rotor (14), the second axle Housing (15), the second electromagnet (16), the second fixing axle (17) and the rotation conllinear of stator (13).
3. 3. according to the double-rotor machine line traffic control brake fluid system described in claim 1, it is characterised in that the second described outer ring (11), the second star-wheel (12) and the second rotor (14) are symmetrically mounted in the right-hand member of stator (13), the second shaft housing (15), the The right-hand member that two electromagnet (16) are symmetrically mounted in motor casing (1) with the second fixing axle (17) refers to：

   Described the second rotor (14) is located in the low order end of stator (13), the left end and the second star-wheel (12) of the second rotor (14) Right-hand member be fixedly connected, the left end of the second star-wheel (12) is sleeved on the right-hand member of feed screw nut (10) and inserted the second outer ring (11) In right-hand member, the left end of the second outer ring (11) is sleeved on the right-hand member of feed screw nut (10) and is fixedly connected with feed screw nut (10)；The The left end of two shaft housings (15) is fixedly connected with the right-hand member of the second rotor (14), and the second electromagnet (16) is sleeved on the second shaft housing (15) on, the left end of the second fixing axle (17) is arranged in the cylindrical groove of the second shaft housing (15), the second fixing axle (17) Gap filling magnetic between the cylindrical groove of left end and the second shaft housing (15), the right-hand member and motor casing of the second fixing axle (17) (1) it is fixedly connected at the medial center of right side wall, right-hand member, the second rotor (14), the second shaft housing (15) of the second star-wheel (12) On the brake master cylinder piston bar (29) for the master cylinder (30) being sleeved on the second fixing axle (17) in brake unit (B).
4. 4. according to the double-rotor machine line traffic control brake fluid system described in claim 1, it is characterised in that described leading screw screw rod (8) right-hand member is fixedly connected with the left end of brake master cylinder piston bar (29) in the master cylinder (30) in brake unit (B) to be referred to：

   It is axially disposed at described leading screw screw rod (8) right-hand member center to have a blind round hole, the blind round hole and master cylinder (30) the cylindrical lip diameter of brake master cylinder piston bar (29) left end in is equal, the cylinder of brake master cylinder piston bar (29) left end Flange is fitted into the blind round hole of leading screw screw rod (8) right-hand member, between the two to be fixedly connected.
5. 5. according to the double-rotor machine line traffic control brake fluid system described in claim 1, it is characterised in that described brake unit (B) brake pedal (18), pedal displacement sensor (19), pedal simulation cylinder (23), fuel tank (26), the first check valve are also included (27), the second check valve (28), the first normally closed solenoid valve (36), the second normally closed solenoid valve (37), the first normally open solenoid valve (38), Second normally open solenoid valve (39), the 3rd normally open solenoid valve (40), the 4th normally open solenoid valve (41), the 5th normally open solenoid valve (42), 6th normally open solenoid valve (43), the 3rd normally closed solenoid valve (44), the 4th normally closed solenoid valve (45), the 5th normally closed solenoid valve (46), 6th normally closed solenoid valve (47), first pressure sensor (48), second pressure sensor (49), the 3rd pressure sensor (50), 4th pressure sensor (51), left front wheel cylinder (52), left back wheel cylinder (53), off-front wheel cylinder (54) and off hind wheel cylinder (55)；

   The described oil inlet of master cylinder first (65) is connected with the oil-out of the first check valve (27) using fluid pressure line, system The dynamic oil inlet of master cylinder second (66) is connected with the oil-out of the second check valve (28) using fluid pressure line, the first check valve (27) Oil inlet be connected with fuel tank (26) using fluid pressure line, the oil inlet of the second check valve (28) uses hydraulic tube with fuel tank (26) Road is connected；The oil-out of master cylinder first (67) is connected with the Single port of the first normally closed solenoid valve (36) using fluid pressure line； The oil-out of master cylinder second (68) is connected with the Single port of the second normally closed solenoid valve (37) using fluid pressure line；First normally closed electricity The another port of magnet valve (36) and the another port of the first normally open solenoid valve (38), the 3rd normally open solenoid valve (40) Single port, Fluid pressure line connection is respectively adopted in the Single port of 4th normally open solenoid valve (41)；The another port of second normally closed solenoid valve (37) and The another port of second normally open solenoid valve (39), the Single port of the 5th normally open solenoid valve (42), the 6th normally open solenoid valve (43) Single port is respectively adopted fluid pressure line and is connected；The Single port of first normally open solenoid valve (38), the one of the second normally open solenoid valve (39) Port is connected with the pedal simulation cylinder oil-out (69) on pedal simulation cylinder (23) using fluid pressure line；3rd normally open solenoid valve (40) another port is respectively adopted fluid pressure line and is connected with Single port, the left front wheel cylinder (52) of the 3rd normally closed solenoid valve (44)； The another port of 4th normally open solenoid valve (41) and Single port, the left back wheel cylinder (53) of the 4th normally closed solenoid valve (45) are respectively adopted Fluid pressure line is connected；The another port of 5th normally open solenoid valve (42) and Single port, the off-front wheel of the 5th normally closed solenoid valve (46) Cylinder (54) is respectively adopted fluid pressure line and is connected；The another port of 6th normally open solenoid valve (43) and the 6th normally closed solenoid valve (47) Single port, off hind wheel cylinder (55) is respectively adopted fluid pressure line and is connected；The another port of the 3rd described normally closed solenoid valve (44), The another port of 4th normally closed solenoid valve (45), the another port of the 5th normally closed solenoid valve (46) and the 6th normally closed solenoid valve (47) Another port fluid pressure line be respectively adopted be connected with fuel tank (26)；

   Described first pressure sensor (48) is arranged on the hydraulic pressure between the 3rd normally open solenoid valve (40) and left front wheel cylinder (52) In pipeline, second pressure sensor (49) is arranged on the fluid pressure line between the 4th normally open solenoid valve (41) and left back wheel cylinder (53) In, the 3rd pressure sensor (50) is arranged in the fluid pressure line between the 5th normally open solenoid valve (42) and off-front wheel cylinder (54), 4th pressure sensor (51) is arranged in the fluid pressure line between the 6th normally open solenoid valve (43) and off hind wheel cylinder (55).
6. 6. according to the double-rotor machine line traffic control brake fluid system described in claim 5, it is characterised in that described pedal simulation Cylinder (23) includes pedal simulation cylinder piston rod (20), pedal simulation cylinder cylinder body (21), pedal simulation cylinder first piston (22), pedal Simulate cylinder second piston (24) and pedal simulation cylinder groups of springs (25)；

   Described pedal simulation cylinder first piston (22) is arranged on pedal simulation cylinder cylinder body with pedal simulation cylinder second piston (24) (21) in, pedal simulation cylinder first piston (22) is located at the right side of pedal simulation cylinder second piston (24), pedal simulation cylinder first Piston (22), pedal simulation cylinder second piston (24) and the rotation conllinear of pedal simulation cylinder cylinder body (21), pedal simulation cylinder (23) the pedal simulation cylinder second piston (24) being located therein is divided into I from left to right with pedal simulation cylinder first piston (22) Chamber, II chamber, III chamber, I chamber and III chamber of master cylinder (30) be do not contain hydraulic oil without sap cavity, II chamber is that hydraulic pressure is contained in inside Oil has sap cavity, and pedal simulation cylinder groups of springs (25) is located at I intracavitary of pedal simulation cylinder (23), pedal simulation cylinder groups of springs (25) Left end and pedal simulation cylinder cylinder body (21) left side wall medial center at be fixedly connected, the right side of pedal simulation cylinder groups of springs (25) End at pedal simulation cylinder second piston (24) left side wall center with contacting connection；Pedal simulation cylinder cylinder in pedal simulation cylinder (23) A pedal simulation cylinder oil-out (69), pedal simulation cylinder oil-out (69) and pedal simulation cylinder (23) are provided with body (21) II chamber connects.
7. 7. according to the double-rotor machine line traffic control brake fluid system described in claim 6, it is characterised in that described pedal simulation Cylinder groups of springs (25) is made up of the spring of three different lengths and different-stiffness, and all spring left ends simulate cylinder cylinder body with pedal (21) it is fixedly connected at left side wall medial center.
8. 8. according to the double-rotor machine line traffic control brake fluid system described in claim 1, it is characterised in that described master cylinder (30) master cylinder body (31), master cylinder first piston (32), the spring of master cylinder first (33), master cylinder are also included Second piston (34) and master cylinder second spring (35)；

   Described master cylinder first piston (32), the spring of master cylinder first (33), master cylinder second piston (34) and system Dynamic master cylinder second spring (35) is arranged in master cylinder body (31) from left to right successively, master cylinder first piston (32), the spring of master cylinder first (33), master cylinder second piston (34), master cylinder second spring (35) and master cylinder The rotation conllinear of cylinder body (31), the master cylinder first piston (32) and master cylinder that master cylinder (30) is located therein Second piston (34) is divided into I chamber, II chamber, III chamber from left to right, and I chamber of master cylinder (30) is the aneroid for not containing hydraulic oil Chamber, II chamber, III chamber are that intracavitary portion contains hydraulic oil and has sap cavity；

   The right-hand member of described brake master cylinder piston bar (29) and the company of fixation at the left side center of master cylinder first piston (32) Connect, one end of the spring of master cylinder first (33) is made with being fixedly connected at the right side center of master cylinder first piston (32) The other end of the dynamic spring of master cylinder first (33) at the left side center of master cylinder second piston (34) with being fixedly connected, braking master One end of cylinder second spring (35) at the right side center of master cylinder second piston (34) with being fixedly connected, the other end and braking It is fixedly connected at master cylinder body (31) right side wall medial surface center.
9. 9. according to the double-rotor machine line traffic control brake fluid system described in claim 8, it is characterised in that described master cylinder The two oil inlets i.e. oil inlet of master cylinder first (65) and the oil inlet of master cylinder second (66) are provided with cylinder body (31), is made The dynamic oil inlet of master cylinder first (65) connects with II chamber of master cylinder (30), the oil inlet of master cylinder second (66) and master cylinder (30) III chamber connection；The two oil-outs i.e. oil-out of master cylinder first (67) and system are provided with master cylinder body (31) The dynamic oil-out of master cylinder second (68), the oil-out of master cylinder first (67) connect with II chamber of master cylinder (30)；Master cylinder Second oil-out (68) connects with III chamber of master cylinder (30).