Vehicle braking system

专利摘要:
1527404 Anti-skid braking systems FIAT SpA 26 Oct 1976 [31 Oct 1975] 44503/76 Heading F2F Valve closure 62 (Fig. 2) blocks communication between brake pressure line 18 and line 36 to a brake actuator, where, in response to a skid signal, an electrical valve armature 74 is moved to allow auxiliary pressure from line 28 past the electrical valve closure 88 into the space 66. The closure 62 has a peripheral lip 71 which allows the auxiliary pressure then to flow through to the brake actuator line 36. Brake pressure then builds up at a slower rate because of the restrictions in the passages for the auxiliary fluid. In Fig. 6, the positions of the lines 18, 36 are reversed and the main valve closure is of two part construction with a radial passage 144 and axial passage 132 to allow the auxiliary pressure fluid to flow into the brake actuator line 36.
公开号:SU730290A3
申请号:SU762414907
申请日:1976-10-29
公开日:1980-04-25
发明作者:Микеллоне Джанкарло；Маджиони Вирджинио
申请人:Фиат Сочиета Пер Ациони (Фирма)；
IPC主号:

专利说明:

(54)
BRAKE TRANSPORT SYSTEM The invention relates to the automotive industry and can be used in a braking control system in conditions of poor adhesion of wheels to the road. The invention is applicable to a pneumatic braking system of an automobile, which has at least two driving wheels, which are driven via a differential. Such systems are already known. On the closest to the invention is a vehicle braking system comprising a pressure source, a check valve for simultaneous braking of the wheels, and connected through main brake pressure lines to the check valve and to the executive bodies of the wheel brakes distribution devices, each of which has. valve mounted in the housing to stop supplying the main brake pressure to the actuators of the brake wheels, and installed in the secondary housing PORN element with electromagnetic drive of sensitivity MEANS
Two elements that determine wheel slip 1. When the electromagnet is energized, the full brake pressure is applied to the non-slip wheel, the wheel is decelerated, and due to the inertia of the system, the repeated braking is delayed, which leads to a decrease in the efficiency and waste of energy of the working brake medium and. electrical energy management. The purpose of the invention is to increase the braking efficiency by making it possible for the torque to be transmitted to the non-slip wheel when another slips. This is achieved by the fact that the system is supplied with an auxiliary brake pressure source connected to distribution devices, in each of which the primary and auxiliary brake pressure chambers are limited by the valve element, and the locking element is located in the Chamber, which is made in an additional case brake pressure, with the last chamber communicated by a connecting channel, made in the switchgear housing, with the camera th) brake pressure and the stop member is mounted for maintaining separation of said chambers to a source of an auxiliary braking pressure.
It is advisable to make the valve element in each distribution device in the form of a truncated cone with an annular groove on a large end surface forming an elastic peripheral bead and set so that the main and auxiliary brake pressure chambers are limited by the larger and smaller end surfaces, respectively.
The valve element can also be made in the form of two parts, each of which is in the shape of a truncated cone with an annular groove on a larger end surface that forms a peripheral flange for the RUGs, and be oriented with large end surfaces towards each other. It is advisable to provide these parts with central rigid cores with axial protrusions for mutual engagement and keeping these parts at a certain distance from each other, while it is necessary in the core of the part to which the main brake pressure chamber is limited, to perform an axial hole, and in one of the cores - a radial opening for supplying working medium from a source of auxiliary brake pressure.
In addition, in the system, the ratio of the cross-sectional area of the connecting channel to the cross-sectional area of the main brake pressure pipes connected to the distribution devices is 1/15.
. Figure 1 shows the scheme of the proposed brake system; Figures 2 and 3 show the longitudinal sections of the first distributor suitable for use in the brake system shown in Figure 1 (two different working positions); Fig. 4 is a diagram of a braking system similar to that shown in Fig. 1, but differing in the shape of the distributors; Figures 5 and 6 show the longitudinal sections of the second distributor, which passes for use in the brake system shown in Figs. 4, in two different: his working positions.
The brake system for the two driving wheels 1, whose half-axles 2Ah | Alx are driven through Differential 3 from the cardan into & 4, is shown in FIG. 1.
A compressed air supply source 5 feeds control valve b,
controlled by the pedal 7, driven by the driver of the car. When you press the brake pedal 7. compressed air is supplied through valve 6 to the main brake line 8, which is connected to two branch pipes 9. Each of the pipes feeds the respective distribution device 10.
Each of the distribution devices 10 has a housing 11 and an additional housing with a controlled solenoid solenoid 12. The solenoid valves 12 are connected by wires 13 to a three-position switch 14 having a neutral position and two workers in which it provides power to one or the other of the solenoids 12 from the source 15, shown as a battery. The distributors 10 have three fittings: the first 16, to which the tube 9 is connected, fed from valve b, controlled by the brake pedal 7; the second - 17, to which the brake tube 18 is connected, leading to the actuator 19 of the brake of the corresponding wheel 1, and the third 20, to which the tube 21 is connected, which is connected via a tee 22 to the tube 23 leading from the auxiliary source 24 of the pressure of compressed of air.
The distributor body 11 lO (see Figures 2 and 3) is molded in a permanent form of aluminum alloy, has a cavity 25, inside which valve element 26 slides, which divides the cavity 25 into chambers 27 and 28 of primary and secondary pressure, respectively. The chamber 27 is open at one end and this opening is closed by a tube connector defining the first fitting 16 of the distributor 10. The connecting tube consists of a plug-in threaded socket 29 attached to the housing 11 with screws 30 and sealed in the opening 27 of the chamber 27 with a ring 3.1. Insertion socket 29 has the shape of a truncated cone with a central through hole 32.
A coaxial elongation 33 protrudes from the socket, to the end of which the element 26 is pressed to close the opening 32, and thereby cuts off the main brake pressure. Hole 32 has a thread 34 in which a connecting nipple 16 is screwed, connecting pipe 9 to valve 10 for communication with it. This design is the first inlet G. In the case 11, in the direction perpendicular to the longitudinal axis of the insertion socket 29, there is a threaded hole 35 which is connected via channel 36 to the chamber 27. Into the threaded hole 35 a connector 17, 5 is screwed which connects the tube 18 to
distributor 10 for communication
with him. This design represents
a second entrance
Parallel to the hole 35 in the housing 11, another threaded hole 37 is made into which the fitting 20 is screwed to fasten the tube 21 to the housing 11 of the distributor 10. This design is a third inlet (II. The hole 37 communicates with the channel 38 leading to the electro-valve 12,
The chamber 28 also communicates with the electro-valve 12 via the connecting channel 39. The cross-sectional area of the channel 39 is approximately 1/15 of the cross-sectional area of the brake pipes 9 and 18 separately, i.e. main brake pressure lines. The electrovalve 12 has a threaded protrusion 40, which is screwed into a threaded socket in the distributor housing 10, into which both the channel 39 connected to the chamber 28 and the channel 38 leading to the third fitting 20 are opened. The threaded protrusion 40 of the solenoid 12 has two axial channels 41 and 42, respectively, communicate with the channels 39 and 38 inside the distributor 10. The end surface of the protrusion 40 has an epiploon 43 surrounding the entrance to the channel 42, to prevent
leakage from the junction of channels 42 and 3
f f f
The solenoid 12 has a winding 44 fed by a flow through the wires 13 and a connector 45 for electrical connection with a switch 14. Inside the winding 44 in the chamber of the additional housing is a movable core - a cylindrical locking element 46 having a longitudinal groove 47 and two cavities 48 and 49, along one sec. each end of the core 46. In the cavity 48 and 49 are placed springs 50 and 51, over which are installed the corresponding sealing elements-valve cutoffs 52 and 53 of the disk type, pressed axially to the corresponding ends of the core 46 by springs 50 and 51.
The end of the solenoid 12, remote from the threaded protrusion 40, which is screwed into the distributor 10, is closed by a stopper 54 having a through hole 55, the entrance to which is blocked by a cut-off 52 when the solenoid 12 is in an excited state, and which allows communication with the atmosphere when solenoid 12 is de-energized. The core 46 of the solenoid 12 is pressed by the spring 56 in the direction to the distributor 10. so that the cutoff 53 is pressed against the entrance to the channel 42, thereby blocking the channel 38 leading to the third fitting 20, In the de-energized position of the solenoid 12 (see Fig.2) the channel 39 the distributor 10 communicates with the atmosphere through the longitudinal groove 47 of the core 46 and the opening 55 in the plug 54.
Thus, the locking element 5 46 is installed with the possibility of communicating and disconnecting the auxiliary brake pressure from the source 24,
The valve element 26 is made of an elastic material in the shape of a truncated cone, the height of which is smaller than the dimensions of its bases - end surfaces. Element 26 is mounted so that the main end pressure chamber 27 S is limited to the primary brake pressure, and the secondary brake pressure chamber 28 is limited to the lower end surface.
In the larger face surface
0 there is an annular groove 57 which defines a peripheral elastic sealing bead 58,
The described device operates as follows.
Figure 2 solenoid shown
5 in the de-energized position, which corresponds to normal conditions when the actuator of the brake 19 of the wheel 1 associated with it is supplied with working medium directly
0 from the main brake circuit 8 when you press the pedal 7.
Under these conditions, compressed air from source 5 is supplied through valve 6 controlled by the brake pedal 7,
5 through the brake tube 8 through the opening 32 of the connecting socket 29 of the first fitting 16 to the inside of the chamber 27. The valve element 26 is pressed against the entrance to the channel 39, closing this channel, the pressure that is large in the chamber 27 than in the chamber 28, tends to release the collar 58, tight clamping
it to the walls of the cavity 25. The pressure from the chamber 27 is thus supplied
5 only through the second fitting 17 into the brake tube 18 and from there to the working body 19 of the brake of the wheel 1 associated with it, the channel 38 is closed by the locking element 46 of the electrovalve0 at 12 and thus the compressed air from the auxiliary source 24 cannot enter the distributor 10 .
If wheel 1 starts to use or is in the initial stage of use, this is detected by sensing elements determining wheel slip (not shown), which flips switch 14 into

权利要求:
Claims (4)
[1]
corresponding to the direction for energizing the winding 44 of the solenoid 12, the excitation of the winding 44 causes the core 46 to be drawn in and the disk cut-off 52 at the end of the core blocks the entrance to the hole 55 communicating with the atmosphere. The disk cut-off 53 at the other end of the heart 46 moves away from the entrance to the channel 38, opening a connection between it and the channel 39 leading to the chamber 28, the valve element 26 is now pressed in the pressure boosting chamber 28 to the entrance to the hole 32, closing the fittings 16. Now the pressure difference between the two chambers has a reverse value than in previous conditions: The pressure is greater in chamber 28 than in chamber 27, the pressure deforms the flange 58 inward, allowing compressed air to flow from chamber 28 into chamber 27 thereby open the message between the third fitting 20 and in torElm fitting 17. Now applied to the executive body 19 of the brake pressure from the auxiliary source 24 Slowly increases due to the small cross-sectional area of the channels 39 and 38 and the resistance of the elastic flange 58 to the passage of air from the second cavity to the first chamber 25. When the wheel 1, found the condition, returns to the normal state, the solenoid 12 de-energizes, stops the resistance to the use and returns the valve to 10 volts. the initial position in which the channel 38 is closed by the cut-off 53 of the solenoid 12 and the channel 39 communicates with the atmosphere: the element 26 is displaced by the pressure difference between the two channels in the cavity 25, re-opening the opening 32 of the connecting socket 29 of the first fitting 16; 4 shows practically the same brake system as in FIG. 1, but the valves 10.1 are different from the valves 10. The difference between the valves 10.1 shown in FIG. 5 and 6 and the valves 10 shown in FIG. 2 and 3, the threaded hole 34.1 and 35.1 of the first and second fittings 16 and 17 are in reverse positions, compared with the positions of the holes 34 and 35 of the first and second fittings, fittings 16 and 17 of the distributor 10. In addition to the distributor 10.1, the cavity 25.1 is significantly larger than the cavity 25 of the distributor 10, the cavity 25.1 has implicit valve member 26.1. The composite valve element 26.1 consists of the first and second parts 59.60, each in the form of a strongly flattened truncated cone, Two parts 59 and 60 face each other with their large-junctional surfaces, each of which has an annular groove 61.62 defining a corresponding peripheral flange 63 and 64, Two parts 59.60, delimit the central chamber 65. Composite element 26.1 divides the cavity 25.1 into two chambers 27.1 and 28.1 The first part 59 limits the first chamber 27.1 of the main pressure and the second part 60 restricts the second camera 2-8.1 auxiliary in the first part 59, a core 66 is fixedly mounted, having a central axial hole 67. In the second part 60, a hollow core 68 is placed, having axial protrusions 69 interlocking with corresponding projections 70 of the core 66 of the first part 59, the core 68 has a radial hole (to . channel) 71, which allows the central axial bore 67 of the core 59 and the chamber 65 to communicate with each other. The end of the brake tube 9 is held in the threaded bore 34.1, which is the first fitting 16, and the channel 72 communicates between The camera is 27.1 and the screw hole 34.1. The device shown in FIGS. 5 and 6 works in the following way. When the solenoid valve 12 is de-energized, air from source 5 passing through the brake tube 9 flows through channel 72 into chamber 27.1 and from there passes through channel 32.1 into. the threaded bore 35.1, which is the second fitting 17, to which the brake on the tube 18 is attached, leading to the actuator 19 of the brake of the wheel 1 associated with it. Composite valve element 26.1 is pressed to the inlet to the channel 39 and the compressed air passes through the hole 67 of the core 66, causes deformation of the radial collar 64 so that it is pressed tightly against the wall of the cavity 25.1 and prevent any access of air from the chamber 27.1 to the inside of the channel 39. In this working position, the solenoid 12 is de-energized and, like at The variant shown in FIGS. 2 and 3 closes the valve 38 by means of dis. 6. The distributor 10.1 is shown with the excited solenoid valve 12 and in this position the outlet 55 is closed and the channel 38 can communicate with the channel 39. Compressed air from the auxiliary source 24 is supplied through the brake tube 21 and thus enter the chamber 28.1. Component 26.1 is pressed by increased pressure to the entrance to the channel 32.1 to close the communication between the brake tubes 9 and 18. Compressed air from the second chamber deforms the elastic shoulder 64 radially inwards and flows inside the chamber 65 between the two parts 59 and 60, from there it passes holes 71 and 67, and finally enters tube 18 through channel 32.1 and hole 35.1. Compressed air in chamber 65 also deforms the flange 63 of the first part 59 radially outward, providing isolation of channel 72 from the second chamber 28.1. The oscillations of pressure in the tube 18 during the antistatic deceleration depend on the size of the hole 71 and the elasticity of the shoulder 6 Again, when the wheel is connected to the distributor. 1 returns to its normal dynamic condition, the solenoid valve 12 b is unresponsive and the composite valve element 26.1 returns to its original position, allowing communication between the nipples 16 and 17, and the third nipple 20 is isolated by the solenoid 12. In the described systems, the solenoid 12 controls the pipes smaller in relation to the pipelines 9 and 18 of the main brake pressure, therefore, the control requires less power compared to the one that occurred before., Invention 1. Brakes a vehicle system in which axle axles of parts of wheels are interconnected via a differential containing a pressure source, a check valve for simultaneous braking of the wheels, and dispensers each connected via main brake pressure lines to the control valve and to the brake control actuators of said wheels. of which has a valve element mounted in the housing for stopping the supply of the main brake pressure to the executive bodies of the wheel and mouth brakes The locking element mounted in the additional housing is electromagnetically driven by sensing elements that determine wheel slip, so that, in order to improve braking efficiency, it is possible to transmit the torque to the non-slip wheel when another slips. equipped with a source of auxiliary brake pressure connected to distribution devices, in each of which the valve element is limited to the chambers of the main and auxiliary brake the pressure, and the locking element is placed in a chamber made in the additional housing, which is connected to the indicated auxiliary braking pressure source, the latter being connected by a connecting channel, made in the switchgear housing, to the auxiliary brake pressure chamber, and the locking separating said chambers from an auxiliary brake pressure source.
[2]
2. The non.l system, characterized by the fact that the valve element of each distribution device is made in the form of a truncated cone, on the larger end surface of which an annular groove is formed, which forms the peripheral elastic shoulder, and is set so that its larger and smaller end surfaces These cameras are limited to the primary and secondary brake pressure chambers, respectively.
[3]
3. Pop. 1 system, characterized by the fact that the valve element of each distribution device is made in two parts, each in the form of a truncated cone with an annular groove on a larger end surface that forms a peripheral elastic bead oriented with large end surfaces each to a friend, these parts are provided with central rigid cores with axial protrusions for mutual engagement and retention of said parts at some distance from one another, while in the core of that part which The main brake pressure chamber is retracted, an axial bore is made, and in one of the core there is a radial bore for supplying the working medium from the auxiliary brake pressure source.
[4]
4. A pop-up system 1, characterized in that the ratio of the cross-sectional area of the connecting channel to the cross-sectional area of the main brake pressure lines connected to the distribution devices is 1/15. Sources of information taken into account in the examination 1. Patent ail number 3677610, cl.303/21, 1972.
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类似技术:

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JP2018509331A|2018-04-05|Hydraulic brake equipment

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同族专利:

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公开号 | 公开日

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FR2329484B1|1978-10-20|

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IT1047382B|1980-09-10|

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GB1527404A|1978-10-04|

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US4057300A|1977-11-08|

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JPS5257472A|1977-05-11|

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FR2329484A1|1977-05-27|

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DE2649106A1|1977-05-12|

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DE2649106C2|1982-07-22|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

---

US3025722A|1959-09-25|1962-03-20|Caterpillar Tractor Co|Wheel slip control for wheel-type tractors|

---

US3677610A|1970-11-16|1972-07-18|Bendix Corp|Adaptive braking control valve|

---

US3767273A|1972-10-11|1973-10-23|Fiat Spa|Vehicle anti-skid braking apparatus having two modes of operation|

---

SE393069B|1974-04-22|1977-05-02|Saab Scania Ab|BRAKE PRESSURE CONTROL VALVE UNIT IN A PNEUMATIC BRAKE SYSTEM|

---

JPS5224672A|1975-08-19|1977-02-24|Mitsuwa Seiki Co Ltd|Modulator at anti-skid device for air brake|DE3319152C2|1983-05-26|1987-04-23|Daimler-Benz Ag, 7000 Stuttgart, De|

---

DE3407539C2|1984-03-01|1991-09-12|Alfred Teves Gmbh, 6000 Frankfurt, De|

---

DE3407538C2|1984-03-01|1994-06-09|Teves Gmbh Alfred|Double-circuit hydraulic brake system with anti-lock and traction control|

---

DE3412351C2|1984-04-03|1987-06-25|Mannesmann Rexroth Gmbh, 8770 Lohr, De|

---

DE3418520C2|1984-05-18|1992-03-05|Alfred Teves Gmbh, 6000 Frankfurt, De|

---

DE3430982A1|1984-08-23|1986-03-06|Alfred Teves Gmbh, 6000 Frankfurt|Wheel slip control arrangement|

---

DE3438401A1|1984-10-19|1986-04-24|Alfred Teves Gmbh, 6000 Frankfurt|DRIVE AND BRAKE-SLIP-CONTROLLED BRAKE SYSTEM|

---

DE3700716A1|1987-01-13|1988-07-21|Wabco Westinghouse Fahrzeug|VEHICLE WITH ANTI-BLOCKING SYSTEM AND DRIVE LOCK CONTROL|

---

US4970034A|1988-09-23|1990-11-13|W. R. Grace & Co.-Conn.|Process for preparing isotropic microporous polysulfone membranes|

---

DE3931315A1|1989-09-20|1991-03-28|Bosch Gmbh Robert|ANTI-BLOCKING CONTROL SYSTEM|

---

US10993546B2|2016-10-28|2021-05-04|Sleep Number Corporation|Noise reducing plunger|

法律状态:

优先权:

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申请号 | 申请日 | 专利标题

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IT69706/75A|IT1047382B|1975-10-31|1975-10-31|BRAKING SYSTEM FOR VEHICLES|

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