DE4336464B4 - Hydraulic brake system - Google Patents

Abstract

hydraulic Brake system with a traction control device for motor vehicles, with a between a master cylinder (11) and at least a wheel brake (13, 14, 15, 16) extending brake line (20) and with one, a liquid from a memory (33) and at least indirectly in the Wheel brake (13, 14, 15, 16) promotional High-pressure pump (29), wherein the memory (33) master cylinder side at least indirectly with the brake line (20) is in communication and the High pressure pump (29) suction side at least indirectly to the memory (33) is connected, characterized in that a yielding Separating element (membrane 54, 62) of the memory (33, 33.1) in the memory (33, 33.1) is arranged to be during the traction control operation the brake system on the one hand in the intake of the high pressure pump (29) and on the other hand under pressure from the brake pipe (20) is yielding.

Description

The invention relates to a hydraulic brake system according to the preamble of the main claim. Such a hydraulic brake system is known ( DE 41 28 386 A1 ).

A Such known brake system has the peculiarity that they are relative low design means without any control effort additional Pressure medium volume for the traction control mode while avoiding narrow cross sections provides a short path to the high-pressure pump. It exists, however the disadvantage that the memory compliant only in the filling direction of the system is. Pressure peaks can not smoothed by the memory because its tubular membrane is usually attached to a solid wall is applied.

Such a disadvantage is particularly serious for the following reasons:
During traction control, a check valve and a pressure relief valve are used. The pressure relief valve regulates the system pressure by means of an integrated pressure limiter.

Of the Pressure build-up for the traction control is via a self-priming return pump carried out, the pump being brake fluid sucked out of the master cylinder. The pressure relief valve allows excess brake fluid to flow back to the master cylinder. There The pump is designed as a single-piston pump, strong behind the pump periodic pressure fluctuations occur. The mentioned pressure relief valve responds to the periodic pressure fluctuations in such a way that it Reaching the opening pressure opens towards the brake line and liquid let abruptly flow to the master cylinder. Such a discharge process takes about one third of the pump period. When falling short the closing pressure the pressure relief valve closes this again and the liquid replenishment is stopped abruptly. The process described has the consequence that the Liquid column, the is in the main cylinder near brake line, first - so when you open the Valves - strong is accelerated. When the pressure relief valve closes again, the flows up Speed brought liquid column with the speed reached, since they are not abrupt can be slowed down. This onward flow is by the circumstance favors, that yourself behind the outflowing Liquid column first Cavity forms with gas or vapor from the brake fluid filled is. The power to hold back the liquid column is so low.

If on the back flowing liquid column the fluid newly ejected from the pressure relief valve will hit the cavity refilled. This causes considerable pressure surges in the main cylinder near Part of the brake line. These pressure impacts are noticeable as disturbing noises. The pressure surges be through regulatory processes the solenoid valves reinforced.

In addition, from the DE 39 40 177 A1 a blockage-protected hydraulic brake system, in which, as to the subject matter of the invention, the suction line of a pump is connected to an intermediate container. This intermediate container has a rolling diaphragm to which a so-called pot is attached. This pot cooperates with a plunger of a valve body which controls a bypass line. The rolling diaphragm is held by a unspecified support member and a spring in its normal position. Starting from this basic position, the rolling diaphragm is only able to perform a stroke, if at the same time limited by the rolling diaphragm storage space increases its volume, so there is a pressure increase. In contrast, in the subject matter of the invention, the separating element in the basic position is yieldable both in the direction of an increase / increase in pressure and a reduction / decrease in pressure in the volume of pressure medium delimited by the separating element.

Further, the DE 39 24 085 A1 a hydraulically switched into the main circuit vibration damper, which is, however, downstream of the hydraulic pump and thus acts only as a pure exhaust damper. When in the DE 39 12 935 A1 disclosed anti-lock hydraulic brake system is also a damping device downstream of a working chamber of a radial piston pump and therefore can not damp suction side pressure pulsations.

Starting from the invention closest to the state of the art, like him DE 41 28 386 A1 describes the invention has the object to reduce the occurring in this known hydraulic brake system on the suction side and on the pressure side of their hydraulic pump pressure pulsations as simple as possible, space-saving and cost-representable means. This object is achieved by an article having the features of claim 1.

For the installation of a storage in the hydraulic brake system two installation sites are possible. A first installation point is located near the pressure relief valve, because there are the volume portions that the pressure relief valve at each Pump stroke releases, be recorded and intercepted. It is also possible to attach the memory directly to the master brake cylinder side terminal of the housing block of the traction control device. The second possible installation point is on the suction side of the system between a shut-off valve open in traction control mode and the inlet of the pump. This point is favorable insofar as the dynamic effects that are trapped in the master cylinder lines, even in this Saugzweig - according to the principle of communicating lines - and can be eliminated there, in Bremsblockierschutzfall this point because of the then closed shut-off of the pressure load Brakes and pulsating return in anti-lock operation is not affected.

Farther Installation at this second location is also beneficial because of it there to a positive influence, i. Removal of pressure peaks, in the case of cooling comes, where the brake fluid contracts and in the blocked line branch between the shut-off valve and the pump inlet negative pressure want to create what through the yielding separator in memory is avoided.

Both potential Installation sites for the memory according to the invention together is the property that a homogenization of the Saugstromes is achieved in the pump and that disadvantageous Pressure peaks in traction control operation can be avoided.

Several advantageous developments of the invention will become apparent from the Features of the dependent claims. So the special clamping of the membrane separator is advantageous. It is also advantageous that the behind the separator lying chamber by using a porous or small perforated partition the possibility an air refill has to resonate the membrane only as a rubber spring or to possibly out of the chamber through the partition in the liquid contained in the system to replace diffused gas with ambient air.

Further Advantages of the solution according to the invention are in the description of the embodiment specified.

drawing

The invention is illustrated simplified in the drawing and explained in more detail in the following description. Show it 1 a hydraulic circuit diagram of a 2-circuit brake system with anti-lock and traction control device and each with a master brake cylinder side connected to a brake line memory, the 2 and 3 each a longitudinal section through two such structurally designed memory and 4 another type of such memory.

description of the embodiment

This in 1 shown circuit diagram shows a hydraulic brake system 10 with a master cylinder 11 , which a pressure medium reservoir 12 wearing. To the master cylinder 11 Two brake circuits I and II are connected. The brake circuit I is used to actuate a wheel brake assigned to the left front wheel 13 and a wheel brake associated with the right rear wheel 14 of the vehicle. At the brake circuit II is a wheel brake 15 the right front wheel and a wheel brake 16 connected to the left rear wheel of the vehicle. This hydraulic brake system 10 therefore has a so-called diagonal division of the brake circuits. The brake system 10 is with a traction control device 17 equipped to limit Antriebschlschlupf on the driven front wheels of the vehicle. Hereinafter, based on the brake circuit II, which is equipped in the same manner as the brake circuit I, the structure of the brake system 10 as far as this is the understanding of the traction control device 17 requires.

The brake system 10 has one from the master cylinder 11 outgoing and to the wheel brake 15 leading brake line 20 on. Radbremsseitig is the brake line 20 a pressure control valve assembly 21 for the brake pressure modulation of the wheel brake 15 assigned. Such a pressure control valve arrangement 21 consists of an inlet valve 22 and an exhaust valve 23 , which are designed as 2/2-way valves. Master cylinder side is in the brake line 20 a pressure relief valve 24 arranged. The pressure relief valve 24 owns a basic position 24a in which it is permeable to pressure medium. In a working position 24b locks the pressure relief valve 24 the brake line 20 ; when a predetermined response pressure is exceeded, it is in the direction of the master cylinder 11 permeable.

For the traction control mode branches from the brake line 20 between the master cylinder 11 and the pressure relief valve 24 a suction line 27 from, in which designed as a 2/2-way valve ASR shut-off valve 28 lies. This locks in its basic position 28a the suction line 27 ; in his working position 28b there is the suction line free. The suction line 27 leads to the suction line of a self-priming high-pressure pump 29 , from whose pressure side a pressure line 30 goes out, which between the pressure relief valve 24 and the pressure control valve assembly 21 to the brake line 20 connected.

The between the master cylinder 11 and the wheel brakes 13 to 16 lying elements of the brake system 10 are in a housing block 31 summarized, whose housing 32 is indicated by a dashed line.

In addition, the brake circuit II with a non-pressurized, passive memory 33 Mistake. This is either in the brake line 20 arranged or it is located on the suction line 27 downstream of the ASR shut-off valve 28 ; There he carries the reference number 33.1 and is shown only by dashed lines.

It is also still an electronic Stuergerät 37 provided, which by means of the vehicle wheels associated speed sensors 38 monitors the wheel rotational behavior of the vehicle wheels and the occurrence of adverse traction the mentioned valves 22 . 23 . 24 . 28 and an electric drive motor 39 the high pressure pump 29 switches according to a predetermined control algorithm.

Upon the occurrence of disadvantageous large drive slip, for example on the wheel brake 15 assigned right front wheel of the vehicle, the control unit turns off 37 the pressure relief valve 24 into the working position 24b , the ASR shut-off valve 28 into the working position 28b as well as the drive motor 39 the high pressure pump 29 one. The high pressure pump 29 now sucks pressure medium from the memory 33 through the master cylinder side section 20.1 the brake line 20 and through the suction line 27 at. The pumped pressure medium is through the pressure line 30 in the wheel brake section 20.2 the brake line 20 promoted and in the wheel brake 15 directed to the generation of brake pressure, so that a reduction of the traction slip is achieved via braking action. In this case, unspecified phases for brake pressure maintenance and brake pressure reduction can follow such a brake pressure buildup.

The in 1 only memory represented as a symbol 33 has following, in 2 reproduced structural design:
In a fitting made of a hexagon piece 41 are two L-shaped channels 42 . 43 one of which ( 42 ), for example, one inlet and the other ( 43 ) represents a sequence. The channel 42 communicates with a storage chamber 44 , The other channel 43 also communicates with the storage chamber 44 For example, on the detour through a created by recess ring chamber 45 , which also belong to the storage chamber 44 is connected and the rest of a transverse bore 46 one the storage chamber 44 receiving block 47 is covered. In two recesses 48 and 49 are sealing rings 50 and 51 inserted, and a screw connection 52 is the connector 41 so with a mother piece 53 or the housing block 31 screwed that seals 50 and 51 the storage chamber 44 seal to the outside. Upstairs is the storage chamber 44 from a membrane 54 covered and over the membrane 54 is an air or gas chamber 55 arranged. In this way, the membrane forms 54 a separating element between the air or gas chamber 55 and the hydraulic system connected to the storage chamber 44 connected is.

Advantageous are membranes made of elastomers, which have a sufficient flexibility. In braking systems, EPDM blends of high elongation and with Shore hardnesses of 70 to 80 Shore A are usually chosen. The membrane 54 has at its clamping a ring bead 56 which is from a retaining wall 57 against a housing shoulder 58 is pressed, something similar, as is usual with brake light switches.

The membrane environment, ie the housing and the supporting wall 57 , are designed so that the membrane 54 can deform in both directions in its symmetry axis direction. Only then can dynamic vacuum areas and overpressure peaks in the system be smoothed.

The support wall 57 is by means of a flange 59 held in the housing. A lid 60 ensures a cover to the outside. The air or gas chamber 55 has, if an installation after 1 as a memory 33 is chosen, a volume of about 50 mm ³ to max. 150 mm ³ , in order to limit the volume absorption during braking and to allow no noticeable further migration of the brake pedal. If the membrane 54 now at the ring bulge 56 is clamped and as shown by 2 no further support on the supporting wall 57 learns, affects the memory 33 particularly good damping when the gas spring effect of the in the air or gas chamber 55 caged gas is used. An inherently very slow permeation of the gas through the membrane 54 through into the liquid and the associated loss of gas can be counteracted when a gas supply via a wholly or partially gas-permeable support wall 57 he follows. For this purpose, the supporting wall 57 either made of a porous material, eg sintered material, or it is with a small caliber through hole 61 Mistake. Variants from very tight to very leaky are possible.

Through the channels in the sintering or through the hole 61 is given the possibility that the air or gas chamber 55 breathes outward, so that the chamber 55 can regenerate when part of its filling through the membrane 54 permeated into the hydraulic system.

Well suited are sintered retaining walls 57 For example, from stainless steel alloy powder having a density of 6.6 to 7.2 g / cm ³ . Such supporting walls 57 then on the one hand have a sufficient gas permeability of 0.5 to 1.6 ml / s, but on the other hand, they represent in dynamic operation a sufficiently large flow resistance, through which the gas can not escape or flow only quickly or only partially. Another advantage of a sintered retaining wall 57 is that the production of the supporting wall with its special contour is inexpensive possible.

Also simple in construction is a solution in which instead of an air or gas spring only the deformation and restoring force of the membrane, so the elastomer is used. Such a membrane arrangement is in the 3 and 4 shown. It can be seen that here is a membrane 62 a hump 63 has, in addition to the support wall 57 can support. In this way is then supported diaphragm 62 the air or gas chamber 55 in two concentric ring chambers 55.1 and 55.2 divided. An initial structure of the membrane 62 is shown in dashed lines.

Such a trained membrane 62 can counteract a pressure of up to about 10 bar and also deform again at lower fluid pressure. At higher pressures, the membrane is supported 62 with the hump 63 at the example leaky retaining wall 57 and can not be damaged. The leaky support wall 57 So it acts as burst protection. The leaky the retaining wall 57 is formed, the more elastic the memory 33.1 respectively. 33 with the intended consequence of the shift of the natural frequency mentioned in the introduction to the description. The support wall 57 but does not have to be gas-permeable, it may for example be tight. In this case, the hump avoids 63 in that with a permeation of air or gas through the membrane 62 this all over the wall to the supporting wall 57 applies during the period of time it takes the filled liquid to pass through the master cylinder 11 to saturate with air from the environment.

The double "L" channel guide in the housing 41 to 2 was chosen because it is in the storage chamber 44 in case of installation of the storage 33 behind the ASR shut-off valve 28 can come to a feinperligen gas excretion, which accumulates in so-called dead water to foam and gas bubbles. These soften the hydraulic brake system. It can also be entrained in the flow of gas bubbles and into the pump 29 where they affect their output. As an alternative to the double "L" channel guide, there is a cross hole with a guide piece.

If the memory 33.1 between the traction slip shut-off valve 28 and the high pressure pump 29 is arranged, its volume can be even greater than previously described, that is greater than 150 mm ³ , designed because the ASR shut-off valve 28 at the ordinary braking and at the work of the anti-lock is closed and the size of the volume consumption of the memory 33.1 for the ordinary braking process does not matter.

Also it is possible to store 33.1 directly into the housing block 31 to integrate. It can be caulked or screwed in or directly molded. In the latter case receives the housing block 31 the necessary contour using a machining tool, then the membrane 54 or 62 inserted and it becomes the supporting wall 57 set, which in turn with appropriate housing block material either caulked directly into the housing or, as in the 4 is shown by means of a threaded screw 64 is fixed. Furthermore, an inlet and an outlet line 65 and 66 to recognize their arrangement, a good flushing a storage chamber 67 guaranteed. Also advantageous are height offset or parallel offset lines to tangential and axial inflows and outflows or vice versa.

Claims (16)

Hydraulic brake system having a traction control device for motor vehicles, with one between a master cylinder ( 11 ) and at least one wheel brake ( 13 . 14 . 15 . 16 ) extending brake line ( 20 ) and with one, a liquid from a memory ( 33 ) and at least indirectly in the wheel brake ( 13 . 14 . 15 . 16 ) conveying high pressure pump ( 29 ), whereby the memory ( 33 ) master cylinder side at least indirectly with the brake line ( 20 ) and the high pressure pump ( 29 ) suction side at least indirectly to the memory ( 33 ) is connected, characterized in that a resilient separating element (membrane 54 . 62 ) of the memory ( 33 . 33.1 ) so in the memory ( 33 . 33.1 ) is arranged so that it during the traction control operation of the brake system on the one hand in the suction direction of the high-pressure pump ( 29 ) and on the other hand under pressure from the brake pipe ( 20 ) is yielding. Hydraulic brake system according to claim 1, characterized in that between the membrane ( 54 . 62 ) and a supporting wall ( 57 ) a chamber ( 55 ) and that in this chamber ( 55 ) Air or gas is present. Hydraulic brake system according to claim 2, characterized in that the supporting wall ( 57 ) is gas-tight. Hydraulic brake system according to claim 2, characterized in that the supporting wall ( 57 ) is made of a porous material and is permeable to an amount of outside air, which is about a possible amount of air diffusion through the membrane ( 54 . 62 ) into the brake system. Hydraulic brake system according to claim 2, characterized in that the supporting wall ( 57 ) with at least one through hole ( 61 ) is provided. Hydraulic brake system according to one of claims 1 to 5, characterized in that the separating element is a membrane ( 54 . 62 ), which is only at one annular bead ( 56 ) is supported. Hydraulic brake system according to one of claims 2 to 5, characterized in that to the supporting wall ( 57 ) the membrane ( 62 ) a hump ( 63 ), by its shape at the supporting wall ( 57 ) hunchback ( 63 ) at least one annular chamber ( 55 ) remains. Hydraulic brake system according to one of claims 1 to 5, characterized in that the membrane ( 54 ) of the memory ( 33 . 33.1 ) is formed in the manner of a stop light switch membrane. Hydraulic brake system according to one of claims 6 to 8, characterized in that the supporting wall ( 57 ) and the membrane ( 62 ) from a threaded screw ( 64 ) are held. Hydraulic brake system according to one of claims 6 to 8, characterized in that the supporting wall ( 57 ) and the membrane ( 54 ) of a flange ( 59 ) are held. Hydraulic brake system according to claim 10, characterized in that the supporting wall ( 57 ) with a lid ( 60 ) is covered to the outside. Hydraulic brake system according to one of claims 1 to 10, characterized in that a housing of the memory ( 33 . 33.1 ) with a housing block ( 31 ) of the traction control device and / or the anti-lock device is screwed. Hydraulic brake system according to claim 12, characterized in that a connecting piece ( 41 ) with two L-shaped channels ( 42 and 43 ) for the fluid passage and with a screw ( 52 ) is provided. Hydraulic brake system according to one of claims 1 to 10, characterized in that the memory ( 33.1 ) in a housing block ( 31 ) is integrated a traction control device and / or an anti-lock device. Hydraulic brake system according to one of claims 12 to 14, characterized in that the memory ( 33 ) in the main brake side brake line ( 20 ) is inserted. Hydraulic brake system according to claim 12 or 14, characterized in that the memory ( 33.1 ) between an input of the high-pressure pump ( 29 ) and an open in traction control operation shut-off valve ( 28 ) connected.