DE2556718C2 - Brake force distributor for a dual-circuit brake system - Google Patents

Description

The invention relates to a firing force distributor for a dual-circuit brake system with one of a control force influenced stepped piston, through which a rear ^ s wheel brakes feedable pressure of a first brake circuit can be influenced above a Umsehalipunktes determined by the control force.

Kin such Breniskraltverteilcr isl from DE-OS 58 J98 known. Inside the graduated piston there is a mi a valve member controlling a valve passage is arranged, which is loaded in Schlicßrichlung by a closing spring and the one protruding through the valve passage The extension is supported by a piston rod. their axial position through the brake door, pressure in the second circle, the front wheel circle will. Hei fallen out front wheel circle is through the Piston rod of the valve opening oflengehalien: es crfolgl none. Influence of the brake pressure of the first brake circuit fed to the rear wheel brakes.

A brake force distributor for a dual-circuit brake system has already been proposed (DE-OS 25 24 842), in which a stepped piston is assigned to each of the two brake circuits, through which a rear wheel braking Permissible pressure of each brake circuit above a look-over point determined by the control force can be influenced The stepped pistons are in tandem with the interposition of another Pistons arranged one behind the other in a housing. If either of the two fails In the braking circuit, the switchover point is not changed in the circuit that is still intact

A brake force distributor of the type mentioned at the beginning is also known from DE-PS 16 55 294. In the known Bremskraftvericiler part of the control force from a first, always supported on the stepped piston Spring applied. A second preloaded spring that applies the second part of the control force is over a Federicller on a gradation of the stepped piston and / or can be supported by an annular piston. The annular piston is arranged coaxially around the stepped piston and sealingly displaceable on it and in the housing and delimits one with its side facing away from the spring annulus connected to a second brake circuit. So if the second brake circuit is intact, the The ring piston is moved by its pressure against the spring, so that the spring plate is off the graduation is lifted off and the second spring has no influence on the stepped piston. The switching point of the Brcniskrafivcrtcilers is only used in this case determined by the force of the first spring. If, on the other hand, the second brake circuit off, the stepped piston is also acted upon by the second spring, i.e. the entire control force, whereby the switchover point is increased so that the stepped piston is fed to the rear wheel brakes The pressure is only reduced at a higher pressure in the first brake circuit

Ks is disadvantageous in that, to the Umschalipunkl To be able to change in the event of failure of the second brake circuit, the control force is composed of two partial forces must be, for which the two springs are required. But even if you disregard it, it comes through the arrangement of the annular piston triple guidance of the stepped piston, the guidance of the stepped piston in the Ringkolbcn must also be coaxial to its guidance in the housing. This will make the parts are manufactured with very tight manufacturing tolerances, whereby the entire brake force distributor is considerably more expensive. Furthermore, the stepped piston must be Its return movement also affects the frictional force of the seal arranged between it and the annular piston in addition, overcome what leads to an enlarged Hysleresc leads.

The invention is based on the object of designing a braking force distributor of the type mentioned at the outset in such a way that that there are different switching points with an intact second brake circuit, the control force but not composed by two partial forces isl.

This object is achieved according to the invention. that by the control force a coaxial to the stepped piston arranged control piston is acted upon in the direction of the spigot piston. where the control piston and a facing Tcii of the stepped piston have different diameters, and that in a space, which is limited by the stepped piston and control piston. Pressure medium of a second brake circuit Ιοί ι -

_: Is bar to the spool hydraulically this; Pressure medium is supported on the stepped piston.
ι _ This training ensures that the Stufv. piston in the event of failure of the second brake force.: is mechanically acted upon by the entire control force. If the second brake circuit fails, the switching point of the brake force distributor is determined by the size of the control force Translation through which; ^: is then determined according to the transmission ratio of the switching points

;! Although it is already a through DE-OS 22 61 381

Brake force distributor has become known in which the |, control force is transmitted to the stepped piston by means of a hydraulic transmission [; ■ .:. With this E -.- ;. The brake force distributor is not, however, influencing f: i ^; provided by the second brake circuit. The hydraulic ratio only serves there to ensure that a very, ...: small control force can be provided and, in spite of this, a relatively high switchover point is reached. In the event of: failure of the second brake circuit, with this known brake force distributor, the first brake circuit slows down; as before regulated completely unchanged.
: Because one that delimits the space in between

Area of the control piston is larger than one of the space facing surface of the stepped piston, it is achieved that the switchover point with an intact second ■■■■ Brake circuit at a lower pressure in the first Brake circuit is reached as if the second brake? -; ' circle has failed.

In an advantageous embodiment it is provided hen that the control piston has an annular groove through which L an annular space connected to the second brake circuit ; ' is formed, and between the annular space and intermediate space a connection that can be closed by a valve member: '■; consists, the valve member as a towards : The space blocking one-way valve is formed and held in the open position by the stepped piston is as long as this control piston is mechanically supported. This ensures that the space only as much pressure medium is supplied to the second brake circuit as is required to establish the mechanical connection between the control piston and the stepped piston. A particularly compact design results, if the connection is provided in the interior of the control piston and the connection is arranged in the connection The valve member is loaded in the closing direction by a closing spring and one in the closing direction in the intermediate space has protruding extension that can be supported on the stepped piston.

Further advantages emerge from the following description and the drawing. In the drawing shows

F i g. 1 an example of execution in section:
2 shows a diagram to illustrate the mode of operation.

In Fi g. 1 has a housing 1 a stepped bore 2, which is shown in section Λ. B and C is divided Here, the section A u ^r \ cl, the section C is each larger than the section B. li ¹ the sections A and ß is a sealingly displaceable ¹ 'stepped piston 3 is arranged, which in its middle! ¹ area delimits an inlet space 4. The EiPlaßrai'rn 4 is connected to the first brake circuit of a master cylinder, not shown. With its end face on the left in the drawing, the stepped piston 3 delimits an outlet space 5 in section A , which is connected to the wheel brakes of a rear axle, also not shown. A pressure medium passage 6, which can be closed by a valve member 7, is provided in the stepped piston 3. The valve member 7 is pretensioned in the closing direction by a valve spring 8.

In section C , a control piston 9 is arranged in a sealingly displaceable manner and delimits an intermediate space 10 with its left end face. The intermediate space 10 is limited in section B by the right end of the stepped piston 3. The control piston 9 has an annular groove 11 through which an annular space 12 is pressure-tight. The annular space 12 is connected to the second brake circuit of the master cylinder, not shown. A connection 13 is provided in the control piston 9, which leads from the annular space 12 to the intermediate space 10; a valve member 14 is arranged in the connection 13 and is biased towards the stepped piston 3 in the closing direction by a closing spring 16. The valve member 14 has an extension 15 which protrudes from the connection 13 in the intermediate space 10, whereby the valve member 14 can be pushed open by the stepped piston 3. so that no pressure medium can then flow from the annular space 12 into the intermediate space 10.

At the right end of the housing 1, a spring hat 17 is attached, in which a spring 18 is arranged, which via a spring plate 19 to the left on the control piston 9 jo and thus the control force for the brake force distributor certainly.

In the diagram of FIG. 2, the master cylinder pressure of the first brake circuit is on the abscissa and on the ordinate of the pressure acting on the rear wheel brakes is plotted.

The following function of the brake force distributor according to the invention results:

When the brake system is completely intact, pressure medium from the first brake circuit is supplied to the inlet chamber 4 and pressure medium from the second brake circuit is supplied to the annular chamber 12. Since all parts are in the position shown and thus the valve members 7 and 14 are held in the open position, the pressure medium supplied to the inlet chamber 4 passes through the. Passage 6 into the outlet space 5 and from there to the rear wheel brakes. The pressure medium fed to the annular space 12 passes through the connection 13 into the intermediate space 10. The pressure building up in the intermediate space 10 shifts the control piston to the right against the action of the spring 18, whereby a pressure medium cushion is created between the stepped piston 3 and the control piston 9 and the valve member 14 arrives in the closed position. This means that no further pressure medium can flow from the annular space 12 into the intermediate space 10. Due to the pressure medium cushion located in the space 10, a hydraulic translation has become effective between the control piston 9 and the stepped piston 3, through which the control force acting on the control piston 9 by the spring 18 corresponds to the w) area ratio of the control piston 9 to the stepped piston 3 in the space 10 only acts still reduced on the stepped piston 3. At a certain pressure in the first Brcm.skreis the stepped piston is 3 overcome the diminished by the hydraulic transmission control force by acting on it pressures in the inlet chamber 4 and the outlet b ^r> room 5 and move to the right. The switchover point 23 in the diagram in FIG. 2 reached.

With further pressure build-up in the inlet chamber 4, only a correspondingly reduced pressure occurs in the outlet chamber 5 Pressure build-up instead. This further increase in pressure is illustrated by straight line 21 in the diagram in FIG. 2.

If the second brake circuit fails, the annular space 12 and thus also the intermediate space 10 do not become Pressure medium supplied. There can therefore also be no pressure medium cushion between the control piston 9 and the stepped piston 3 form, which is why in this case always the full control force determined by the spring 18 on the stepped piston 3 works. This means that there must be a higher pressure in the inlet chamber 4 and in the outlet chamber 5 until the stepped piston 3 is able to move against the control force of the spring 18 to the right. It results Thus in this case the one in the diagram of FIG. 2 is higher switchover point 24 shown. From this switchover point 24, the pressure in the Outlet chamber 5 compared to the pressure in the inlet chamber 4 with further pressure build-up, which is reduced by the Just 22 is shown.

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Claims (5)

Patent claims: 1. Bremskraftverteiier for a two-circuit brake system with a ^r , stepped piston influenced by a control force, by means of which a pressure of a first brake circuit which can be fed to a rear wheel braking can be influenced above a switching point determined by the control force, characterized in that a piston (3 ) the coaxially arranged control piston (9) is acted upon in the direction of the stepped piston (3). wherein the control piston (9) and a facing him part of the stepped piston (3) have different diameters, and that in an intermediate space i i ^r (10). which is limited by the stepped piston (J) and control piston (9), pressure medium of a second brake circuit can be conducted until the control piston (9) is hydraulically supported on the stepped piston (3) via this pressure medium. 2. Bremskraftverteiier according to claim 1, characterized in that one of the intermediate space (10) delimiting area of the control piston (9) is larger than an area facing the intermediate space (10) of the stepped piston (3). 3. Bremskraftverteiier according to claim I or 2, characterized in that the control piston (9) has a Has an annular groove (11) through which an annular space (12) connected to the second brake circuit is formed and between the annular space (12) and the intermediate space (10) jo a connection which can be closed by a valve glicd (14) (13) consists, the Ventilglicd (14) as a blocking in the direction of the intermediate space (10) One-way valve designed isl and from the Siufenkolben (3) is held in the open position. as long as this Γι mechanically supported on the control piston (9) isl. 4. Breniskraftverteiler according to claim 3, characterized characterized in that the connection (13) is provided in the interior of the piston (9), and that in the Connection (13) arranged valve member (14) loaded in the closing direction by a closing spring (16) is and one in Schl.icßriehtung in the gap (10) protruding, on the stepped piston (3) can be supported Extension (14) has. 5. Bremskraftverteiier according to one of claims 4 ^r > before 1 to 4, characterized in that the control force is determined by a spring (18) supported on the control piston (9).