HYDRAULIC BLOCK FOR A HYDRAULIC POWER UNIT OF A HYDRAULIC VEHICLE BRAKING SYSTEM

20220363231 ยท 2022-11-17

    Inventors

    Cpc classification

    International classification

    Abstract

    A hydraulic block for a hydraulic power unit of a hydraulic, slipped-controlled power vehicle braking system. A power piston of an electromechanical power brake pressure generator in a power cylinder borehole of the hydraulic block is guided radially in the power cylinder borehole with the aid of a guide bushing.

    Claims

    1-9. (canceled)

    10. A hydraulic block for a hydraulic power unit of a hydraulic vehicle braking system, having a power cylinder borehole in which a power piston is axially displaceable, wherein a guide bushing is situated in the power cylinder borehole, which guides the power piston radially in the power cylinder borehole.

    11. The hydraulic block as recited in claim 10, wherein the guide bushing includes a circumferential sealing groove in its inner circumferential surface, in which a first piston seal is situated, which provides sealing between the power piston and the guide bushing.

    12. The hydraulic block as recited in claim 10, wherein the power cylinder borehole includes an annular step on a front face of the guide bushing, in which a second piston seal is situated, which is held axially in the annular step by the guide bushing.

    13. The hydraulic block as recited in claim 12, wherein a brake fluid line opens into the power cylinder borehole axially at a height of the guide bushing, and the guide bushing includes a channel, which leads from the brake fluid line to the annular step of the power cylinder borehole on the front face of the guide bushing.

    14. The hydraulic block as recited in claim 10, wherein the guide bushing includes a circumferential groove on an outside of the guide bushing, and brake fluid lines open into the power cylinder borehole axially at a height of the circumferential groove of the guide bushing on the outside of the guide bushing, which communicate with one another using the circumferential groove on the outside of the guide bushing.

    15. The hydraulic block as recited in claim 10, wherein the power cylinder borehole passes through the hydraulic block, and one end of the power cylinder borehole is closed by a cylinder cover, which protrudes from the hydraulic block and axially extends the power cylinder borehole.

    16. The hydraulic block as recited in claim 15, wherein, outside the guide bushing, an annular gap exists between the power piston and the power cylinder borehole and/or an annular gap exists between the power piston and the cylinder cover.

    17. The hydraulic block as recited in claim 10, wherein a power drive for the power piston at the hydraulic block is situated at an opening of the power cylinder borehole, using which the power piston is displaceable for generating a brake pressure in the power cylinder borehole.

    18. The hydraulic block as recited in claim 10, wherein the hydraulic block includes a master brake cylinder borehole and/or a simulator cylinder borehole.

    Description

    BRIEF DESCRIPTION OF THE DRAWINGS

    [0013] The present invention is described in greater detail hereafter based on one specific embodiment shown in the figure.

    [0014] FIG. 1 shows a section of a hydraulic block axially through a power cylinder bore of a hydraulic power unit according to an example embodiment of the present invention.

    DETAILED DESCRIPTION OF EXAMPLE EMBODIMENTS

    [0015] Hydraulic power unit 1 according to an example embodiment of the present invention shown in FIG. 1 is provided for a pressure generation in a hydraulic power vehicle braking system including a slip controller. Such slip controllers are, for example, anti-lock braking units, traction control units and/or vehicle dynamics control units/electronic stability programs, for which the abbreviations ABS, TCS and VDC/ESP are common.

    [0016] Hydraulic power unit 1 according to the present invention includes a hydraulic block 2 for a mechanical attachment and hydraulic interconnection of hydraulic and other components of the slip controller, such as solenoid valves, check valves, hydraulic accumulators and damper chambers. The components are situated at and in hydraulic block 1 and hydraulically connected to one another by a bore of hydraulic block 2, which is not shown, corresponding to a hydraulic diagram of the power vehicle braking system and the slip controller. Two solenoid valves 27 are shown as graphical symbols by way of example.

    [0017] In the illustrated and described specific embodiment of the present invention, hydraulic block 2 is a cuboidal, flat metal block made up of, for example, an aluminum alloy, which is provided with boreholes for accommodating the components and includes boreholes corresponding to the hydraulic diagram of the vehicle braking system and the slip controller.

    [0018] Hydraulic block 2 includes a through-hole perpendicular to two large, mutually opposing sides of hydraulic block 2 as a power cylinder borehole 3, in which a power cylinder 4 is axially displaceably accommodated. For an axially displaceable guidance of power piston 4, a guide bushing 5 is axially fixed in power cylinder borehole 3, which radially guides power piston 4 in power cylinder borehole 3.

    [0019] In the exemplary embodiment, guide bushing 5 is made of plastic. On the outside, guide bushing 5 is sealed by a force fit in power cylinder borehole 3 in hydraulic block 2.

    [0020] On the inside, guide bushing 5 includes a circumferential sealing groove 6 in which a sealing ring is situated as first piston seal 7. First piston seal 7, which may also be interpreted as a high pressure seal for power piston 4, provides sealing between power piston 4 and guide bushing 5.

    [0021] An annular step 8 of power cylinder borehole 3 axially adjoins guide bushing 5, with the aid of which power cylinder borehole 3 is reduced to a smaller diameter than in the area of guide bushing 5. Annular step 8 has an axial distance from guide bushing 5, so that a circumferential groove is formed in which a second piston seal 9 is situated, which may also be interpreted as a low pressure seal. Second piston seal 9 is held axially between guide bushing 5 and annular step 8 of power cylinder borehole 3. It provides sealing between power cylinder borehole 3 and power piston 4.

    [0022] Axially at the height of guide bushing 5, a brake fluid line 10 in hydraulic block 2 opens into power cylinder borehole 3. In the exemplary embodiment, brake fluid line 10 opens into power cylinder borehole 3 between first and second piston seals 7, 9. Guide bushing 5 includes a channel 11, which leads from the opening of brake fluid borehole 10 to a front face of guide bushing 5 which faces annular step 8, so that brake fluid line 10 communicates through channel 11 on a front face facing guide bushing 5 with second piston seal 9. Channel 11, as shown, may, for example, be an axially parallel groove in an outer circumference of guide bushing 5 or a borehole in guide bushing 5 extending from the outer circumference to the front face of guide bushing 5 which faces annular step 8 (not shown). Guide bushing 5 is situated in power cylinder borehole 3 rotated in such a way that its channel 11 communicates with brake fluid line 10. Brake fluid line 10 communicates with a brake fluid reservoir, which is not shown, and causes a lubrication of an outer circumference of power piston 4 in the area of second piston seal 9. During an axial movement, the brake fluid on the outer circumference of power piston 4 also reaches first piston seal 7, so that both piston seals 7, 9 are lubricated.

    [0023] On the outside, guide bushing 5 includes a circumferential groove 12, which is interrupted at channel 11 and ends on both sides at a distance from channel 11, so that groove 12 does not communicate with channel 11. Brake fluid lines 13, which communicate with one another by groove 12, open axially into power cylinder borehole 3 at the height of groove 12 in the outer circumference of guide bushing 5 at two circumferential points. In this way, the two brake fluid lines 13, which connect hydraulic components of the slip controller of the hydraulic power vehicle braking system to one another, are connected to one another on the outside around power cylinder borehole 3. In the shown exemplary embodiment of the present invention, the two brake fluid lines 13 are situated outside the section plane, which is why one of the two brake fluid lines 13 is shown rotated into the section plane. The other brake fluid line 13 is not visible in the drawing.

    [0024] Power cylinder borehole 3 extending through hydraulic block 2 is closed at one end by a cup-shaped cylinder cover 14, which in the exemplary embodiment is screwed into power cylinder borehole 3. Fastening with the aid of a spring washer is also possible, for example, which on the outside engages in a circumferential groove on the inside of power cylinder borehole 3, and on the inside engages in a circumferential groove on the outside of cylinder cover 14 (not shown). Cylinder cover 14 protrudes to the outside from hydraulic block 2 and extends power cylinder borehole 3, and thereby a displacement travel of power piston 4.

    [0025] Cylinder cover 14 is a crown cover including an edge which includes radial slots and by which it holds guide bushing 5 axially in power cylinder borehole 3. Brake fluid may pass through the radial slots.

    [0026] Outside guide bushing 5, power cylinder borehole 3 has a larger diameter than power piston 4, so that an annular gap 15 exists between power piston 4 and power cylinder borehole 3. Cylinder cover 14 also has a larger inside diameter than power piston 4, so that an annular gap 16 also exists between the power piston and cylinder cover 14 in cylinder cover 14. As a result, power piston 4 is exclusively radially guided in guide bushing 5.

    [0027] For the displacement of power piston 4 in power cylinder borehole 3 for generating a brake pressure using external power, hydraulic power unit 1 includes an electric motor 17, which displaces power piston 4 via a planetary gear 18 as a reduction gear and a ball screw 19 in power cylinder borehole 3. Ball screw 19 may, generally speaking, also be interpreted as a worm gear or as a rotatory/translatory conversion gear. Ball screw 19 is partially situated in power piston 4 coaxially to power piston 4 and to power cylinder borehole 3, the power piston being designed as a hollow piston for this purpose. Ball screw 19 is mounted with the aid of a ball bearing 20, which is situated with a tubular bearing holder 21 on the outside of hydraulic block 2. Planetary gear 18 is also situated coaxially to power cylinder borehole 3 and to power piston 4, between ball screw 19 and electric motor 17. Electric motor 17 includes a motor housing 22, which is also screwed to the outside of hydraulic block 2 coaxially to power cylinder borehole 3 and to power piston 4. Electric motor 17, planetary gear 18, and ball screw 19 form an electromechanical power drive 23, by which power piston 4 is axially displaceable in power cylinder borehole 3 for generating the brake pressure for the vehicle braking system using external power. Together with power cylinder borehole 3, cylinder cover 14, and power piston 4, power drive 23 forms a power brake pressure generator 24 of hydraulic power unit 1 according to the present invention. The present invention does not preclude a generation of the brake pressure using external power other than the electromechanical generation.

    [0028] In the illustrated and described specific embodiment of the present invention, hydraulic block 2 includes a master brake cylinder borehole 25, in which a master brake cylinder piston (not shown) is situatable, which is mechanically displaceable via a piston rod with the aid of a foot brake pedal, which is not shown, or a hand brake lever in master brake cylinder borehole 25. Furthermore, hydraulic block 2 includes a simulator cylinder borehole 26 for a simulator piston, which is not shown and, for example, is acted upon by a spring. From master brake cylinder borehole 25, brake fluid is displaceable into simulator cylinder borehole 26 to be able to displace the master brake cylinder piston in master brake cylinder borehole 25 during a power actuation of the vehicle braking system. In addition to power brake pressure generator 24, the vehicle braking system may also be actuated by muscle power by the displacement of the master brake cylinder piston in master brake cylinder borehole 25, which is, in particular, provided in the event of a malfunction or a failure of power brake pressure generator 24.

    [0029] Power cylinder borehole 3, master brake cylinder borehole 25 and/or simulator cylinder borehole 26 may also be created in a manner other than boring.