ELECTRIC MOTOR-PUMP ASSEMBLY

Abstract

In an electric motor-pump assembly, two working diaphragms, each delimiting a working chamber, are cyclically driven by a crank drive via connecting rods. The crank drive includes eccentrics for each connecting rod, which are placed on an axial bearing journal in the extension of an output shaft of an electric motor. In order to ensure a rotationally fixed connection between the eccentrics and the bearing journal to be produced and in order to ensure an angularly precise position of the two eccentrics, each of the eccentrics is connected to the bearing journal by a positively locking engagement.

Claims

1. An electric motor-pump assembly, for providing pressure for a brake actuation device of a motor vehicle brake system, having a pneumatic brake booster comprising: a vacuum pump; and an electric motor driving the vacuum pump, wherein the vacuum pump comprises at least two working chambers, each defined by a working element, wherein each working element is connected to a connecting rod, which is supported by a crank drive, which comprises a bearing journal, which is driven by the electric motor and onto which an eccentric for each connecting rod is rotationally locked, for which purpose said eccentric has an opening, through which the bearing journal projects, and wherein the rotationally locked connection between the bearing journal and each of the eccentrics is produced by a positive interlock, for which purpose the bearing journal and the opening have a cross section deviating from a circular shape.

2. The electric motor-pump assembly as claimed in claim 1, wherein the bearing journal has at least one lateral flat and that the circumferential surface of each opening through which the bearing journal passes has a boundary surface, which is set against the flat to form a positive interlock.

3. The electric motor-pump assembly as claimed in claim 2, wherein the bearing journal has at least two opposing flats, the distance between which corresponds to the distance between the parallel boundary surfaces of the openings.

4. The electric motor-pump assembly as claimed in claim 1, wherein the bearing journal is provided with a plurality of longitudinal channels.

5. The electric motor-pump assembly as claimed in claim 4, wherein a free end of the bearing journal comprises a head tapering conically towards the free end of the bearing journal.

6. An electric motor-pump assembly, for providing pressure for a brake actuation device of a motor vehicle brake system, having a pneumatic brake booster, comprising: a vacuum pump (1); an electric motor driving the vacuum pump; wherein the vacuum pump comprises at least two working chambers, each defined by a working element, wherein each working element is connected to a connecting rod, which is supported by a crank drive, which comprises a bearing journal, which is driven by the electric motor and onto which an eccentric for each connecting rod is rotationally locked, and wherein the output shaft of the electric motor has an open blind hole in the end face, that the eccentrics each have a hole with the same cross section as the blind hole, and that a clamping sleeve runs through the hole and the blind hole.

7. The electric motor-pump assembly as claimed in claim 6, wherein the clamping sleeve comprises a spring steel hollow cylinder, which is provided with a longitudinal slot.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] The invention will be explained in more detail below with reference to an exemplary embodiment. In the drawing:

[0018] FIG. 1 shows an embodiment according to the state of the art,

[0019] FIG. 2 shows a side view of a bearing journal as output shaft of an electric motor,

[0020] FIG. 3 shows a side view of an eccentric, matching the bearing journal according to FIG. 2,

[0021] FIG. 4 shows a crank drive, which is connected to the output shaft by means of a clamping sleeve,

[0022] FIG. 5 shows a side view and a cross sectional view of the clamping sleeve and FIG. 6 shows a further embodiment of the bearing journal.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0023] Referring first of all to FIG. 1:

[0024] The vacuum pump 1 is a double-diaphragm pump having two opposing working diaphragms 2, which are each clamped between a pump housing 3 and a working chamber cover 4 and thereby define a working chamber 5. The working diaphragms 2 can be moved in opposite directions by means of a crank drive 6, wherein the crank drive 6 has an eccentric 7 for each working diaphragm 2, on which the eye of a connecting rod 8, connected to the respective working diaphragm 2, is supported. The reciprocating movement of the working diaphragms 2, which in this exemplary embodiment form the working elements of the vacuum pump 1, causes air to be drawn into the working chamber from the unit to be exhausted, before it is expelled into the atmosphere.

[0025] A discharge valve—not shown here—via which the air expelled from the working chamber is fed, in each case via a discharge port in the working chamber cover, to a discharge port in the pump housing 3, is provided in each of the working chamber covers 4. The two discharge ports in the pump housing open into an internal chamber 9 of the pump housing 3, the so-called crank chamber, which encloses the crank drive 6. An air outlet 10 provided in the pump housing allows the air to be quietly discharged from the internal chamber 9.

[0026] Eccentrics 7, 7′ are press-fitted onto a bearing journal 11 of circular cross section, which extends the output shaft 12 of an electric motor 13, externally fitted to the pump housing 3, in an axial direction, and the axis of which lies in the axis of the output shaft 12.

[0027] By contrast, an aspect of the invention, as represented in FIGS. 2 and 3, provides for a bearing journal 11 having an angular cross section with multiple lateral flats 14, which each run parallel to the axis of the bearing journal 11, and at least two of which are situated opposite one another and run parallel.

[0028] Each eccentric 7 according to FIG. 3 comprises a disk, which has an off-center opening 15, which has a rectangular cross section. A balance weight 16, which extends in a radial direction, can also be seen, integrally formed with the disk.

[0029] The distance between the two long sides of the opening 7, which each form a boundary surface 17, is equal to the distance between the two aforementioned flats 14. The distance between the short sides of the opening 15 is equal to the diameter of the bearing journal 11, relative to a plane, parallel to the flats 14 and running through the axis of the bearing journal. In this way a positive interlock is obtained between the bearing journal and the eccentric 7.

[0030] The disks are of a certain thickness, so that the opening 15 has a certain depth, allowing the flats 14 to bear against the long boundary surfaces of the rectangular opening 15 over a sufficiently large contact area. This ensures that a sufficiently large torque can be transmitted.

[0031] In addition, this allows a second eccentric 7′, which is of similar construction to the first eccentric 7 represented, to be fitted onto the bearing journal at precisely 180° to the first eccentric 7.

[0032] FIG. 4 shows the cross section through a further invention. An axial blind hole 18 is made in the end face of the output shaft 12. Holes 19 in the eccentrics 7 for receiving the bearing journal 11 are circular.

[0033] For a rotationally locked connection of the eccentrics 7 to the output shaft 12, a clamping sleeve 20 is provided. This is a hollow cylinder having a longitudinal slot 21 and made from a spring steel. The longitudinal slot 21 allows the clamping sleeve 20 to be radially compressed when it is fed through the holes. The resilient characteristics then cause the clamping sleeve 20 to expand and create a secure positive interlock in the openings of the eccentric disks and in the blind hole.

[0034] FIG. 6 shows a further embodiment of the bearing journal 11. The bearing journal 11 has a knurled surface, which comprises a plurality of longitudinal channels 22, which allows a positively interlocking connection to an eccentric, which has a corresponding, mating knurled surface.

[0035] At its free end the bearing journal has a conical head 23, which facilitates the fitting of the eccentrics. A groove 24, running around the bearing journal runs between the knurled surface and the head.

REFERENCE NUMERALS

[0036] 1 vacuum pump [0037] 2 working diaphragms [0038] 3 pump housing [0039] 4 working chamber cover [0040] 5 working chamber [0041] 6 crank drive [0042] 7 eccentric [0043] 8 connecting rod [0044] 9 internal chamber [0045] 10 air outlet [0046] 11 bearing journal [0047] 12 output shaft [0048] 13 electric motor [0049] 14 flats [0050] 15 opening [0051] 16 balance weight [0052] 17 boundary surface [0053] 18 blind hole [0054] 19 hole [0055] 20 clamping sleeve [0056] 21 longitudinal slot [0057] 22 longitudinal channels [0058] 23 head [0059] 24 groove