WO2023232361A1

WO2023232361A1 - Motorised brake pressure generator for an externally powered braking system

Info

Publication number: WO2023232361A1
Application number: PCT/EP2023/061298
Authority: WO
Inventors: Herbert Vollert; Willi Nagel; Janos Tamas Csoti; Michael OSSES
Original assignee: Robert Bosch Gmbh
Priority date: 2022-05-30
Filing date: 2023-04-28
Publication date: 2023-12-07
Also published as: DE102022205423A1

Abstract

The invention relates to a motorised brake pressure generator for an externally powered braking system comprising an electric motor (10), a primary piston (12) a main brake cylinder housing (14) with at least one primary spring (16) arranged in the main brake cylinder housing (14), wherein the primary piston (12) is supported by the primary spring (16), and a transmission (22) with at least one rotational and translational transmission stage formed by a spindle (24) and a nut (26) arranged on the spindle (24), wherein the main brake cylinder housing (14) is screwed onto a first side (32a) of a transmission housing (32), with the transmission (22) arranged therein, by means of at least one screw (30), and wherein the electric motor (10) is mechanically connected to the primary piston (12) via at least the rotational and translational transmission stage of the transmission (22) in such a way that the primary piston (12) can be adjusted along an adjustment axis (28) by means of a transmitted motor force of the electric motor (10) against a restoring force at least of the primary spring (16).

Description

title

Motorized brake pressure generator for an external power braking system

The invention relates to a motorized brake pressure generator for an external power braking system and an external power braking system for a vehicle.

State of the art

DE 10 2018 211 443 A1 describes a pressure generating device which is integrated together with a master brake cylinder in a housing manufactured as an extruded profile. The pressure generating device is equipped with an electric motor and a rotation and translation gear stage consisting of a spindle and a nut.

Disclosure of the invention

The invention creates a motorized brake pressure generator for a power braking system with the features of claim 1 and a power braking system for a vehicle with the features of claim 11.

Advantages of the invention

The present invention creates a motorized brake pressure generator for an external power brake system, the master brake cylinder housing of which is designed as a separate assembly from the gearbox housing with at least the gearbox arranged therein. The master brake cylinder housing can therefore be produced comparatively inexpensively. In addition, the master brake cylinder housing, which is screwed to the transmission housing using at least one screw, can be repaired or replaced relatively easily. In the event of service, any damage that occurs to the master brake cylinder housing can therefore be repaired more easily. In particular, despite the use of the motorized brake pressure generator according to the invention in an external power brake system, its master brake cylinder housing can be a component of a brake system type which is designed to convert a driver's braking force into a brake pressure increase. The present invention thus increases the usability of the same type of master brake cylinder housing for different brake system types.

The master brake cylinder housing is preferably a chill casting. Due to its cast design, the master brake cylinder housing can be manufactured relatively inexpensively in this case.

In an advantageous embodiment of the motorized brake pressure generator, the electric motor is mechanically connected to the primary piston via at least the rotational and translational gear stage of the transmission in such a way that, during operation of the electric motor, a rotor of the electric motor moves into a rotating movement about an axis aligned parallel to the adjustment axis of the primary piston and the rotation axis spaced from the adjustment axis is offset. The embodiment described here thus realizes a parallel arrangement of the electric motor to the primary piston, whereby a maximum expansion of the motorized brake pressure generator along the adjustment axis of its primary piston can be reduced.

In particular, the master brake cylinder housing can be screwed to a protruding first section of the first side of the transmission housing by means of the at least one screw, the electric motor being arranged in a motor housing and the motor housing being fastened to a second section of the first side of the transmission housing which is set back compared to the first section . The parallel arrangement of the electric motor to the primary piston and the arrangement of the electric motor in its own motor housing can thus enable a compact design of the motorized brake pressure generator.

In a further advantageous embodiment, the electric motor is mechanically connected to the primary piston via at least the rotational and translational gear stage of the transmission in such a way that during operation of the Electric motor, the rotor of the electric motor is offset in a rotating movement about a rotation axis aligned perpendicular to the adjustment axis of the primary piston. The embodiment of the motorized brake pressure generator described here also has a comparatively short installation space length along the adjustment axis due to a vertical or L-shaped arrangement of the electric motor to the primary piston of its primary piston.

For example, the electric motor can be arranged in the motor housing and the motor housing can be attached to a third side of the gear housing, which lies between the first side of the gear housing and a second side of the gear housing directed away from the first side of the gear housing. The compact structure of the motorized brake pressure generator realized in this way facilitates installation of the motorized brake pressure generator on a large number of vehicle types/motor vehicle types.

Alternatively, the electric motor can be mechanically connected to the primary piston via at least the rotational and translational gear stage of the transmission in such a way that the rotor of the electric motor is set in a rotating movement about the adjustment axis of the primary piston during operation of the electric motor. The embodiment of the motorized brake pressure generator described here has relatively small dimensions due to a coaxial arrangement of the electric motor and the primary piston perpendicular to the adjustment axis of its primary piston.

In particular, the electric motor can be arranged in the motor housing and the motor housing can be attached to the second side of the gear housing directed away from the first side of the gear housing. The master brake cylinder housing, the transmission housing and the motor housing can thus be arranged coaxially or one behind the other along the adjustment axis of the primary piston.

It can also be advantageous if the electric motor is arranged in the transmission housing. In this case, the gearbox housing can be used as a gearbox and motor housing with increased functionality. As an advantageous further development, a first recess can be formed on a first piston side of the primary piston, in which at least a partial section of the primary spring aligned with the primary piston is fastened, and a second recess can be formed on a second piston side of the primary piston directed away from the first piston side, in which a portion of the spindle aligned with the primary piston or a portion of the nut aligned with the primary piston is fastened, wherein the spindle or the nut can be set in a rotational movement in relation to the primary piston by means of the operation of the electric motor and at least one portion aligned with the primary piston Partial section of the spindle or nut set into rotational movement can be rotated into the second recess of the primary piston, and wherein the first recess formed on the first piston side frames at least a partial section of the second recess aligned with the first piston side. A stroke of the spindle or nut can thus be at least partially accommodated in an additional installation space provided by the primary piston, which advantageously contributes to reducing the overall length of the motorized brake pressure generator along the adjustment axis of its primary piston.

An external power braking system for a vehicle with such a motorized brake pressure generator also ensures the advantages explained above. The external power braking system can be, for example, a brake-by-wire braking system. The advantages explained above can therefore be used specifically for a type of brake system in which the master brake cylinder formed in the master brake cylinder housing is mechanically decoupled from a brake actuating element of the brake system, such as a brake pedal.

Brief description of the drawings

Further features and advantages of the present invention are explained below with reference to the figures. Show it:

1a to 1c show schematic representations of a first embodiment of the motorized brake pressure generator;

2a and 2b show schematic representations of a second embodiment of the motorized brake pressure generator; 3 shows a schematic representation of a third embodiment of the motorized brake pressure generator;

4a and 4b show schematic representations of a fourth embodiment of the motorized brake pressure generator; and

5a and 5b schematic representations of a fifth embodiment of the motorized brake pressure generator.

Embodiments of the invention

1a to 1c show schematic representations of a first embodiment of the motorized brake pressure generator.

The motorized brake pressure generator shown schematically in FIGS. 1 a to 1 c is designed with an electric motor 10, the motor power of which can be transferred to at least one primary piston 12 of the motorized brake pressure generator in the manner described below. The primary piston 12 is supported by a primary spring 16 arranged in a master brake cylinder housing 14. Merely as an example, in the embodiment described here, the primary piston 12 is supported by means of the primary spring 16 from a secondary piston 18 arranged in the master brake cylinder housing 14, the secondary piston 18 being supported by means of a secondary spring 20 from an inner wall of the master brake cylinder housing 14. Alternatively, the primary piston 12 can also be supported by the primary spring 16 from the inner wall of the master brake cylinder housing 14.

The motorized brake pressure generator also includes a gear 22 with at least one rotational and translational gear stage consisting of a spindle 24 and a nut 26 arranged on the spindle 24. The rotational and translational gear stage consisting of the spindle 24 and the nut 26 can, for example, be a thread -Spindle stage or a ball screw drive (KGT). The electric motor 10 is mechanically connected to the primary piston 12 via at least the rotational and translational gear stage of the transmission 22 in such a way that the motor power of the electric motor 10 can be transferred to the primary piston 12 via at least the rotational and translational gear stage of the transmission 22 is/is transmitted that the primary piston 12 is/is adjustable along an adjustment axis 28 by means of the transmitted motor force against a restoring force of at least the primary spring 16 (and possibly the secondary spring 20). As can be seen in FIGS. 1a and 1c, the motor power of the electric motor 10 is transmitted from the rotational and translational gear stage of the transmission 22 to the primary piston 12 via mechanical contact of the spindle 24 and/or the nut 26 with the primary piston 12. The motorized brake pressure generator therefore does not require a variety of components conventionally installed on a brake pressure generator, such as a reaction disk, a valve body, an input rod and an output rod. This reduces the space required for the motorized brake pressure generator and reduces its manufacturing costs.

In addition to the master brake cylinder housing 14, the motorized brake pressure generator also has at least one further housing 32, which is further referred to as the gear housing 32 (due to the arrangement of at least the gear 22 therein). In addition, the master brake cylinder housing 14 is screwed by means of at least one screw 30 to a first side 32a of the transmission housing 32 with the transmission 22 arranged therein. In the motorized brake pressure generator, a master brake cylinder formed in its master brake cylinder housing 14 is therefore a separate or independent assembly. This makes it easier to repair or replace the master brake cylinder, for example in the event of service.

The master brake cylinder housing 14 can be a chill casting, such as specifically a chill casting made of aluminum. Although the motorized brake pressure generator is optimized for use in a power brake system, a component of a brake system type designed to convert a driver's braking force into a brake pressure increase may be used as its master cylinder housing 14. The technology described here thus increases the usability of the master brake cylinder housing 14 for different types of brake systems. This contributes to an additional reduction in the manufacturing costs of the motorized brake pressure generator.

The transmission 22 can also be understood as an electromechanical brake booster. In addition to that from the spindle 24 and the nut 26 formed rotational and translational gear stage, the gearbox 22 can have at least one further gear stage. However, the rotational and translational gear stage formed from the spindle 24 and the nut 26 is preferably a final stage of the power transmission path of the gear 22 from the electric motor 10 to the primary piston 12.

As can be seen in FIGS. 1a and 1c, a first recess 12b is formed on the primary piston 12 on a first piston side 12a, in which at least a partial section of the primary spring 16 aligned with the primary piston 12 is fastened. On a second piston side 12c of the primary piston 12 directed away from the first piston side 12a, a second recess 12d is formed, in which a partial section of the spindle 24 aligned with the primary piston 12 or a partial section of the nut 26 aligned with the primary piston 12 is fastened. Optionally, either the spindle 24 or the nut 26 can be set into a rotational movement in relation to the primary piston 12 by means of the operation of the electric motor 10, whereby at least a portion of the spindle 24 or nut 26 that is aligned with the primary piston 12 and is set into rotational movement into the second recess 12d of the primary piston 12 can be turned in/is turned in. A stroke of the spindle 24 or nut 26 can thus be at least partially accommodated in an additional installation space provided by the primary piston 12. This can be used advantageously to reduce the overall length of the motorized brake pressure generator along the adjustment axis 28 of the primary piston 12. By “sinking” the spindle 24 and nut 26 at least partially into the second recess 12d of the primary piston 12, undesirable protrusion of the spindle 24 into a passenger compartment can also be avoided.

As an advantageous further development, the primary piston 12 described here is also shaped in such a way that the first recess 12b formed on the first piston side 12a frames at least a portion of the second recess 12d that is aligned with the first piston side 12a. This contributes to the additional increase in compactness of the motorized brake pressure generator. The advantageous shape of the primary piston 12 can also be described by saying that the second recess 12d of the primary piston 12 extends from the second side 10c into a partial piston volume of the primary piston 12 framed by the first recess 12b. Preferably, by means of a on the first side 12a of the primary piston 12 is formed Cover section/piston crown of the piston partial volume prevents brake fluid from penetrating from the master brake cylinder housing 14 into the second recess 12d of the primary piston 12

In the primary piston 12 described here, at least the portion of the nut 26 aligned with the primary piston 12 is fastened in the second recess 12d of the primary piston 12, while the spindle 24, which is set in rotation, can be rotated into the second recess 12d. In this case, a maximum stroke of the spindle 24 and nut 26 can be accommodated completely in the installation space of the primary piston 12. Alternatively, however, at least the portion of the spindle 24 aligned with the primary piston 12 can be fastened in the second recess 12d, while the nut 26, which is set in rotation, can be rotated into the second recess 12d.

As an advantageous further development, at least one torque support component 26a can be attached or formed on the nut 26 or the primary piston 12. By means of the at least one torque support component 26a, the primary piston 12 can be supported on an inner wall of a gear housing 32 in such a way that an undesirable co-rotating movement of the primary piston 12 together with the spindle 24 or nut 26 which is set in rotation is prevented. Merely as an example, in the embodiment described here, the at least one torque support component 26a is fastened or formed on the nut 26 fastened in the second recess 12d of the primary piston 12.

In the embodiment described here, the electric motor 10 is mechanically connected to the primary piston 12 via at least the rotational and translational gear stage of the transmission 22 in such a way that, during operation of the electric motor 10, a rotor (not shown) of the electric motor 10 rotates by one Rotation axis 34 is offset, which is aligned parallel to the adjustment axis 28 of the primary piston 12 and is spaced from the adjustment axis 28 by a non-zero distance. The arrangement/alignment of the electric motor 10 described here can be described as a parallel arrangement of the electric motor 10 to the primary piston 12. By arranging the electric motor 10 in parallel with the primary piston 12, a maximum expansion of the motorized piston can be achieved Brake pressure generator can be reduced along the adjustment axis 28 of its primary piston 12. The motorized brake pressure generator shown in FIGS. 1 a to 1 c is therefore optimized in terms of its overall length.

To transmit the motor power of the electric motor 10 via the transmission 22 to the primary piston 12 with a parallel arrangement of the electric motor 10 to the primary piston 12, the transmission 22 can, for example, have a first stage adjacent to the electric motor 10, such as a spur gear stage or with a planetary gear . Between the first stage and the rotational and translational gear stage, the gearbox 22 can also have a (further) spur gear stage.

In addition, in the embodiment described here, the electric motor 10 is arranged in its “own” motor housing 36 and outside the transmission housing 32. While the master brake cylinder housing 14 is screwed to a protruding first section of the first side 32a of the transmission housing 32 by means of the at least one screw 30, the motor housing 36 is attached to a second section of the first side 32a of the transmission housing 32 which is set back compared to the first section. This results in a compact overall structure of the motorized brake pressure generator, which is why it can be easily installed on a variety of vehicle types/motor vehicle types. For example, an installation space “gained” by attaching the motor housing 36 to the recessed second section of the first side 32a of the gear housing 32 can be used to attach control electronics 38 by

Control electronics 38 is/is attached to a side of the motor housing 36 directed away from the second section of the first side 32a of the transmission housing 32. Likewise, a brake fluid reservoir 40 can easily be attached to the master brake cylinder housing 14.

2a and 2b show schematic representations of a second embodiment of the motorized brake pressure generator.

In contrast to the previously described embodiment, in the motorized brake pressure generator of FIGS. 2a and 2b, the electric motor 10 is arranged/integrated in the transmission housing 32. The gearbox 32 surrounding the electric motor 10 and the gearbox 22 can therefore be referred to as an electric motor-gearbox housing 32. The common one Integration of the electric motor 10 with the gearbox 22 in the electric motor gearbox housing 32 can thus be combined with the parallel arrangement of the electric motor 10 to the primary piston 12. That is why the motorized brake pressure generator in FIGS. 2a and 2b is also optimized in length. 2a and 2b, a compactness of the motorized brake pressure generator can be increased by, while the master brake cylinder housing 14 is screwed to the protruding first section of the first side 32a of the transmission housing 32, the control electronics 38 on the compared to the first Section set back second section of the first side 32a of the gear housing 32 is / is attached.

With a parallel arrangement of the electric motor 10 to the primary piston 12 and a simultaneous integration of the electric motor 10 into the electric motor transmission housing 32, the transmission 22 can, for example, have a spur gear stage or a planetary gear as a first stage adjacent to the electric motor 10. There can be a (further) spur gear stage between the first stage and a third stage. The third stage arranged between the second stage and the rotary and translational gear stage may be a threaded spindle stage.

With regard to further features of the motorized brake pressure generator of FIGS. 2a and 2b and their advantages, reference is made to the previously described embodiment of FIGS. 1a to 1c.

Fig. 3 shows a schematic representation of a third embodiment of the motorized brake pressure generator.

In the motorized brake pressure generator shown schematically in FIG a rotation axis 42 aligned perpendicular to the adjustment axis 28 of the primary piston 12 is offset. The arrangement/alignment of the electric motor 10 described here can also be described as a vertical arrangement or L-shaped arrangement of the electric motor 10 relative to the primary piston 12. As can be seen from FIG. 3, it is also possible to use the vertical or L-shaped arrangement Arrangement of the electric motor 10 to the primary piston 12 allows a maximum expansion of the motorized brake pressure generator to be reduced along the adjustment axis 28 of its primary piston 12. In addition, the motorized brake pressure generator of FIG. 3 has a space requirement due to the vertical or L-shaped arrangement of its electric motor 10 relative to the primary piston 12, which can be easily implemented in an assembly concept for a large number of vehicle types/motor vehicle types.

In the vertical or L-shaped arrangement of the electric motor 10 relative to the primary piston 12, the gear 22 can, for example, comprise a worm gear as a first stage adjacent to the electric motor 10. Between the first stage and the rotation and translation gear stage, the gear 22 can also have a threaded spindle stage or a ball screw drive (KGT).

Merely as an example, in the motorized brake pressure generator described here, the electric motor 10 is arranged in its “own” motor housing 36. The motor housing 36 is attached to a third side 32c of the transmission housing 32, which lies between the first side 32a of the transmission housing 32 with the master brake cylinder housing 14 screwed thereto and a second side 32b of the transmission housing 32 directed away from the first side 32a.

In addition, the control electronics 38 is attached to a side of the motor housing 36 that is directed away from the transmission housing 32. Alternatively, the electric motor 10 can also be integrated into the transmission housing 32 in the vertical or L-shaped arrangement relative to the primary piston 12. In this case, the control electronics 38 can be attached to the third side 32c of the transmission housing 32, which lies between the first side 32a and the second side 32b, to save space.

With regard to further features of the motorized brake pressure generator of FIG. 3 and its advantages, reference is made to the previously described embodiment of FIGS. 1 a to 1 c.

4a and 4b show schematic representations of a fourth embodiment of the motorized brake pressure generator. The mechanical connection of the electric motor 10 of the embodiment of FIGS. 4a and 4b to the cooperating primary piston 12 via at least the rotational and translational gear stage of the transmission 22 is designed such that during operation of the electric motor 10, the rotor of the electric motor 10 moves into a rotating movement is offset about the adjustment axis 28 of the primary piston 12. In the motorized brake pressure generator of FIGS. 4a and 4b, the electric motor 10 and the primary piston 12 are thus arranged coaxially or one behind the other. By means of the coaxial arrangement of the electric motor 10 and the primary piston 12 interacting with it, an expansion of the motorized brake pressure generator in a spatial direction aligned perpendicular to the adjustment axis 28 of the primary piston 12 can be reduced. This can also be described as an optimization of a diameter of the motorized brake pressure generator that is aligned perpendicular to the adjustment axis 28 of the primary piston 12.

To transmit the motor power of the electric motor 10 via the transmission 22 to the primary piston 12 with a coaxial arrangement of the electric motor 10 to the primary piston 12, the transmission 22 can, for example, comprise a planetary gear as a first stage. A second stage, for example a planetary gear, can be arranged between the first stage and the rotation and translation stage.

Even with a coaxial arrangement of the electric motor 10 to the primary piston 12, the electric motor 10 can be arranged in its “own” motor housing 36. In this case, the motor housing 36 can be attached to the second side 32b of the transmission housing 32, which is directed away from the first side 32a of the transmission housing 32 with the master brake cylinder housing 14 screwed thereto. By attaching the control electronics 38 to a side of the motor housing 36 directed away from the transmission housing 32, it can be ensured that the control electronics 38 does not/hardly lead to an increase in a maximum expansion of the motorized brake pressure generator in a spatial direction aligned perpendicular to the adjustment axis 28 of the primary piston 12 contributes.

With regard to further features of the motorized brake pressure generator of FIGS. 4a and 4b and their advantages, reference is made to the previously described embodiment of FIGS. 1a to 1c. 5a and 5b show schematic representations of a fifth embodiment of the motorized brake pressure generator.

In contrast to the previously described embodiment, in the motorized brake pressure generator of FIGS. 5a and 5b, the electric motor 10 is integrated into the transmission housing 32. The coaxial arrangement of the electric motor 10 to the primary piston 12 can therefore also be combined with an integration of the electric motor 10 into the transmission housing 32. In this case too, an increase in the expansion of the motorized brake pressure generator in a spatial direction aligned perpendicular to the adjustment axis 28 of its primary piston 12 can be avoided by attaching the control electronics 38 to the second side 32b of the gear housing 32.

5b shows the rotor 10a and a stator 10b of the electric motor 10. An interface 44 for controlling the electric motor 10 by the control electronics 38 can be implemented via at least one plug connection between the electric motor 10 and the control electronics 38.

Even with a coaxial arrangement of the electric motor 10 to the primary piston 12 and an integration of the electric motor 10 into the gear housing 32, the gear 22 can, for example, have a planetary gear as the first stage, a planetary gear as the second stage and the rotational and translational gear stage as the third stage the spindle 24 and the nut 26 have. The planet carriers 46 (planet carriers), the planets 48 interacting with them, a ring gear 50 and end shields 52 are sketched in Fig. 5b.

With regard to further features of the motorized brake pressure generator of FIGS. 5a and 5b and their advantages, reference is made to the previously described embodiment of FIGS. 1 and 4.

All of the motorized brake pressure generators described above can be advantageously used in an external power braking system, especially in a brake-by-wire braking system. The external power brake system/brake-by-wire brake system is to be understood as meaning a brake system in which the master brake cylinder formed in the master brake cylinder housing 14 is controlled by a brake actuating element of the brake system, such as a brake pedal. is mechanically decoupled The force-pressure conversion carried out in the master brake cylinder housing 14 therefore only includes a conversion of the motor force of the electric motor 10 into a brake pressure caused in the master brake cylinder housing 14, but not a conversion of a brake pressure on the brake actuating element of the external power brake system/brake-by-wire brake system applied driver braking force. The usability of the motorized brake pressure generators described above is not limited to any specific type of vehicle/motor vehicle equipped with the respective external power brake system/brake-by-wire brake system.

The motorized brake pressure generators described above are suitable for independently supplying two brake circuits with brake fluid. However, it should be noted that the design of the master brake cylinder housing 14 for a dual-circuit brake system shown in the figures described above is only to be interpreted as an example. Alternatively, the brake system designed with the motorized brake pressure generator can also only have a single brake circuit.

Claims

Expectations

1 . Motorized brake pressure generator for an external power brake system with: an electric motor (10); a primary piston (12); a master brake cylinder housing (14) with at least one primary spring (16) arranged in the master brake cylinder housing (14), the primary piston (12) being supported by means of the primary spring (16) from an inner wall of the master brake cylinder housing (14) or by means of a secondary spring (20). Inner wall supported secondary piston (18) is supported; and a gear (22) with at least one rotation and translation gear stage consisting of a spindle (24) and a nut (26) arranged on the spindle (24); characterized in that the master brake cylinder housing (14) is screwed by means of at least one screw (30) to a first side (32a) of a gear housing (32) with the gear (22) arranged therein, and the electric motor (10) is mechanically connected in this way via at least the Rotational and translational gear stage of the transmission (22) is connected to the primary piston (12) so that a motor force of the electric motor (10) can be transferred to the primary piston (12) via at least the rotational and translational gear stage of the transmission (22). is that the primary piston (12) counteracts a restoring force by means of the transmitted motor force at least the primary spring (16) is adjustable along an adjustment axis (28). Motorized brake pressure generator according to claim 1, wherein the master brake cylinder housing (14) is a chill casting. Motorized brake pressure generator according to claim 1 or 2, wherein the electric motor (10) is mechanically connected to the primary piston (12) via at least the rotational and translational gear stage of the transmission (22) in such a way that during operation of the electric motor (10) a rotor (10a) of the electric motor (10) is offset in a rotating movement about a rotation axis (34) which is aligned parallel to the adjustment axis (28) of the primary piston (12) and spaced from the adjustment axis (28). Motorized brake pressure generator according to claim 3, wherein the master brake cylinder housing (14) is screwed to a protruding first portion of the first side (32a) of the transmission housing (32) by means of the at least one screw (30), and wherein the electric motor (10) is in a motor housing ( 36) is arranged and the motor housing (36) is attached to a second section of the first side (32a) of the gear housing (32) which is set back compared to the first section. Motorized brake pressure generator according to claim 1 or 2, wherein the electric motor (10) is mechanically connected to the primary piston (12) via at least the rotational and translational gear stage of the transmission (22) in such a way that during operation of the electric motor (10), the rotor (10a) of the electric motor (10) is set in a rotating movement about a rotation axis (42) aligned perpendicular to the adjustment axis (28) of the primary piston (12). Motorized brake pressure generator according to claim 5, wherein the electric motor (10) is arranged in the motor housing (36) and the motor housing (36) on a third side (32c) of the gear housing (32), which is between the first side (32a) of the gear housing ( 32) and a second side (32b) of the gear housing (32) directed away from the first side (32a) of the gear housing (32), is fastened. Motorized brake pressure generator according to claim 1 or 2, wherein the electric motor (10) is mechanically connected to the primary piston (12) via at least the rotational and translational gear stage of the transmission (22) in such a way that during operation of the electric motor (10), the rotor (10a) of the electric motor (10) is set in a rotating movement about the adjustment axis (28) of the primary piston (12). Motorized brake pressure generator according to claim 7, wherein the electric motor (10) is arranged in the motor housing (36) and the motor housing (36) is attached to the second side (32b) of the gear housing (32) directed away from the first side (32a) of the gear housing (32). Motorized brake pressure generator according to claim 3, 5 or 7, wherein the electric motor (10) is arranged in the gear housing (32). Motorized brake pressure generator according to one of the preceding claims, wherein on a first piston side (12a) of the primary piston

(12) a first recess (12b) is formed, in which at least one portion of the primary spring (16) aligned with the primary piston (12) is fastened, and on a second piston side (12c) directed away from the first piston side (12a). Primary piston (12), a second recess (12d) is formed, in which a portion of the spindle (24) aligned with the primary piston (12) or a portion of the nut (26) aligned with the primary piston (12) is fastened, the spindle (24) or the nut (26) can be set into a rotational movement in relation to the primary piston (12) by means of the operation of the electric motor (10) and at least a partial section of the spindle (24) which is set into rotational movement and aligned with the primary piston (12) or nut (26) can be rotated into the second recess (12d) of the primary piston (12), and wherein the first recess (12b) formed on the first piston side (12a) has at least a portion of the second recess aligned with the first piston side (12a). (12d) framed.

11. Power braking system for a vehicle with a motorized

Brake pressure generator according to one of the preceding claims.

12. Power braking system according to claim 11, wherein the power braking system is a brake-by-wire braking system.