WO2013030113A1

WO2013030113A1 - Actuating devices for motor vehicle brake systems and method for operating an actuating device for a vehicle brake

Info

Publication number: WO2013030113A1
Application number: PCT/EP2012/066510
Authority: WO
Inventors: Heinz Leiber; Valentin Unterfrauner
Original assignee: Ipgate Ag
Priority date: 2011-08-29
Filing date: 2012-08-24
Publication date: 2013-03-07
Also published as: DE102011112515A1; DE112012003557A5

Abstract

The invention relates to an actuating device for a vehicle brake, comprising an actuating apparatus (10; 110; 2b), in particular a brake pedal, at least one first piston-cylinder unit (4), which is connected by means of a hydraulic line (28, 226) to the vehicle brake (brake circuit) in order to supply pressure medium to the brake circuit and pressurize the vehicle brake, and a brake booster. According to the invention, at least one additional piston (5c; 132, 133; 232, 233) is provided in order to change the effective area over which pressure medium is supplied to the brake circuit. According to a second invention, at least one additional piston-cylinder unit (132, 133; 232, 233) is provided, which is connected to the actuating apparatus (110; 210) in order to be actuated by the actuating apparatus and which is connected to the first piston-cylinder unit (104; 204) by means of a hydraulic line. A third invention relates to a method for operating an actuating apparatus for a vehicle brake, whereupon additional pressure medium is fed to at least one brake circuit in an operating state.

Description

description

ACTUATING DEVICES FOR MOTOR VEHICLE BRAKING SYSTEMS AND A METHOD FOR OPERATING AN ACTUATING DEVICE

FOR A VEHICLE BRAKE

The invention relates to an actuating device for a motor vehicle brake system.

PRIOR ART Demands on brake systems are increasing. This applies in particular also with regard ^¬ fail-safe and good fallback. If the brake booster fails, it should be achieved at the internationally predetermined foot force of 500 N, a delay greater than 0.64 g, which compared to the minimum requirement of the legislature of 0.24 g significantly more means. One advantage of the high achievable delay, it is also possible that a red warning light, which irritates the driver not be ^¬ must be controls.

This requirement is solved by brake-by-wire systems with path simulators. Here, the main cylinder or THZ is designed for the fall-back level in case of failure of the brake system. This is done by appropriate dimensioning with a small diameter. This creates higher

Prints at a corresponding foot force. The necessary Volume for 0.64 g and corresponding pressure is relatively small compared to the maximum pressure at full vehicle delay and fading. The necessary volume can not fully apply a THZ even with a larger stroke. In DE 102007062839 of the Applicant this is a

Solution proposed with storage chamber, which feeds corresponding volume at higher pressures in the brake circuit. Furthermore, in DE 102011009059 the applicant describes a further solution in which volume from HZ is conveyed from the reservoir into the brake circuit via appropriate valve and HZ control. For vehicles with large volume intake, z. B. SUV and vans, the filling of the brake circuits during braking must be done even before the blocking pressure for high μ necessary. Both solutions make high demands on the tightness of the valves. Moreover ver ^¬ connected to the additional filling of the brake circuits a interrup ^¬ monitoring of the pressure buildup and less braking distance loss.

Object of the invention

The invention has for its object to provide an improved ^¬ te actuator for a motor driving convincing brake system, which in particular on einfa ^¬ che way an improvement in the fallback level at a relatively large piston of the piston-cylinder unit or main cylinder piston allows. This object is achieved by the patent ^{¬ claim} 1 characterizing features.

With the invention is in a surprisingly simple way created a solution with which in an operating condition, especially in case of failure of the brake booster, a change in the effective area of the piston-cylinder unit and the main cylinder is possible. This can, if necessary, the filling of the brake circuits only in extreme cases, z. As fading, while maintaining the possible high delay in the fallback level. In addition, a smaller dimensioning of the HZ is possible to achieve even higher vehicle deceleration greater than 0.64 g. The solution according to the invention is possible for all brake booster genera, such as vacuum brake boosters, hydraulically and electrically driven

Brake booster. Advantageous embodiments of the invention provide that parallel to the primary DK piston, an additional piston (additional piston) is provided, which is connected to the drive of the BKV. In an electric brake booster, this may be the spindle of the ball screw transmission (KGT). This additional piston can be arranged coaxially to the DK piston within this. Alternatively, an additional piston can be provided for each brake circuit, which introduces the corresponding volume. It is by a plunger from the pedal to the DK piston, z. B. through a hole in the spindle, a

Power transmission from the pedal to the piston possible, which is necessary for the fallback level. The drive is decoupled, so that here the volume of the primary piston does not work, ie this eliminates the retroactive effect on the pedal force in the fallback level. These solutions can be applied to all types of brake booster with corresponding design changes. The auxiliary pistons may alternatively be arranged parallel to the HZ pistons in the same housing. The additional pistons do not have a separate sniffer bore. It can be dispensed with the additional effort, since the additional piston chamber is connected to the corresponding HZ-piston and thus uses its sniffing from the reservoir with. In addition, only one additional seal per piston is necessary. With the solution, a longer HZ stroke in comparison to the pedal stroke is not necessary because the required Volu ^¬ men of the larger main cylinder piston or additional piston is supplied. Thus, the free travel is reduced from the brake pedal to the DK piston, which arises during braking of the brake booster, especially in higher pressure ranges, since here the distance / free travel between pedal plunger and HZ piston is large.

The potential for reducing HZ-piston can be used in a concept according to DE 102010050133 the appli ^¬ derin. This is for the Wegsimulatorbetätigung on

Used auxiliary piston, the volume of which arrives in case of brake booster failure via a feed valve in the DK brake circuit. Thus, the HZ-piston can then be made smaller because additional volume is fed to avoid large pedal travel. Thus, about 20-30% higher vehicle deceleration rates greater than 0.64 g can be achieved in the fallback level with the same pedal force. The additional pistons lying parallel to the HZ piston are preferably actuated by a pressure plate from the spindle driven by an electric motor. The Drehmo ^¬ ment of the spindle must be supported on the other. For this purpose, the pressure plate offers, which additionally takes over the Drehmomentabstüt tion of the spindle. For this purpose, the pressure plate is guided on a preferably designed as a square bolt. This also takes over the support of the additional piston force, which arises in brake circuit failure. Alternatively, two additional pistons per brake circuit can also act symmetrically on the pressure plate. The spindle reset can be made very simple by compression springs in HZ housing directly on the

Pressure plate act.

In DE 102011017436 of the applicant, a Wegsimu ^¬ latorsystem has been described with auxiliary piston whose pistons are arranged parallel to the HZ. It is advantageous DIE se in addition to the auxiliary piston in the HZ-housing to integrie ^¬ ren. The push rods are arranged in oa application outside of the motor and the actuators Zvi ^¬ rule the coils. These are now advantageously integrated into the outer jacket of the engine.

In the solution with coaxial auxiliary piston, the pressure plate for Drehmomentabstüt tion and spindle reset can be used. The spindle acts here preferably on the DK piston.

To cover the volume requirement, the additional ^pistons suffice. Alternatively, additional solenoid valves can be used for the reservoir, which are used for Nachförde ^¬ tion in the border region according to DE 102011009059 the applicant or even hydraulic Leerwegfreischaltung according to DE 102009055721 of the applicant. In addition, these solenoid valves can also be used for pressure reduction with clamping spindle. A diagnosis of all piston movements is provided.

With the invention or its embodiments, an actuating device for motor vehicle brakes with an ner (not shown) electronic control and regulating device (ECU) is created in which sufficient volume is available, with a rapid Nachförderung with small piston movements is possible and where there are practically no restrictions with regard to the control. Feeding may, if desired or required, take place in one or more than one brake circuit. A change of the THZ springs is not required.

All applications listed above and hereinafter the applicant or the corresponding parts are hereby incorporated in the description or description of the figures and drawings by reference accordingly to open ^¬ barungszwecken. Further advantages of the invention will become apparent from the following description of the figures.

FIG. 1 shows a first embodiment of the invention with a coaxial auxiliary piston;

Figure 2 shows a second embodiment of the invention with parallel additional piston;

FIG. 3 shows a third embodiment of the invention with parallel additional pistons; 3a shows a fourth embodiment with two

Feed-in valves,

Figures 4 to 4f show the procedures of Leerwegfreischal- and Nachförderung.

1 shows in a transparent manner the structure of the system with the known basic components such as electric motor 1, rotor with spindle nut 1 a, spindle 2, piston-cylinder unit here as a tandem master cylinder 4, with push rod piston (DK piston) 3, Floating circle piston (SK piston) 21, return spring 23 for DK piston 3, two switching valves 13, 13a (storage chamber 24 with 2/2 MV 27 according to DE 102009055721 Applicant with DK brake circuit 28), motor rotary encoder 15 with redundant pedal travel sensors 11th , brake pedal 10 with the pedal push rod 5. This Kom ^¬ components are, for example, in DE 102005018649A1 of the applicant, the simplicity is taken in this regard and for purposes of disclosure by reference.

The brake pedal 10 acts on the pedal plunger 5 on an auxiliary piston 6, wherein the displaced volume of this passes through a through-opening in the cylinder and the surrounding housing 41, and a line 29 to the mechanical hydraulic displacement simulator 8. With the movement of the auxiliary piston 6 redundant pedal travel sensors 11 are coupled, which drive the motor 1 via a not shown here ECU and at the same time the normally open 2/2

Actuate pressure control solenoid valve 18, ie close. The path simulator 8 generates the desired reaction to the pedal force. The auxiliary piston 6 is placed in an intermediate position With approximately 40% of the total piston stroke S _H K blocked, when the Wegsimulatorkolben 8a comes to a stop. The solenoid valve 18 has a pressure control function for safety reasons. Corresponding to the travel simulator spring 8b, a pedal travel-dependent pressure is created on the auxiliary piston 6.

Should the travel simulator piston 8a clamp, the pedal travel printing function is disturbed. Solenoid valve 18, which is then opened by the ECU (not shown here), flows pressure medium via line 29a (illustrated here via the THZ) to reservoir 40.

For a good response characteristic, it is known to incorporate a speed s- and direction-dependent throttling of the actuator. For this purpose, a throttle 19 is installed in the line to the way simulator 8 and for the fast return ^¬ a check valve 17. The auxiliary piston 6 is reset by a return spring 20. The auxiliary piston 6 with seals is guided in a corresponding housing 41 and stored. This housing 41 may preferably via a multi-part intermediate housing

Plastic be connected to the engine 1. Housing 41 and intermediate housing can also be in one piece.

At fast pedal speed caused by the throttle 19, a higher pressure. Accordingly, the set value of the pressure regulating valve 18 must be correspondingly higher up to the control point of the movement.

The auxiliary piston 6 can continue to be used in case of failure of the BKV to optimize the braking effect. In case of failure BKV the pedal force should be as small as possible, which requires small main cylinder piston diameter. If these are used, large pedals in the small pressure range ne necessary due to the flat course of the pressure-volume characteristic.

About a normally closed 2/2-way solenoid valve or feed valve 30 (S _E ) can be promoted in the lower pressure range from the auxiliary piston 6 pressure fluid to the pressure build-up in the DK circuit 28. When pressure builds up the pressure medium can be controlled by the auxiliary piston 12 via the pressure transducer.

A critical case is when the BKV fails during ABS operation on ice and then a positive μ jump occurs during braking. In this case is in the

Brake circuits a low pressure in the limit of 1 - 2 bar, so that the initial range of the pressure volume characteristic begins at the Aussteuerpunkt the travel simulator with about 40% pedal travel, which also represents a piston stroke and thus volume ^¬ loss. In systems with travel simulator, the pedal stroke is smaller than the piston stroke. In the ABS control on low has ever ^¬ but the plunger for pressure reduction are returned almost to its initial position, which according to the collision with the pedal tappet or execution. Fig. 1 would lead to the auxiliary piston. In the above-mentioned DE 10 2009

055721 of the applicant is described a system for Leerwegsteuerung the piston in ABS operation. Thus, in the lower pressure range in the ABS control of the DK piston does not hit the pedal plunger, so a corresponding piston path and thus distance to the pedal plunger = free travel da ^¬ achieved by a corresponding volume is passed into the storage chamber 24. The advantage of this Sys tems ^¬ in the critical case is that the volume can be recovered back into the brake circuit.

Instead of the storage chamber 24 with solenoid valve 27 can also be used for simplicity only a 2/2-way solenoid valve 27 a, which serves for Leerwegsteuerung, d. H. if the distance from the auxiliary piston 6 or pole piece to the transfer ram becomes too small. This is in the DE

102009055721 described in more detail by the applicant, to which reference is hereby made. If the free travel is too great, volume can be sucked out of the reservoir 40 by means of a corresponding piston control.

This 2/2-way solenoid valve il can also be used for the same function in the SK circuit, instead of storage chamber 24 and upstream 2/2-way solenoid valve 27th

These valves may be used for an additional function of tracing volume by appropriate piston control from the reservoir 40.

This replaces the Nachförderkammer to promote additional Volu ^¬ men in the brake circuits when the master cylinder piston no longer reaches the necessary pressure. For this purpose, it is advantageous to make the main cylinder seals stronger in order to be vacuum-tight. It can also be a switching device z. B. solenoid valve between reservoir and main cylinder are provided. This is to prevent air from being sucked into the brake circuits during the above-mentioned re-feeding process. From the pressure and the piston position, the volume is calculated, which is discharged during the pressure reduction back into the reservoir via the valve 27 a. This avoids that the main cylinder seals are stressed too much. Both cases and solutions with storage chamber or exhaust valve can be improved if necessary by the volume of the auxiliary piston is used in this critical case to improve the braking effect via the feed valve S _E 30. The necessary feed of the auxiliary ^¬ piston is controlled by the pressure transducer.

Also, an additional feed valve for the SK-circuit can be used to promote the limiting case described in the fallback level and volume of the auxiliary piston in the SK district in order to achieve a higher pressure level or soon ^¬ ren pedal travel. In this case, the volume stored in the travel simulator 8 can also be utilized or isolated via an isolation valve 22.

With the potential of the auxiliary piston, a decisive step in improving fault tolerance is possible.

Equally important is the diagnosis of functionally relevant components. For this purpose, the system has two or at least one, in particular force-locking coupling. The first frictional clutch 14, preferably with a permanent magnet 16 embedded in a magnet housing 16 a, acts on a pole piece 2 a of the spindle. This coupling is also appropriate to enhance the coupling force by in particular ^¬ sondere at low pressures, the piston is returned via the spindle.

For the diagnosis of the auxiliary piston movement, the spindle 2 is retracted with the clutch 14, until the full clutch force acts at zero travel. This is the DK piston preferably on stop 43. During the subsequent Prior ^¬ downward movement of the auxiliary piston via the full stroke S _H K with and moves with the pedal position sensors 11 can be measured. Too high friction in piston or too low coupling force movement and the error stops it is ^¬ known. During this movement, the valve 18 is open. In a second movement, the valve 18 is closed, the movement of the auxiliary piston is stopped via 17 and measured by sensor 11. With regard to even more detailed embodiments of the structure and the operation, reference is made to the DE102010045617 of the applicant.

The system according to the invention is compared to

DE102010045617 of the applicant supplemented by a piston system with at least one piston to improve the

Fall-back level with relatively large HZ pistons. Normally, the drive of the BKV, in this case the spindle 2, moves the DK piston 3 and additionally an additional piston 5c connected to the piston tappet 5b which is arranged in a central bore of the spindle 2 and which is supported in the spindle 2. A connected to the spindle 2 or formed by this annular piston is secured by a seal 36. The limited by the seal ring piston chamber 36 is connected via a passage opening 37 with the working space of the DK piston. Instead of a seal can also act more seals in the additional piston 5c and in the inner bore of the DK piston 3. In case of failure BKV the auxiliary piston acts on the piston plunger after passing through the free travel 7 on the auxiliary piston 5c. This in turn acts on the DK piston. In this case, the additional piston does not move, so that the effective Kol ^¬ benfläche is smaller. This results in greater pressures at a given pedal force, which is a great advantage. These pistons only work in the DK circuit. Since the additional piston normally performs no relative movement to the annular piston, a movement and diagnosis is necessary at intervals.

For this purpose, z. B. at vehicle standstill without Bremsbetä ^¬ tion, the spindle 2 moves counter to the direction during pressure build-up to the right. Here, the DK-piston 3 so that then lies on stop 43. During the movement of the pole piece solves 2a from the magnet and the motor = motor current drops after passing through the empty path 7 then meets the Kol ^¬ benstößel 5b on the auxiliary piston 6, a Relative movement of the annular piston with seal to the additional piston takes place. If this would jam in the ring piston, the higher friction causes a current increase, which is used for diagnosis.

2 shows an arrangement without coaxial stepped piston with electric motor 101, rotor with spindle nut 101a, spindle 102, motor housing 106, tandem HZ 104 with DK piston

103 and floating piston 121. Instead of an electric motor and a vacuum BKV or hydraulic BKV can be used with a corresponding drive. The DK piston 103 is connected to a piston plunger 105b, on which via a free travel 7, a transfer plunger 5a acts, which is actuated by the actuator or by the brake pedal 110 via a pedal plunger 105.

This can be directly connected to the pedal plunger, which is coupled to the brake pedal. In the simplest case, the pedal travel acts on a pedal travel sensor 111, which operates the BKV as a consequence ^¬ amplifier via an ECU, not shown here, in which the pedal force with to Dru- is used. However, it is also possible to use a travel simulator 108 which is constructed in such a way that the pedal force acts on the HZ piston only in the event of a failure BKV. With the spindle 102, two additional pistons 132 and 133 are coupled, which are arranged in bores which are connected through passage openings with the corresponding working spaces of the THZ in order to promote additional volume in the brake circuits 125 and 126. In case of failure BKV these do not work because the spindle force is not effective. Here, as in Fig. 1 results in a smaller effective ^¬ area with the advantage of smaller pedal forces in the fallback mode. The diagnosis of the ram friction takes place as described in FIG. Fig. 3 corresponds in construction with respect to BKV of Fig. 2 with electric motor 201, housing 237, rotor 201a, spindle 202, THZ 204 with DK piston 203 and SK piston 221. Again, parallel auxiliary piston 232 and 233 are used which are coupled to the spindle 202. The Zusatzkol- ben are arranged in bores which are through-holes ^¬ with the corresponding working chambers of the THZ compound in order to promote additional volume in the brake circuits 226 and 228th Thus, in case of failure brake circuit no asymmetric forces acting on the spindle, both pistons can be used to support the DK circuit similar to Fig. 1. The DK piston is in the initial position to stop 243. Again, in the DK piston with respect to FIG. 1 and DE

102010045617 described coupling, which has the same task.

Notwithstanding FIGS. 1 and 2, here auxiliary pistons 206 and 206 'are not connected to one another via a line coaxial, but parallel to the axis as described in principle in DE 102011017436. The auxiliary pistons are connected to a carrier 239 via plungers 206a. The plungers 206a are expediently embedded in the yoke of the motor stator in order to realize a small outer diameter in this area. For this purpose, the plunger with respect to the piston radially offset slightly outwards (ie eccentric ^¬ risch) may be arranged. The provision of auxiliary piston 206a and carrier 239 via provided on the plungers 206 of the auxiliary piston return springs 220. The carrier is mounted axially fixed to guide bolts arranged on housing fixed 238. In the carrier 239, a pedal plate 245 is mounted, on which a prestressed spring 246 acts. The sensor 239 and the pedal plate 245 are acted on by sensor actuating elements 247, which are connected to the two pedal travel sensors 211. By the spring force and corresponding relative movement, the pedal force generated by the pedal plunger 205 is measured. Further details of this are described in DE 102010050132 of the Applicant, to which reference is made in this regard.

The diagnosis of the piston plunger 205b corresponds in principle to Fig. 1. Notwithstanding, the piston plunger 205b is pressed against the pedal plate with a spring which is eg mounted in a central bore at the end of the piston plunger and is supported on the intermediate bottom of the DK piston. The free travel is seen between piston plunger and DK piston before ^¬ . The valve circuit corresponds to FIG. 1. Here, too, as in FIG. 1, the idle travel circuit can be carried out via a storage chamber with a solenoid valve (24, 27 in FIG. 1) in one or both brake circuits. It is too possible, for example, in the SK circuit the Leerwegschaltung eg partially with a (not shown in Fig. 3) storage chamber (24 in Fig. 1) in combination with Leerwegverschaltung in DK circuit via a solenoid valve 227a (27a in Fig.l) in the reservoir 240. For pressure build-up can then be refilled from the storage chamber 240 in the SK-circuit or alternatively preferably sucked in the DK circuit from the piston 203 from the reservoir 240.

For a given intake volume, a corresponding suction stroke of the piston is necessary. In the situation described low μ and pedal plunger with path simulator fully out ^¬ controls the distance between DK and SK pistons low at correspondingly low pressure level. A corresponding suction stroke of the DK piston can be achieved by striking the SK piston and building up pressure in the SK brake circuit. In this case, no pressure build-up in the DC circuit is possible. The closing stroke on ^¬ means suction and can be adjusted in the stroke to a corresponding volume. When on ^¬ closing delivery stroke is sufficient distance between the piston, since initially at the start of stroke, the switching valves

28/228 of the SK circuit are closed. When the switching valves of the SK circuit are opened, the pressure is equalized between the SK and the DC circuit with the corresponding piston distance. This is sufficient for the next För ^¬ derhub and the following, if z. B. with positive μ jump a higher pressure level is built up in the brake circuits. Alternative to p _on at the described conditions at low μ with Leerwegfreischaltung and according to the following p _on also the DK-piston can be moved to suck in the direction of the auxiliary piston 6. This is then just enough distance between the piston. This is possible if the spindle 2 with appropriate structural design in Fig. 1, the stepped piston 6 is moved back or in Fig. 3, the carrier 3. The combination of the Leerwegsteuerung and described Nachförderung the necessary for Leerwegsteuerung volume only in the DK circuit is very easy. In order for the SK-circuit remains ge ^¬ closed, which is a big safety advantage. However, this requires that the piston system according to the main idea of the invention creates enough volume in the brake circuits.

Here, the Leerwegsteuerung and the corresponding Nachfördern only via the DK-piston, which has the advantage that the brake circuit of the SK-piston has no additional valve and thus is safer. If the Fa ^¬ ding area missing volume, it can be replenished in DK district as described and in SK-circle at ge ^¬ closed switching valves 228 on the cuff of the SK-piston.

With this arrangement with multiple pistons, the effective area of the HZ piston in conjunction with the feed valve 230 can be made particularly small and thus effective. As is known, the volume intake is relatively large at low pressures. This can be solved with the feed valve as a pre ^¬ filling (Prefill-) function.

The auxiliary piston 206 is provided here with a seal. For even greater leakage safety, two seals can be used. In addition, the

Designed as a pressure circuit (DK) piston with primary and secondary seal, with a connection to the primary seal or primary Council container.

The arrangement according to FIG. 3 is particularly compact and short, which is of great importance for future vehicle concepts. Also in terms of production, the arrangement is particularly well, since all the piston bores are in a housing and the connection to the mounted or integrated HCU is very short. Figure 3a shows an embodiment which is largely the of

Figure 3 corresponds, wherein in the figure 3a except the feed valve 230 for the pressure circuit another Einspei ^¬ seventil 230a between the pressure circuit 226 and the

Floating circle is provided. This design has further advantages. In the embodiment like FIG. 3 prevents the spring preload of the THZ springs with pressure reduction to low-μ, that the SK piston 221 goes to the zero position, the pressure is reduced to only 2 to 3 bar. In comparison, the pressure in the DK circuit drops to zero because of the connection 227a to the reservoir 240. At full modulation of the pedal plunger and Wegsimula ^¬ sector together with the Leerwegfreischaltung the DK piston 203 at about 40% stroke. Accordingly, the stronger DK spring prevents the SK piston 221 from going to zero. The volume removal into the reservoir 240 in the Leerwegfreischaltung requires a positive μ-jump Nachfördern in both brake circuits. Here, the post-promotion in the SK circuit is limited in ^¬ result of too low excess force of the SK-piston 221 for sucking.

The Nachfördern at high pressure and a position of the SK piston 221 near the stop in the THZ housing requires large adjustment of the DK piston 3 until the SK-piston 221 moves to suck. Again, the restoring force is relatively small. The result is a high time requirement for the Nachförderung and a relatively small Nachfördervolumen. These problems are solved with the arrangement of another feed valve in a simple and cost-effective manner. In particular, a fast Nachfördern from the DK circuit can be done directly in the SK-circuit or via the SK-piston 221 with a positive μ-jump. Furthermore, a pressure reduction at extreme low μ to a pressure reduction to zero in the DC circuit can be done. If there is fading, re-feeding can take place from the DK circuit. The SK piston is at stop and the DK piston spring force is considerably greater than the spring force of the SK spring. Also, a good fallback level ie when, for example, the engine or the transmission is blocked, since a symmetrical filling of the pressure circuit and the

Floating circuit via the first feed valve 230 can take place in the fallback level. The further feed valve may be dimensioned like the first feed valve, z. B. Δρ = 200 bar.

The feed valves 230, 230a are switched relatively sel ^¬ ge. Experience has shown that sealed solenoid valves remain tight when not switched. A diagnosis can therefore be made appropriately after a circuit when the vehicle is stationary and then after every 1000 brakes. The different pressure levels in the circuits and the associated piston movements can be suitably used for the diagnosis.

At the valve circuit can advantageously between the DK circuit and the SK-circuit means for monitoring the feed valves 230, 230a to be connected. Insbeson ^¬ particular when only one feed valve 230 is provided, a plunger 219 may act between the circuits, as is known from the prior art in and of itself. Two Einspeiseventilen 230, 230a, it is advantageous to employ a further feed valve 230b for additional Absi ^¬ assurance against leakage of the feeding between the two brake circuits. Between the feed valves valves 230a, 230b is then expediently a small (about 0.5 cm ³ ), provided with about 5 bar preloaded memory. The further supply valve forms a redundancy with regard to the tightness of the valves between the two brake circuits. If one of the valves should be leaking, this can be determined via the reservoir and a corresponding diagnostic circuit in the additional volume intake via the DK piston. In this way, the tightness of the valves can be checked and the Kreissennung be ensured.

Fig. 4 to 4f show the procedures of Leerwegfreischaltung with Nachförderung.

Fig. 4 shows the initial position of the piston DK 3 and SK 21 with the known return springs, which are not described here and on the following pictures in addition. On the DK piston 3, the additional piston 5 c, piston plunger 205 b or 2 spindle act.

Fig. 4a shows the pistons 3, 21 at full control. The additional piston 5c / piston plunger 205 is here in a position WS, which corresponds to the stop or control of WS, ie the DK piston is no longer in contact. Fig. 4b shows the position of the piston for the descriptions ^¬ ne Leerwegfreischaltung to low μ. The DK piston 3 is through the valve circuit described below with a small free travel in the limit case 0 to 5c / 205. About the 2/2-solenoid valve 27a il pressure medium is discharged as needed, the ABS control in the reservoir. Accordingly, the switching valves 13 / 13a of the SK circuit and the DK circuit are open or partially closed. Here, the SK piston 21 comes to a small distance a to the DK piston 3. This is in both circles that for the

ABS control required pressure level also achieved with additional individual control of the individual switching valves. Fig. 4c shows the subsequent piston movement to build up pressure. This can with appropriate volume to

Pressure build-up of the DK piston 3 impinge on the SK piston 21, which then still allows pressure build-up in the SK circuit. This becomes apparent when no pressure buildup occurs despite piston movement of the DK piston. All 13 / 13a switching ^¬ valves are opened here.

Fig. 4d shows the return movement of the DK piston 3. The switching valves are in this case closed, the 2/2 solenoid ^¬ valve 27 a open to suction. The piston 3 is in turn controlled to almost free travel 0 to 5c / 205b.

Fig. 4 c shows the further pressure build-up for the DC circuit with opened switching valves, the switching valves 13/13 a of the SK circuit are closed. When the DK piston 3 impinges on the SK piston 21 again, the procedure described in FIG. 4a is repeated.

4f shows a piston position with another not 21

Fig. 4b shows the position of the piston for the described Leerwegfreischaltung to low μ. The DK piston 3 befin ^¬ det by the valve circuit described below with a small free travel in the limit case 0 to 5c / 205. About the 2/2-solenoid valve 27a pressure fluid is discharged as needed, the ABS control in the reservoir. Accordingly, the switching valves 13 / 13a of the SK circuit and the DK circuit are open or partially closed. In this case, the SK piston 21 comes to a small distance a to the DK piston 3. As a result, the pressure level required for the ABS control is achieved in both circuits with additional individual control of the individual switching valves. Fig. 4c shows the subsequent piston movement to build up pressure. This can with appropriate volume to

Pressure build-up of the DK piston 3 impinge on the SK piston 21, which then still allows pressure build-up in the SK circuit. This becomes apparent when no pressure buildup occurs despite piston movement of the DK piston. All 13 / 13a switching valves are open.

Fig. 4d shows the return movement of the DK-piston 3. The switching valves are in this case closed, the 2/2 solenoid valve 27a opened to suction. The piston 3 is in turn controlled to almost free travel 0 to 5c / 205b.

Fig. 4 e shows the further pressure build-up for the DC circuit with open switching valves, the switching valves 13/13 a of the SK circuit are closed. When the DK piston 3 impinges on the SK piston 21 again, the procedure described in FIG. 4a is repeated.

4f shows a piston position with another not 22 drew! Post-deliver. Here, the piston distance a is so large that simultaneously with open switching valves in both circuits DK and SK pressure build is possible ^¬ Lich.

23

electric motor

Rotor with spindle nut

spindle

Pole piece of the spindle

Push rod piston DK

Tandem master cylinder or piston cylinder

unit

pedal tappet

transfer ram

plunger rod

additional piston

auxiliary piston

Pestle to the auxiliary piston

Free travel (s) on the pedal ram

Travel simulator or travel simulator housing

WegsimulatorkoIben

travel simulator

Spindle return spring

Brake pedal or actuator

Pedal travel sensor

thruster

switching valves

first clutch

Rotation angle sensor

permanent magnet

magnet housing

check valve

Pressure control MV S _D

throttle

Return spring for auxiliary piston 24

21 floating piston SK

22 Isolation valve for travel simulator

23 Return spring for push rod piston

24 storage chamber

25

26 SK circle

27 2/2-way solenoid valve for storage chamber 27a 2/2-way solenoid valve for idle travel control

28 DK brake circuit

29 cable to the route simulator

29a line to the reservoir

30 Inlet valve S _E or 2/2-way valve

31 passage opening

40 storage tanks

101 electric motor

101a rotor with spindle nut

102 spindle

103 push rod piston

104 piston-cylinder unit or THZ

105 pedal rams

105a transfer ram

105b piston plunger

106 motor housing

107 Free travel on the pedal ram

108 path simulator

110 actuator or brake pedal

111 pedal travel sensor

121 floating piston SK

126 SK circle

128 DK circle

131 bulkhead

132 Additional piston DK circuit

133 Additional piston SK circuit 25

137 Motor housing

140 storage tank

201 electric motor

201a rotor with spindle nut

202 spindle

203 push rod piston

204 piston-cylinder unit or THZ

205 pedal ram

205b piston plunger

206 auxiliary piston

206 'auxiliary piston

206a plunger to the auxiliary piston

208a displacement sensor piston

210 Brake pedal or actuator 212 Pressure transducer

215 rotation angle sensor

211 pedal travel sensor

212 pressure transmitter

218 pressure control valve

219 Plunger or accumulator

220 return spring

221 SK pistons

226 SK brake circuit

227a 2/2-way valve for idle travel control 228 Dk brake circuit

230 feed valve

230a feed valve

230b feed valve

232 additional piston

233 additional pistons

237 housing

238 guide pins

239 carriers 26 reservoir

Housing for auxiliary piston DK piston stop

pedal plate

feather

Sensor actuator spring

Claims

27

P a n t a n s p r e c h e

Actuating device for a vehicle brake, with an actuating device, in particular a brake pedal, at least a first piston-cylinder unit which is connected via a hydraulic line to the vehicle brake (brake circuit) to supply the Brems ^¬ circle pressure medium and the vehicle brake to pressurize and with a brake booster, characterized in that at least one further piston (5c; 132, 133; 232, 233) is provided to change the effective area over the at least one brake circuit additional pressure medium is supplied or can be supplied.

Actuating device according to claim 1, characterized in that at least one further piston-cylinder unit (5c; 132, 133; 232, 233) is seen ^¬ before, which via a hydraulic line to a working space of the first piston-cylinder unit (4; 204) connected to supply additional hydraulic fluid to the brake circuit, wherein the betae ^¬ account the further piston-cylinder unit takes place by means of the amplifier; 104th

Actuating device according to one of claims 1 or 2, characterized in that each brake circuit is associated with a further piston-cylinder unit (132, 133; 232, 231). 28

Actuating device according to one of the preceding claims 1 or 2, characterized in that the further piston-cylinder unit (132, 133; 232, 231) is arranged parallel to the first piston-cylinder unit, in particular parallel to the first Kol ^¬ ben cylinder Unit is integrated in its housing.

Actuating device according to one of the preceding claims, characterized in that in case of failure of the amplifier (fallback level), the Actu ^¬ tion of the first piston-cylinder unit is independent of the amplifier by means of the actuator.

Actuating device according to one of the preceding claims, characterized in that ei ^¬ ne filling of the brake circuits or by means of the further piston-cylinder unit (5c; 132, 133; 232, 233) only in extreme cases, eg fading takes place.

Actuating device according to one of the preceding claims, characterized in that for the actuation of the further piston-cylinder unit (5c; 132, 133; 232, 233) a transmission device, in particular a pressure plate or pedal plate (245) is provided, which by means of the actuating device 210) is movable.

Actuating device according to one of the preceding claims, characterized in that the amplifier has an electric drive, in particular Elekt ^¬ romotor (1; 101; 201) and a gear, in particular a ball-screw transmission. 29

Actuating device according to one of the preceding claims, characterized in that the transmission with the piston of the first piston-cylinder unit (4; 104; 204) via a coupling, in particular a non-positive coupling is connected.

Actuating device for a vehicle brake, with an actuating device, in particular a brake pedal, at least a first piston-cylinder unit which is connected via a hydraulic line to the vehicle brake (brake circuit) to supply the Brems ^¬ circle pressure medium and the vehicle brake to pressurize and with a brake booster, in particular according to one of the preceding claims, characterized in that at least one further piston-cylinder unit

(Auxiliary piston) (6; 132; 133), which is connected to the actuating device (10; 110; 210) to be actuated by the latter and which is connected via a hydraulic line to the first piston-cylinder device.

Actuating device according to one of the preceding claims, characterized in that the actuating device has a travel simulator (8; 108; 208).

Actuating device according to one of the preceding claims, characterized in that a further piston (5c; 132, 133; 232, 233) to ^¬ least is provided with a piston with the drive or transmission is coupled and a piston for the return ^¬ case level connected to the brake pedal. 30

Actuating device according to one of the preceding claims, characterized in that the additional piston in a housing, in particular the

Main cylinder housing are arranged.

Actuating device according to one of the preceding claims, characterized in that ei ^¬ ne HCU arranged on the actuating device, in particular flanged to the piston housing.

Actuating device according to one of the preceding claims, characterized in that egg ^¬ ne diagnostic device is provided to check the movement of the individual pistons.

Actuating device according to one of the preceding claims, characterized in that a Leerwegschaltung and / or a Nachförderung is provided for at least one brake circuit.

Actuating device, for a vehicle brake, with an actuating device, in particular a brake pedal, at least a first piston-cylinder unit which is connected via a hydraulic line to the vehicle brake (brake circuit) to supply the Brems ^¬ circle pressure means and to pressurize the vehicle brake with pressure and with a brake booster, in particular according to one of the preceding claims, characterized in that the at least one further piston-cylinder unit (auxiliary piston) (6; 132; 133) is provided which is connected to the actuating device (10; 110; 210) 31 is to be actuated by this and which is connected via a hydraulic line to the first piston-cylinder device, and in that at least one solenoid valve, in particular two solenoid valves (230, 230a) is connected or in the hydraulic line at least in one, in particular in two or at ^¬ the brake circuits to control the pressure fluid supply and discharge from or into the other (n) piston-cylinder unit.

Actuating device according to one of the preceding claims, characterized in that the at least one further piston (5c; 132, 133; 232, 233) has at least one, in particular two, seals (primary and secondary seals), wherein a connection to the reservoir is provided after the primary seal is.

Actuating device according to one of the preceding claims, characterized in that for leakage monitoring between the brake circuits, a plunger or a biased memory (219) is arranged. 20. A method for operating an actuating device for a vehicle brake, in particular according to one of the preceding claims, characterized in that at least one brake circuit in particular ^¬ special by means of a change in the effective area in an operating condition additional pressure medium is led to ^¬ .

21. Method according to claim 20, characterized 32 shows that in at least one brake circuit Leerwegfreischaltung and / or a Nachförderung is made. 22. The method according to claim 20 or 21, characterized

characterized in that the Nachförderung in the DK circuit via solenoid valve and in the SK-circle on the cuff of the SK-piston, mainly in the higher pressure range with appropriate piston control of the DC circuit.