EP1097071A2

EP1097071A2 - Tandem-type pneumatic brake booster

Info

Publication number: EP1097071A2
Application number: EP99940009A
Authority: EP
Inventors: Roman Teutsch; Wilfried Wagner; Kai-Michael Graichen
Original assignee: Continental Teves AG and Co OHG
Current assignee: Continental Teves AG and Co OHG
Priority date: 1998-07-20
Filing date: 1999-07-15
Publication date: 2001-05-09
Also published as: WO2000005115A3; WO2000005115A2; DE19832357A1

Abstract

The invention relates to a tandem-type pneumatic brake booster, comprising a housing (2), two chambers (6, 7) which are separate from each other, two movable walls (8, 11) which each separate a vacuum chamber (9, 12) from a working chamber (10, 13), as well as one or more connecting channels (15) between the first working chamber (10) and the second working chamber (13) through which the pressure between these two chambers can be equalized. The essence of the invention resides in the fact that fixing means (20) are provided for which in relation to the connecting channels (15) are arranged on a separate, other pitch diameter such that they are staggered in the direction of circumference. The invention allows for the multiple and variable adjustment and mounting of a master brake cylinder unit of a brake booster in different vehicle types made by different motor vehicle manufacturers.

Description

Pneumatic power amplifier in tandem design

The invention relates to a pneumatic booster in tandem design, in particular for hydraulic vehicle brake systems with a housing, the interior of which is divided into a front and a rear booster chamber with the aid of a partition, with a first and a second movable wall, the front and the rear booster chamber divide into a first vacuum chamber and into a first working chamber or a second vacuum chamber and into a second working chamber, as well as with one or more connecting channels between the first working chamber and the second working chamber for pressure equalization between these two chambers.

Such a power booster is known for example from EP 327 997 B1 and has fastening means which protrude through the chambers of the brake booster and which also pass through the center of the connecting channels. This design requires only a single recess in the housing components concerned both for fasteners and for the associated connecting channel.

Brake boosters in tandem construction are also known, in which the pressure equalization between the first and third chambers is carried out by means of connecting channels which are integrated in the radially outer fastening flange of the two housing half-shells. The object of the present invention is to show another solution for pressure equalization between the two chambers and for fastening the brake booster to a wall fixed to the vehicle. The brake booster should be particularly versatile.

This object is achieved in that each connection channel has a free flow cross-section, the flow cross-section is preferably circular, and in that the connection channel is arranged separately from at least one fastening means for the power booster on a pitch circle in such a way that the fastening means and the connection duct are provided offset with respect to one another in the circumferential direction. According to the invention, there is a separation of tasks with regard to the components concerned and fastening means for the power amplifier perform only fastening tasks, whereas the connecting channel, as a means for pressure equalization, only performs pressure equalization tasks. This design allows an extremely flexible adaptation of the brake booster in tandem to different connection dimensions in the motor vehicle concerned, i.e. given different installation situations.

In an embodiment according to claim 2 it is provided that fasteners and connecting channels are each provided in pairs and that the pairs of fasteners and the connection channel pairs lie on partial circles of different diameters. This design enables the cross section of the Connection channels independent of the fastening means and also independently of other components of the brake booster, for example the control housing, to be provided with a particularly large cross section, so that the response times of the brake booster are minimized.

According to claim 3, two pitch circle diameters are provided in an advantageous embodiment, on each of which the connection channels or the fastening means are provided. The grouped arrangement of the corresponding components on a specific pitch circle diameter permits rational production and simple adaptation of the fastening situation to different vehicle types if the two pitch circle diameters correspond to the corresponding connection dimensions for different types of motor vehicles or vehicle manufacturers. If, for example, a larger pitch circle diameter (as a connection dimension for fastening the braking device) is used by a vehicle manufacturer A) and a smaller pitch circle diameter by a vehicle manufacturer B), the invention enables the use of the larger pitch circle diameter for the power amplifier for fastening to the vehicle-fixed wall of vehicles from manufacturer A) and the use of the smaller pitch circle diameter for pressure compensation purposes. In vehicles from manufacturer B, however, the smaller pitch circle diameter is used for fastening and the larger pitch circle diameter is used for the ventilation purposes described. The power boosters are consequently can be installed very variably without much effort and allows a kind of exchange installation.

Further advantageous embodiments of the invention emerge from subclaims in connection with the description and the drawing.

The drawing shows:

Fig. 1 longitudinal section of a first embodiment of the

Power booster according to the invention along the line I-I in Fig. 2;

FIG. 2 shows a view of the brake booster according to FIG. 1 in the direction of arrow X to illustrate the pitch circle diameter;

Fig. 3 shows a second embodiment of the invention in section along the line III-III m Fig. 1;

FIG. 4 section as in FIG. 3 through a further modified exemplary embodiment and;

Fig. 5 is an additional, modified

Exemplary embodiment on average as in FIG. 4.

The force booster shown in the figures in tandem construction comprises a housing 2 which has two shell-shaped housing halves or housing half-shells 3, 4, preferably with the help of metal-forming technology Measures are pressed together. The interior of the housing 2 is divided with the aid of an approximately centrally arranged, fixed partition 5 into a front, master cylinder-side amplifier chamber 6 and a rear, brake pedal-side amplifier chamber 7, the front amplifier chamber 6 being constant through a first movable wall 8 m a first vacuum chamber 9 Pressure and in a first working chamber 10 variable pressure and the rear amplifier chamber 7 is divided by a second movable wall 11 m, a second vacuum chamber 12 and a second working chamber 13. The front housing half-shell 3 is usually provided with a vacuum connection (not shown), by means of which the first vacuum chamber 9 can be connected to a suitable vacuum source, for example an intake manifold of the motor vehicle engine, or to a pump.

The second housing shell 4 is provided with an axial section of smaller diameter, to which a control housing 14 is guided so as to be axially movable. Provided in the interior of the control housing 14 is a valve arrangement (not shown) which is of no further interest here, which enables controlled ventilation of the two working chambers 10, 13 and thereby controls the pressure difference between the vacuum chambers 9, 12 and the working chambers 10, 13. The power booster also has a connecting channel 15 between the first working chamber 10 and the second working chamber 13, which according to the embodiment shown in FIG cylindrical sleeve 16 is formed, which preferably consists of deep-drawn sheet metal or plastic material. As can be seen from the figure, the sleeve 16 has a collar 17 with which it rests against a seal buttoned into an opening in the partition 5. It is important that the end of the sleeve 16 still protrudes into the second working chamber 13. In the other direction, the sleeve 16 with its wall 18 projects through the first vacuum chamber 9 and passes through the first movable wall 8 in a sealed manner, a free end projecting into the first working chamber 10. The seal in the area of the second movable wall 11 is used, for example, by a sliding seal 19 which rests movably on a smooth sealing surface on the outer circumference of the wall 18. The measures described thus ensure pressure equalization between the first and second working chambers 10, 13, the free, preferably circular cross section of the connecting channel 15 ensuring particularly rapid pressure equalization and thus particularly short times in order to reach the actuation point of the power amplifier.

In a modification of the drawn in Fig. 1

Embodiment, it is also conceivable to reverse the kinematics with respect to the connecting channel 15, that is, to arrange the connecting channel 15 with its sleeve 16 sealed on the second wall 11 and to provide the recess in the region of the partition 5 with the sliding seal, so that in operation of the brake booster, the sleeve 16 together with the first movable wall 8 immersion movements in the direction of the first working chamber 10 executes relative to the partition 5. The advantages associated with the first exemplary embodiment described above also apply without restriction to this kinematically reversed exemplary embodiment, which also falls under the teaching of patent claim 1.

The power booster 1 also preferably has a fastening means 20 (tie rod) which extends through the amplifier space 6, 7 and projects with a front and a rear end 21, 22 from the two housing half-shells 3, 4. The front end 21 of the fastening means 20 is used to fasten a master brake cylinder, not shown, which is pressed against a flat end face of the front housing half-shell 3 with a flange. The rear end 22 of the fastening means 20 is used to arrange a unit consisting of the master brake cylinder and the power booster 1 on a vehicle-mounted wall of a motor vehicle, which can usually be placed directly on a flat end face of the housing half-shell 4. On the other side of the vehicle-fixed wall, usually the so-called splash or fire wall, a so-called pedal bracket is arranged, through which the rear end 22 also grips, in order to be screwed, for example, with a nut in such a way that the desired fastening of the brake booster Hauptbremszylmdere unit is accomplished on the vehicle. Seals of the movable walls 8, 11 and the partition 5 are of course also provided on the circumference of the fastening means 20 and the detailed function of the fastening means as a tie rod need not be discussed further here become .

2 shows a plan view in the direction of arrow X in FIG. 1 and for the rest FIG. 2 illustrates the section of FIGS. 1 and 3. In addition, a first pitch circle 23 and a second pitch circle 24 are shown, and on the First, large pitch circle 23, the only schematically indicated connection channels 15 are arranged. The through bores for the fastening means 20 are located on the second, small pitch circle 24 and it is further clearly evident that the fastening means 20 and the connecting channels 15 are arranged offset to one another in the circumferential direction. Without leaving the concept of the invention, it is conceivable to arrange the fastening means 20 on the large pitch circle 23 and to assign the connecting channels 15 to the small pitch circle 24. All conceivable exemplary embodiments, however, have in common that connecting channels 15 m circumferential to the fastening means 20 are provided. In other words, connection channels 15 and fastening means are arranged alternately. With regard to the exemplary embodiment shown in FIG. 2, connecting ducts 15 and fastening means 20 are each arranged in pairs on the associated pitch circle diameters 23, 24 and the offset between a fastening means 20 and a connecting duct 15 is 90 degrees.

In the exemplary embodiment according to FIG. 3, a bellows 25 is provided as the connecting channel 15, which bellows on the second movable wall 11 and on the fixed partition 5 attached sealed, preferably buttoned. The bellows 25 has folds, which fold when the movable wall 11 moves axially in the direction of the partition 5, so that the bellows has an extremely small axial length in the folded state. The bellows 25 is here a separate component with respect to the movable wall 11 and the partition 5. In the embodiment, no tie rod protruding through the chambers is provided, but there are the half-sheared fastening bolts, which are also offset relative to the connecting channel 15 on the circumference, so that a protruding head on the fastening means does not hinder the flow of electricity on the ventilation duct.

4 shows an exemplary embodiment with a bellows 25, which is integrally formed on a membrane 26 of the movable wall 11, preferably molded or vulcanized, plastic or rubber basically being considered as the membrane material. In this variant, separate sealing measures in the area of the movable wall 11 can be omitted. The other end of the bellows 25 is buttoned into a cylindrical recess in the partition 5, as in FIG. 3. Because, in the exemplary embodiment according to FIG. 4, at least one button operation in the area of the movable wall 11 can be omitted, this represents a solution that is particularly easy to assemble.

Finally, Fig. 5 em with exemplary embodiment can be seen from a bellows 27 integrally formed on a membrane 26 '. Because of the one-piece construction with the membrane 26 ', an assembly process in the area of the movable wall 11 is also omitted here. It should be particularly pointed out that the bellows body 28 can increasingly be rolled on the outer circumference of the connecting channel 15 in the course of an axial operating movement of the wall 11 in the direction of the partition wall 5 is. This measure thus ensures a quasi-friction-free and in particular injury-insensitive seal between the connecting channel 15 and the movable wall 8 and its membrane.

Another basic effect of the invention which has not yet been mentioned will be described at this point. The principle of task separation according to the invention allows the cross section of the connecting channel to be optimized independently of fastening means or other components of the brake booster with regard to the control behavior (time until modulation). For example, particularly large cross sections for rapid pressure equalization are conceivable, the resulting noise being minimized due to the free, in particular circular, flow cross section.

Claims

claims

1. The invention relates to a pneumatic

Power amplifier (1) in tandem design, in particular for hydraulic vehicle brake systems with a housing (2), the interior of which is divided into a front and a rear booster chamber (6, 7) with the aid of a partition (5), with a first and a second movable wall (8, 11) which divide the front and rear amplifier compartments (6, 7) into a first vacuum chamber (9) and into a first working chamber (10) or a second vacuum chamber (12) and into a second working chamber (13) subdivide, as well as with one or more connecting channels (15) between the first working chamber (10) and the second working chamber (13) for a pressure equalization between these two chambers (10, 13), characterized in that each connecting channel (15) has a free flow cross section has the

Flow cross section is preferably circular, and that the connecting channel (15) is arranged separately from at least one fastening means (20) for the power amplifier on a pitch circle (23, 24) in such a way that the fastening means (20) and the connecting channel (15) are offset from one another in the circumferential direction are.

2. Power amplifier according to claim 2, characterized in that fastening means (20) and connecting channels (15) are provided in pairs are and that the pairs of fasteners and the pairs of connecting channels are on partial circles (23, 24) of different diameters.

3. Power amplifier according to one or more of the preceding claims, characterized in that two pitch circle diameters (23, 24) are provided, on each of which the connecting channels (15) or the fastening means (20) are provided.

4. Power amplifier according to one or more of the preceding claims, in particular according to claim 2, characterized in that the fastening means (20) lie on the pitch circle (24) with a small diameter.

5. Power amplifier according to one or more of the preceding claims, in particular according to claim 2, characterized in that the fastening means (20) lie on the pitch circle (23) with a large diameter.

6. Power amplifier according to one or more of the preceding claims, characterized in that

Fastening means (20) relative to a connecting channel (15) are each offset by 90 degrees on the corresponding pitch circle (23, 24).

7. Power amplifier according to one or more of the preceding claims, characterized in that cylindrical sleeves (16) are provided as connecting channels (15), which are either arranged in a sealed manner on the second wall (11) and can be displaced with the latter by means of a sealing surface relative to the partition (5), or that the connecting channels (15) are sealed are fixedly arranged on the partition (5), the second movable wall (8) movably abutting the sealing surface of the connecting channel (15).

8. Power amplifier according to claim 7, characterized in that the sleeves (16) consist of sheet metal or plastic material.

9. Power amplifier according to one or more of the preceding claims, characterized in that a bellows (25) is provided as a connecting channel (15) which is fastened in a sealed manner to the second movable wall (11) and to the partition (5).

10. Power amplifier according to one or more of the preceding claims, characterized in that a bellows (25) is provided as the connecting channel (15), which is integrally connected at one end to a membrane (26, 26 ') of the wall (11) and is attached to the partition (5) at another end.

11. Power amplifier according to claims 9 or 10, characterized in that the bellows (25) is designed as a bellows.

2. Power amplifier according to claim 10, characterized in that the bellows (25) is designed as a bellows, the bellows body (28) on the outer circumference of the connecting channel (15) can be applied,