EP1409319A1 - Brake master cylinder comprising plunger pistons and radial grooves inserted into the housing in order to receive sealing joints - Google Patents

Abstract

The invention relates to a main tandem cylinder (20) comprising two plunger pistons (1, 3). The invention is characterised in that it is constructed in the most simple and most economical way possible. The round-shaped annular grooves (16 - 19) are inserted directly into the housing (15) of the master cylinder (20) in order to accommodate sealing joints i.e. the primary joint (6) and in another embodiment for the primary joint (7), the piston which is situated on the side of the pressure rod, as well as the secondary joints (12, 14) of both pistons (1, 3). Further advantages are proposed for the collecting annular grooves (45, 46) at the level of the connecting outlets for the compensating holder (5, 10).

Description

Master brake cylinder with plunger and radial grooves inserted in the housing to accommodate the sealing sleeves

The invention relates to a master cylinder, preferably a tandem master cylinder, as is required in hydraulic brake systems. Master cylinders of this type serve as transmitters for actuating the pistons in the brake calipers, the pedal force exerted by the driver possibly being evenly distributed over the transmitter to the brake calipers by a brake booster. Such an encoder is described, for example, in US Pat. No. 5,187,934. In order to insert the cuff seals into the housing, the cylinders were previously regularly closed at the end in the direction of actuation by a cover, while a sealing ring was screwed or caulked in at the opposite (driver-side) end, which is used to guide the push rod facing the driver and as a system serves for the secondary piston. Although the inner surface of the cylinder does not have to be specially machined, the known master cylinders with plungers have a number of disadvantages. Since several parts have to be joined together in the axial direction, the diameter of the known master cylinder is considerable. Furthermore, a large number of components are required to provide the necessary contact surfaces for the sealing sleeves.

Efforts can be seen from the patent literature to save the closure cover lying in the actuation direction in the case of the master cylinders mentioned (see, for example, EP 1018459, DE-US 3905917). As a result, the housings were gradually extended towards the driver in order to provide the necessary contact surfaces for the seal. In some cases no primary sleeves were used in such master cylinders, but these were replaced by spring-loaded valve bodies.

The invention is therefore based on a tandem master cylinder of the type resulting from the preamble of claim 1. The object of the invention is to provide a novel master cylinder of this type, which is characterized by the use of very few components and a very inexpensive structure. The object is achieved by the combination of features resulting from the characterizing part of claim 1. In principle, the invention therefore consists in accommodating the primary seal in a circumferential groove which is introduced directly into the housing. The main advantage is that the primary seal, which is exposed to considerable forces, can be supported directly on the housing. This means that the forces do not have to be absorbed by assemblies screwed or caulked to the housing that have to be inserted into the housing. This significantly reduces the diameter of the housing with the same force absorption by the master cylinder. In addition, screwing or caulking eliminates the necessary joints between components that are susceptible to faults under permanent load. The preparation of the necessary ring groove within the housing is not a considerable difficulty for an automatic milling machine. With suitable devices, it is still possible to insert the ring-shaped seal into the ring groove produced in this way without any problems.

In an advantageous development of the invention, the use of the combination of features according to claim 2 is recommended. If a first annular groove for the primary seal is produced with the aid of the milling tool mentioned, this tool can also be used to produce an axially sets arranged second annular groove can be used, in which the annular secondary seal can then be inserted. In this way, the advantage obtained by the combination of features according to FIG. 1 increases considerably. It should also be noted that by saving the components used to support the sealing sleeves, the overall length for the master cylinder is also saved, so that it can not only be smaller in diameter but also shorter in length with the same performance.

The application of the inventive principle to the second secondary seal, which seals the surroundings of the master cylinder from the second chamber and the expansion tank, has the further advantage that no special closure part has to be inserted at this end of the master cylinder, which in addition increases the diameter of the Master cylinder must lead. The housing and its seal thus simultaneously serve to support the driver's second piston of the tandem master cylinder.

According to the development of the invention according to claim 4, the second primary seal is additionally introduced into an annular groove inserted into the housing of the master cylinder. All four ring grooves can then be made with the same tool. The same also applies to the devices which serve to insert the ring-shaped seals into the associated ring grooves. The material of the housing also limits a possible tilting movement of the second piston projecting into the housing. A further additional simplification of the master cylinder according to the invention can be achieved by using the features according to claim 5. The end of the master cylinder lying in the actuation direction is through the housing even closed in one piece. In other words, no additional cover is required which closes the master cylinder on the actuating end and thus forms the first chamber in connection with the first piston.

In order to improve the functionality of the master cylinder according to the invention, the combination of features according to claim 6 is recommended in a development of the invention. The ring groove in question is inserted so deeply into the housing that the primary seals which are subjected to considerable pressure are supported by their seals which support the bottom of the groove Can support the load on the side of the groove. In this way it is safely prevented that the foot can be pulled out of the groove under pressure.

In order to improve the self-ventilation of at least one chamber in the direction of the wheel outlet, the combination of features according to claim 8 is recommended in a further development. It is particularly appropriate to use the features according to claim 9 according to which the upper region of the annular groove and the primary seal have a flow connection to the recess is connected according to claim 8.

In order to design a device for capturing the pistons as a structural unit, it is proposed according to the features of claim 10 that the springs do not act directly on the pistons, but via a preferably plate-like component which transmits the captive force applied by the spring to the piston. In order to be able to connect the chambers to the trailing container in a simple manner, a development of the invention according to features 11 and 12 proposes, on the one hand, to establish the flow connection between the chambers and the container chambers exclusively via flow passages in the piston and in the housing. len. It is also proposed that a collecting ring groove be provided between the primary seal and the secondary seal at least in the second chamber and that the collecting ring chamber of the first and / or second chamber be connected to the associated expansion tank through a bore. With regard to at least the second chamber, a transverse bore can be provided which runs parallel to the cylinder space and which is connected to the second chamber by a tap hole. The transverse bore then leads to an expansion tank assigned to the second chamber.

The invention is explained below on the basis of exemplary embodiments.

Show it:

Fig. 1 is provided with a plunger master cylinder according to the prior art

2 is a sectional view of a first embodiment for a tandem master cylinder according to the invention,

Fig. 3 shows a cross section through the master cylinder according to Fig. 2 and

Fig. 4 shows a second embodiment of a tandem master cylinder according to the present invention. The tandem master cylinder shown in FIG. 1 is intended to explain the state of the art and has already been sufficiently described in DE-OS 19527955. Therefore, only the essential features are discussed at this point in order to make the features of the present invention clearer compared to the prior art. The tandem Master cylinder 20 according to FIG. 1 has a housing 15 which is closed with a cover 48. In the housing 15, two plunger pistons 1 and 3 are guided, each of which is sealed with a primary seal 6 or 7 and a secondary seal 12 or 14 against the adjacent rooms. The pistons delimit a first chamber 2 or second chamber 4. A return spring 32 or 33 also acts on the pistons, the return spring 33 being bound by elements 35, 36. In order to obtain contact surfaces for the seals 6, 7, 12, 14, several assemblies are inserted into the interior of the housing 21, which form the contact surfaces for the seals.

It can easily be seen that a considerable number of components are required for the structure according to FIG. 1, which results in considerable manufacturing and assembly costs. The object of the invention is now to simplify the known tandem master cylinder according to FIG. 1. FIG. 2 shows a first exemplary embodiment in connection with FIG. 3. In order to keep the description concise, identical components in connection with FIGS. 2 to 3 are not explained again insofar as they have already been described in connection with FIG. 1 , In the solution according to FIG. 2, it is striking that the cover 48 according to FIG. 1 has been dispensed with. Rather, this cover is connected in one piece to the housing 15. The housing 15 represents a reworked casting, the undercuts mainly having to be produced by appropriate milling processes. This applies in particular to the circumferential annular grooves 16 to 19, which accommodate the primary seals and secondary seals. Apart from the saving of additional components, which ensure that the sealing surfaces are in contact, the construction according to FIG. 2 has the advantage that the seals can be supported against the inner end surfaces (see, for example, inner end surface 30). End faces are integrally connected to the housing and can absorb correspondingly high forces. 1 is also a circumferential collecting ring groove 45 or 46, which is inserted between the ring grooves 1, 17 and 18, 19 in the housing. These round grooves not only allow liquid to be conveyed to the expansion tanks largely without pressure, but at the same time it also ensures the sliding properties of the subsequent seals 6, 7 and 12, 14. Bores extend from the collecting ring grooves 45, 46, a direct bore 41 and a tap hole 43 being provided, via which the first chamber 2 and the second chamber 4 are connected to the associated container chambers 5 and 10 (see FIG. 3) , The tap hole 43 opens in FIG. 2 into a transverse bore 44, which in turn opens into the second container chamber 10 (see FIG. 3). The flow passages 40 and 42, through which it is possible that the chambers 2 and 4 extend into the pistons 1 and 2, are also advantageous for the design of the master cylinder according to FIG. 2, whereby the chambers are enlarged with the same external dimensions become. The flow passages 40, 42 provide ventilation of the chamber when the pistons are retracted to the right in the figure.

It is also essential for the invention that the width of the circumferential annular grooves is somewhat larger than the width of the seals inserted into them. This makes it possible for pressure medium to easily get to the base of the individual seals, as a result of which the seals are guided in moisture and cannot adhere dry to the bottoms of the grooves in the housing.

An advantageous feature of the master cylinder according to the invention are also the recesses 28, 29, which on both sides of the ring grooves 16, 17 into the associated cam mern are inserted into the housing. These recesses, which are provided at least in the upper region of the chambers, enable or at least improve self-venting in the direction of the wheel outlets for both chambers. It is also advantageous that the recess 29 in front of the primary seal has a flow connection 60 to the annular groove of the primary seal 16, which enables self-ventilation in the direction of the wheel outlets and at the same time prevents the seals from running dry.

The structure of the master cylinder according to FIG. 2 is further characterized in that the two container chambers 5 and 10 are arranged next to one another transversely to the longitudinal axis of the cylinder. This saves installation space in relation to the engine compartment, since, as can be seen from FIG. 2, the master cylinder can be inserted much more deeply into the bulkhead 27 than in the structure according to FIG. 1.

The return springs (see return springs 32 and 36 in FIG. 1) can also be advantageously configured in FIG. 2 in accordance with the structure according to FIG. 1. In this case, a construction is preferably chosen for the bondage, as is shown in connection with spring 33 in FIG. 1. Here, two spring plates 36, 37 are connected to one another via a bolt 35, the maximum distance between the two plates being fixed to one another by projections on the bolt. At least one of the two spring plates 37 can slide on the bolt, so that the two spring plates 36, 37 can be moved towards one another against the force of the spring 33. The spring plates are supported directly on the piston and can be locked with them or connected in any other suitable way. A further simplification for a tandem master cylinder is the structure according to FIG. 4 compared to the structure according to FIG. 2. The transverse bore 44 and the closure element 47 closing this transverse bore from the environment have been omitted and the branch bore 43 directly into the container chamber 10 guided. In contrast to the embodiment according to FIG. 2, the container chambers are now one behind the other in the longitudinal direction of the cylinder axis.

A simplification can also be achieved with regard to the return springs 32, 33, in that they are not tied but act directly on the pistons opposite one another. It may be advisable to design the bottom 11 of the cylinder opening 13 in such a way that the spring can engage there or at least is held in place by static friction. 2 and 4, the end of the spring is chamfered to match the pitch of the coil to the ground so that the force is transmitted precisely along the longitudinal axis of the cylinder. The attack areas 50, 51 on the piston 1 or on the housing 15 can also be provided with projections in which the springs can snap into place. Another possibility, as already explained above, is to use the features according to FIG. 1 with regard to the return springs. It is also important for the invention that the seals 6, 7 and 12, 14 with their sealing foot 25, 26 bear against the inner end face 22, 23 and 30, 31 of the associated annular groove 16 to 19 and support them there. Since these inner end faces are integrally connected to the housing 15, they can absorb considerable forces in a small installation space.

Claims

claims

1. tandem master brake cylinder (THZ, 20) consisting of a housing (15), a linearly displaceable in the housing first piston (1) which can displace a pressure medium from a first chamber (2), a second linearly displaceable in the housing Piston, (3) which can displace a pressure medium from a second chamber (4), the first piston (1) being acted upon by the pressure of the first chamber (2) on the end face in the actuating direction and by the pressure of the second chamber (4), a first primary seal (6) which seals the first chamber (2) after the closing of a flow connection between the first chamber (2) and a first container chamber (5) along the lateral surface of the first piston of the first container chamber (5) seals the prevailing container pressure, a second primary seal (7) which seals the second chamber (4) after the closing of a flow connection (9) between the second chamber (4 ) and a second container chamber (10) along the lateral surface of the second piston to the container pressure prevailing in the second container chamber (10), a first secondary seal (12) which seals the second chamber (4) along the lateral surface of the first piston (1) to the container pressure prevailing in the first container chamber (5), a second secondary seal (14) which seals the second chamber (4) along the lateral surface of the second piston (3) to the pressure in the vicinity of the THZ (20), thereby characterized in that the first primary seal (6) is mounted in a first annular groove (16) made directly in the housing (15) and is thus supported directly on the housing (15).

2. tandem master cylinder (20) according to claim 1, characterized in that the first secondary seal (12) is mounted in a directly into the housing (15) introduced second annular groove (17) and is thus supported directly on the housing (15) when pressurized ,

3. tandem master cylinder according to claim 1 or 2, characterized in that the second secondary seal

(14) is mounted in a third annular groove (18) made directly in the housing and is thus supported directly on the housing (15) when pressure is applied.

4. tandem master cylinder according to one of the preceding claims, characterized in that the second primary seal (7) in a directly into the housing (15) introduced fourth annular groove (19) is mounted and thus is supported directly on the housing (15) when pressurized. ₍

5. Tandem master cylinder according to one of the preceding claims, characterized in that the housing (15) is formed in one piece in the actuating direction (a) and the introduction of the annular groove (s) (16 to 19) and the assembly of the seals from the opposite side he follows.

6. Tandem master cylinder according to one of the preceding claims, characterized in that the primary seal / s (6 or 7) with their sealing foot (25, 26) at the start when actuated in the actuating direction (a) lying in the actuating direction inside face (30) of the annular groove (s) can support.

7. tandem master brake cylinder according to claim 6, characterized in that the sealing foot (25, 26) of the primary seal has one or more recess (s) which provide a flow connection between the chamber (2, 4) and the annular groove (6, 7) guaranteed in the case of support on the inner end face (25, 26) of the annular groove.

8. tandem master cylinder according to one of the preceding claims, characterized in that at least in the upper region of the chamber (s) (2,4) recesses (28) are made which allow self-venting in the direction of wheel outlets or at least improve.

9. tandem master cylinder according to claim 8, characterized in that a flow connection (60) between a recess and the upper region of the annular groove (s) of the primary seal (s) (8, 7), which allow self-venting in the direction of wheel outlets or at least improve.

10. Tandem master cylinder according to one of the preceding claims with springs (31, 32) which reset the pistons (1, 3) counter to the actuating direction (a), characterized in that one or both springs are tied and the tether (35, 36 , 36) with a component which transmits the tethering force applied by the spring to the piston (1, 3).

11. Tandem master cylinder according to one of the preceding claims, characterized in that the flow connections between chambers (2, 4) and container chambers (5, 10) exclusively via flow passages (40 to 44) in the pistons (1, 3) and the housing (15) gen.

12. Tandem master cylinder according to one of the preceding claims, characterized in that the flow connection between the first chamber (2) and the first container chamber (5) within the housing (15) through a direct bore (41) between one between the first annular groove (25) of the first primary seal (6) and the annular groove of the first secondary seal lying first collecting ring groove (45) and a first container connection (5).

13. another master brake cylinder according to any one of the preceding claims, characterized in that the flow connection between the second chamber and the second container chamber within the housing via a tap hole between a second collecting ring groove (46) and a transverse bore, (44) is in turn connected to a second container connection.