DE4240495A1 - Hydraulic master cylinder for controllable braking system - has two sections of different diameters and with piston seal also aligning piston interior bore - Google Patents

Abstract

The cylinder is made in one piece by deep drawing with the narrow section (3) comprising the high pressure section and the wider section (4) locating the piston rod guide (12,15). The end of the piston has a pressure seal (9) fitted over a sleeve (11) which has a press-fit on the end of the piston. This seal therefore forms one support for the piston, with the piston rod seal (15) the other support. The piston sleeve has a press-fit mounting on the piston, with an integral seal and enclosing the central valve through which lost fluid is replaced. ADVANTAGE - It can stand large pressures and provides a cost effective construction.

Description

The invention relates to a master cylinder with a simple Structure that, if possible, also for regulated brake systems should be applicable, d. H. even under high pressure works reliably.

Simply constructed master cylinders are from, for example P 33 31 834.4, P 38 16 607.0 and P 38 16 608.9, from the US-PS 46 85 301, WO 89/09712, WO 87/03344, DE-OS 34 31 115 or DE-OS 38 16 608 known.

A disadvantage of the known simply constructed cylinders is it that these are only used to operate Couplings are suitable, so only with comparative work reliably at low pressure.

The present invention is therefore based on one Master cylinder resulting from the preamble of claim 1 resulting genus. The object of the invention is a such cylinders using only less inexpensive Individual parts particularly stable and under high pressure to design reliably working, this one Master cylinder can preferably be used in a twin circuit  should, as for example in patent application P 41 21st 413.7 of the applicant.

The task is characterized by the characteristic part of the combination of features resulting from claim 1. The In principle, the invention therefore consists in a stepped, preferably deep-drawn sheet metal housing within the Pressure chamber with a very small diameter in the piston to insert a central valve. Furthermore, the Guide surface of the piston increased significantly, so that the Master cylinder is quite stable against lateral forces. The Sleeve still provides protection for the central valve, so that it is also easier to store and assemble later can be. The central valve must be a certain size have to realize appropriate flow cross sections can.

The space required for the diameter of the second stage can be followed by using the combination of features Keep claim 2 small. This makes the seal opposite the central valve to the brake line connection offset arranged the sleeve.

A particularly simple solution results from use of the features of claim 3, by the piston-fixed seal at the same time to seal the surface between the sleeve and Piston is used. By the features according to claim 4 the sleeve can be particularly easily on the piston assemble. The seal is thus in front of the central valve set.

Earlier it was explained that the housing to reduce the cost and to achieve an enlarged Strength preferably made from deep-drawn sheet metal  is. The same method can be used advantageously Apply claim 5 also for the piston sleeve, the Piston sleeve then by latching tongues or after Assembly in corresponding recesses in the piston indented tongues is connected to this.

On the one hand, the above-mentioned measures work Piston shape quite simple. According to claim 6, the Sleeve also to support the valve Apply the acting spring.

The present invention leaves a number of advantageous housing designs, for example in patent application P. . . . (P 7409) by the applicant more are described in detail. It is recommended in particular an embodiment, the features of which are in Claim 8 are listed.

Another way of forming a suitable one Approach and at the same time mounting flange shows in advantageous development of the combination of features Claim 9. To the necessary seal between the Interface of the leadership insert and the inner one To reach the outer surface of the stepped housing appropriate seals required. When using a Paragraph according to claim 9 is particularly recommended the application of the features of claim 10 not just the seal of the interface between the Guide part and the housing sleeve, but also also still reached between the housing sleeve and housing pot as well possibly also the seal between the guide part and Housing pot.  

To the interior of the housing compared to the environment on the sealing the side facing the piston rod is recommended the measures according to claim 11. This will Seal placed behind the guide surface, resulting in a improved lubrication of the piston surface compared to the Leadership and thus an improved running and Sealing behavior of the master cylinder and especially the Manufacture of the guide sleeve facilitated.

In order to improve the guidance of the piston in the master cylinder, it is advantageous to apply the features of claim 12. Then the guide part extends into the first housing stage. As a result, the cylinder pin is guided and the guide part is also centered in the housing 1 .

Another solution of the invention results from the Combination of features according to claim 13 Central valve no longer in the piston or its sleeve installed, but the sleeve is quasi by a housing - fixed insert, which is close to the Pressure connection is arranged. This allows one achieve particularly slim embodiment as they for example for switching as a twin master cylinder is appropriate.

For a simple and stable brake line connection for The present master cylinder was created in the Patent application P. . . . (P 7409) by the applicant proposed this in an adjacent to the pressure room incorporate additional fourth stage so that a  deep-drawn connection nipple aligned with the housing arises, which is characterized by special strength and simple Manufacturability distinguishes. In the event that the Follow-up tank for spatial reasons near the Brake line connection must be routed, is recommended the combination of features according to claim 14.

To avoid that when installing the insert the corresponding channel not with the associated opening of the Trailing tank must be aligned and to in terms of Installation position of the insert to be largely free is recommended the combination of features in a development of the invention according to claim 15. Then the connection from the pressure chamber via the central valve and the associated channel via a circumferential recess on the outer circumference of the insert, so that regardless of the angular position of the insert Follow-up drilling of the tank always with the central valve in Connection is established.

A lag when pulling back the piston can be in simply by the features of claim 16 achieve by sealing the insert against the inner surface of the housing at the same time as a valve for the inflowing pressure medium when returning the piston is exploited.

Exemplary embodiments of the invention are described below the drawing explained. In it shows

Fig. 1 in a sectional view a first embodiment,

Fig. 2, in a sectional view of a modification of the embodiment of FIG. 1

Fig. 3 in a second embodiment,

Fig. 4 shows a comparison with FIG. 3 modified embodiment,

Fig. 5, 6 mounting possibilities of the expansion reservoir and the embodiment of Fig. 4,

Fig. 7, 8, a third embodiment of the invention.

Fig. 1 shows a manufactured from deep-drawn sheet metal housing 1, comprising a fourth stage 2, a first stage 3 and second stage 4, the steps after the open end of the housing 1 to increase in diameter. Details of possible embodiments of the housing, as are also partially described below, can be found in patent application P. . . . (P 7409) from the applicant.

At the fourth stage, a connection thread is provided for connecting a brake line or a brake hose. The fourth stage 2 has a corresponding connection opening on its bottom.

In the first stage 3 there is the pressure chamber 7 , which is delimited on the right in the drawing by a movable piston 8 . At the front end of the piston, a recess is provided for receiving a first sleeve seal 9 , which is designed as a lip seal. The piston 8 itself consists essentially of the piston rod 10 and the piston sleeve 11 , which is connected to the piston rod 10 via an interference fit.

The piston 8 is guided via the piston sleeve 11 in the first stage 3 and with the piston rod 10 via a guide sleeve 12 in the second stage 4 . Details on this can also be found in the already mentioned patent application P. . . (P 7409) by the applicant, which is also the subject of the disclosure of the present application.

The transition from the first stage 3 to the second stage 4 forms a first shoulder 13 against which a support disk 14 bears. The other side of the support disk 14 forms the contact surface for a second sleeve seal 15 which bears on the opposite side of the guide sleeve 12 . The inner diameter of the support disk 14 allows the piston rod 10 to be passed through to the left in the drawing, but forms a stop for a stop pin 16 for a movement of the piston rod directed to the right in the drawing. The stop pin sits in a control bore 17 in the piston rod 10 , which permits a relative movement of the stop pin 16 with respect to the piston rod 10 within certain limits (approximately 2 mm). This relative movement moves a valve tappet 18 relative to the piston rod and thus a movable valve body 19 relative to a valve seat 20 that is fixed to the piston, in a manner known per se. Due to the relative movement of the control pin 16 , the valve 19, 20 is thus closed or opened depending on the position of the piston rod 10 . To close the piston rod moves from the end position shown in the drawing to the left, so that due to the action of a biasing spring 21, the valve lifter 18 performs a relative movement relative to the piston 8 to the right until finally the valve 19 , 20 closes. The valve is opened in the opposite manner by a relative movement of the stop pin 16 to the left by the action of the support disk 14 .

The use of the piston sleeve 11 shown is particularly important for the invention. On the one hand, this enables the first cuff seal 9 to be offset to the left in the drawing with respect to the central valve 18-21 and also enables the piston to be supported relatively far to the left. On the other hand, this design allows the housing to be designed with a comparatively small diameter, which makes the master cylinder according to the invention particularly suitable for use in a twin circuit. Furthermore, the central valve is accommodated within the sleeve 11 so that it is easy to assemble, so that here the central valve cannot be damaged during long storage prior to the final installation.

The piston sleeve 11 also has a diameter reduction 22 . As a result, the overrun via the bore 6 in the housing 1 is ensured and, on the other hand, extensive wetting of the surface of the piston rod 10 is ensured, which leads to an improvement in its runnability compared to the second sleeve seal 15 , which is thus protected, which improves the sealing behavior.

The plunger 18 is held at a distance from the plunger bore by ribs 23 indicated in cross section in the drawing, so that the pressure medium passing the valve can stroke along the ribs in the axial direction of the piston.

Also very important for the invention is the fact that the piston-fixed valve seat 20 , which is essentially made of a rubber ring, not only serves to seal the valve 19 , 20 , but at the same time also a seal for the pressure medium from the interface 24 between Piston rod 10 and piston sleeve 11 forms. In this way, pressure equalization is also prevented when the master cylinder is actuated from the pressure chamber 7 to the diameter reduction 22 via the interface 24 . This risk exists because the pressure level of the trailing tank, ie the ambient pressure, prevails in the channel formed by the diameter reduction 22 .

From the invention it can also be seen that the essential mechanical support surfaces on the piston sleeve and the piston rod are given by the front region of the piston sleeve 11 and the guide sleeve 12 , these parts being far apart. As a result, the piston has considerable strength against transverse forces exerted on the piston rod.

The paragraph 13 is formed by a fold 25 as a flange with which it can be placed against a bulkhead or a booster.

Fig. 2 shows a modified embodiment. The piston sleeve 11 was not cast, but was manufactured in a deep-drawing and rolling process. Internal pressure molding processes can also be used, such as those described in the applicant's application P 42 01 422.0. The piston sleeve 11 is fastened to the piston rod 10 with the aid of tongues 26 or suitable beads which are pressed into a corresponding, if appropriate, circumferential recess 27 in the piston rod 10 . The attachment by tongues can be done so that they point alternately in both directions and thus secure the piston sleeve 11 in both directions of movement. Another possibility is to use a stop ring 28 .

Fig. 3 1, the possibility of the second housing step 4 shows as a second modification of the first embodiment shown in FIG. FIG. 1 by a housing pot 29 to be formed. Such an embodiment is in the application P. . . . (P 7409) by the applicant is sufficiently described. Advantageous here to secure the simplified secure the guide sleeve 12 and the possibility to the bottom of the housing pot 29 and the second cup seal 15 far to the right and thus favorable to arrange for a smooth running of the piston rod 10 and.

By widening the diameter of the housing pot 29 compared to a third stage of the housing 1 designed as an intermediate stage 30 , a further shoulder 31 is obtained , against which the guide sleeve 12 can be supported in the axial direction by means of a corresponding extension. The O-ring 32 also serves to seal the interfaces between the guide sleeve on the one hand and the intermediate stage on the other. An axial seal is achieved in this way. The guide part 12 according to FIG. 3 differs from the guide part 12 according to FIG. 1 by an elongated annular section 34 which projects into the intermediate step 30 for guiding the cylinder pin and for centering. The sliding property of the guide part 12 with respect to the piston rod and the piston sleeve is particularly good due to the pressure medium film on the piston. The diameter expansion of the housing 1 in the area of the trailing bore also serves to be able to manufacture the housing with a very small master cylinder diameter using the deep-drawing process.

FIG. 4 shows a modification of the second exemplary embodiment according to FIG. 3, the O-ring 32 being moved to the left in the drawing and being located radially further inward than in the second exemplary embodiment according to FIG. 3. According to FIG. 4, further measures can be seen which facilitate the transport of the pressure medium flowing in from the trailing tank via the connection opening 6 in the direction of the second sleeve seal 15 . Slot channels 35 serve this purpose. At the front end of the guide sleeve 12 , webs 36 are further provided, which enable the guide sleeve 12 to be supported with respect to the intermediate step 30 .

Here, the as shown in FIG. 5 can be seen, sleeve-shaped sealed lower end of the container 37 via a sealing ring 38 relative to the intermediate stage 30 and thus the housing. The sealing ring 38 is inserted into a corresponding annular recess on the end face of the container connection.

The expansion of the housing resulting from the intermediate stage 30 also creates the possibility of providing a flattening 39 locally, as shown in FIG. 6. This results in an improved sealing behavior and a simplified configuration of the lower end of the container connection 40 . Another connection option is shown in FIG. 5, in which the flattening 39 has been omitted.

Fig. 7 shows another possible solution for the inventive task. A structure is assumed which has been largely described in connection with FIG. 1. It is essential here, however, that the piston sleeve has been replaced by a valve insert 41 which is arranged at the left end of the first stage 3 in FIG. 7. Such a central valve carrying inserts are known for example from US-PS 49 24 673 or 49 41 323. It is essential for the invention that the insert 41 is designed such that it is suitable for a brake line connection 5 explained in connection with FIG. 1 due to the high pressure to be processed. For this purpose, the valve insert 41 is provided with a valve channel 42 which opens into a transverse container channel 43 . The container channel merges into a circumferential groove 47 which is connected to the container opening 6 . The container is then attached above the container opening 6 , possibly in a manner as described in connection with FIGS. 5 and 6. Instead of the valve tappet 18 , a valve rod 44 is provided in FIG. 7, which allows the movable valve body to move relative to the piston rod 10 .

If the piston rod 10 is moved to the left in FIG. 7, the tied valve rod 44 also moves to the left under the force of the spring 21 until the valve closes. The valve channel 42 is then sealed off from the pressure chamber and pressure can be built up in the pressure chamber 7 . After the valve has been closed, the valve rod 44 remains stationary even when the piston rod 10 moves to the left by pushing its end into the inner bore 45 of the piston rod 10 . Conversely, when the piston rod 44 is moved to the right when the piston rod 10 moves to the right shortly before the stop is reached by the piston rod, the valve is opened and the pressure chamber 7 is brought to ambient pressure. The connection between the pressure chamber 7 and the connection 5 takes place via an essentially axially extending connection bore 46 , which must be designed in such a way that it neither intersects the container bore 43 nor the circumferential channel 47 or the valve channel 42 . For this purpose, according to FIG. 8, the container bore 43 may only be made in sections and not continuously, as shown in FIG. 7. In order to ensure a good seal of the connection 5 with respect to the container, the insert 41 must be sealed with appropriate seals, preferably O-rings. Instead of the O-ring facing the pressure chamber 7 , a fourth sleeve seal 48 can be used, as indicated in FIG. 7. With this sleeve seal, it is possible to suck up the piston rod 10 from the container opening 6 via the groove 47 in the pressure chamber when the piston rod 10 is retrieved, which can be done by overflowing the fourth sleeve seal 48 . To reduce to improve the sealing performance and to the tolerance in the production of the master cylinder according to the invention, the insert may be provided with a cylindrical projection 49 41 which rests against the bottom of the second stage. 3 Due to the reduced diameter of the cylinder shoulder 49 compared to the inner diameter of the second stage 3 , the unique position of the insert 41 is independent of the curvature with which the floor merges into the side walls of the first stage. Another possibility according to FIG. 8 is to move the outlet-side seal of the insert 41 into the fourth stage 2 .

The gradual expansion of the housing 1 , in particular the expansion that follows the pressure chamber 7 , is very advantageous since a deep-drawn part with a very small diameter can still be realized for the master cylinder. In other words: the gradual narrowing towards the pressure chamber creates the possibility of using a deep-drawing process to obtain a comparatively very small diameter for the pressure chamber and thus for the master cylinder.

Furthermore, the invention shows the possibility of dividing the housing in the axial direction in order to keep the depth of the deep-drawing part as short as possible axially and thus to simplify its manufacture. Reference is once again made to the advantageous embodiment, in the area of the housing extension, that is to say the intermediate stage 30 according to FIG. 6, to flatten the cylindrical surface of the housing in order to obtain an improved sealing of the trailing container seated there.

Claims (15)

1. Master cylinder for a preferably controllable brake system with a housing having at least two stages ( 3, 4 ), the first stage ( 3 ) accommodating the pressure chamber ( 7 ) and the second stage ( 4 ) being a guide part for guiding the first stage ( 3 ) projecting piston ( 8 ), characterized in that the piston ( 8 ) immersed in the pressure chamber ( 7 ) is provided with a central valve ( 18 to 23 ) and the piston seal ( 9 ) sits on a piston sleeve ( 11 ), which is connected to the piston ( 10 ) and surrounds the central valve ( 18 to 23 ). 2. Master cylinder according to claim 1, characterized in that the piston seal ( 9 ) on the piston sleeve ( 11 ) in the direction of the pressure chamber is arranged spatially in front of the central valve ( 18 to 23 ). 3. Master cylinder according to one of the preceding claims, characterized in that the central valve ( 18 to 23 ) as a movable valve body ( 18,19 ) has a steel body and as a piston-fixed valve body ( 20 ) has an annular, preferably substantially hollow cylindrical sealing seat made of elastic material and that the piston-fixed valve body ( 20 ) serves at the same time to seal the interface between the piston ( 10 ) and the piston sleeve ( 11 ). 4. Master cylinder according to one of the preceding claims, characterized in that the piston sleeve ( 11 ) with a press fit ( 24 ) sits on the piston ( 10 ). 5. Master cylinder according to one of claims 1 to 3, characterized in that the piston sleeve ( 11 ) is formed from deep-drawn sheet metal and is held on the piston by recesses ( 27 ) of the piston ( 10 ) projecting tongues ( 26 ). ( Fig. 2) 6. Master cylinder according to one of claims 1 to 5, characterized in that the spring ( 21 ) acting on the movable valve body ( 18, 19 ) is supported on the inner wall of the piston sleeve ( 11 ). 7. Master cylinder according to one of the preceding claims, characterized in that the second stage ( 4, 29 ) adjoins the first stage ( 3 ) in a horizontal direction via a shoulder ( 13 ) connecting the two housing stages and in that a guide sleeve ( 12 ) is supported on the shoulder ( 13 ) in the horizontal direction ( Fig. 1, 3). 8. Master cylinder according to claim 7, characterized in that the paragraph ( 13 ) in a by folding the housing ( 1 ) formed flange ( 25 ) merges ( Fig. 1, 7). 9. A master cylinder according to claim 7 or 8, characterized in that the shoulder is formed by a connected to the housing (1) housing pot (29) whose diameter is greater than that of the adjacent first stage and an intermediate stage (30) is arranged between the first stage ( 3 ) and the housing pot ( 29 ) ( Fig. 1, 7 and ä, 5). 10. Master cylinder according to claim 9, characterized in that a seal is placed in the radial plane of the interface ( 33 ) between the housing ( 1 ) and housing pot ( 29 ) ( Fig. 3). 11. Master cylinder according to one of the preceding claims, characterized in that a seal ( 15 ) on the pressure chamber ( 7 ) facing away from the bottom of the housing pot ( 29 ) is inserted and held by them in the axial direction. 12. Master cylinder according to one of the preceding claims, characterized in that the guide part ( 12 ) is held in the housing pot ( 29 ) and centered in the housing ( 1 ) and in particular in the retrieved state of the piston ( 10 ) surrounds the piston sleeve ( 11 ) ( Fig . 3, 5). 13. Master cylinder for a preferably controllable braking system with a housing having at least two stages ( 3 , 4 ), the first stage ( 3 ) accommodating the pressure chamber ( 7 ) and the second stage ( 4 ) being a guide part for guiding the first stage ( 3 ) projecting piston ( 8 ), characterized in that an insert ( 41 ) sealed against the pressure chamber is inserted at the outlet end of the pressure chamber ( 7 ) and carries a central valve which is actuated by an actuating rod ( 44 ) bound in the piston will ( Fig. 7). 14. Master cylinder according to claim 13, characterized in that the insert ( 41 ) is provided with channels ( 42 to 47 ) which one with the pressure chamber ( 7 ) aligned pressure line connection ( 5 ) on the housing directly with the pressure chamber ( 7 ) and Connect the connection ( 40 ) of a trailing tank ( 37 ) to the pressure chamber ( 7 ) via the central valve. 15. Master cylinder according to claim 13 or 14, characterized in that the insert ( 41 ) is provided with a circumferential recess ( 47 ) which is connected to the container connection ( 40 ) and into which the associated channel ( 42 , 43 ) opens. (Fig. 7) 16. A master cylinder according to any one of claims 13 to 15, characterized in that one of the seals (48) is designed as a lip seal with the leading to the supply reservoir (37) channel (43, 47) and the pressure chamber ( 7 ) is connected and allows suction of pressure medium by overflow when returning the piston ( 10 ). 17. Master cylinder according to one of the preceding claims, characterized in that the surface of the housing ( 1 ) is flattened in the area in which the trailing container sits on the housing.