DE10144619A1 - Brake force transmission device for a brake booster - Google Patents

Abstract

The invention relates to a brake force transmission device for a brake booster with an elastic reaction element (7), an input member (22) with an assigned active surface (d4), an output member (24) with an assigned active surface (d4) and with a first transmission ratio, which is determined by a is the ratio of the active areas in operative connection with the reaction element (7). DOLLAR A The invention is based on the problem of specifying simply constructed means, preferably arranged in the form of an assembly, which provide greater assistance to the driver of a motor vehicle when high braking power is required. DOLLAR A The essence of the invention lies in the fact that the means (2, 4, 6, 11) are provided which, from a certain pressure in the reaction element (7), the reaction force introduced into the input member (22) by a certain amount Reduce proportion. Consequently, the driver is additionally supported and requires a relatively smaller increase in the input force for a further increase in the output force. This makes it possible to better dose the required higher braking forces by the driver after the jump in the ratio of the reinforcement.

Description

The invention relates to a brake force transmission device for a brake booster with a elastic reaction element, an input member with a assigned effective area, an output member with a assigned effective area and with a first Gear ratio, which by an, in operative connection ratio of the active areas with the reaction element is defined.

Such a transmission device is known for example from Japanese utility model Sho 61-205858. The transmission device has a resiliently biased movable pressure piece ( 38 b) arranged on an input side (or on an output side), which causes a sudden increase in the amplification ratio at a predetermined input force by changing the area ratio on the input side (or on the output side).

The invention is therefore based on Transmission device deriving from the preamble of Claim 1 resulting genus. Task of the present Invention is a transmission device  To provide which with a particularly small size simply into a standard type brake booster can be integrated. It is therefore intended to enable that If desired, transmission device also in already to be able to use existing brake boosters without having to make expensive new or change designs.

The task is characterized by the characteristic part of claims 1, resulting combination of features solved.

In the solution according to claim 1, the invention consists in Principle in that by the deformation of the Reaction element of the switching ring against the force of The spring is moved towards the input song until the area of the control surface which is retroactive to the control Reaction element around the ring surface of the switching ring is increased. This results in a smaller effective area at the entrance and thus also an enlargement of the Gear ratio of the forces. Expressed differently it means that after the stop of the switching ring on the Control housing that acting on the input member Reaction of the output member is reduced. The driver can therefore have the same braking effect with reduced foot strength to reach.

A particularly simple structure for the Transmission device results in further training Invention by the combination of features according to claim 2. Das As explained in more detail below, the spring assembly can be very simple. The spring assembly can continue form a self-contained unit that the Assembly of the brake booster in one piece in the Control housing is inserted. The same can also be said for  apply the switching ring, which is in one piece with the spring assembly can advantageously be connected but a separate unit forms. The advantage of these measures lies in particular in which both the spring assembly and the shift ring in different embodiments are kept in stock can then with which the control housing as needed and desired course of the reinforcement is equipped.

In an advantageous development of the invention is recommended with regard to the spring assembly listed in claim 3 Apply characteristics. The spring assembly can be constructed essentially symmetrically. It is essential only that the two holding elements against the force of the spring can be moved against each other. The stop elements further ensures that the two holding elements to one Unity are united and none of the holding elements can be lost. Also, by choosing the spring and the choice of the distance between the two holding elements the force with which the two can be clearly determined Holding elements are biased towards each other.

According to the combination of features according to claim 4, the first holding elements by one by the second Holding elements extending approach directly to the Attack reaction element. But it is also conceivable that first holding element only indirectly via a pressure piece on the Reactive element acts. The advantage of this is that Pressure piece according to the course of the desired Gain can be selected. As also above already explained with regard to the separately insertable Switching rings a selection is possible can be made through the Combination of the switching ring with a pressure piece of the course vary the characteristic of the gain largely. So that can  through the choice of the switching ring of the pressure piece and the Spring element the reinforcement behavior of Brake booster depending on the input force largely adapted to the respective needs. It is also advantageous that the elements mentioned can be retrofitted and thus an adjustment of the enable amplifiers already in series production.

The features according to a saying 5 describe in further training the invention a particularly simple way of leadership for the switching ring inside the housing. The Switch ring with its inner surface both through the Be outside surface of the approach as well as with his outer surface on the inner surface of a Approach to the control housing. In the event that the first Holding elements only indirectly via a pressure piece on the Reaction element then only attacks one Guide of the switching ring on its outer surface possible.

Corresponding to the combination of features according to claim 6, it can recommend that the switching ring on the control housing stops and thus changes the characteristic of the gain. On the structure can be simplified even further by the Achieve features according to claim 11. The beats Switching ring not directly on the control housing indirectly via the second holding element on which he acts. This makes the switching ring very easy designed so that it is still a simple cylindrical ring is made. Furthermore, the Design according to claim 11 in a very simple manner reach a larger stop surface, then the second Holding elements for receiving a sufficiently large spring  anyway a larger extension in the radial direction must have.

A simplified production can also be done through the Achieve combination of features according to claim 7. Since the fixed ring at the same time as a guide for the switching ring can serve, can by an appropriate Dimensioning of the inner recess of the fixed ring and the outer diameter of the switching ring the strength of the Switching rings and thus the course of the characteristic of Affect gain.

Another simplification for building the Transmission device according to the invention can be Achieve measures according to claim 8. This serves Control housing simultaneously for axial guidance for the second Holding element and as a stop. The walls of the guide grooves are thus used twice by simultaneously Guide in the longitudinal direction and serve as a stop.

To ensure sufficient spring force despite small dimensions To achieve is recommended in further development of the invention Combination of features according to claim 9. But the spring can Influence the course of the characteristic curve of the gain by the characteristic curve of the spring is selected accordingly. The Approach can be according to the features of claim 10 be connected directly in one piece to the first holding element. For saving material and for a suitable combination of The holding element can also be made of materials with the attachment be riveted.

An important aspect for the invention is that as explained in connection with claim 11, they in  particularly expedient in a controlled braking system is inserted. This is especially true if regulated braking system the distribution of braking forces on the individual wheels or wheel groups depending on the Slip on the respective wheel or wheels regulated is. This ensures that with little effort it is possible that the brake on the pedal too weakly actuating driver is nevertheless a sufficiently large one Brake pressure can be generated. On the other hand, worries the regulated distribution of the braking forces that the Vehicle does not slip due to one or more wheels gets off track.

The advantage of the invention is based essentially on following facts. The principle of operation here is based essentially and simply on a preloaded spring that acts in the axial direction between Valve piston and the piston is placed. Are there function-related stops provided, a direct Transmission ensured when controlling the amplifier is. The preferred design features are following. It is simply tied up Compression spring provided, it is a very simple structure Spring element used. The control housing is with a fixed ring, which is very simple as a force receiving disc is designed. This pinned ring can be against the face of a stepped bore in the Put the control housing into the wall of the stepped bore Grooves are embedded which are also used for guidance also serve as a stop. In other words u. a. in the The construction described here is particularly important as follows.  

The functional principle here is based essentially and in a simple manner on a prestressed spring, which is placed in the axial mode of operation between the valve piston and the annular piston, with a few function-related stops, with a direct power transmission being ensured during the control. Particularly noteworthy design features are the compression spring (s) ( 5 ), an inexpensive power transmission element, tied up in a simple manner, a control housing area ( 4 ) behind the power-absorbing disc ( 1 ) takes up multifunctional, the forces switching ring ( 2 ) and simultaneously serves to guide the Stop disc as second holding element ( 6 ) with stop. The stop disc ( 6 ) prestresses the spring, transmits the reaction forces of the ring piston ( 2 ) to the spring, is the stop of the ring piston, and is a transmission element when controlling.

The invention is particularly effective in connection with a electronic regulated braking force distribution since at ABS (anti-lock braking system) usually also fails Failure of the electronic brake force distribution (EBV) occurs. In this case, the driver can brake pressure Measure the steep branch of the amplifier characteristic curve well. This stands in contrast to systems with a panic brake function such as z. B. Brake assistant (BA) or mechanical brake assistant (MBA), which when switching to an infinite (steep) Characteristic of the brake force boost much more difficult are manageable.

Two embodiments of the invention are as follows explained using the drawing. It shows curvature

Fig. 1 shows a transmission device according to the invention according to a first embodiment in section and in broken out representation

FIG. 2 shows a section through the exemplary embodiment according to FIG. 1 at the height of section line AA in FIG

Fig. 3 shows a second embodiment of the invention.

The structure and function of the transmission device 1 are discussed in detail below, the basic function of a brake booster, as can be seen, for example, from PCT / EP98 / 07314, is assumed to be known.

Basically known brake boosters have considered idealized over the entire operating range up to towards the so-called modulation point via a constant Gear ratio, being the evoked Output force (foot force and reinforcement force) linearly over the input force (foot force) increases. Is very basic the translation, which reflects the driver's pedal feel in the significantly influenced by the ratio of the Output member assigned effective area (d4) to the Defined effective area (d3) assigned to the input element. For higher braking performance, that is, with higher Braking level is considered positive, the driver support more. In other words, it becomes a greater gear ratio like it For example, JP-Sho-61-205858 can be found.

A transmission device 20 according to the invention comprises, in addition to other parts to be attributed to the brake booster, which have no decisive influence here and are therefore not described below, an input member 22 with a valve piston 23 movably arranged in a control housing 8 with a first sealing seat 21, and an output member 24 for actuating a master brake cylinder, not shown. Between the input member 22 and the output element 24 there is a preferably disc-shaped and made of plastic material or elastic material elastic reaction element 7 , which is surrounded on all sides by surfaces of parts of the transmission device 20 , in other words is, as it were, encapsulated between movable walls. Under pressure, the elastic reaction element 7 behaves like an incompressible fluid according to the laws of constant volume and acts as a mediator between the foot forces introduced via the input member 22 and the braking reaction forces, which act on the vehicle driver from the vehicle braking system. As a result, there is a force balance on the reaction element 7 in each brake actuation position.

The reaction element 7 is seated in a pot 25 which is open to the left in FIG. 1 and which is formed by a first bore 26 in the control housing 8 and a fixed ring 1 which is supported on the edge 28 of a second bore 27 in the control housing 8 . The pot has an input opening 29 in which the front end of the output element 24 is guided in the drawing. The output member 24 passes at its right end in FIG. 1 into a plate 10 which closes the pot 25 and bears against the wall of the reaction element 7 pointing to the left in FIG. 1. To the right, the reaction element 7 is supported against the fixed ring 1 , which in turn bears against the circumferential edge 28 or step between the first bore 26 and the second bore 27 . The area for the plate 10 is given the value d4. The fixed ring 1 has an opening on the inside, which is given the value d3 as the area of the opening. A switching ring 2 is guided in the opening (d3) and can be displaced in the longitudinal direction of the amplifier relative to the fixed ring 1 . A spring element is composed of a first holding element 3 , a second holding element 6 and a spring 5 . The spring 5 biases the two holding elements 3 and 6 against each other so that they can only be moved against each other with a certain force. The maximum distance between the two holding elements is fixed by a stop 12 which is arranged on a shoulder 13 of the first holding element 3 .

The first holding element 3 is provided with an extension 13 which, together with the holding element, can be formed as a single, continuous piece. However, it also makes sense to design the projection 13 as a riveted part, as shown in FIG. 1. For this purpose, the rivet part can be selected from a material with a suitable strength, while the first holding element 3 is formed from a formable sheet metal. At the end of the rivet part 13 , a stop 12 is provided, which is designed as a circumferential projection. This stop ensures that the second holding element 6 can only move a predetermined distance from the first holding element 3 . The approach 13 can protrude into the interior of the switching ring 2 . As in the present exemplary embodiment, a pressure piece 31 can also connect to the rivet part 13 , which protrudes through the switching ring 2 and acts on the reaction element 7 .

It is important for the present invention to guide the second holding element 6 in the control housing 8 . This guidance takes place with the aid of guide grooves 4 , which are worked into the inner lateral surface of the second bore 27 distributed over the circumference of the bore. For the purposes of guidance, the second holding element 6 is provided with appropriately designed guide projections 15 which engage in the grooves 4 , as is shown in FIG. 2. An end wall 11 in each groove forms a stop for the guide lugs 15 , so that when the guide lugs 15 stop on the respective end wall 11, a force directed towards the second holding element 6 in FIG. 1 to the right is absorbed by the control housing 8 . The further components shown in FIG. 1 are not essential for the present invention and are therefore not described in more detail here.

The operation of the embodiment of Fig. 1 is as follows. If, in the position shown in FIG. 1, the input member 22 is shifted to the left in FIG. 1, the pressure piece 31 and the switching ring 2 act on the reaction element 7 . A surface d3 is thus effective on the reaction element 7 , while the reaction element 7 acts with the surface d4 toward the output member 24 . The ratio of these two areas determines the gain ratio of the amplifier in this working state. The switching ring and thrust piece 31 move in parallel with each other since the spring 5 is so stiff that it does not yield in this area to the input force acting on the input member 22 .

As the input force increases, the force exerted by the output member 24 and acting in the direction of the input becomes greater, and the proportionate force acting on the switching ring 2 also increases . This force finally becomes so great that the second holding element 6 is raised by the stop 12 by the force exerted by the switching ring 2 , since the spring 5 begins to yield. The shift ring 2 thus shifts to the right in relation to the pressure pieces 31 in FIG. 1. This shift increases with increasing strike input force on until finally the guide projections 15 on the associated end wall. 11 The spring 5 is pressed together and shortened accordingly. With a further increase in the input force, the additional forces acting in the direction of the input on the switching ring 2 are only absorbed by the end wall 11 and thus the control housing 8 . From this point in time, only the surface d2 acts on the input member 22 as the retroactive force of the reaction element 7 . The gain of the amplifier, which is dependent on the effective areas, thus results from the ratio of the areas d4 to d2. By striking the guide lugs 15 on the end wall 11 , a sudden increase in the gain of the amplifier is achieved.

When the input force decreases, the processes described proceed in the opposite direction. The pressure piece 13 moves relative to the fixed switching ring 2 in FIG. 1 to the right until finally the spring 5 moves the switching ring 2 to the left away from the end wall 11 via the second holding element 6 . The switching ring 2 thus acts again in the direction of the input and transmits a corresponding counterforce via the spring 5 to the input member 22 . The reinforcement ratio has thus decreased by an amount corresponding to the increase in the retroactive force.

The second exemplary embodiment shown in FIG. 3 is only slightly changed compared to the exemplary embodiment according to FIG. 1. The main difference is that instead of a spring 5, two parallel springs 5 and 32 are used. The internally seated second spring 32 has a lower spring constant than the first spring 5 . In this way, a larger and more precisely adjustable spring force can be set up in the same space.

Claims (11)

1. Transfer means for the braking force of a brake booster with an elastic reaction element (7), an input member (9), which acts via an input effective area on the reaction element (7) and having an output member (10) which comprises an output effective surface (d4) on Reactive element ( 7 ) acts, wherein at least a part (d4-d3) of the force exerted on the output active surface (d4) is absorbed by the control housing ( 8 ) of the brake booster and wherein change means ( 3 , 5 , 6 ) are provided, by which the force transmission ratio between the input member ( 9 ) and the output member ( 10 ) determined by the ratio of the active surfaces (d2, d4 or d1) depending on the forces exerted on the reaction element ( 7 ) via the active surfaces or the deformation of the reaction element ( 7 ) is changed, characterized in that a part (d3-d2) of the area of the R Action element ( 7 ) via a switching ring ( 2 ) and a spring element ( 3 , 5 , 6 ) is supported on the input member ( 9 ), with the force exerted on the reaction element ( 7 ) increasing the switching ring ( 2 ) against the force of the Spring element ( 3 , 5 , 6 ) is moved towards a stop ( 11 ) on the control housing ( 8 ) and engages it, thus reducing the input effective area (d2). 2. Transmission device according to claim 1, characterized in that the spring element is a tied spring assembly ( 3 , 5 , 6 ). 3. Transmission device according to claim 2, characterized in that the spring assembly ( 3 , 5 , 6 ) is provided with a spring ( 5 ) which is clamped between two mutually movable holding elements ( 3 , 6 ) under pretension, which is at its maximum distance are limited to each other by a stop element ( 12 ). 4. Transmission device according to claim 3, characterized in that the first of the two holding elements ( 3 ) abuts the input member ( 9 ) and forms a shoulder ( 13 ) for the input member ( 9 ), which can act on the reaction element ( 7 ) and continue is provided with a stop ( 12 ) opposite the second holding element ( 6 ) which forms the stop element. 5. Transmission device according to one of the preceding claims, characterized in that the switching ring ( 2 ) is designed as an exchangeable loose component and is preferably guided with its inner lateral surface through an outer lateral surface (d2) of the extension ( 13 ) and / or with its outer lateral surface (d3) is guided through the inner circumferential surface of a radial housing projection ( 1 ) of the control housing ( 8 ), which receives a part (d4-d3) of the forces exerted axially by the reaction element ( 7 ) towards the input side. 6. Transmission device according to claim 5, characterized in that the forces absorbed by the switching ring ( 2 ) from the reaction element ( 7 ) from the second holding element ( 6 ) via the spring ( 5 ) to the first holding element ( 3 ) until the second holding element ( 6 ) strikes on the control housing ( 8 ). 7. Transmission device according to claim 6, characterized in that the reaction element ( 7 ) directly into the control housing ( 8 ) in the input direction forces are transmitted to a ring in the input direction against the control housing ( 8 ) ( 1 ). 8. Transmission device according to claim 3 or one of the following claims, characterized in that the second holding element ( 6 ) is provided with radial second guide lugs ( 15 ) which are axially guided in assigned second guide grooves ( 4 ) in the control housing ( 8 ), the End wall ( 11 ) of the second guide grooves ( 4 ) forms the axial stop in the control housing ( 8 ). 9. Transmission device according to one of the preceding claims, characterized in that the spring element ( 3 , 5 , 6 , 14 ) with two mutually concentrically arranged coil springs ( 5 , 14 ) is provided. 10) Transmission device according to one of claims 4 to 9, characterized in that the extension ( 13 ) is riveted to the first holding element ( 3 ). 11. Transmission device according to one of the preceding Claims characterized in that they are regulated Brake system is inserted, in particular the Distribution of the braking forces on the individual wheels or Wheel groups depending on the slip on the respective Wheel or wheels is regulated.