DE2022556C3 - Dual-circuit storage brake system, in particular for motor vehicles - Google Patents

Description

The invention relates to a Zweikre ^'11 security brake system, in particular for motor vehicles, according to the preamble of claim 1.

Such, e.g. known from DE-OS 19 28 320 Brake systems, their accumulator brake valves from the brake pedal or another brake lever of the respective Are operated from the vehicle, have a separate storage tank for each pressure storage circuit whose gas space is separated from the liquid space by a membrane is a disadvantage with such Brake systems that the aforementioned memory work uneconomically with the same gas filling pressure. As a result of complete mutual independence of the two pressure lines leading from the pressure accumulators to the brake valve is a separate pressure switch for each pressure line to control the pump of the liquid circuit required, which is sensitive and particularly easy to interfere, e.g. B. leaks, can lead.

The invention is based on the object to avoid the aforementioned defects and to perfect the aforementioned brake system so that whose susceptibility to failure is further reduced and the entire system is less extensive if possible, is simpler and therefore cheaper at the same time

According to the invention, this object is achieved by what is stated in the characterizing part of claim 1 Features solved

In this way, the two pressure storage tanks previously required have become a single storage tank summarized, the two liquid spaces on both sides of the middle one, serving as a gas spring Such a memory is cheaper to manufacture and takes up less space than the two previously required pressure accumulators. Since there is only one common gas space, eventually only one gas filling valve is required. The number of pressure switches and lines for this is also reduced

Further refinements of the invention are contained in the preceding claims 2 to 9. It surrendered thereby further advantages, z. B. not only results in an advantageous fixation of the membranes in their Working positions, but at the same time an advantageous centering of the same. Furthermore, z. B. at the proposed design of the safety switch not only with each inadmissibly extensive pressure reduction in the pressure line adjoining the affected pressure storage space, but due to the The aforementioned springs are also actuated when the associated membrane is no longer in the gas space should seal properly from the allocated pressure storage space. Finally, through the proposed Training achieved not only a simplification and cheaper, but also a potential Failure and especially potential leak point of the system avoided.

In the drawing, the invention is illustrated by way of example; it shows

F i g. 1 the dual-circuit storage brake system in a schematic representation;

F i g. 2 the double diaphragm accumulator of the system according to FIG. 1 in cross section (in opposite to FIG. 1 enlarged scale).

The in F i g. 1 has a brake system shown schematically for the brakes of the front axle 1 and the rear axle 2 of a vehicle, otherwise not shown, each on a separate brake fluid supply, which is supplied from an associated pressure storage space 3 or 4 of a common double diaphragm accumulator 5 via separate lines 6a or 6b or la

and Tb as well as via a dual-circuit accumulator brake valve 8 connected to these lines.This is a conventional switchover valve, which is therefore not shown in detail, through which the line parts 6a and Ta leading to the brakes via a drain line 9 with a storage container 10 when the brake pedal is not actuated for the pressure fluid and when the brake pedal is actuated, accordingly increasingly connected to the line parts 66 and Tb. Each of the two line parts 66 and 7b is also connected to a pump 13 via a check valve il and a pressure line 12 leading to these two, which can take brake fluid from the reservoir 10 via its suction line 13a. This mutual safeguarding creates two independent pressure sources, ie two brake fluid circuits, after the check valves 11. The pump 13 can be driven in the usual way by an electric motor 136.

The Dopyel membrane memory shown in more detail in Fig.2 5 has one of a central profiled sheet metal ring 14 and two identically manufactured, approximately cup-shaped Pressed sheet metal parts 15 welded together housing, in the profiled sheet metal ring 14 within the Housing in two halves dividing plane of symmetry a perforated disk 16 is set between the to the two annular weld seams 17 inside converging wall parts of the profiled sheet metal ring

14 and of the two pressed sheet metal parts 15 is a conventional rolling diaphragm 19 penetrating the associated interior space 18 or 18 'with its outer edge 20 tightly clamped The two pressure storage spaces 3 and 4 formed between the two rolling diaphragms 19 and each associated pressed sheet metal part 15 (see 6b or Tb connected. Since the two openings 22 and 22 'according to FIG. 2 are not pressurized, the rolling diaphragms 19 are there by the two helical compression springs 21 against the associated base parts of the two pressed sheet metal parts

15 pressed so that no pressure storage space is visible there.

The profiled sheet metal ring 14 is still over one with the entire interior space between the two rolling membranes 19 connected opening 23 connected to a pressure switch 24 (Fig. 1), and between the pressure switch and the opening 23 is also a gas filling valve in the usual manner (not shown) provided, via which the said interior space can be placed under a desired excess gas pressure can. The electric motor 136 and the pump 13 are switched on via the pressure switch 24 when the value falls below one Turned on predetermined overpressure in the said interior space and when this pressure is exceeded turned off again like that

During the operation of the motor vehicle equipped with the braking system described, the pressure in the falls entire interior 18, 18 'after a certain number of braking operations up to the switching threshold of the Pressure switch 24, whereby the pump 13 is switched on! μ will. Although with the usual brake systems, the brake cylinders in the front axle circuit per braking Both of them take up significantly more brake fluid than the brake cylinders in the rear axle circuit Pressure storage spaces 3 and 4 jointly assigned interior space 18, 18 'for both pressure storage spaces common medium pressure that is effective at the pressure switch 24

So that a further supply of brake fluid into the double diaphragm accumulator 5 and into the two brake circuits via the pressure lines 6b and Tb can be prevented in the event of any major leakage losses and a corresponding pressure drop in the associated line part 6b and Tb as well as in the associated pressure storage space 3 or 4, a pressure switch 25 is provided not only in each of the two line parts 6b and Tb , but also a safety switch 26 on each pressure storage chamber 3 and 4, which is designed as a contactless switch according to the embodiment shown in FIG is fixed on the outside of the associated rolling diaphragm 19, so that contact is only made in the case of the one shown in FIG. 2, the outer position of the rolling diaphragm 19 shown takes place At each of the two points, where on the one hand the line part 66 and on the other hand the line part Tb is connected to the associated branch of the pressure line 12, there is a solenoid valve 27, the solenoid winding 28 of which, if one of the two is switched on Switch 25 or 26 brings the solenoid valve 27, which was previously in the illustrated open position, into its final position in which all three connections adjoining these branching sections are separated from one another. If in the simplified diagram of FIG. 1 is also not shown a power source so it is of course assumed that all the switches 24, 25 and 26 shown connect the dashed-line electrical lines emanating from these switches to a power source, ie for example to the motor vehicle battery, when they are switched on. Likewise, it is assumed, without a special representation, that both the electric motor 136 and the two magnet windings 28 of the magnet valves 27 are connected to the vehicle battery, each with a further connection point, for example via the ground of the vehicle.

Should a leak occur in one of the two brake circuits, the brake fluid in one such measure escapes that the pressure threshold at one of the pressure switches 25 is below or one the two safety switches 26 is closed, then the associated solenoid valve 27 closes immediately, whereupon further losses of brake fluid are avoided. Also, if one of the two Diaphragm 19 should become leaky, in which case this diaphragm despite maintained brake fluid pressure Via the assigned helical compression spring 21 into the position shown in FIG. 2 shown outer end position reaches, the associated solenoid valve 27 closes in the manner described. This avoids that in the brake fluid in the area of the membrane 19 dissolved gas from the Interior 18, 18 'of the double diaphragm accumulator 5 with the brake fluid further into the rest of the brake system reaches, where it finally boils out after the pressure has been released in the storage container 10 and escapes would. Such an escape of the gas from the Double diaphragm accumulator 5 would result in a corresponding reduction in the usable storage volume bring and the memory will eventually become completely ineffective

do.

In addition, it is assumed that the circuit of each of the two magnet windings 28 of two solenoid valves 27 a warning lamp od. Like. Warning device is connected, which is preferably is arranged on the instrument panel of the vehicle and notifies the driver of the fault that has occurred.

For this purpose 2 sheets of drawings

Claims (9)

Patent claims: 1. Two-circuit storage brake system, especially for motor vehicles, with a two-circuit brake valve, with each of the two circuits pressurized brake fluid from a separate, at the same time serving as a storage space pressure storage space can be supplied, and with one of two pressure storage spaces assigned pump, with which the two pressure storage spaces are pressure-dependent with ι ο Brake fluid can be refilled, characterized in that the two pressure storage spaces (3 and 4) are provided in a double diaphragm accumulator (5), in each of which a diaphragm (19) delimits one of the two pressure storage spaces (3 or 4) and the one between the two Membranes a common gas chamber filled with pressurized gas (interior space 18, 18 ') is provided 2. Brake system according to claim 1, characterized in that that each of the two membranes (19) towards the associated pressure storage space (3 or 4) is biased by a separate spring (21) 3. Brake system according to claim 2, characterized in that both springs (21) on a common, The perforated disk (16) of the housing (14, 15) of the housing (14, 15) penetrating the gas space (interior 18, 18 ') Double diaphragm accumulator (5) are supported. 4. Brake system according to one of the preceding claims, characterized in that each pressure storage space (3 or 4) is assigned a safety switch (26) with which a further brake fluid supply can be shut off and / or a warning device through the membrane (18) which has reached its emptying position is actuated ^ 5. Brake system according to claim 4, characterized in that the safety switch (26) as non-contact magnetic switch is formed 6. Brake system according to one of the preceding claims, characterized in that a gas to the space (interior space 18,18 ') is used to input ^4' and off of the pump (13) of the dual diaphragm accumulator (5) connected pressure switch (24). 7. Brake system according to claim 5 or 6, characterized in that to shut off the further Brake fluid supply a solenoid valve (27) that can be actuated by the safety switch (26) serves 8. Brake system according to one of the preceding ⁵ "claims, characterized in that the housing of the double diaphragm accumulator (5) consists of a central profiled sheet metal ring (14) to which two identical, approximately cup-shaped pressed sheet metal parts (15) are welded on both sides. 9. Brake system according to claims 3 and 8, characterized in that between the to the two annular weld seams (17) on the inside converging to a point V / andteile of the Profilblechrtnges (14) and the pressed sheet metal parts (15) each have the so assigned interior space (18 or 18 ') penetrating rolling membrane (19) with its outer edge (20) is tightly clamped.