DE1015325B - Adjustable pressure gas spring, preferably for vehicles - Google Patents

Description

GERMAN

Gas spring systems are known in which the resilient medium - enclosed in elastic spring bodies - consists of air, gases or vapors. To such spring systems in practical operation occurring different load conditions, e.g. B. to adapt to the payload differences of vehicles, to be able to adjust, air springs have been developed, whose air weight by pumping or Relief of air can be varied according to the load conditions. However, such spring systems have the disadvantage that the resilient medium - in this case air - is constantly lost and replenished must be, which annoying side effects, such as corrosion, water separation with the through they caused dangers of ice formation and freezing of the control organs in winter, as well as certain Maintenance work is unavoidable. In addition, the consumption of mechanical work for the compression of the compressed air used for control purposes is not insignificant, especially if it is springs are involved, which very often have to adapt their load capacity to different payloads, as well as if the springs are still sufficiently soft with greater load capacity, d. H. with a correspondingly large Volume (liters) need to be built.

One has also developed spring systems whose load-bearing capacity is influenced by the temperature of the spring Medium can be varied. However, depending on the season, such springs require provision different, sometimes not insignificant amounts of heat energy, if they z. B. in vehicles in which waste heat (e.g. cooling water heat from engines) etc. is not available stands.

Such thermally regulated springs can also be used in conjunction with vaporizable liquids or Gases and liquids in which these gases go into solution in large quantities have been proposed, with the advantage of significantly less heating required to generate a large Changes in pressure inside the system characterize the functioning of these springs. However are also these systems rely on the provision and installation of heating and recooling systems.

Compression gas spring systems have also become known whose internal pressure, which determines the load-bearing capacity, can be increased by gases generated with the aid of chemical reactions or with the aid of electrolysis, with gas generation taking place inside the systems and gas generation being determined by the spring height of the spring. However, if such springs are to be set to a lower pressure when the pressure is released, the amount of gas that has become superfluous according to the release must be released into the open.
preferably for vehicles

Applicant:

German Federal Railways,
represented by the Bundesbahn-Zentralamt Minden,
Minden (Westphalia), Weserglacis 2

Dr.-Ing. Gustav-Adolf Gaebler, Langen (Hess.),
has been named as the inventor

be left. For such springs it has also been suggested to pump up the chemical reaction or electrolysis of the required substance with the aid of pump devices driven by the spring movement undertake a solution such as that used in connection with air springs of differential or auxiliary pistons has already been recommended.

However, all these devices, as far as they use a pumping device, must be different from the normal Compress atmospheric pressure to the system working pressure.

According to the invention, on the other hand, a controllable pressure gas spring, preferably for vehicles, is designed in such a way that that within a closed and in the rest and normal position of the spring under medium working pressure standing system is connected between a gas-filled spring body and a storage container Compressor the pressure in the spring over a known manner from the spring height of the Spring-influenced control element by pumping in or pumping out resilient medium, automatically load-dependent changes. Such a system has the advantage that

1. It can be made completely closed, so that any contamination of the interior of the system is reliable is avoided

TOS «0/257

3 4

2. the mean pressure potential of the resilient me- medium to be compressed from the mean pressure to the diums in the system only by increasing or decreasing a slightly higher control pressure either in the spring 3 ken to bring the pressure in the spring itself from the mitt- or in the reservoir 12, while for leren pressure to the maximum or minimum pressure, the intermediate states in which the pressure z. B. in 3 is changed. The earnings to be made accordingly 5 is greater than in 12 and the compressor is still open work is much less, pumping is switched from 3 to 12, the compression

3. Any kind of resilient medium, even at a cost, with practically no performance - possibly even as playful, but especially for the purpose of the spring compressed gas engine - works and the outflow of the suitable medium, such as neutral gases, also vapors medium from 3 to 12 practically no resistance or steam generator, can be used, io opposed, thus no electrical power

4. when using gases and vapors and absorbs. The power requirement of such small compressors for the additional application of thermal influencers is very low. If the resilient medium differs in compression, more favorable prerequisites of 3 to 4 at and at 0.6 to 0.8 m ^s / h for the control technology can be created than with normal thermal delivery rate (on the medium sucked in by Atschen springs, 15 related to atmospheric pressure) with about Vs PS required

5. The compressor in a container, which can be calculated under the drive power.

System pressure is, completely encapsulated and against any will you want the adjustable spring to work

Leakage can be housed securely, how more economical, so you can also

this z. B. in the completely closed modern grain from in particular the containers 12 and 5 as well as the

pressors for refrigeration systems with good sealing containers 13 and the line 4 still against

results takes place, isolate heat emission, so that the compressor heat

6. the necessary regulatory bodies - z. B. rotation is retained in the system and - especially with slide - by vulcanizing the slide using media in vapor form - nor the the slide cylinders are also absolutely tight and there- fore thermal expansion of the medium for pressure release can be designed practically maintenance-free 25 maintenance or increase is exploited. (Fig. 2d). In practice - z. B. in the cushioning

The possibility of constructing such a spring in vehicles - usually several such springs - is required in Fig. 1 using an example for a driving equation. In such a case, it is not shown in sketch form. The between required that each spring has its own compressor vehicle body 1 and drive frame 2 switched ₃₀ receives. Rather, a whole system of springs spring body 3 is operated in its interior with the spring with a compressor. Fig. 3 shows the medium filled. The spring body 3 is the arrangement diagram of a four-spring system, in the case of pipelines with a large cross-section 4, possibly also the four springs 3 via four control valves 6 and with the interposition of a container 5, which participates in the spring work, the corresponding pipelines with a container, with the control element 6 ver 35 12 and a compressor 7 are connected, each connected, which knows three different positions, a differential double check valve 17 in front of each as shown in Fig. 2 schematically. Rotary valve 6 the unintentional backflow from position a is the position selected in the sketch, medium higher pressure is prevented, as well as four reverse in which the compressor 7 via the bores 8 impact valves 18 behind the compressor the same and 9 in the pipeline 4 while he is off 40 Performing the task in the opposite direction. In addition, the container 12 via the compressor container 13 with which a non-return and non-return valve 19 drives the drive motor to suck in the medium to be compressed via the higher pressure bores 10 and 11 for the free return of medium. This is the filling from the pipeline system into the container 12, the position of the spring, in which the adjusting device 14 is set during the operating state if such a higher, elongated hole is strongly compressed by the load.

ter springs the rotary valve 6 via the lever 15 according to the operation of the differential double check above has twisted. Is the spring 3 sufficient valve 17 is explained with reference to Fig. 4. That inflated, the adjusting device 14 pulls the valve allowing the passage of gas in two rich levers 15 in the horizontal position, and the rotary valve functions, even with the smallest pressure difference insert the final position shown in Fig. 2b, at 50 according to the dashed arrows from below over the the non-return valve 32 closed by the spring 31 for each connection from 12 through 7 and 6 to 5 and 3 is interrupted. At the same time, the one to the left is shown in this position (flap open). The gas power supply to the drive motor 16 of the compression passage from the left - while pushing back the age 7 interrupted. The engine stands still. Valve disk 33 expands - downwards, the course of the ausdie Spring as a result of relieving the load on vehicle 1 according to the arrows drawn further 55 (valve disk 33 in off, the adjusting device 14 pulls the lever 15 final position drawn), the valve sets a into the lower position and thus rotates the rotary slide higher, determined by the setting of the spring 34 About 6 in the position shown in Fig. 2c. At the same time, force against. The spring 34 is adjusted so that he switches the drive motor 16 of the compressor 7 so that the valve disk 33 only opens when the sub again a. The compressor 7 now promotes the 60 pressure behind the plate through the suction effect resilient medium from the spring 3 via the line 4, the compressor 7 the most minimal in the springs the bores 9 and 10 in the compressor cylinder 7 has fallen below the prevailing gas pressure. Through this and from here via the bores 11 and 8 in the loading it is ensured that it is possible to take the slightest holder 12 back until the equilibrium gas pressure required in the springs is reduced is reached again and the adjusting device 65 suck the gas to produce without being out of the 14 through the lever 15 the rotary slide 6 again flows into the reservoir 12 with new medium. Turn back the final position (see Fig. 2b). This throttling effect of the spring plate 33 in With such an arrangement, the gas flow of course also has a certain power In other constructive forms, increase in the compressor 7 result. Around can, the compressor 7 is only responsible for the 70 through the necessary lower suction pressure

To keep the required increase in output as small as possible, the valve disk 33 is connected via the rod 35 connected to the hydraulic ram 36, in which the ball check valve 37 is likely to open quickly against the spring pressure of 34 allows, however, the reclosing of the plate 33 one by the dimensions the bore 38 prescribes a certain time delay, since the closing process Ball 37 is in the final position and the oil only slowly flows in through the small bore 38 can. It is thereby achieved that the valve 33, which has been opened once by the negative pressure in the pipelines remains open for a longer period of time, during which the medium to be sucked in the compressor 7 with not throttled tank pressure in 12 can flow.

The use of such a valve is only one of the possibilities for meaningful control of the circuit in the multi-link spring systems. Of course, other solutions are also available, for example under Use of slide controls, possible. Electrical control devices are also conceivable with whose help even a control of the circuits without any source of loss, such as those caused by the temporary The throttling effect of the double check valve according to Fig. 4 can still be present, can be achieved.

The system shown here in Fig. 3 as an example works as follows: The upper right spring 3 is switched off and locked by the rotary valve 6 in the rest position. There is no charge change here and so that no pressure change takes place.

The lower right spring is switched to filling by the rotary slide valve 6. The compressor 7 sucks fresh medium out of the container via lines 20, 21, check valve 17, lines 22 and 23 12 and presses it into the spring 3 via the lines 24 and 25.

The two springs on the left are switched to deflate. The process is only based on the lower one left spring described. Here the compressor 7 sucks out of the spring body 3 via the line 26, 27 and 20 the resilient medium and presses it - provided it does not fill the right lower spring is already in use - via lines 28, check valve 17, lines 29 and 30 into the container 12. With this arrangement it can happen that a spring (as drawn, right below) is switched to filling and a spring (lower left) is switched to emptying. The compressor 7 is - there the check valves 17 open depending on the back pressure on them - initially against the Promote lower pressure in the line 28 until the rotary valve 6 (bottom left) is in the final position stands, and only then because of the pressure over the line, which has now risen rapidly in 28 24 convey further into the right lower spring according to its filling position. Are all springs in the final position switched, the power supply to the compressor 7 is also interrupted.

If a spring 3 under high pressure is suddenly connected to the line by a rotary valve 6 20 connected, it does not take the work of the compressor 7 until the pressure equalization is over Line 20 and the backflow and check valve 19 has taken place.

At the beginning it was said that the pressure level of the system should be in the middle between those occurring maximum and minimum pressures is to be set. Deviating from this, the pressure level can also be the same be chosen that it lies in the middle of the most frequently occurring stress conditions, whereby minimum power consumption of the system can be achieved.

Finally, it should be mentioned that instead of the electric compressor drive shown in Fig. 1 also a drive of the compressor by the movement of the spring itself is possible. Also, the pressure level can of the system can be arbitrarily changed by, for example, a hydraulic pump The pressure level due to the pumping in or pumping out of compressor fluid, for example into the storage container 12 he follows. The displaced gas volume is thus varied without that which participates in the spring work Volume of the spring itself is changed. That changing the pressure level by heating or cooling devices for example in the storage container 12 also without influencing the temperature in the springs itself is possible, was already mentioned.

Claims (9)

Patent claims: 1. Adjustable pressure gas spring, preferably for vehicles, characterized in that within one closed and in the rest and normal position of the spring under medium working pressure standing system between a gas-filled spring body (3) and a storage container (12) switched compressor (7) the pressure in the spring over a known manner of the spring height the spring (3) influenced control element by pumping in or pumping out resilient medium changed automatically, depending on the load. 2. Adjustable gas spring according to claim 1, characterized in that also consists of several spring bodies (3) existing spring systems fed by a storage container (12) and with only one Compressors (7) are operated, each spring (3) by its associated control element (6) can experience a pressure increase or pressure decrease as required. 3. Adjustable gas spring according to claim 1 and 2, characterized in that in per se known Wise thermal influences on the spring system, let them be connected with the functioning of the system (Compressor heat, expansion cold), be it arbitrarily by heating or cooling devices that support the load-dependent control of the system. 4. Adjustable gas spring according to claim 1 to 3, characterized in that the pressure level of the system is set according to the most frequently occurring load conditions will. 5. Adjustable gas spring according to claim 1 to 4, characterized in that the compressor (7) is arranged gas-tight housed within the pressurized spring system. 6. Adjustable gas spring according to claim 1 to 5, characterized in that the drive power of the compressor derived directly or indirectly in a manner known per se from the spring movement will. 7. Adjustable gas spring according to claim 1 to 6, characterized in that the required Control organs (6) by vulcanizing the slide or valves into the valve body within the Systems are arranged gas-tight. 8. Adjustable gas spring according to claim 1 to 7, characterized in that the resilient medium adapted to the operating conditions, composed of several gases or vapor formers, selected will. 9. Adjustable gas spring according to claim 1 to 8, characterized in that the pressure level of the System can be changed in a manner known per se by pumping in or out. of displacer fluid Considered publications: German Patent Specifications No. 897 811, 913 720, 719. 1 sheet of drawings