DE3418262A1 - HYDRAULIC, ADJUSTABLE SHOCK ABSORBER - Google Patents

Description

PRP 456 *: *** -:. ". Γ" '. ".: May 11, 1984

Hydraulic, adjustable shock absorber

The invention relates to a hydraulic, controllable Shock absorber with a damping piston attached to a piston rod, which divides the working cylinder in two with damping · divided liquid-filled working spaces and having at least one throttle element and that the working cylinder together with a jacket tube forms a compensation space, which with the working cylinder via at least one Flow connection is connected and a parallel to the throttle body effective bypass valve is provided which connects the upper working space with the compensation space via a bypass.

Shock absorbers are already known (e.g. DE-OS 32 31 739) in which the damping force is generated by a bypass connection can be changed by arranging the bypass valve on the cylinder or on the piston rod guide. Such a thing Bypass valve regulates the change in cross-section of the bypass depending on the pressure or electromagnetically. Such a one Embodiment has the disadvantage that it is only applicable to shock absorbers without an additional Coil spring. For reasons of space, if a pressure connection or a control valve is used outside the jacket pipe such a design is no longer applicable. This applies to suspension struts, for example Coil spring, shock absorber with coil spring and cartridges for use in struts too. Besides, there is such a thing

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Execution for shock absorbers where an additional Protective tube is required, also not applicable. However, since the bypass valve is in the area of the piston rod guide is provided and this is mostly above the spring plate and thus within the coil spring, such solutions can only be used to a limited extent.

In addition, shock absorbers are known (e.g. DE-OS 29 11 768) in which the control of a bypass valve is arranged within a hollow piston rod. A coil is provided in the upper part of the piston rod, within which an armature moves axially. Acts with the bypass bores in the piston rod the electromagnetically actuated spool together. The disadvantage of these designs is the one required high construction costs for the connecting lines, fittings, the Membrane and its attachment, usually also have to Valve systems other than the series are used and a long pull rod is inserted in the hollow piston rod necessary. The arrangement of the controllable bypass valve machining measures required in the piston rod cause a weakening of this piston rod, so that only under special precautions wheel guidance forces can be included. In addition, the axial dimensions of the damper typically increase when placed of the bypass valve in the piston rod.

Proceeding from this, it is the object of the invention to change the damping force in a shock absorber by means of a To achieve bypass connection, wherein a construction is created that is both a vibration damper and a wheel-guiding strut as well as a strut cartridge can be used and wherein the bypass valve As a standard part, it not only guarantees inexpensive storage, but also with a built-in unit can be replaced or when replacing a defective vibration damper in the newly installed damper

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can be used without mounting or remodeling problems to be considered.

To solve this problem, the invention provides that as a bypass a channel opens from the upper working chamber in the area of the bottom of the shock absorber into the compensation chamber and that a control slide of the bypass valve arranged in the area of the floor acts on the channel.

In this embodiment it is advantageous that the bypass valve is arranged in the lower area of the shock absorber, so that taking into account the tight installation space an unproblematic solution is possible. It is so in Area of the coil spring or the spring plate none constructive restriction necessary, so that the solution proposed here both with a shock absorber with Helical spring, a wheel-guiding spring strut and also provided for a cartridge for exchange in a spring strut can be. It must also be taken into account that there is no weakening of the piston rod guide complex with wheel-guiding spring struts is to be considered.

According to a further essential feature it is provided that the channel as a tubular connection through the compensation space The already existing compensation space of a vibration damper runs through it used to ensure that either a flexible or a fixed pipe connection from the upper part of the vibration damper, namely, the upper working space is guided into the lower area of the shock absorber. In the bottom of the vibration damper this pipe connection is then passed into a flow connection which acts on the bypass valve.

In a further essential feature it is provided that the channel is arranged coaxially outside the working cylinder is. In such an embodiment, the rotationally symmetrical shape of a shock absorber can be used by making the channel circular in cross section

PRP 456 τ 7. · - *: j "*. '. **.:.:. 11.5.1984

is formed in the form of a large volume exchange to ensure. It is provided according to a special embodiment that the channel through a jacket tube surrounding pipe is formed and connected to the compensation chamber via a bore provided in the jacket pipe is. This embodiment is possible with a twin-tube vibration damper With an additional third pipe, a channel can be arranged without any problems.

In order to achieve great variability, simple storage and the use of unit parts, an essential feature provides that the bypass valve is screwed to the shock absorber. Here, similar bypass valve ^e can be used to ensure a same bore a Bypaßregelung. In such an exemplary embodiment, a corresponding cross-sectional area of the bypass is merely assigned to the shock absorber or suspension strut type. If a strut cartridge is used, the bypass valve can be unscrewed from the outside so that the inner parts of the strut can then be removed and, after inserting a corresponding cartridge and then screwing in the bypass valve, the strut is functional again.

To take advantage of options that are favorable in terms of manufacturing technology with regard to the design of the bypass channel and the arrangement of the bypass valve, a particularly favorable one Embodiment that the bypass valve is screwed into the floor approximately at right angles to the central axis of the shock absorber is.

According to a further essential feature it is provided that at least two bypass valves are circumferentially distributed are. In the case of a bypass duct with a large cross-section and the arrangement of several bypass valves, a regulation is required

PRP 456 - * e-r. ".: -. · - .: 11.5.1984

a large flow rate possible without any problems. DaD (Ti ^ "^ the arrangement of two or three valves at a distance of 120 ° or even more, depending on the space available than three valves be possible.

A favorable embodiment provides that when using of several bypass valves a corresponding number of channels is available. In this embodiment there is the possibility of each bypass valve to arrange separate channel accordingly.

In the event that a twin-tube shock absorber with a additional pipe is provided, starting from the coaxially arranged channel, several individual channels open in the compensation room. The individual channels each acted upon by a bypass valve.

According to a preferred embodiment it is provided that the bypass valve consists of an electromagnet and a Anchor exists. According to the modular principle, it is easily possible that when the functions are separated of the bypass valve and the regulation of the bypass channel of the armature of the electromagnet an axially movable control slide applied. In this case the control slide is part of the shock absorber and on the corresponding one Cross-section of the channel adapted and the electromagnet together with the control slide as a unit Can be used in different versions of shock absorbers in the same design.

When using an appropriately designed stepped bore and one-sided axial movement of the armature during the activation time of the electromagnet, it is provided that the control slide works together with a return spring. The task of the return spring is to to keep the bypass constantly open in the event that the

PRP 456 «δ"!.: ** :: "". · "- :. May 11, 1984

Electromagnet is not switched on. When the Magnet, the bypass is closed, so that after switching off the magnet, the spring, the axial displacement of both the Control slide as well as the armature of the electromagnet takes over. Preferred embodiments according to the invention are shown schematically in the drawing.

It shows:

Figure 1 shows the lower area of a vibration damper in section

FIG. 2 shows a section of the vibration damper shown in FIG

Figure 3 shows a standard shock absorber in section, which has no wheel guidance properties

FIG. 4 shows a shock absorber in principle as already shown in FIG. 3, but as a wheel-guiding spring strut educated

Figure 5 shows a shock absorber in principle as shown in Figure 4, however, the actual shock absorber is available as a strut cartridge for subsequent replacement educated

FIG. 6 shows an embodiment in principle as in FIG. 1 shown, but with several bypass valves

Figure 7 shows the embodiment shown in Figure 6 in cut

FIGS. 8 and 9 show an embodiment in principle as in FIG

FIG. 6, however, the channels opening into the compensation space are different large diameter

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FIG. 1o shows a further embodiment of the one shown in FIG Shock absorber with the difference that a coaxially arranged, designed as an annular channel Bypass channel is provided

The hydraulic vibration damper shown in FIG essentially shows the working cylinder 3, the piston rod 1, at the end of which the damping piston 2 is attached. The damping piston 2 divides the interior of the working cylinder 3 in the upper working space 4 and the lower working space 5. The damping piston 2 has throttle organs 6, which serve to dampen vibrations. Fastening devices are used to fasten the vibration damper in the vehicle provided above and below 22. The displaced volume of the plunging piston rod 1 in the working cylinder 3 is passed into the compensation chamber 9 via the bottom valve 7. The compensation space 9 is through the working cylinder 3 and the jacket tube 8 is formed.

A tubular connection runs in the compensation space 9 14 to channel 11, this channel 11 being acted upon by a bypass valve 1o and depending on the position of the armature

20 and thus a bypass corresponding to the control slide 13 from the upper working space 4 via the pipe 14 and the channel 11 to the compensation space 9 releases or closes.

The bypass valve 1o consists of the electromagnet 19 with an integrated coil and a magnet armature 2o, both via a screw connection 23 in the bottom 12 of the shock absorber are arranged. The bypass valve 1o is arranged approximately at right angles to the central axis 17 of the shock absorber. The spool 13 is controlled by the return spring

21 is applied, which constantly generates a force in the direction of the open position of the channel 11. Above the O-ring 24

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and the pressed-in ball 25 is sealed off the channel 11 from the atmosphere. The connecting line 26 is used for the electrical supply of the electromagnet 19.

When using a corresponding base 12, the jacket tube is on a projection by the form-fitting Connection 27 fastened and correspondingly sealed via the seal 28.

Figure 2 shows a section in the area of the bottom 12 of the vibration damper shown in Figure 1, wherein the attachment 22 can be seen and the working cylinder 3 together with the jacket tube 8 create the compensation space 9, in which the tubular connection 14 is provided as a supply line to the KanaT ^. The electromagnet 19 is approximately Arranged at right angles to the central axis 17 of the shock absorber. The interlocking connections 27 consist of about the Partial indented areas distributed around the circumference.

FIG. 3 shows a standard shock absorber in principle as shown in FIG. 1, but which does not have any wheel guidance properties has to take up in practical operation. It consists of the piston rod 1, the damping piston 2, the Working cylinder 3 and the jacket tube 8 and the lower attachment 22 and the upper attachment 29. From the upper working space 4 leads out the tubular connection 14 into the channel 11, past the control slide 13 into the Compensation chamber 9. The electromagnet 19 controls this bypass connection.

4 shows a radführendes strut is shown in contrast to the shock absorber in Figure 3, a tab 3o is additionally provided in which the z \ ir fastening an axle

PRP 456 * 15? -:: "": ":" V ·: · 11.5.1984

gift ice is used. The jacket tube 8 is connected in the upper area to the lower spring plate 31, wherein this lower spring plate 31 to support a helical spring serves. Such wheel-guiding struts are usually part of a McPherson wheel suspension. These Embodiment clearly shows that a replaceable bypass valve 10 can not be arranged in the upper area can. In addition, a tubular connection 14 from the upper working space 4 is also in this embodiment the channel 11 to the compensation chamber 9 is available. The control slide 13 is separated from the armature 2o of the electromagnet 19 and acted upon by a return spring 21 via the stepped bore 32. The connecting bolt 33 is required for fastening the shock absorber on the body side.

FIG. 5 again shows a wheel-guiding spring strut in which an outer tube 34 is provided with a screw cap 35 is so that the interior can accommodate a retrofit cartridge. This retrofit cartridge is a complete shock absorber consisting of the piston rod 1, the damping piston 2, the working cylinder 3 and the Casing tube 8. These parts together with the casing tube ■ can be replaced when worn, so that the outer tube 34, the lower spring plate 31 and the tab 3o and the steering knuckle attached to it can remain in the vehicle. This exchange takes place in that the bypass valve 1o is unscrewed, so that the axial freedom of movement is then the retrofit cartridge is given. Otherwise the principle is comparable to that in FIG. So it can be defective Vibration damper the electromagnet with bobbin, Armature 2o and the connecting line 26 continue remain in the vehicle.

The embodiment of a bypass control shown in FIGS. 6 and 7 relates to an embodiment with a large volume exchange and variable control through three bypass valves 1o. These bypass valves 1o are at an angle of 12o ° in the bottom 12 of the Arranged vibration damper and control the volume of the

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Liquid flowing through the tubular connection and flow through the channel 11 into the compensation chamber 9. The acute angles of the individual control slides 13 are each 12o °, so that when all three electromagnets 19 are switched on, the bypass is closed and depending on the parallel activation a single or two electromagnets the channel 11 is only partially released. Through the parallel control of each individual bypass valve 1o you get a quick response and a great variability of the entire system.

In the case of the channel 11 shown in FIGS. 8 and 9, the volume equalization from the upper working chamber 4 to the equalizing chamber 9 in the mouth area is regulated by individual channels 36, each of which is acted upon by an electromagnet 19. These individual channels 36 can have the same diameter have or different as shown in Figure 9 have large diameters, so that with different Controlling the electromagnet 19 a large number of flow cross-sections can be achieved. The accordingly The flow cross-section to be cleared can be adapted to the respective Adjust and regulate driving operations. However, such electronics is not necessarily a prerequisite for the function of the actual shock absorber.

A two-tube shock absorber is shown in FIG. 1o as a further alternative shown with an additional tube 15, which together with the jacket tube 8, the tubular Forms connection 14, but in the form of a large volume arranged coaxially around the working cylinder 3 Bypass. The damping agent flows from the upper working chamber 4 via the transverse bore 37 into the annular one Connection 14 and from there via the bore 16 through the jacket tube 8 into the compensation chamber 9. The channel 11 of the

PRP 456 ^v : - WK-: :: .., - .. · :. May 11, 1984

Figures 1 to 9 are to be equated with the bore 16. This embodiment also shows a control slide 13, which is not connected to the armature 2o of the electromagnet 19 connected is.

PRP 456 \ \ $ - '- ■ : * "." - "V" May 11, 1984

Reference symbol! Iste

1 - Piston rod Single channels 2 - Damping piston Cross hole 3 - Working cylinder 4 - upper work space 5 - lower work space 6 - Throttle organ 7 - Bottom valve 8th - Jacket pipe 9 - Compensation space 1o - ■ bypass valve 11 - channel 12 - floor 13 - Control spool 14 - tubular connection (channel) 15 - pipe 16 - Hole in the jacket pipe 17 - Center axis 18 - Single channels 19 - Electromagnet 2o - anchor 21 - Return spring 22 - Attachment 23 - Screw connection 24 - O-ring 25 - Bullet 26 - Connecting cable 27 - positive-locking connection 28 - poetry 29 - upper attachment 3o - Tab 31 - lower spring plate 32 - Stepped bore 33 - Connecting bolt 34 - Outer tube 35 - Screw cap 36 - 37 -

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Claims (12)

BÖGE GmbH · -; ϊ ::] "': *:':: - * 1 * May 1, 1984 Bogestrasse 5ο ** 1PRP 456 St / do 52ο8 Eitorf 318262 patent claims 1. Hydraulic, adjustable shock absorber with one on one Piston rod-attached damping piston, which divides the working cylinder into two working spaces filled with damping fluid and has at least one throttle element and that the working cylinder together with a jacket tube forms a compensation space, which with the working cylinder is connected via at least one flow connection and an effective parallel to the throttle element A bypass valve is provided, which connects the upper working chamber with the equalization chamber via a bypass, characterized, . that as a bypass a channel (11) from the upper working chamber ^v in the area of the bottom (12) of the shock absorber opens into the compensation chamber (9) and that a control slide (13) of the bypass valve (1o) arranged in the area of the bottom (12) the channel (11) applied. 2. Shock absorber according to claim 1,
characterized, that the channel (11) as a tubular connection (14) through the compensation space (9) runs therethrough. PRP 456: -: "2 -::::: · *: ■ May 11, 1984 3. Shock absorber according to claim 1, characterized in that the channel (11) is coaxial outside the working cylinder (3) is arranged. 4. Shock absorber according to claim 3, characterized in that that the channel (11) is formed by a tube (15) surrounding the jacket tube (8) and via an im Jacket tube (8) provided bore (16) is connected to the compensation chamber (9). 5. Shock absorber according to claim 1, characterized in that the bypass valve (1o) is screwed to the shock absorber is. 6. Shock absorber according to claim 1, characterized in that the bypass valve (1o) in the bottom (12) approximately at right angles is screwed in to the central axis (17) of the shock absorber. 7. Shock absorber according to claim 1, characterized in that that circumferentially distributed at least two bypass valves (1o) are arranged. 8. Shock absorber according to claim 1, characterized in that when using several bypass valves (1o) a corresponding number of channels (11) is provided. PRP 456 * T'-. : **: ■ · ;; *. '"' I. May 11, 1984 9. Shock absorber according to claim 3, 3418262 characterized in that starting from the coaxially arranged channel (11) Several individual channels (18) open into the compensation space (9) and the individual channels (18) each through a Bypass valve (1o) are acted upon. 10. Shock absorber according to claim 1, characterized in that that the bypass valve (1o) consists of an electromagnet (19) and an armature (2o). 11. Shock absorber according to claim 1o, characterized in that the armature (2o) of the electromagnet (19) has one axially movable control slide (13) acted upon. 12. Shock absorber according to claim 11, characterized in that the control slide (13) with a return spring (21) cooperates.