DE4310458C2 - vibration - Google Patents

Description

State of the art

The invention relates to a vibration damper, especially for a chassis system, according to the genus of Claim 1.

A system for adjusting the damper characteristics of a forming part of a chassis system Vibration damper is known from DE 41 12 005 A1. at the known system for adjusting the Damper characteristics of a damper, one side with a vehicle body and its other side with at least a wheel unit is directly or indirectly connected the relative movement of two relatively movable Damper parts detected and a corresponding, electrical Signal generated. This signal becomes a dependent one Derived signal value, in particular a signal which the Piston acceleration corresponds, and from the two Signals are then made using a logical Link derived a control signal, the known The overall procedure aims at adjusting the Perform damper characteristics in the operating phases, in which the damper has low damping forces is exposed. These operating phases result in generally in the area of the reversal points of the damper piston, and a switchover of the damper characteristics in these Operating phases is in terms of noise optimization Advantage, since switching the damper when there is a higher differential pressure Damper switching noises, which when switching in  At least the area of the reversal points of the damper piston can be largely avoided.

Although the known system is usually too advantageous Results have further studies shown that a further improvement of the known In any case, the method or the known damper system certain applications would be desirable.

The present invention is therefore based on the object a reliable, inexpensive Specify vibration damper and it is supposed to be suppression of switching noises can be further improved.

The task is carried out by the vibration damper solved the features of claim 1.

Advantages of the invention

An important advantage of the shock absorber is that that a fluid flow, in particular a pressure oil flow, in a flow channel very precise and on the other hand relative simply on the occurrence of zero crossings of the Flow rate can be monitored, whereby compared to the known vibration damper first of all the advantage is achieved that only a single measurand monitored and for the generation of switchover enable signals must be evaluated. It also results from the monitoring of the flow velocity of the Damper fluids versus monitoring Relative movements of the damper parts have the advantage that before a switchover in the area of the reversal points of the  Piston movement still certain pressure equalization processes can be waited for at the time of Reversal of direction of the damper piston to one Continue to flow the fluid in the previous direction, until the flow rate is actually zero has become so that the switchover really takes place only then occurs when the switch noise may occur leading differential pressure has actually become zero.

There is a particular advantage of the vibration damper further in that the devices for measuring the Flow rate of damper fluid using a single leaf spring can be realized in the Hibernate closes a monitored circuit and from the damper fluid flowing through a flow channel is deflected and thus interrupts this circuit, where a single leaf spring is sufficient, one Switching the damper characteristics in the area of both Control reversal points of the damper piston. There is also the possibility of one at either end Flow channel or at opposite openings to arrange a leaf spring for each of two flow channels, both leaf springs preferably in series in one common circuit, which so long through one or other leaf spring is broken like that Flow rate is different from zero or still is higher than a predetermined limit. At this However, design cannot be between the two Reversal points can be distinguished.

Here is regarding the preferred shock absorber to note that it is already from DE 40 19 463 A1  is known, with the help of changeover contacts on the piston a damper to detect piston movements; in the known arrangement, the switch contacts are used, however Possibility of detecting the presence of the entry stroke and the extension stroke of the piston and the control of one Valve depending on the respective operating state and not to sense a flow in one Flow channel and for the targeted introduction of Switching operations in the area of the zero crossings of the Flow velocity of the damper fluid. Besides, is in the known system, the structural design of the Changeover contacts using one on the piston seated and slidable relative to the piston Sliding part constructive for certain applications relatively complex.

drawings

Further details and advantages of the invention will be explained in more detail below with reference to drawings.

Show it:

Fig. 1 is a schematic block diagram for explanation;

Figure 2 is a schematic partial longitudinal section through a damper assembly.

Fig. 3a u. b are schematic representations of the time profile of the piston speed or the current in a circuit for generating switchover enable signals;

Fig. 4 is a schematic partial longitudinal section through a modified damper assembly; and

Fig. 5a u. b schematic representations of the time course of the piston speed or of the current in a circuit for generating switchover enable signals.

In particular, FIG. 1 shows a chassis control system 10, which voltage in the conventional manner a Dämpferanord 12 includes, for example, a shock absorber with a damper housing and a piston guided therein for sliding, which is provided with a controllable valve device 14. According to the invention, the speed of a damper fluid in a flow channel of the damper arrangement is now measured with the aid of a flow meter 16 . The output signal of the flow meter 16 is fed to a zero crossing detector 18 , which then delivers an output signal when the flow velocity becomes zero or - generally speaking - falls below a predetermined limit value. The output signal of the zero crossing detector 18 is fed to one input of a logic circuit 20 shown as an AND circuit.

The chassis control system 10 further includes devices for switching the damping characteristics of the chassis or a damper of the same. These facilities include a changeover signal generator 22 , through which sen output signals according to the prior art often directly switch the controllable valve device 14 of the damper arrangement 12 . According to the invention the output of the Umschaltsignalgenera is tors 22 but with a second input of the AND TIC connected 20 so that when there is a switching signal of the Umschaltsignalgenerators 22 only occurs a switching of the controllable valve device 14 when the other input of the AND Gate 20 from the output of the zero crossing detector 18 is simultaneously signaled the presence of zero flow velocity. The zero passage detector 18 connected to the flow meter 16 thus provides a changeover enable signal in the presence of a zero crossing of the flow velocity, by means of which the AND condition is fulfilled at the input of the AND circuit 20 , so that a changeover signal from the output of the changeover signal generator 22 is only then a changeover the controllable Ven tileinrichtung can cause when a pressure equalization is brought about via the monitored flow channel, so that the switching of the controllable valve device 14 without switching noise and with maximum protection of the valve device 14 and the other parts of the damper arrangement 12 can be carried out.

For practical implementation can be largely common and commercially available Available electrical circuits, flow meters and Valve devices are used, as z. B. - apart from the flow meter - at the beginning discussed, known systems are used. There are also numerous useful ones on the market Flow measuring devices available, their difference liche designs are at least partially without further ado for measuring the speed of fluid flow in the flow channel of a damper arrangement are suitable.

For the implementation however, a damper arrangement is preferred in which the Flow meter elements in simple, inexpensive stiger and reliable way in the damper assembly are integrated.

In detail, the damper arrangement 12 according to FIG. 2 of the drawing comprises a conventional shock absorber with a cylindrical housing or an outer tube 24 and a piston 26 slidably movable therein, which is attached to a piston rod 28 in the region of a free end 28 a, which has a reduced outside has diameter, is secured by means of a nut 30 in the axial direction. The piston 26 has two Kol ben bores 32 , the inner wall of which is each covered with an insulation layer 34 , which extends adjacent to the piston bores 32 and also over the end faces of the piston 26 . In the area of each piston bore 32 , the insulation layer 34 made of electrically non-conductive material surrounds a tube 36 made of electrically conductive material, such as. B. copper. Each tube 36 defines in the piston 26 a continuous flow channel 37 , which connects an upper working space 38 and a lower working space 40 of the shock absorber as a throttle bore and with a relative movement of the piston 26 relative to the outer tube 24 of a flow of the shock absorber located damper fluids, in particular a damper oil, in which one or the other direction is flowed through. Each tube 36 ends at the end faces of the piston 26 in alignment with the outside of the insulation layer 34 provided there or, if appropriate, also projects slightly outwards beyond the adjacent regions of the insulation layer 34 .

In the preferred exemplary embodiment shown in FIG. 2, a leaf spring 42 or 44 , which is insulated from the piston material by the insulating layer 34, is provided on each of the end faces of the piston 26 . The upper leaf spring 42 has a recess 42 a in the region of the left flow channel 32 in FIG. 2, while the lower leaf spring 44 has a corresponding recess 44 a in the region of the other flow channel. The Blattfe 42 , 44 are designed and arranged so that in their idle state, namely when the flow speed of the damper fluid in the assigned flow channel 37 is zero or almost zero, in electrically conductive contact with the respectively adjacent pipe end stand. If, however, due to a movement of the piston 26 with respect to the outer tube 24, a flow of the damper fluid through the throttle channel or the tube 36 from the working space 38 into the working space 40 or vice versa, then the radially outer end of each on the outlet side of the tube 36 located leaf spring 42 and 44 lifted from the associated end of the tube 36 , so that the electrically lei connection between the tube 36 and the relevant leaf spring 42 and 44 is interrupted.

Since the two leaf springs 42 , 44 are connected to each other in an electrically conductive manner in series in the exemplary embodiment via the conductive tube 36 , consequently, when the damper fluid flows through the tube 36 , the electrically conductive connection between two connecting lines 46 , 48 which are passed in the usual way through a bore 28 b of the piston rod 28 and connected to the radially inner ends of the leaf springs 42 and 44 , interrupted. An interruption of the electrically conductive connection between the connecting lines 46 , 48 consequently signals the lifting of one or the other Blattfe 42 or 44 from the associated end of the electrically conductive tube 36 and thus a non-zero flow rate of the damper fluid in the relevant, throttle or flow channel 37 defined by the tube 36 . On the other hand, the existence of an electrically conductive connection between the connecting lines 46 , 48 indicates that both leaf springs 42 , 44 each lie on the associated pipe end in a conductive manner, which means that the velocity of the flow of the damper fluid through the pipe 36 is zero or, at a certain preload of the leaf springs 42 , 44 against the associated tube ends has reached a predetermined, lower threshold value.

From the above description of the exemplary embodiment according to FIG. 2 it is clear that with the aid of the simple leaf spring arrangement described on the piston ben 26 of the shock absorber, not only is it indicated whether a flow of the damper fluid through one of the flow channels 37 is present, but at the same time, whether a zero crossing of the flow velocity is present, so that the leaf spring assembly shown in Fig. 2 at the same time the flow meter 16 and the Nulldurchgangsde Tektor 18 of the chassis control system 10 of FIG. 1 forms, wherein the tapped off at the connecting lines 46, 48 signal "stream" or "No current" can be applied directly to one input of the AND circuit 20 , the second input of which is connected to the output of the changeover signal generator 22 . A prerequisite for the operation of the damper assembly of FIG. 2 in the above-be written such that the piston rod 28 made of a non conducting material or, as indicated in the drawing voltage is' compared with the leaf springs 42, 44 insulated by insulation layers 34 and that you also work with a non-conductive damper fluid.

As shown in FIGS . 3a and 3b, in the exemplary embodiment from FIG. 2 with a temporal course of the piston speed v according to FIG. 3a, movement in the area of the upper and lower dead center of the piston each have short gate pulses T, as shown in FIG is shown Fig. 3b in which the leaf springs 42, shows the waveform of the current i 44 containing circuit. In the method according to the invention, the gate pulses T serve as switchover enable signals and ensure this - cf. the AND circuit in the arrangement of FIG. 1 - that changeover signals for an adjustment of the damper characteristic can only be effective when the damper is subjected to low damping forces, which ideally go to zero, the appropriate switching times according to the invention through a special monitoring of the flow of the damper fluid can be determined in at least one flow channel.

From Fig. 3b it is also clear that when using a damper arrangement according to FIG. 2, regardless of the direction in which a zero crossing of the piston speed v is passed, a positive gate pulse T is always obtained, so that it is in accordance with the damper arrangement Fig. 2 is not possible to take into account when releasing a switchover whether the piston is just in the area of its top dead center or in the area of its bottom dead center.

According to Fig. 4 of the drawings of the invention is therefore staltung in further Substituted gen a damper assembly provided schla which allows to generate point thereof different or distinguishable Umschaltfreigabesignale upon reaching the top dead point of the piston, and upon reaching the lower dead, as further will be explained below with reference to the schematic representation of the time course of the current in the damper arrangement according to FIG. 4 in conjunction with FIG. 5 of the drawing.

In detail, the damper assembly has in Fig. 4 only one, with a flow channel 37 cooperating leaf spring 42, wherein the flow channel 37, as in the embodiment according to FIG. 2, again from an insulated relative to the piston 26, electrically conductive tube is formed , Furthermore, the piston 26 is additionally provided with at least one further throttle opening or a channel 50 connecting the two working spaces 38 , 40 . This ensures that a connection between the upper working space 38 and the lower working space 40 is maintained when the piston 26 for the damper fluid moves upward when the leaf spring 42 closes the flow channel 37 .

As 5a and 5b, it is clear from the diagrams shown in Fig., The leaf spring 42 is lifted by the flow of the damping fluid in the flow channel 37 during the downward movement of the piston 26 from the conductive pipe 36 so that the circuit between the leads 46, 48, which contains the leaf spring 42 and the conductive tube 36 in the embodiment example according to FIG. 4, is interrupted. If the fluid flow through the flow channel 37 is then approximately in the region of the bottom dead center of the piston to zero or a lower limit is reached, which is determined by the geometry of the arrangement and the elasticity of the leaf spring 42 , then the above-mentioned circuit is closed , wherein the current i jumps from zero to a predetermined value i _o in the region of a positive edge of the signal according to FIG. 5b. The circuit between the connecting lines 46 , 48 remains closed during a subsequent upward movement of the piston 26 , since the leaf spring 42 is pressed firmly against the upper end of the tube 36 by the increased pressure in the upper working space 38 . However, when the piston 26 begins a downward movement again, the leaf spring 42 is lifted from the tube 36 by the fluid flow in the flow channel 37 and the circuit is interrupted, the current being in the region of a negative switching edge of the signal according to FIG predetermined value i _o jumps to the value zero. In the exemplary embodiment according to FIG. 4, there is the possibility of distinguishing between reaching the bottom dead center of the piston movement and reaching top dead center of the piston movement, since the current profile in the first case has a positive edge or a jump from zero to i _o and in the second case shows a negative edge, ie a jump from i _o to zero. This direction of the current change in the monitored th circuit can easily be determined by means of a suitable, known circuit arrangement and can be evaluated in such a way that certain Umschaltvor processes are only permitted when top dead center and other switching operations are only allowed when bottom dead center is reached. It goes without saying that the circuit outlined in FIG. 1 for distinguishing between these two possibilities must be supplemented accordingly.

While it was assumed above specifically in connection with the exemplary embodiment according to FIG. 4 that the leaf spring completely closes the flow channel 37 during an upward movement of the piston 26 , in an embodiment of the invention there is also the possibility of making the leaf spring 42 so thin and narrow trainees that it affects the free cross section of the flow channel 37 depending on whether it is deflected or abuts the tube 36 , only marginally. In this case, a separate flow channel 50 can of course be dispensed with. With a corresponding design of the two leaf springs 42 , 44 in the exemplary embodiment according to FIG. 2, there is then also the possibility of arranging both leaf springs at the opposite ends of the same flow channel 37 . On the other hand, it must be ensured in all embodiments that the forces acting in the circumferential direction of the piston 26 are distributed as evenly as possible, so that from this aspect, even with the use of narrow leaf springs, it can be useful and recommendable to have several flow channels symmetrical about the circumference of the piston distribute, regardless of whether leaf springs are provided at one end or at both ends of the flow channels in question, since in this way a tendency of the piston 26 to tilt can be counteracted ent.

Claims (6)

1.Vibration damper with two mutually movable damper parts and with at least one flow channel which is flowed through by a flow of a damper fluid at least when there is a relative movement of the damper parts, in which an adjustment of the damping characteristic as a function of a signaling the presence of low damping forces Switchover enable signal, characterized in that a flow measuring device ( 16 , 18 ) is assigned to the flow channel ( 37 ), by means of which the switchover enable signal is generated when the flow velocity falls below a predetermined limit. 2. Vibration damper according to claim 1, characterized characterized that depending on the direction of the Relative movement of the damper parts one out of two distinguishable switching enable signals is generated. 3. Vibration damper according to claim 1 or 2, characterized in that the flow measuring device ( 16 , 18 ) comprises at least one leaf spring ( 42 ; 44 ) made of electrically conductive material which is clamped on one side and can be acted upon and deflected by the fluid flow in the region of the flow channel ( 37 ), which is part of a control circuit ( 46 , 42 , 36 , 44 , 48 ) which can be actuated by deflecting the leaf spring from its rest position to generate the switchover release signal. 4. Vibration damper according to one of claims 1 to 3, characterized in that two continuous throttle openings each forming a flow channel are provided and that the one end of the one flow channel ( 37 ) on the one end face of the piston ( 26 ) a first through a flow of the damper fluid deflectable leaf spring ( 42 ) is assigned that the opposite opening of the other flow channel ( 37 ) on the other side of the piston ( 26 ) is assigned a second leaf spring ( 44 ) and that the two leaf springs ( 42 ; 44 ) are electrically conductive Walls ( 36 ) of their associated flow channels ( 37 ) between connecting lines ( 46 ; 48 ) of the control circuit ( 46 , 42 , 36 , 44 , 48 ) are electrically connected in series. 5. Vibration damper according to one of claims 1 to 4, characterized in that at both ends of the flow channel ( 37 ) a deflectable by a flow of the damper fluid leaf spring ( 42 ; 44 ) is arranged and that the leaf springs ( 42 ; 44 ) by a electrically conductive wall ( 36 ) of the flow channel ( 37 ) can be connected to one another in an electrically conductive manner. 6. Vibration damper according to claim 4 or 5, characterized in that the conductive wall of each flow channel ( 37 ) is formed by a conductive tube ( 36 ) inserted into a piston bore and insulated from the piston ( 26 ).