DE4134354A1 - Vibration damper for IC engine belt tensioning device - uses electro-rheological fluid supplied with variable field to alter viscosity characteristic - Google Patents

Abstract

The vibration damper uses the physical characteristics of an electro-rheological fluid, exhibiting a viscosity which is varied in dependence on the applied electrical field and contained in a sealed housing (10) together with a movable damping element (15). The electrical field is provided by a pair of electrodes (15, 16) coupled to a voltage source (19) which is controlled in dependence on the movement of the damping element (15), which acts as a flow resistance within the electrical field. Pref. the damping element (15) acts as one of the electrical field electrodes (15, 16) the other electrode (16) provided by a disc segment attached to the damper housing (10). USE - Integration in engine drive belt tensioning device.

Description

The invention relates to a vibration damper, in particular for Clamping devices for traction devices in internal combustion engines, consisting of one sealed to the environment with electrorheological fluid filled housing, one movably arranged therein, with a Vibrator coupled damping element, which is arranged is that there is a flow of electrorheological rivers when moving elicits one, and one with one depending on the evidence gop state of the damping element regulated voltage source pelten pair of electrodes to generate a viscosity of the elec trorheological fluid controlling electric field.

In DE-OS 34 33 797 a vibration damper is disclosed, which as Motor bearings can be used. This vibration damper is made from a housing designed to be deformable by means of flexible membranes, on which the motor rests on the one hand and that on the other hand on a Support structure is attached. The housing is complete on the outside sealed and at a right angle to the direction of loading orderly wall in two filled with electrorheological fluid Chambers divided. Both chambers are through one passage other hydraulically connected. There is a pair of electrodes in this passage arranged that with a depending on the engine vibration controlled voltage source is coupled. Depending on the Voltage on this pair of electrodes creates an electric field which is the viscosity of the electrorheological fluid in the passage influenced. During operation, the housing is unilaterally ver forms so that liquid from a chamber through the passage into the other chamber is displaced. Becomes a tension during this phase  applied to the pair of electrodes, the viscosity of the liquid decreases abruptly. Energy is then destroyed in the liquid, hence the movement of the motor is damped. The passage with the In this arrangement, the pair of electrodes acts like a controllable valve.

Such engine mounts are quite suitable, highly sensitive to Schwin responses and dampen them. Its area of application is due to the basic structure with flexible membranes limited. The membrane materials known today react namely very sensitive to unfavorable temperatures and chemical environment influences: You then tend to premature aging and embrittlement. Furthermore, the use of such vibration dampers is likely to be small Vibration frequencies and relatively large vibration amplitudes are limited be, because the membranes used usually a high inherent possess skill.

In DE-OS 37 09 447 a shock absorber is disclosed, which according to one similar "displacement principle" works. This version is in a hollow cylindrical housing with a piston rod with the Vibration exciter coupled piston guided longitudinally. The Housing is sealed to the outside, so that the piston in the interior divided into two chambers filled with electrorheological fluid. Both chambers are by a valve-like arranged in the piston Passage, which is connected to an external voltage source NEN electrode pair is provided, hydraulically connected. With diff Exercise of the piston through this passage is liquid from a Chamber displaced into the other. A corresponding circuit of the Pair of electrodes with the resulting change in viscosity Electrorheological fluid then leads to damping of the piston movement.

This type of shock absorber is also usually required a volume-compensating element, the z. B. as one by one Membrane of gas separated from the liquid in one of the rivers liquid chambers can be formed. The use of such volume balancing elements as well as the basic structure after the  "Displacement principle" suggests that such a shock absorber for high-frequency vibrations, such as those used in transmissions NEN occur on internal combustion engines in motor vehicles, not ge is suitable.

The object of the invention is to create a vibration damper fen, which is suitable for damping high-frequency vibrations and at thermally and chemically unfavorable environmental conditions can be.

This object is achieved in that the damping element in the housing is dragged freely, so that only form and friction resistance in the liquid are effective and that the damping element at least partly in the area of the electri generated by the pair of electrodes the field is arranged.

This arrangement ensures that apart from the formbe due displacement of the damping element within the housing there is no displacement of liquid. Freely towed means in this context that the damping element so from the liquid is surrounded that gap effects, displacement currents or the like caused by the movement of the damping element in the housing, not may occur. In such an arrangement according to the invention in the housing Neten damping element consequently finds no displacement of the liquid speed in the sense of conventional vibration dampers instead, so that a volume compensation is not necessary. Any changes to the specific Volume of the electrorheological fluid by temperature Rivers are usually very low and can be done by simple measures that are based on the overall damping behavior of the Vibration damper have no influence.

The actual damping is achieved in that the damping element at least partially in the area of the electrode pair generated electric field are arranged. When increasing the toughness The friction of the electrorheological fluid then decreases resistance of the damping element in the area of electrical  Field liquid located there, so that there the kinetic energy destroyed and the movement of the damping element is damped.

An ideal embodiment of the invention therefore provides that the damper element as symmetrical, completely in the electrorheological Liquid immersed disc is formed by the Vibration exciter for a rotating or swiveling movement around its longitudinal axis is excited. With this arrangement, the damping is displaced element no liquid, as its in the liquid volume does not change during the entire operating time. The The total volume in the housing therefore remains constant. That through that Electrical field generated pair of electrodes is conveniently parallel aligned with the axis of rotation of the damping element. Advantageously is the damping element itself as opposed to the shaft and the housing insulated electrode, which has at least a second, Electrode fixed to the housing, arranged parallel and at an axial distance faces. Damping from friction is increased when on electrodes arranged on both axial sides of the damping element are.

Another embodiment of the invention is that both the damping element designed as an electrode and the electrode not as a complete disc, but as disc segments are. Damping element and electrode are then arranged so that do not completely cover their surfaces in the axial direction. By this structure, similar to a variable capacitor, can be used for capacitance Changes between the damping element and the associated elec trode detected when twisted and to control the electrodes applied voltage can be used.

In an alternative embodiment of the invention, the damping element ment executed as a cylindrical or hollow cylindrical drum, the also from the vibration exciter to a rotating or swiveling one Movement. The damping element in turn forms itself one of the electrodes, the other electrode is through a coaxial arranged hollow cylinder formed, between the outer jacket  surface of the damping element and inner surface of the electrode electric field builds up.

A further embodiment variant is designed in a similar manner, in which the damping element is piston-like and in one hollow cylindrical housing is guided longitudinally. The outside outer surface of the piston and the inner surface of the housing or a hollow cylindrical electrode arranged there form that Pair of electrodes. In order to prevent liquid displacement with this type of construction prevent, the piston is at both axial ends with piston rods provided, which each protrude from the housing. Through this sym The metric structure also changes when the piston moves Damping element, i.e. pistons and piston rods, displaced liquid volume in the housing. To continue possibly resistances The gap between pistons must be excluded by gap effects outer surface and housing inner surface selected so that there no gap flow can occur. To reduce form resistance level of the piston in the liquid are axial through holes intended.

The invention is based on a few exemplary embodiments explained. Show it:

Fig. 1 a longitudinal section of a clamping device for pulling means with an integrated shock absorber,

Fig. 2 shows a cross section along line II-II through the tensioning device in Fig. 1 and

Fig. 3 shows a longitudinal section through a further vibration damper.

Fig. 1 shows a tensioning device 1 for traction means such as belts, chains or the like in internal combustion engines with an integrated vibration damper 2nd The tensioning device consists of a tensioning element 3 , which is pre-tensioned by a spring 4 in the sense of increasing the tension of the train, here a belt 5 . In this embodiment, the tensioning element 3 is designed as a tensioning arm 6 , at one end of which a roller 7 is rotatably arranged and which lies on a belt 5 with its outer circumference. The tension arm 6 is connected at the other end to a shaft 8 which is rotatably mounted in a housing 10 by means of the bearings 9 . In the housing 10 , the spring 4 designed as a spiral spring is arranged and supported so that the tensioning arm is pre-tensioned accordingly. The housing 10 is essentially hollow cylindrical and at its axial ends by a bottom 11 or a cover 12 ver closed and tet by the seals 8 surrounding the shaft 13 tet. The interior of the housing 10 is completely filled with electrorheological fluid. With the shaft 8 rotatably connected and arranged at right angles to the shaft axis, two damping elements 15 are arranged at an axial distance from one another. Between the Dämpfungsele elements 15 and parallel to this, the housing-fixed, also formed as a disc electrode 16 is provided. The electrode 16 is electrically insulated from the housing by the insulation 17 . The damping elements 15 themselves are electrically conductive and are used directly as an electrode. The damping elements 15 and the electrode 16 are electrically connected to the voltage source 19 . The applied voltage is regulated depending on the movement of the clamping element 3 via the controller 20 shown as a black box.

FIG. 2 shows a cross section of the tensioning device according to FIG. 1 in accordance with the arrows II entered there. It can be seen that the damping element 15 is ausgebil det as a segment-shaped disc, which in the axial direction partially covers the electrode 16 also formed as a segment-shaped disc. The damping elements 15 and the electrode 16 are arranged in a circuit and form a capacitor, the capacitance of which depends on their coverage in the axial direction. When the damping elements 15 are rotated, the change in capacitance of this capacitor can be detected. This change in capacitance is a measure of the movement of the clamping element 3 and can consequently be processed by means of the controller 20 for regulating the voltage source 19 , or the voltage applied to the electrodes.

The controller works in this tensioning device 1 so that in the operating phases in which the tension in the belt 5 is increased by the drive, an electric field between the damping elements 15 and the electrode 16 builds up, so that the electrorheological fluid there is their Toughness suddenly increased, with the result that the frictional resistance of the damping elements 15 in the liquid increases. The movement of the tensioning arm 6 generated by the increase in tension of the belt 5 is thus damped. In the opposite case, with tension locking in the belt, the voltage source 19 is switched off, the field between the electrodes is reduced, the friction of the damping elements 15 in the electrorheological fluid is reduced and the tensioning arm 6 can be adjusted via the spring 4 without damping the belt .

Fig. 3 shows a longitudinal section of another embodiment of a vibration damper. 2 In a hollow cylindrical housing 21 , which is closed at both axial ends by a bottom 22 or a cover plate 23 , a damping element 24 , which is connected to a piston rod 25 penetrating the housing 21 , is longitudinally displaceably guided. The leadership takes place via the bearing 26 of the piston rod 25 . The damping element 24 is designed as an electrode, a second hollow cylindrical electrode 27 is arranged on the inner circumferential surface 28 of the housing 21 . The damping element 24 and the electrode 27 are connected to a voltage source 29 which is controlled as a function of the movement of the damping element 24 . When a voltage is applied to the electrodes, an electrical field arises between the outer circumference of the damping element 24 and the inner circumference of the electrode 28 . Since the interior of the housing is completely filled with electrorheological fluid, the toughness of the electrorheological fluid in the region of the electrodes then increases. The frictional resistance of the damping element 25 increases and its movement is damped. In order to reduce the dimensional resistance of the damping element 24 , axial through bores 30 are provided in it.

It should be noted that the statements shown are single  are examples with which by no means all of the invention Variants are recorded.

List of reference numbers

1 tensioning device
2 vibration dampers
3 clamping element
4 spring
5 straps
6 tension arm
7 roll
8 wave
9 bearings
10 housing
11 floor
12 lids
13 seal
14 interior
15 damping element
16 electrode
17 insulation
18 circlip
19 voltage source
20 control
21 housing
22 bottom
23 cover plate
24 damping element
25 piston rod
26 bearings
27 hollow cylindrical electrode
28 inner surface
29 voltage source
30 through hole

Claims (8)

1. Vibration damper, in particular for tensioning devices ( 1 ) for traction means ( 5 ) in internal combustion engines, consisting of a housing ( 10 , 21 ) filled with electrorheological fluid and sealed from the environment, a damping element ( 15 , 24 ) movably arranged therein and coupled to a vibration exciter ), which is arranged so that it causes a flow of electrorheological fluid when moving, and with a voltage source ( 19 , 29 ) coupled with a voltage source ( 19 , 29 ) which is regulated as a function of the movement state of the damping element ( 15 , 24 ), coupled electrode pair ( 15 , 16 , 24 , 27 ) for the generation of an electric field which controls the viscosity of the electrorheological fluid, characterized in that the damping element ( 15 , 24 ) in the housing ( 10 , 21 ) is dragged free, so that only the form and frictional resistance in the fluid are effective and that the damping element ( 15 , 24 ) at least partially in Area of the electric field is arranged. 2. Vibration damper according to claim 1, characterized in that one of the electrodes of the pair of electrodes is formed by the damping element ( 15 , 24 ) and the other electrode ( 16 , 27 ) is arranged on the housing ( 10 , 21 ). 3. Vibration damper according to claim 1 or 2, characterized in that the damping element ( 15 ) is rotatably arranged in the housing and is connected to the vibration exciter that it carries out rotary or swivel movements. 4. Vibration damper according to claim 3, characterized in that the damping element ( 15 ) is designed as a completely immersed in electrorheological liquid speed, which is rotatably connected to a shaft ( 8 ) caused by the vibration exciter in rotational movement and that at least one in the axial direction spaced apart, housing-fixed, designed as a disc electrode ( 16 ) is provided. 5. Vibration damper according to claim 3, characterized in that the Damping element as non-rotatable with one by the vibration exciter rotated shaft connected and as coaxial to the Shaft axis arranged drum is formed which is concentric in a drum fixed as an electrode is. 6. Vibration damper according to claim 2, characterized in that the housing ( 21 ) is hollow cylindrical and that the damping element ( 24 ) as in the housing ( 21 ) longitudinally displaceable piston is ausgebil det, and that the electrodes ( 24 , 27 ) are arranged so are that an electric field between the outer surface of the piston ( 24 ) and the inner surface of the housing ( 21 ) can be generated. 7. Vibration damper according to one of claims 1 to 3, characterized in that the damping element ( 15 ) is coupled to a tensioning element ( 3 ) which interacts with a traction means ( 5 ) and by a spring ( 4 ) in the sense of increasing the tension the traction means ( 5 ) is biased. 8. Vibration damper according to claim 3, characterized in that the damping element ( 15 ) and the housing-fixed electrode ( 16 ) are formed as Schei bensegmente, which partially overlap in the axial direction and that electrical elements ( 20 ) are provided by the damping element and the housing-fixed electrode is connected in a capacitor-like manner, the electrical elements ( 20 ) being designed such that the changes in capacitance caused by the twisting of the damping element ( 15 ) and the electrode ( 16 ) are detected and used to control the voltage applied to the electrodes.