ES2379847A1 - Damper for vehicle, has high frequency sensor that directly measures actual position and/or speed of piston ram relative to damping cylinder, where measured actual values are evaluated for regulating flow of damper fluid - Google Patents

Abstract

The damper has a damping cylinder (10) in which a piston ram (20) is guided by a piston rod (26). The flow of damper fluid (16) i.e. damper oil, is adjustable by a flow regulating valve (22) for adjusting damper characteristic values. A high frequency sensor (30) is integrated into the piston ram for direct measurement of actual position and/or speed of the piston ram relative to the damping cylinder. The measured actual values are evaluated for regulating the flow of damper fluid. The high frequency sensor is implemented as a highly integrated sensor in silicon germanium technology. An independent claim is also included for a method for operating a vehicle damper.

Description

Shock absorber for a vehicle and system operation for a vehicle shock absorber.

Current state of the art

The present invention refers to a shock absorber for a vehicle, according to the class of the independent claim 1, and an operating system corresponding for a vehicle shock absorber.

From the current state of the art sensors are known High frequency based for distance and speed measurement for short range. In this case the measurement margins of these High frequency sensors are in dimensions of \ mum up to cm.

In patent application DE 10 2006 037 172 A1 a shock absorber for a vehicle is described. Shock absorber described comprises a cushion cylinder, in which a plunger is driven through a piston rod. For the adjustment of characteristic values of the damper, the flow can be regulated of a buffer fluid. For this purpose, inside the cylinder damper are arranged regulating elements, which they have two independent regulation circuits for a period of traction stage and a period of pressure stage, thereby the regulating elements, during the period of pressure stage, regulate the flow of the damping fluid in a first flow direction with first means of travel, and during the traction stage period, in a second flow direction with second means of movement. The magnitudes of displacement for the first means of displacement, and / or for the second means of travel can be determined by example, through the evaluation of signals from sensor units. The sensor units are shaped, for example, as pressure sensors, acceleration sensors and / or sensors position, and comprise corresponding electronic commutations for control and signal evaluation.

Exhibition of the invention

The shock absorber for a vehicle conforming to the invention, with the features of the claim independent 1, has the advantage that the piston find at least one high frequency sensor integrated for the direct measurement of a position and / or current speed of the piston in relation to the damping cylinder, with which the measured quantities current are valued for fluid flow regulation of damping The implementation of high frequency sensors enables, advantageously, the direct measurement of speed of the piston and enables, compared to a measurement that determines the speed and position by pressure, a measurement with considerably greater accuracy, since contrary to the pressure measurement, the measurement is not visible affected by transverse influences such as temperature, lack of linearity, initial starting torques, etc. Thus, in the buffer according to the invention, the flow of the damping fluid can be regulated by at least one flow regulating valve, depending directly on the piston speed and / or current piston position.

Through measurements and refinements mentioned in the dependent claims, are possible Advantageous improvements of the shock absorber for a vehicle indicated in the independent claim 1, and of the operating system corresponding to a vehicle shock absorber indicated in the independent claim 9.

It is especially advantageous that the at least one high frequency sensor is shaped as a sensor High scale integration with Germanium silicon technology. This makes the implementation of cheaper sensors possible, manufactured on a large scale. The measurement direction of the sensor high frequency is determined by the signal direction of measurement or sensor mounting orientation high frequency.

In the design of the shock absorber according to the invention, the measurement signal, generated by the at least one high frequency sensor, faces a wall side of the shock absorber cylinder, perpendicular to the direction of movement of the plunger. To do this, the measurement signal generated by the at least one high frequency sensor, it It is oriented towards a dial scale with position, arranged inside the side wall, through a plunger window in a side wall, whereby the at least a high frequency sensor values the reflected measurement signal by the dialing scale for position recognition. During the movement of the piston in the damping cylinder, correspondingly placed placemarks, which they are shaped for example as cavities, they are detected and valued. To do this, placemarks represent a absolute position recognition. By valuing the time lag between the detection of at least two markings of position on the dialing scale can be determined, so advantageous, the current speed of the plunger.

In an alternative shock absorber design according to the invention, the measurement signal generated by the less, a high frequency sensor, is oriented towards a cylinder bottom or cylinder cylinder cover shock absorber, parallel to the direction of movement of the piston, that is, in the direction or against the direction of the piston movement. For this, the generated measurement signal is emitted through a plunger window in the background or in the piston cover, so that the high frequency sensor receives the measurement signal reflected by the bottom of the cylinder or the cylinder cover, and values it for direct determination of the distance of the piston from the bottom of the cylinder or from of the cylinder cover and / or for direct determination of the current piston speed. Additionally the at least one High frequency sensor can determine the current speed, indirectly through the assessment of a modification of distance and a temporary duration. In this way, the speed of plunger can be determined directly through the assessment of a Doppler signal or indirectly through a determination journey-time.

Through the operating system according to the invention for a vehicle shock absorber a position and / or Current piston speed are measured directly in relation to the shock absorber cylinder, bringing the current measured quantities are valued for fluid flow regulation of damping For measurement, a measurement signal can be oriented towards a side wall of the damping cylinder, of perpendicular to the direction of movement of the plunger or towards a cylinder bottom or a cylinder cylinder cover shock absorber, parallel to the direction of movement of the piston, whereby the reflected measurement signal is rated for the determination of the position and / or for the determination of the distance and / or for speed determination.

Examples of Execution of the invention and the following description explains more details.

Brief description of the drawings

Figure 1 shows a block diagram schematic of a first example of a shock absorber for a vehicle according to the invention.

Figure 2 shows a block diagram schematic of a second example of a shock absorber for a vehicle according to the invention.

Forms of Execution of the Invention

As can be seen in fig. 1, a first Execution example of a shock absorber 1 for a compliant vehicle to the invention comprises a cushion cylinder 10, in which a piston 20 is driven through a piston rod 26. For the adjustment of characteristic values of the shock absorber can be adjusted the flow of a buffer fluid 16 through several valves flow regulators, of which it is represented, to For example, a flow regulating valve 22. The valve flow regulator 22 is controlled by an adjustment unit 24, with which for the regulation of the flow regulating valve 22, the adjustment unit 24 receives information, through a line of Power 3, from a vehicle control unit, not represented, or from a high frequency sensor 30 integrated in the piston 20. Through the high frequency sensor 30 it is possible a direct measurement of a current position and / or piston speed 20 in relation to the cushion cylinder 10, whereby Current measured quantities are valued for the regulation of damping fluid flow 16.

As can also be seen in fig. 1, the shock absorber 1 is arranged between a wheel 4 and a body 2 of the vehicle, represented as a fragment, with which the piston rod 26 is connected to the body 2 of the vehicle. To avoid a loss of the damping fluid 16, for example a damping oil, the piston rod 26 is is sealed with respect to the cylinder cover 14 a through a piston rod seal 11 in the cover of the cylinder 14. In addition, a piston seal 13, which is located disposed between the plunger 20 and the inner side of a side wall of the cylinder 17, prevents the liquid damping fluid 16 arrive, avoiding flow regulating valve 22, from an area upper cylinder, which is arranged between the piston 20 and the cylinder cover 14, towards a lower cylinder area, which is arranged between the piston 20 and a cylinder bottom 12. In addition, an area is located in the lower cylinder area separated by a membrane 19, which contains a buffer fluid in gas form 18. In the exemplary embodiment shown, the sensor high frequency 30 is shaped as a sensor with High scale integration with Germanium silicon technology.

In the first example of execution of damper 1 according to the invention according to fig. 1, one measurement signal 32, generated by the high frequency sensor 30, it is oriented towards the side wall 17 of the cylinder shock absorber 10, perpendicular to the direction of movement of the piston 20. On the inner side of the side wall of the cylinder 17 a dial scale 34 with markings is arranged of position, which are shaped, for example, as cavities The generated measurement signal 32 is oriented towards the dialing scale 34 with position markings, through a plunger window 28, which is arranged in a wall side of the plunger 20, whereby the high frequency sensor 30 receives and evaluates the measurement signal reflected by the scale of dial 34 for position recognition. In this case it It is a measurement in the absolute near area. During the displacement of the plunger 20 along the marking scale 34 arranged in the cushion cylinder 10, the markings of correspondingly positioned position of the scale of Dial 34, are detected and assessed. To do this, the markings of position of the dial scale 34 represent a absolute position recognition. By valuing the duration of time between the detection of at least two dials of position of the dial scale 34 you can determine the piston speed 20. The measurement signal measurement 32 it can be performed, preferably, directly on the sensor high frequency 30 and / or in the adjustment unit 24. alternative or additional, the measurement signal measurement 32 it can also be done in the vehicle control unit, not represented.

As can be seen in fig. 2, one second Execution example of a 1 'shock absorber for a compliant vehicle the invention comprises, analogously to the first example of execution, a cushion cylinder 10 ', in which a plunger 20' is driven through a piston rod 26. For adjustment of characteristic values of the shock absorber, here you can adjust the flow of a buffer fluid 16 through two valves 22 'flow regulators. The 22 'flow regulating valves are controlled by an adjustment unit 24 ', so that for regulation of flow regulating valves 22 ', the unit of 24 'setting receives information, through a power line 3, from a vehicle control unit, not shown, or from a high frequency sensor 30 'integrated in the piston 20'. From analogously to the first example of execution, through the sensor high frequency 30 'direct measurement of a position is possible and / or current speed of the piston rod 20 'in relation to the 10 'shock cylinder, with which the measured quantities current are valued for fluid flow regulation of damping 16. The shock absorber 1 'is also arranged between the wheel 4 and the body 2 of the vehicle, whereby the piston rod 26 is connected to body 2 of the vehicle. To avoid a loss of the damping fluid 16, the piston rod 26 is sealed against the cylinder cover 14 through a piston rod seal 11 on the cylinder cover 14. Analogously to the first example of execution, a piston seal 13, which is arranged between the piston 20 'and the inner side of a side wall of the cylinder 17, prevents liquid damping fluid 16 arrive, avoiding the flow regulating valve 22 ', from a upper cylinder area towards a lower cylinder area, and a area separated by a membrane 19, which contains a fluid gas-shaped shock absorber 18, is also arranged in the lower cylinder area.

Unlike the first example of execution according to fig. 1, in the second example of execution according to fig. 2 a measurement signal 32, generated by the high sensor frequency 30 ', which is also shaped as a sensor With high scale integration with Germanium silicon technology, it is oriented towards the bottom of the cylinder 12 of the cylinder 10 'shock absorber, parallel to the direction of movement of the 20 'plunger. The generated measurement signal 32 'is oriented towards the bottom of cylinder 12, through a piston window 28 ', which is is arranged at the bottom of the piston 20 ', so that the sensor High frequency 30 'receives and values the measurement signal reflected by the bottom of the cylinder 12 for recognition of the position. Here the distance A of the piston 20 'or the sensor of the high frequency 30 'towards the bottom of the cylinder 12. The speed of piston feed 20 'can be determined directly through an evaluation of the Doppler signal, or indirectly through the path-time determination. The valuation of measurement signals 32 'can also be performed, so preferably, directly on the high frequency sensor 30 'and / or in the adjustment unit 24 '. Alternatively or additionally, the measurement signal measurement 32 'can also be performed in the vehicle control unit, not shown.

In the case of an alternative form of execution not shown in the present invention, the measurement signal generated is oriented towards the cylinder cover of the shock absorber cylinder, parallel to the direction of piston movement, so that the measurement signal generated, in that case, is oriented towards the cylinder cover, through a plunger window arranged in the plunger cover. In this case, the high frequency sensor receives the measurement signal reflected by the cylinder cover and values it for the position recognition. Here, the distance is measured from the piston or high frequency sensor to the cover of the cylinder. The feed rate of the piston can then also be determined directly through a signal evaluation Doppler, or indirectly through determination journey-time. The assessment of the signals of measurement can be performed, analogously, directly on the high frequency sensor and / or in the adjustment unit and / or in the vehicle control unit.

With high sensor implementation frequency, the shock absorber according to the invention and the corresponding operating system enable, so advantageously, the direct measurement of the speed of the piston and / or the piston position, so that accuracy can be achieved considerably older. With high sensor layout frequency inside the plunger and / or the corresponding direction of the measurement irradiation, the measurement direction can be default The measurement can be performed, for example, in a perpendicular to the direction of movement of the plunger or shape parallel to the direction of movement of the plunger.

Claims (10)

1. Shock absorber for a vehicle with a shock absorber cylinder (10), in which a piston (20, 20 ') is driven through a piston rod (26), thereby adjusting characteristic values of the shock absorber You can adjust the flow of a damping fluid (16) through at least one flow regulating valve (22, 22 '), characterized by at least one high frequency sensor (30, 30') integrated in the piston (20, 20 ') for the direct measurement of a current position and / or speed of the piston (20, 20') in relation to the damping cylinder (10, 10 '), whereby the current measured quantities can be assessed for damping fluid flow regulation (16). 2. Shock absorber according to claim 1, characterized in that the at least one high frequency sensor (30, 30 ') is formed as a sensor with high scale integration with Germanium silicon technology. 3. Shock absorber according to claim 1 or 2, characterized in that a measuring signal (32), generated by the at least one high frequency sensor (30), is oriented towards a side wall (17) of the damping cylinder (10), perpendicular to the direction of movement of the plunger (20). 4. Shock absorber according to claim 3, characterized in that a measurement signal (32), generated by the at least one high frequency sensor (30), is oriented towards a marking scale (34) with position marks , through a plunger window (28) in a side wall, whereby the at least one high frequency sensor (30) evaluates a measurement signal reflected by the marking scale for position recognition. 5. Shock absorber according to claim 4, characterized in that the at least one high frequency sensor (30) determines a current speed of the piston (20), and for this, it assesses a time lapse between a detection of at least two markings position on the dial scale (34). 6. Shock absorber according to claim 1 or 2, characterized in that a measuring signal (32 '), generated by the at least one high frequency sensor (30'), is oriented towards a cylinder bottom (12) or a cylinder cover (14) of the damping cylinder (10 '), parallel to the direction of movement of the piston (20'). 7. Shock absorber according to claim 6, characterized in that the at least one high frequency sensor (30 ') generates a measurement signal and sends it through a piston window (28') at the bottom or the piston cover (20), whereby the high frequency sensor (30 ') receives the measurement signal (32') reflected by the bottom of the cylinder (12) or the cylinder cover (14) and values it for the direct determination of the piston distance (20 ') with respect to the bottom of the cylinder (12) or with respect to the cylinder cover (14) and / or for direct determination of the current speed of the piston (20'). 8. Shock absorber according to claim 7, characterized in that the at least one high frequency sensor (30) determines a current speed, indirectly through the assessment of a distance modification and a time duration. 9. Operating system for a vehicle shock absorber, whereby the shock absorber (1, 1 ') comprises a shock absorber cylinder (10), in which a piston (20, 20') is driven through a piston rod (26), so that for the adjustment of characteristic values of the damper, the flow of a damping fluid (16) is adjusted through at least one flow regulating valve (22, 22 '), characterized in that a position and / or current speed of the piston (20, 20 ') in relation to the damping cylinder (10, 10') is measured directly with a high frequency sensor (30, 30 '), whereby the current measured quantities are valued for the damping fluid flow regulation (16). 10. Operating system according to claim 9, characterized in that a measuring signal (32, 32 ') is oriented towards a side wall (17) of the damping cylinder (10), perpendicular to the direction of movement of the piston ( 20) or is oriented towards a cylinder bottom (12) or a cylinder cover (14) of the damping cylinder (10 '), parallel to the direction of movement of the piston (20'), whereby the signal of Reflected measurement is assessed for position determination and / or for distance determination and / or for speed determination.