EP1230111A1

EP1230111A1 - Wiper device for wiping a window and method for operating the same

Info

Publication number: EP1230111A1
Application number: EP00975812A
Authority: EP
Inventors: Markus Kliffken; Michael May; Claus Fleischer
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 1999-11-06
Filing date: 2000-09-29
Publication date: 2002-08-14
Also published as: CZ20021494A3; WO2001034440A1; JP2003513852A; KR20020059675A; DE19953515B4; CN1387485A; DE19953515A1; BR0015361A

Abstract

The invention relates to a method for wiping a window (12), and to a wiper device comprising an active regulating stage that is provided for compensating for, in particular, periodic impairments. To this end, a chatter compensating stage (22) is integrated along with the customary position regulator (20) inside the wiper device.

Description

Windscreen wiper device for wiping a window and method for operating such a window

State of the art

The invention relates to a windshield wiper device according to the type of the independent claims.

It has long been known that windshield wiper devices, particularly when the windshield is relatively dry, tend to "rattle". This tendency of wiper blade rubbers to depend on many mechanical parameters. It results from an oscillatory system with different elasticities (wiper blades, wiper arms, linkage) as well as their masses and external forces, e.g. the frictional force on the disc, which depends on the coefficient of friction between the rubber and the disc as well as the wiper blade contact force, and the

Drive power of the wiper motor. The motor drives the wiper blades via the linkage and the wiper arms. The squeegees generate a frictional force depending on the contact force of the squeegee on the disc and the coefficient of friction on the disc.

Under certain operating conditions, for example with a relatively dry pane, the so-called stick-slip effect can now occur. The friction force opposes the squeegee during a "stick phase" and delays its speed on the disc.

In the meantime, the motor continues to introduce its torque into the system via wiper arms and linkage. The components, in particular the linkage, wiper arm and wiper blade are thereby elastically preloaded.

At the moment when the drive torque on the wiper blade becomes greater than the friction torque, the static friction of the wiper rubber is overcome and the rubber is torn from its adhesion to the window. In this “slip phase”, the elastically prestressed components release their energy stored by the prestress and the wiper blade is greatly accelerated.

The transition from static friction to sliding friction reduces the coefficient of friction, which means that the system, consisting of a wiper arm and wiper blade, leads the actual drive speed, which leads to overshoot. When the elastic energy is used up, the wiper blade is braked again, adheres to the window again and the stick-slip cycle starts again.

This chatter behavior has been attempted to date by optimizing the mechanical components, as shown, for example, in US Pat. No. 4,793,020.

Advantages of the invention

In the method according to the invention according to the features of claim 1, it proves to be particularly advantageous that. Faults that result from the action of external forces can be corrected quickly and precisely, which in particular prevents the rattling of the wiper blade on the window. The measures listed in the subclaims result in advantageous developments and improvements of the method specified in the main claim.

Are the faults recurring or oscillating faults, as is the case with

If a wiper blade rattles on a window, the disturbances can be counteracted beforehand, it being particularly advantageous to control the wiper motor in phase opposition to the oscillating disturbance, since this ensures a smooth movement of the

Wiper blade is reached along the target trajectory

If the method is carried out with the aid of an active control stage, for example with a vibration compensation controller, different periodic disturbances which last longer can be corrected well. This

Vibration compensation controller can, for example, also be capable of learning, can be designed as a neural network and as fuzzy logic, as a result of which adaptive properties are achieved.

The fact that a characteristic of the wiper motor, in particular the current I, is used as a control variable for the active control stage eliminates the need for a further sensor in the wiper motor, thereby reducing costs and wear.

A position signal is used as a controlled variable for the active

Related control level, so maximum accuracy is achieved without higher costs, since modern wiper motors often already have position sensors. The position sensor can also be attached to the wiper linkage itself. It is also possible to attach an acceleration sensor to the wiper arm or wiper linkage, which is connected to the control device. In this way, an even more precise regulation can be achieved.

A control device with a frequency selection stage, which is designed in such a way that it is permeable to the frequencies typical of the rattling of the wiper blade, has proven to be a further advantage, in particular if it is designed as a bandpass filter. In this way, uncharacteristic frequencies can be filtered out for the disturbance to be compensated. In addition, bandpasses are available as inexpensive mass-produced goods of the appropriate quality.

Another advantage is the use of a phase shift element. It can be used to precisely set the phase of the manipulated variable of the active control level. The phase shifting element is advantageously designed as a low-pass filter, since these are also available as inexpensive mass-produced goods of the appropriate quality.

It has also proven to be advantageous to implement all of the aforementioned modules such as phase shift element, frequency selection stage and differentiating unit on a software basis within the control device.

drawings

Show it:

Figure 1 shows a windshield wiper device according to the invention in a schematic representation Figure 2 is a diagram of the speed ω of the wiper motor over time t.

Description of the embodiment

Fig. 1 shows a windshield wiper device for performing the method according to the invention according to claim 1 in a schematic representation. A wiper blade 10 moves on a disk 12 and is driven by a wiper motor 14 via a motor shaft 15. A position sensor 16 is located in the wiper motor 14 itself, for example a Hall sensor or a resistive sensor, which emits signals about the position of the motor shaft 15. These position signals 17 are recorded by a control device 18. This includes a position controller 20 and a chatter compensation stage 22, for example as an active control stage. The chatter compensation stage 22 has a differentiating unit 24, a frequency selection stage 26 and a phase shift element 28.

2, the motor speed ω is plotted against the time t for three wiping periods, in the case in which the wiper blade 10 "rattles" over the window. The signal has a large oscillation of the amplitude A, which is caused by the back and forth movement , between the reversal of the wiper blade 10 on the window 12. The amplitude A is controlled by the position controller 20.

In addition, the curve shows a higher harmonic

Frequency and smaller amplitude, which results from the rattling of the wiper blade and is transmitted to the wiper motor 14 via the linkage of the windshield wiper device. If the squeegee sticks, the friction torque increases, causing the speed and therefore the engine speed to decrease. This increases the current consumption at the motor during this "stick" phase.

In order to minimize the duration of the stick, that is to say the time interval in which the squeegee 11 adheres to the window 12, the current I of the wiper motor 14 must be briefly increased further.

If the squeegee 11 tears off the disk 12 in a subsequent “slip” phase, the wiper blade 10 is accelerated by the released elastic energy. This increases the engine speed n.

At this moment, the current I of the motor must be reduced in order to reduce the overshoot of the system, i.e. the system must be braked by the wiper motor 14.

For this purpose, the position signal of the wiper motor 14 is passed to the chatter compensation stage 22, which serves as a component which compensates for disturbances. To improve the signal quality, one or more time derivatives of the signal are carried out in a differentiating unit 24; in principle this is irrelevant for the function of the active control. The signal is then introduced into a frequency selection stage 26, for example a bandpass filter, which passes the frequencies typical for rattling, and in particular filters out the amplitude A resulting from the back and forth between the reversal positions of the wiper blade 10. The following phase shifter 28 now fits the phase of the filtered signal according to the above Compensation characteristic and acts on the input current I of the wiper motor 14 accordingly.

As a result, the input current I of the wiper motor 14 is acted upon as the manipulated variable of the position controller 20 with the manipulated variable of the chatter compensation stage 22.

If no position signal is available, the chatter behavior can also be recognized and compensated for on the basis of the current I consumed by the wiper motor 14. This has a similar behavior to that seen in FIG. 2.

The chatter compensation stage 22 can, for example, also be designed as an active control stage. Such a compensation controller as a control stage is described for example in DE 197 40 153 AI. This active control level can detect and compensate for periodic faults.

It is also possible to attach an acceleration sensor to the wiper linkage, as is known from DE 198 45 674, which is not previously published, and to feed its signals to the chatter compensation stage 22 for recycling. In this way, the motor is then controlled in real time to counter the stick-slip behavior.

Claims

Expectations

1. A method for wiping a window (12), in particular the windshield of a motor vehicle, with at least one wiper blade (10) moving along the window (12), which is made by one, by a

Control device (18) controlled wiper motor (14) is driven, and is prevented from its uniform desired movement by disturbances, characterized in that the disturbances are actively counteracted.

2. The method according to claim 1, characterized in that the disturbances are briefly recurring or oscillating disturbances.

3. The method according to claim 1 or 2, characterized in that the disturbances are counteracted by an active control stage.

4. The method according to claim 3, characterized in that the active control stage uses an intelligent characteristic, in particular a fuzzy logic or a neural network.

5. The method according to claim 3 or 4, characterized in that a parameter of the wiper motor (14), in particular a position signal (17), an acceleration signal or the current I consumed by the wiper motor, serves as a control variable for active control.

6. The method according to any one of the preceding claims, characterized in that the interference is selected by means of a frequency selection stage.

7. The method according to any one of the preceding claims, characterized in that the counteraction takes place in the correct phase, this being done by means of a phase shift element (28), in particular a low-pass filter.

8. Windshield wiper device, in particular for

Carrying out the method according to one of the preceding claims, with at least one wiper blade (10) moving along the window (12), at least one wiper motor (14) moving the at least one wiper blade (10) and one wiper motor (14) controlling the wiper motor Electronic control device (18), characterized in that the control device (18) has at least one component (22) which compensates for interference.

9. Windshield wiper device according to claim 8, characterized in that the control device is an active one

Level of regulation.

10. Windshield wiper device according to claim 9, characterized in that a parameter of the wiper motor (14) serves as a control variable for the active control stage.

11. Windshield wiper device according to one of claims 9 or 10, characterized in that the current I consumed by the wiper motor (14) serves as a controlled variable.

12. Windscreen wiper device according to one of claims 9 to 11, characterized in that a position signal (17) of the wiper motor (14) serves as a controlled variable.

13. Windscreen wiper device according to one of the preceding claims, characterized in that the Faults are recurring or oscillating faults.

14. Windscreen wiper device according to one of the preceding claims, characterized in that the control device (18) a the wiper motor (14)

Control device (18) which counteracts the fault.

15. Windshield wiper device according to one of the preceding claims, characterized in that the control device (18) on at least one frequency selection stage (26).

16. Windshield wiper device according to claim 15, characterized in that the frequency selection stage (26) has at least one bandpass.

17. Windshield wiper device according to one of the preceding claims, characterized in that the control device (18) has at least one phase shift element (28).

18. Windshield wiper device according to claim 17, characterized in that the phase shifting element (28) has at least one low-pass filter.

19. Windscreen wiper device according to one of the preceding claims, characterized in that the interference-compensating component (22) is at least partially designed as a computer program stored in a computer unit.