DE19755920A1 - Actuator for adjusting headlight reflectors, in particular of road vehicles - Google Patents

Abstract

An actuator for adjusting headlight reflectors that can be tilted around an axis has a direct current motor which is used as a drive mechanism. Said motor acts upon a spindle drive by means of a gear. The threaded spindle of said drive performs a translational movement. A planetary-roller-threaded spindle gear(25) known from DE 37 39 059 is used as a spindle drive. The nut of the spindle (24) is fixed both axially and radially and is driven by the gear (22,23). An opto-electronic position sensor (29) is connected to the spindle rod (26) of the planetary-roller-threaded spindle gear(25). The position sensor (29) is connected to the spindle rod (26) to enable precise positioning of said rod.

Description

The invention relates to an actuator for adjusting Headlight reflectors, in particular of road vehicles according to the preamble of claim 1.

As shown schematically in FIG. 4, in order to adjust a headlight reflector or headlight reflectors, an actuator 2 , the conventional structure of which is briefly described below, acts on a push rod 3 , the translation movement of which is generated by the actuator 2 , on a push rod in FIG. 4 schematically shown ball joint 4 is transmitted, which is connected to the headlight reflector 1 in the schematic representation of FIG. 4.

Usually, however, the ball joint 4 is connected to a lower part of a support frame of the headlight reflectors 1 , not shown in FIG. 4. In general, in contrast to the simplified illustration in Fig. 4, in which an axis of rotation 5 is provided at the top of the headlight reflector 1 , at the upper part of such a support frame in which the headlight reflectors 1 are held, an axis of rotation of the support frame and thus also the headlight reflectors, which is formed by example, two ball or universal joints.

This can be translated into a tilting movement generated by the actuator 2 and transmitted via the push rod 3 and the ball joint 4 to the headlamp reflector 1 or its support frame translatio movement via the pivot axis formed by appropriately designed joints, whereby the headlamp reflectors are adjusted accordingly .

Conventional headlight adjustment devices in the form of operate in an open timing chain without position measurement  Systems generally have stepper motors, which Sliding nuts are subordinate.

The main disadvantage of such systems is that in the event of sudden occurrence of high forces, for example may be caused by jamming, uncertain on the position of the headlight setting. Furthermore, such systems have only a limited loading acceleration and top speed as they start up and subsequent braking via a ramp the.

Furthermore, at a higher translation the used Slide nut systems no longer the adjustment device self-locking. Furthermore, if large forces are generated who the should, the volume and / or the magnetic density of the clog stepper motors and thereby almost increase the costs and the installation volume for such are also common Stepper motors.

In the case of headlamps operating on a different basic principle Adjustment devices are used to drive a DC motor used, which is assigned a slide nut, which in turn engages with a threaded spindle. In such DC motors are, however, if a usable torque ment should be applied, the speed so high that the Spindle rod of the threaded spindle is not driven directly can be, but between the DC motor and the A reduction must be provided for the threaded spindle.

Referring to Figs. 5a and 5b show two examples are described such forth kömmlicher drive systems for adjusting Scheinwerferre reflectors. In the examples given in FIGS . 5a and 5b, a sliding nut 8 is in each case reduced by a DC motor 10 , in FIG. 5a via spur gears 6 ₁ and 6 ₂ or in FIG. 5b via bevel gears 7 ₁ and 7 ₂ with a corresponding Speed driven. The slide nuts 8 are each with a threaded rod 9 in a meshing grip. At the top in Fig. 5a end of the spindle 9 and in Fig. 5b right end of the spindle rod 9 , a Ku gel 90 is provided, which corresponds to the ball 30 , which in the schematic representation of Fig. 4 at the right end of the Function of the threaded spindle 9 fulfilling push rod 3 is seen before and in Fig. 4 part of the ball joint 4 bil det.

Since the pitch of the threaded spindle rods 9 is usually of the order of 1 mm, which corresponds to the pitch of an M6 thread, or more, the toothing formed from the spur gears 6 ₁ and 6 ₂ or the bevel gears 7 ₁ and 7 _{2 is} large Gear ratio required. This in turn results in an increased space requirement for the spur or bevel gear teeth in order to reduce the engine speed accordingly.

At a certain slope, the respective drive system is then no longer self-locking, so that other mechanisms must be provided to ensure self-locking of the threaded spindle. If a correspondingly smaller reduction ratio is selected for the gears, strong and therefore more expensive motors must be provided for considerably larger torques. In general, it can be assumed that the scope for designing the drive systems shown schematically in FIGS. 5a and 5b is relatively small.

The invention is therefore based on the object of being compact th and variably designed actuator for adjusting Headlight reflectors, in particular of road vehicles  to train so that the headlight reflectors exactly in egg ner required tilt position can be positioned.

According to the invention, this object is for an actuator Adjusting headlight reflectors according to the generic term of claim 1 by the features in its characterizing Part solved.

According to the invention, the actuator is a spindle drive known planetary roller (PWG) thread spin from DE 37 39 059 del gearbox used, its axially and radially fixed Spindle nut via a gear, for example a forehead gear is driven so that the spindle rod of the PWG gearbox, between which and the spindle nut rolling or roller body are arranged in the axial direction performs translatory movement. Furthermore, the exact Position the spindle rod this an optoelectronic Position sensor can be assigned.

In the actuator according to the invention for adjusting the appearance projector reflectors is an almost infinite change in Spindle pitch and thus the spindle rods possible by the spindle rod and the surrounding rolling or rolling elements to be replaced by such elements, their thread have different thread pitches.

Through a variable design of the drive DC motor and also by replacing the previous one elements of the PWG gearbox can be changed visibly the power can be achieved by a small spin slope and a high gear ratio between the DC motor and the spindle nut provided gear, is preferably chosen in the form of spur gear teeth, or in terms of speed, in which has a large spindle pitch and a low reduction  the gear, for example in the form of a spur gear is taken.

Another advantage is that in the fiction Actuator for adjusting headlight reflectors accordingly small and therefore cheaper motors are used can be brought.

According to the invention, a very compact overall created linear actuator with which to adjust of headlight reflectors, for example, a hub in the Order of magnitude of about 10mm can be executed. With the actuator according to the invention lie on the forces to be applied in a range from about 15N (nominal force) to about 80N (Maximum force). On top of that, the actuator according to the invention be operated in a closed control loop.

Below is a preferred embodiment of the invention tion with reference to the accompanying drawings described individually. Show it:

Fig. 1 is a schematic illustration of a Schnit tansicht a preferred embodiment of an actuator according to the invention;

FIG. 2 shows a perspective view of an overall view of the actuator according to the invention according to FIG. 1, in which the housing has been removed;

Fig. 3 is a position sensor used in the Favor th embodiment of the invention a schematic structure;

Fig. 4 is a schematic diagram of the structure of a conventional headlight drive, and

FIGS. 5a and 5b show two examples of conventional drive systems for the adjustment of headlamp reflectors.

In the sectional view of FIG. 1, a DC motor 21 is rotatably connected to a base plate 20 in the manner shown in the sectional view. A spur gear 22 is seated on the output shaft 210 of the direct current motor 21 and meshes with a spur gear 23 . The spur gear 23 bil det a unit with an axially and radially fixed, but freely rotatable in the circumferential direction spindle nut 24 of a known from DE 37 39 059 planetary roller screw (PWG) gear 25th

In the PWG gear 25 , a number of rolling or rolling elements 27 are arranged between the spindle nut 24 and a spindle rod 26 , of which two pairs can be seen in the sectional view of FIG. 1.

The spindle rod 26 is fixed in a forming a unit with the base plate 20 bearing socket 20 'in the circumferential direction in such a manner that in a drive of the spindle nut 24 gear formed by the DC motor 21 from above consisting of the spur gears 22 and 23, the screw rod 26 of a function the direction of rotation of the DC motor 21 is displaced translationally in the direction of the dash-dotted axis of the spin del rod 26 , that is in Fig. 1 up or down is moved. With such a translatory displacement of the spindle rod 26 , this fulfills the same function as that shown in FIG. 4, actuated by the actuator 2, push rod 3 .

At the lower end in Fig. 1 of the spindle rod 26 , a holding element 28 is fastened, to which in turn a function sensor 29 described in detail in its function with reference to Fig. 3 is attached so that it is translational at (in Fig. 1) Upward or downward movement of the spindle rod 26 together with it is moved parallel to its dash-dot line as the given central axis.

The position sensor 29 is an opto-electronically working displacement measuring unit, in which two PSD (Photo Sensitive Device) elements 29 ₁ and 29 _{2 are} provided. Here, the PSD element 29 _{1 on} the left in FIG. 3 fulfills the function of an “optical resistance path”. This means that when the position sensor 29 moves parallel to the center axis of the spindle rod 26 , light from a light-emitting diode (not shown in the figures) is passed through a narrow slot 29 ₃ , for example about 0.3 to 0.5 mm wide, above the PSD element 29 ₁ moved back and forth. Depending on the position of the light gap on the PSD element 29 ₁ , a voltage can then be tapped on the PSD element 29 ₁ , the height or amplitude of which is proportional to the position of the slot 29 ₃ .

The voltage tapped off in accordance with the displacement of the position sensor 29 on the PSD element 29 ₁ is related to the voltage tapped off on the second PSD element 292 , which voltage is likewise via a light emitting diode not shown in the figures above a slot 29 ₃ corresponding slot 29 _{4 is} illuminated. The slot 29 ₄ runs parallel to the center axis of the spindle rod 26 , while the slot 29 ₃ assigned to the PSD element 29 ₁ , as can be seen from FIG. 3, runs at an acute angle to the slot 29 ₄ .

As shown in FIG. 1 and FIG. 2 is entnehmen-, the spindle rod 26 is provided a ball 260 at the free end, the tion in radio and an object of the ball 30 corresponds to the reflector-side end of the push rod 3 in Fig. 4.

The actuator shown in Fig. 1 in section is housed in a housing 200 which, in addition to the function to protect the various elements of the actuator from contamination and in particular to protect the position sensor from incidence of light, has the further function of the axial forces of the spindle nut 24 record, which in the illustrated embodiment, for example, is supported by sliding disks 24 ₁ , 24 ₂ on the housing 200 or the bearing base 20 '.

According to an advantageous embodiment, the spindle rod 26 can have a right-hand M6 thread 26 ₁ . The between the spindle rod 26 and the spindle nut 24 arranged rolling or rolling elements 27 then have on the one hand the thread 26 _{1 of} the spindle rod 26 corresponding groove profiles and on the other hand to the spindle nut internal thread pas sending profile. In the preferred embodiment, the rolling or rolling elements 27 have a left-hand thread with a pitch of 1 mm corresponding to the M6 thread of the spindle rod.

With such a design of the right-hand thread on the spindle rod 26 and the matching left-hand thread on the rolling and rolling elements 27 , there is a computational total pitch Ge per revolution of the spindle rod 26 of 0.178 mm. Of course, the actual gradient also depends on the slippage of the system. By the combination of, for example, a right-hand thread on the spindle rod 26 and left-hand threads on the rolling and rolling elements 27 , the slope of the spindle rod results at maximum slip as a negative overall pitch of the PWG gearbox, which in turn corresponds to a reversal of direction.

Reference list

1

Headlight reflector

2nd

Actuator

3rd

Push rod

30th

Bullet

4th

Ball joint

5

Axis of rotation

6 ₁

,

6 _2nd

Spur gears

7 ₁

,

7 _2nd

Bevel gears

8th

Sliding nut

9

Threaded spindle

90

Bullet on

9

10th

DC motor

20th

Housing plate

200

casing

21

DC motor

210

Output shaft

22

,

23

Spur gear

24th

Spindle nut

24th ₁

,

24th _2nd

Sliding washer

25th

PWG gear

26

Spindle rod

26 ₁

Thread on

26

260

Bullet on

26

27

Rolling or rolling elements

28

Holding element

29

Position sensor

29 ₁

,

29 _2nd

PSD elements

29 _4th

,

29 _3rd

Slots in

29

Claims (3)

1. Actuator for adjusting headlight reflectors, which are held tiltable about an axis, with a drive serving as a DC motor, which acts via a gear on a spindle drive so that its threaded spindle performs a translational movement, characterized in that as a spindle drive known planetary roller screw (PWG) gearbox ( 25 ) is used, which consists of a spindle rod ( 26 ), a surrounding spindle nut ( 24 ) and a number of roller or rolling element ( 27 ) arranged therebetween pill profiles matching the thread of the spindle rod ( 26 ) and with a profile matching the internal thread of the spindle nut, whereby
the axially and radially fixed spindle nut ( 24 ) is driven via the gear ( 22 , 23 ), and
an optoelectronic position sensor ( 29 ) is connected to the spindle rod ( 26 ). 2. Actuator according to claim 1, characterized in that an opto-electronic position sensor ( 29 ) is connected for precise positioning with the spindle rod ( 26 ). 3. Actuator according to claim 1, characterized in that the transmission is formed by two meshing spur gears ( 22 , 23 ), of which one spur gear ( 22 ) is driven by the DC motor ( 21 ) and with this ( 22 ) engaged other spur gear ( 23 ) with the spindle nut ( 24 ) is firmly connected.