Taillight fixture for motor vehicles with printed circuit boards with connectors and LED's

A motor vehicle taillight fixture has a first printed board having at least one electric connector for contacting an electric supply line. The first printed board has at least one plug-in contact. A second printed board has at least one plug-in connector for receiving the at least one plug-in connector. LEDs are connected to the second printed board.

BACKGROUND OF THE INVENTION 
The present invention relates to a taillight fixture for motor vehicles 
with at least one printed board having at least one connector for an 
electrical supply line and receiving openings for lighting devices. 
In known taillight fixtures of this kind, the receiving openings of the 
printed board receive different types of incandescent lamps for the brake 
light, the taillight or the turn signal. The electrical supply is provided 
by cable lug connectors that require time consuming and expensive 
mounting. 
It is therefore an object of the present invention to improve a taillight 
fixture of the aforementioned kind such that it can be manufactured and 
mounted easily and inexpensively. 
SUMMARY OF THE INVENTION 
The motor vehicle taillight fixture according to the present invention is 
primarily characterized by: 
A first printed board having at least one connector for contacting an 
electric supply line; 
The first printed board having at least one plug-in contact; 
A second printed board having at least one plug-in connector for receiving 
the at least one plug-in contact; 
LEDs connected to the second printed board; 
Advantageously, the plug-in connector comprises pins extending through an 
opening of the second printed board and the pins are fastened to the 
opening by soldering. 
The plug-in connector preferably comprises at least two springy tongues. 
The tongues are preferably bent to a semi-circular shape. 
The plug-in connector preferably has a U-shape and two legs connected by a 
transverse bar. 
The tongues are preferably positioned between the legs. 
The tongues extend upwardly from the transverse bar. 
The legs have free ends and each one of the free ends has at least one of 
the pins connected thereto. 
The free ends of the tongues and the free ends of the legs are positioned 
substantially at the same level. 
The tongues preferably have identical length. 
The tongues are preferably positioned opposite one another. 
The taillight may comprise three such tongues, wherein a centrally arranged 
one of the tongues is positioned opposed to the other two of the tongues 
and wherein the centrally arranged tongue is curved oppositely to the 
other two tongues. 
The centrally arranged tongue has a greater width than the other two 
tongues. 
The other two tongues are preferably congruently arranged when viewing the 
plug-in connector in an end view onto the U-shape. 
Advantageously, the plug-in connector is stamped as a rectangular sheet 
metal piece and folded into the U-shape. 
The plug-in connector is symmetrical relative to a longitudinal center 
plane of the rectangular sheet metal piece. 
The tongues, when viewing the plug-in connector in a top view, abut a 
transverse center plane positioned perpendicularly to the longitudinal 
center plane. 
The tongues viewed in the top view define a tapering insertion opening in 
an insertion direction of the at least one plugin contact. 
A longitudinal center plane of the centrally arranged tongue coincides with 
the longitudinal center plane of the rectangular sheet metal piece. 
The inventive taillight fixture can be easily and quickly mounted. The 
printed board containing the LEDs simply receives the plug-in contact of 
the printed board with the electric connector. Complicated soldering work 
is no longer required. The printed boards can be produced in a simple and 
inexpensive manner. The LEDs are also inexpensive components. They can be 
used as the turn signal light, the brake light, and the actual taillight 
for the motor vehicle taillight fixture. Depending on the respective use, 
the LEDs have different colors.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
The present invention will now be described in detail with the aid of 
specific embodiments utilizing FIGS. 1 through 8. 
The printed boards represented in FIGS. 1 through 8 as well as the plug-in 
connector are part of a taillight fixture for a motor vehicle. 
The printed board 1 according to FIGS. 1 and 2 supports a plurality of LEDs 
2 which are soldered with their legs 3 onto the printed board. The 
electric supply to the LEDs is provided via the two plug-in connectors 5, 
6 via which the printed board 1 is connected to another printed board 4. 
The printed board 4 (FIGS. 3 and 4) comprises plug-in contacts 7 and 8 
which are tab-shaped and can be plugged into the receiving openings 10 of 
the plug-in connectors 5, 6 of printed board 1. The plug-in connectors 5, 
6 are fastened with pins 11 through 14 (FIG. 8) extending through 
corresponding plug-in openings of the printed board to the printed board 1 
by soldering. 
The printed board 4 is comprised in a manner known per se of an 
electrically conducting material, preferably of zinc-coated sheet metal. 
It comprises non-represented plus and minus supply lines for incandescent 
lights which are received in receiving openings 4a through 4d (FIG. 4). 
The printed board 4 is fastened to the back side of a non-represented 
reflector housing of the motor vehicle taillight fixture, preferably, by 
high temperature deformation of plastic rivets which are inserted through 
openings 17 of the printed board 4. 
The printed board 4 has a plurality of contacts 15 arranged adjacent to one 
another for contacting a non-represented multiple terminal plug. The 
electric supply from the vehicle battery is achieved with these contacts 
15. The plug-in contacts 7 and 8 are provided at a portion of the printed 
board 4 which is bent out of the plane of the printed board 4 (see 
reference numeral 16 in FIG. 3) so that they extend substantially 
perpendicularly toward a plate portion 16' of the printed board 4. 
In FIGS. 5 through 8, the plug-in connector 5 is shown in detail. The other 
plug-in connector 6 is of the same design and will therefore not be 
disclosed in more detail. 
As shown especially in FIG. 8, the plug-in connector 5 is produced from 
sheet metal preferably by stamping. The pins 11 through 14 are of 
identical construction. They project past the narrow sides 18 and 19 of 
the substantially rectangular stamped sheet metal piece 5. The pins 11 
through 14 are positioned relatively closely adjacent to the longitudinal 
sides 20 and 21 of the sheet metal piece which is essentially 
symmetrically embodied relative to the longitudinal center plane L. 
Between the opposingly arranged pins 11, 12 and 13, 14 the narrow sides 18, 
19 are provided with U-shaped cutouts 22, 23 which have a relatively large 
width so that at both longitudinal sides 20 and 21 projections 25 and 26 
are respectively formed past which the pins 11, 12, 13, 14 extend. The 
pins 11-14 taper in the area of their free ends preferably in a 
trapezoidal shape in order to ensure easy introduction into the 
corresponding plug-in openings of the printed board 1. 
Between the two oppositely arranged longitudinal edges 20 and 21 the 
tongues 28 to 30 are formed which are defined by a meander-shaped cutout 
31. The tongues 28 through 30 are substantially of the same length and 
extend parallel to one another and to the longitudinal sides 20 and 21. 
The tongues 28 and 29 have a transition into the narrow side portion 32 
with edge 22, while the tongue 30 is connected to the other narrow side 
portion 33 having edge 23. In the shown embodiment, the centrally arranged 
tongue 30 is somewhat wider than the tongues 28 and 29 which are of 
identical design. The tongues 28 and 29 are positioned at a same spacing 
to the longitudinal side portions 34 and 35 with longitudinal edges 20 and 
21 as well as to the centrally arranged tongue 30. The free planar end 
faces 36 through 38 of the tongues 28 through 30 have a spacing to 
parallel extending inner edges 39 to 41 of the side portions 32, 33 that 
are perpendicularly arranged to the longitudinal center plane L. This 
spacing is greater than the distance of the tongues relative to one 
another. 
In the developed projection represented in FIG. 8, the stamped rectangular 
sheet metal piece is shown which is bent to the U-shape represented in 
FIG. 5. The tongues 28 to 30 are inwardly bent so as to assume a 
semi-circular shape. The tongues 28, 29 are bent in an opposite direction 
to the centrally arranged tongue 30. In the end view according to FIG. 5, 
the tongues 28, 29 and 30 contact the transverse center plane Q of the 
plug-in connector 5. The tongues 28 through 30 are bent to such an extent 
that their ends faces 36 through 38 have only a minimal distance from the 
neighboring legs 42, 43 of the plug-in connector 5 (FIG. 5). The legs 42, 
43 are formed by a part of the longitudinal side portions 34, 35 of the 
stamped sheet metal piece (FIG. 8) and are longer by about one third than 
the connecting transverse stay 34' (FIG. 5) which is also formed by a 
portion of the longitudinal side portions 34, 35 of the stamped sheet 
metal piece. 
The tongues 28 through 30 are bent in a semi-circular shape inwardly (into 
the space defined by the "U" in the direction toward the free ends of the 
legs 42, 43 and extend upwardly substantially over the entire length of 
the legs 42, 43 (FIG. 5). 
When the taillight fixture is mounted, the printed board 1 is fastened to 
the printed board 4 by inserting the plug-in contacts 7, 8 into the 
plug-in openings 9 and 10 in the area of the transverse stay 34' of the 
two plug-in connectors 5 and 6. Since the tongues 28 through 30 extend to 
the transverse center plane Q of the respective plug-in connector 5, 6 
(FIG. 1) and are substantially semi-circularly bent into the vicinity of 
the legs 42, 43 (FIG. 5) the contacts 7, 8 can be simply inserted into the 
plug-in connector 5, 6. Due to the bent tongues 28 through 30 a tapering 
insertion opening 9 results in the direction of insertion 44 (FIG. 5) 
which allows for a simple introduction of the plug-in contacts 7, 8. Since 
the tongues 28 and 30 extend to the transverse center plane Q of the 
plug-in connector 5, 6, the tongues are resiliently deformed by the 
contacts 7, 8 so that they rest with sufficiently high pressure at the two 
sides of the contacts 7, 8. The distance that the free ends 38 through 40 
of the tongues 28 through 30 have in the initial state from the legs 42, 
43 of the plug-in connector 5, 6 is sufficiently great to allow the 
resilient (springy) deformation of the tongues 28 through 30 upon 
insertion of the plug-in contacts 7, 8. The contacts 7, 8 can be removed, 
if needed, in a simple manner from the plug-in connectors 5, 6. The 
printed board 1 with the plug-in connectors 5, 6 can thus be simply and 
quickly connected to the contacts 7, 8 of the printed board 4. 
The present invention is, of course, in no way restricted to the specific 
disclosure of the specification and drawings, but also encompasses any 
modifications within the scope of the appended claims.