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Claims  |
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What is claimed is:
1. An LED module comprising:
a rear wall with sidewalls extending outwardly therefrom;
a plurality of LEDs secured between said sidewalls;
driver means, including processing circuit means, secured between said
sidewalls in communication with said plurality of LEDs, said processing
circuit means including input means for receiving data from a preceding
similar LED module, output means for transmitting data to a subsequent
similar LED module, and memory means;
an electrical jack in communication with said processing circuit means,
said electrical jack providing power and bi-directional communication of
data to said processing means via said input means and said output means
from a preceding similar LED module and to a subsequent similar LED
module, respectively;
an aperture within said rear wall providing access to said electrical jack;
and
means on at least one of said rear wall and said sidewalls for attaching
the LED module to an external surface.
2. The LED module of claim 1 wherein said plurality of LEDs and an
associated display circuitry are affixed to a first circuit board which is
supported at least in part by said sidewalls.
3. The LED module of claim 2 wherein said first circuit board is supported
at least in part by an interior ledge of said sidewalls.
4. The LED module of claim 3 wherein said driver means and said processing
circuit means are affixed to a second circuit board, said first circuit
board and said second circuit board being mechanically and electrically
affixed to each other by pins.
5. The LED module of claim 1 wherein said processing circuit means, said
plurality of LEDs, and an associated display circuitry are affixed to a
single circuit board which is supported at least in part by said
sidewalls.
6. The LED module of claim 1 wherein said sidewalls comprise a top wall,
two lateral walls, and a bottom wall in a successive right angle
configuration thereby forming a rectangular or square shape.
7. The LED module of claim 6 wherein said top and bottom walls are inclined
slightly below the horizontal when said rear wall is inclined vertically.
8. The LED module of claim 7 wherein said plurality of LEDs are inclined
substantially parallel to said top and bottom walls.
9. The LED module of claim 8 wherein said top wall extends substantially
further outwardly than said bottom wall so as to form a means for shading
said plurality of LEDs.
10. The LED module of claim 9 wherein an area immediately inward of said
plurality of LEDs is covered with a polyurethane-like material to seal the
LED module from exposure,
11. The LED module of claim 9 wherein said means for attaching the LED
module to an external surface includes screw-hole tabs extending outwardly
from said rear wall.
12. The LED module of claim 9 wherein said means for attaching the LED
module to an external surface includes at least one tab extending
outwardly from said rear wall to engage an aperture in the external
surface.
13. The LED module of claim 12 wherein said at least one tab is L-shaped
with a first portion substantially perpendicular from said rear wall and a
second portion substantially perpendicular to said first portion, said at
least one tab being adapted to twist on and off from an aperture in the
external surface.
14. The LED module of claim 9 wherein said plurality of LEDs are mixed
single color LEDs.
15. The LED module of claim 9 wherein said plurality of LEDs are all of a
single color.
16. The LED module of claim 9 wherein said LED module represents a pixel in
a display.
17. The LED module of claim 1 wherein said bi-directional communication is
facilitated by two separate data paths.
18. A display comprised of a plurality of LEDs modules, each LED module
representing a single pixel in the display, each said LED module
comprising:
a rear wall with sidewalls extending outwardly therefrom;
a plurality of LEDs secured between said sidewalls;
driver means, including processing circuit means, secured between said
sidewalls in electrical communication with said plurality of LEDs, said
processing circuit means including input means for receiving data from a
preceding similar LED module, output means for transmitting data to a
subsequent similar LED module, and memory means;
an electrical jack in communication with said processing circuit means,
said electrical jack providing power and bi-directional communication of
data to said processing means via said input means and said output means
from a preceding similar LED module and to a subsequent similar LED
module, respectively;
an aperture within said rear wall providing access to said electrical jack;
and
means on at least one of said rear wall and said sidewalls for attaching
the LED module to the display; and
the display further including cables providing electrical communication
between at least some adjacent LED modules, wherein data bound for a given
LED module is passed through successive adjacent LED modules via said
processing circuit means of said successive adjacent LED modules.
19. The display of claim 18 wherein said plurality of LEDs and an
associated display circuitry are affixed to a first circuit board which is
supported at least in part by said sidewalls.
20. The display of claim 19 wherein said first circuit board is supported
at least in part by an interior ledge of said sidewalls.
21. The display of claim 20 wherein said driver means and said processing
circuit means are affixed to a second circuit board, said first circuit
board and said second circuit board being mechanically and electrically
affixed to each other by pins.
22. The display of claim 18 wherein said processing circuit means, said
plurality of LEDs, and an associated display circuitry are all affixed to
a single circuit board which is supported at least in part by said
sidewalls.
23. The display of claim 18 wherein said sidewalls comprise a top wall, two
lateral walls, and a bottom wall in a successive right angle configuration
thereby forming a rectangular or square shape.
24. The display of claim 23 wherein said top and bottom walls are inclined
slightly below the horizontal when said rear wall is inclined vertically.
25. The display of claim 24 wherein said plurality of LEDs are inclined
substantially parallel to said top and bottom walls.
26. The display of claim 25 wherein said top wall extends substantially
further outwardly than said bottom wall so as to form a means for shading
said plurality of LEDs.
27. The display of claim 25 wherein an area immediately inward of said
plurality of LEDs is covered with a polyurethane-like material to seal
said LED modules from exposure.
28. The display of claim 26 wherein said means for attaching the LED module
to the display includes screw-hole tabs extending outwardly from said rear
wall.
29. The display of claim 26 wherein said means for attaching the LED module
to the display includes at least one tab extending outwardly from said
rear wall to engage an aperture in the display.
30. The display of claim 29 wherein said at least one tab is L-shaped with
a first portion substantially perpendicular from said rear wall and a
second portion substantially perpendicular to said first portion, said at
least one tab being adapted to twist on and off from an aperture in the
display.
31. The display of claim 26 wherein said plurality of LEDs are mixed single
color LEDs.
32. The display of claim 25 wherein said plurality of LEDs are all of a
single color.
33. The display of claim 18 wherein said bi-directional communication is
facilitated by two separate data paths.
34. The display of claim 33 wherein said two separate data paths alternate
input and output functions between successive LED modules. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
This application is related to commonly-owned U.S. patent application Ser.
No. 08/131,895 entitled "Circuit for Direct Drive of LED as Bulb
Replacement" filed Oct. 5, 1993.
1. Field of the Invention
This invention pertains to a replaceable module for large-scale LED
displays wherein the module can be removed from the array by merely
removing a few screws or twisting the module and unfastening an electrical
connector. The reverse procedure is used for connecting a new module to
the display. The module includes processing means with both input and
output capability allowing the module to be "daisy-chained" with
successive modules to simplify the wiring of an LED matrix display.
2. Description of the Prior Art
In the prior art, it is well known to make displays with large-scale LED
(light emitting diode) arrays. However, it has been difficult to replace
the LEDs in these prior art displays if an LED or an LED module became
inoperative. Typically, the replacement of an LED or an LED module
required access to the rear of the display with the disconnection and
re-connection of several wires extending from the control electronics to
the LEDs or LED modules. This process was inefficient, time consuming and
error prone.
Furthermore, in the prior art, large-scale LED arrays have had complicated
wiring in that separate wires ran from a central processing unit to each
of the individual modules, making any module replacement or
reconfiguration inefficient, time consuming and error prone.
OBJECTS AND SUMMARY OF THE INVENTION
It is therefore an object of the invention to provide an LED module for a
display, particularly a display with a large-scale LED array, wherein the
module can be easily replaced.
It is therefore a further object of this invention to provide an LED module
for a display, particularly a display with a large-scale LED array,
wherein the module can be replaced without access to the rear of the
display.
It is therefore a still further object of this invention to provide an LED
module for a display, particularly a display with a large-scale LED array,
wherein the initial wiring is simplified and any subsequent
reconfiguration is similarly simplified.
It is therefore a still further object of this invention to provide an LED
module for a display, particularly a display with a large-scale LED array,
wherein the module can be replaced with a minimum of reconfigured
electrical connections.
These and other objects are achieved by providing a plurality of LEDs
within a module, typically one module per pixel. The module is attached to
the face of the display by screws, a twist-on connector or similar
fastening means. The rear face of the module includes an aperture through
which an electrical connector with several prongs extends. The electrical
connector and prongs releasably engage a complementary jack extending from
an aperture in the face of the display. The electrical connector receives
power, commands and data through the prongs. Power is drawn from a passing
ribbon cable, commands are monitored from the passing ribbon cable, and
data is input and output bi-directionally (on separate pins) from the
ribbon cable through the prongs allowing for the module to pass data
received from a previous module to a subsequent module. This allows a row
of modules to be "daisy-chained" together thereby eliminating dedicated
wiring from a central processor to each module thereby greatly simplifying
the initial wiring and any subsequent replacement or reconfiguration of
the modules. The power is used to power the processor and to light the
LEDs as instructed by the received commands and data as processed through
an intermediate processor within the module.
BRIEF DESCRIPTION OF THE DRAWINGS
Further objects and advantages of the invention will become apparent from
the following description and claims, and from the accompanying drawings,
wherein:
FIG. 1 is a perspective front view of the LED module of the present
invention.
FIG. 2A is a side plan view, partly in cut-away, of a first embodiment of
the LED module of the present invention.
FIG. 2B is a side plan exploded view, partly in cut-away, of a first
embodiment of the LED module of the present invention.
FIG. 3A is a front plan view, inclined slightly upwardly so that the line
of sight is parallel with the top sunshade, of a first embodiment of the
LED module of the present invention.
FIG. 3B is a front plan view of an array of the LED modules of the present
invention thereby forming a large-scale display, displaying the pixels of
the letter "E".
FIG. 4 is rear plan view of a first embodiment of the LED module of the
present invention.
FIG. 5 is a side plan view, partly in cut-away, of a second embodiment of
the LED module of the present invention.
FIG. 6 is a rear plan view of a second embodiment of the LED module of the
present invention.
FIG. 7 is a plan view of a portion of the face of the display to engage the
second embodiment of the LED module of the present invention.
FIG. 8 shows a "daisy-chain" wiring configuration of successive LED modules
of the present invention, along with the input board and driver board on
the rear of the display of the present invention.
FIG. 9 is a schematic of the processing circuit of the present invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
Referring now to the drawings in detail wherein like numerals indicate like
elements throughout the several views, one sees a front perspective view
of LED module 10 in FIG. 1, and a front plan view of the LED module 10 in
FIG. 3A.
As viewed from the front as illustrated in FIG. 3A, the LED module 10 has a
square cross section, with, in clockwise order, an upper wall 12, a right
sidewall 14, a lower wall 16 and a left sidewall 18, respectively, at
successive right angles to one another thereby forming a closed periphery
with the LEDs 22 visible therebetween. The number and configuration of
LEDs 22 as well as the shape of LED module 10 itself may be changed or
varied with the various applications of LED module 10. As shown in FIGS.
2A, 2B and 4, a rear wall 20 is formed with edges intersecting walls 12,
14, 16, and 18. Rear wall 20 is somewhat inclined from a right angle with
the upper wall 12 and the lower wall 16 so that when the rear wall 20 is
attached to the vertical wall of a display 100 in the configuration of
FIG. 3B, LED module 10 is inclined downwardly somewhat as such large-scale
displays 100 are typically configured at a height where the viewer has to
look upwardly at the display 100. In order not to obscure the view of the
LED module 10 and the LEDs 22, the lower wall 16 is of a length not
extending horizontally substantially beyond the position of the LEDs 22.
Upper wall 12, however, extends well beyond the position of the LEDs 22 in
order to form a sunshade 24, which shades the LEDs 22 from sunlight or
other strong ambient light in order to enhance the visibility of the LEDs
22. As shown in FIGS. 1, 2A and 2B, sidewalls 14 and 18 include upwardly
and outwardly inclined surfaces 26, 28, respectively, which rise from the
outward edge of lower wall 16 toward upper wall 12 and sunshade 24.
Immediately below sunshade 24, inclined surfaces 26, 28 curve outwardly
and dip below the horizontal so as to be parallel with sunshade 24 until
curving upwardly and reaching the outermost tip 30 of sunshade 24.
Two screw-hole tabs 32, 34 extend upwardly from the intersection of the
upper wall 12 and the rear wall 20 at an inclination congruent with the
rear wall 20. Similarly, screw-hole tab 36 extends downwardly from the
intersection of the lower wall 16 and the rear wall 20 at an inclination
congruent with the rear wall 20. Screw-hole tabs 32, 34, 36 allow the LED
module 10 to be removably attached to the face of the display 100.
Alternately, as shown in FIGS. 5 and 6, screw-hole tabs 32, 34, 36 can be
replaced with L-shaped locking tabs 56, 58 with vertical portions 60, 62,
respectively. The use of locking tabs 56, 58 in combination with a display
100 including a plurality of apertures 102 as illustrated in FIG. 7 (only
one aperture shown) allows LED modules 10 to be twisted on and off.
Locking tabs 56, 58 are inserted into detent channels 106, 104,
respectively, and LED module 10 is twisted clockwise through approximately
a forty-five degree angle until locking tab 58 engages stop notch 108.
Rear wall 20 includes a centrally located aperture 38 and a ring-shaped
groove 40. Electrical jack 42 extends through centrally located aperture
38 to allow commands, electrical power and bi-directional data
communication (on separate pins) from a complementary electrical jack (not
shown) extending from display 100. The complementary electrical jack is in
communication with ribbon cable 110 (see FIG. 8, described in detail
hereinafter). Preferably, the centrally located processing unit (not
shown) of the large-scale display 100 is programmed to provide commands
and data to the LED module 10 for a single pixel of the display 100.
However, configurations with more than one pixel within LED module 10 are
certainly possible. The ring-shaped groove 40 engages a rubber O-ring (not
shown) when mounted against the display 100 to provide water-tight seal to
protect the electrical connections against the elements, particularly in
an outdoor application.
Electrical jack 42 is mechanically affixed to and in electrical
communication with the LED driver board 44 which is positioned immediately
in front of the electrical jack 42 and contains intermediate processing
unit 46 for decoding the commands and data communicated through the
electrical jack 42. As shown in FIG. 9, intermediate processing unit 46
includes memory 47, and input means 49 and output means 51 to receive and
send data, respectively. Input means 49 further monitors commands via
electrical jack 42. The input/output capability allows LED module 10 to
receive data from a prior LED module, extract the data intended for LED
module 10, and pass the remaining data to subsequent LED modules (while
monitoring commands). This allows a "daisy-chain" configuration as shown
in FIG. 8 with ribbon cable 110 running between LED modules carrying a
stream of data, commands and power for the entire row of LED modules with
data intended for a specific LED module being extracted from the data
stream by the processing unit 46 of that LED module. Additionally,
commands communicated along ribbon cable 110 are monitored by processing
unit 46 and power for LED module 10 is drawn from ribbon cable 110. By
eliminating dedicated wiring from a central processor to each LED module,
the wiring of a large-scale display 100 is simplified.
Electrical jack 42 typically includes ten prongs which correspond to the
ten wires of a ribbon cable. In order to facilitate the bi-directional
communication of data on separate pins, sequential LED modules 10 are
arranged so that a first LED module 10 in a row receives input data
through the first pin and outputs data through the last or tenth pin. The
next LED module 10 receives input data through the last or tenth pin and
outputs data through the first pin. These two configurations are
alternated. This requires alternating first and last wires to be removed
from the ribbon cable 110 between successive LED modules 10 in order to
maintain the proper data path and to reduce the likelihood of error in
either the initial or subsequent configuration of the display 100.
As further shown in FIG. 8, data, power and commands for a row of LED
modules 10 are initially provided by an input board 112 which is typically
at an end of a row (i.e., an edge of the rear side of the display 100) to
ribbon cable 110. Although not shown in FIG. 8, a single input board 112
typically provides information to several rows of LED modules 10.
Similarly, a driver board 114 is placed on the rear of display 100 at a
spacing of several LED modules 10 within a row. Driver boards 114 are used
to buffer the commands and data signals and maintain the power (and
provide shorter ground paths) being transmitted over ribbon cable 110. A
typical driver board 114 extends for seven or eight rows of LED modules
10.
Referring back to FIGS. 2A and 2B, LED driver board 44 (not to be confused
with element 114 of FIG. 8) is mechanically affixed to and in electrical
communication with the LED display board 48 via pins 50. Alternatively, as
shown in FIG. 5, LED driver/display board 45 can incorporate the functions
of both LED driver board 44 and LED display board 48.
The LED display board 48 is positioned so as to abut the interior ledge 52
which is formed within the interior of the walls 12, 14, 16, 18 so as to
be perpendicular therewith. LED display board 48 contains an arrangement
of a plurality of LEDs 22, preferably mixed single-color LEDs (although
use of LEDs all of the same color is suitable for some applications),
oriented outwardly substantially parallel with the sunshade 24. As shown
in FIG. 1, a thick layer 54 of polyurethane or a similar material is
placed on an outward side of the LED display board 48, but not so as to
obscure the arrangement of a plurality of LEDs 22, so as to seal the
circuit boards 44 and 48 from the weather and elements.
To place the LED module 10 on the large-scale display 100, the user places
an O-ring into ring-shaped groove 40. The user then attaches an electrical
jack (not shown) extending from an aperture in the large-scale display 100
to the electrical jack 42 of LED module 10 and places the rear wall 20
flush against the face of the large-scale display 100 and aligns the
screw-hole tabs 32, 34, 36 with corresponding apertures in the face of the
large-scale display 100. The user then inserts screws into the screw-hole
tabs 32, 34, 36 and the corresponding apertures in the face of the
large-scale display 100 so as to secure the LED module 10 to the face of
the large-scale display 100. Alternately, in place of the screw-hole tabs
32, 34, 36, one may substitute locking tabs 56, 58 and detent channels
104, 106 and a "twist-on-twist-off" configuration in achieved.
Additionally, the user should assure that the data input/output
configuration for the first/last pins is compatible with adjacent LED
modules.
Subsequent removal of the LED module 10, particularly if defective, is
substantially the reverse of the above procedure and does not require
access to the rear of the display 100.
Thus the several aforementioned objects and advantages are most effectively
attained. Although preferred embodiments of the invention have been
disclosed and described in detail herein, it should be understood that
this invention is in no sense limited thereby and its scope is to be
determined by that of the appended claims.
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