DE102004002398A1 - Light source comprising printed circuit board with RGB LEDs and controllers, used in optical scanner, produces white light with stable color temperature - Google Patents

Abstract

The circuit board (20) has side surfaces. The RGB light-emitting diodes (LEDs) (22A-22H) comprise a red, green and blue LED (30A-C). The controllers (24A-C) regulate the drive current to each respective diode. Each RGB-LED unit produces white light with a stable color temperature.

Description

The The invention relates to a light source with light-emitting diodes, in particular a light source with light emitting diodes to overcome any quality deviations when producing and producing white light with stable color temperature.

generally known becomes white Light as an indispensable light source often in electronic devices and devices In particular, its commercial use in home appliances (e.g., modules with backlight for Scanners, telecopiers and color monitors with liquid crystal display, etc.) gained in importance in recent years. Of special Interest is the technical improvements and developments to the Production of such products, in particular white light sources.

1 shows a schematic exploded view of a conventional, side-lit backlight module 10 which has a plate-shaped light guide 100 one on one side of the plate-shaped light guide 100 trained light tube 102 , one the light tube 102 enveloping lamp mirror body 104 and one under the plate-shaped light guide 100 designed mirror body 106 a prismatic lens (not shown in the drawing) and a light diffusing plate (not shown in the drawing). These components are already known from the prior art and are therefore not discussed here. Such a side-lit backlight module 10 can be used in a monitor (screen) and the light tube 102 (eg a CCFL bulb) can produce white light. The white light of the light tube 102 is from the lamp mirror body 104 reflected and then to generate a forward emission by means of the plate-shaped light guide 100 , led the prism lens and the light scattering plate. The plate-shaped light guide 100 interacts with the mirror body 106 , the prism lens and the light scattering body to evenly diffuse the light to generate backlighting (eg, for a liquid crystal display monitor). A disadvantage of a CCFL incandescent lamp, however, is: 1. It needs an electrical high voltage to excite, which complicates the design of the light source and its circuits. 2. The luminous efficiency changes depending on the operating temperature, whereby a stable light source is not available. 3. Poor light output on the two sides of the light pipe, which adversely affects the display quality. The above application example concerns only one monitor. If the above-mentioned side-lit backlight module 10 is used on a scanner, the color temperature of the light source and the image scanning quality may be poor due to the characteristics of the light pipe 102 be changed significantly.

• 1. Eine blau leuchtende Diode kombiniert mit gelben Phosphoren. Jedoch wird die Lichtausbeute einer solchen Lichtquelle erheblich von den Phosphoren beeinflusst.
• 2. Ein Farbsystem kombiniert eine rote, eine grüne und eine blaue Diode und verwirklicht damit das ersehnte Weißlicht. Nachteilig bei einem weißen Licht erzeugt aus einem solchen Farbsystem ist allerdings, dass eine Steuerung der Farbtemperatur erschert ist, weil verschiedene Eigenschaften aufgrund von Abweichungen beim Herstellen hervorgerufen werden können. Sogar beim Betrieb unter einem festgesetzten Strom kann eine unerwartete Farbtemperatur erzeugt werden.

The light bulb is getting competition. Light researchers rely on the long-lasting and energy-saving light-emitting diodes. Furthermore, the light generated by LEDs is "monochromatic", the light is emitted over a narrow wavelength range, and a few years ago, it was also possible to produce blue LEDs, making it possible to produce white light through the combination of LEDs of different colors. Its color temperature can be controlled by the relative brightness of the different luminous colors, and the cost-effective production of large-area LEDs can safely produce economical light sources that can replace conventional light tubes getting produced:

• 1. A blue glowing diode combined with yellow phosphors. However, the luminous efficacy of such a light source is significantly affected by the phosphors.
• 2. A color system combines a red, a green and a blue diode, thus realizing the longed for white light. A disadvantage of a white light generated from such a color system, however, is that a control of the color temperature is hampered because different properties can be caused due to variations in the manufacturing. Even when operating below a fixed current, an unexpected color temperature can be generated.

With The invention will now be a light source with light emitting diodes for generating white Light or light of a different color with stable color temperature be created, which does not have the above-mentioned disadvantages.

These Task is solved essentially with the features in claim 1.

The light emitting diode light source of the present invention has a printed circuit board formed with a plurality of side surfaces, a plurality of light emitting diode units each having a red, a green, and a blue light emitting diode disposed on a side surface of the printed circuit board (hereinafter called "RGB LED unit"). The control unit is in each case electrically connected to each light-emitting diode of the plurality of RGB LED units for controlling the driver Current of each LED connected so that each RGB LED unit can generate white light with a fixed stable color temperature.

In addition, can each control unit has a memory for storing the drive current data for every Have light emitting diode. The memory may be a programmable read-only memory Be (EEPROM). The printed circuit board is preferably made a material with good thermal conductivity prepared, e.g. made of aluminum or copper.

advantageous Further developments of the invention will become apparent from the dependent claims.

The Invention will now be an embodiment and on the basis of the attached Drawing closer explained. In the drawing represent:

1 a schematic exploded view of a conventional side-lit backlight module,

2 a perspective view of a preferred embodiment of a light source according to the invention with light emitting diodes,

3A a plan view of the preferred embodiment of the light source according to the invention with light-emitting diodes,

3B a bottom view of the preferred embodiment of the light source according to the invention with light-emitting diodes,

4 a plan view of an RGB LED unit of the preferred embodiment of the light source according to the invention with light emitting diodes,

5A a top view of a preferred second embodiment of the light source according to the invention with light-emitting diodes,

5B a plan view of a preferred third embodiment of the light source according to the invention with light-emitting diodes, and

6 a bottom view of the preferred second embodiment of the light source according to the invention with LEDs.

A preferred embodiment of the light source with LEDs 2 according to the invention, as in 2 . 3A and 3B is shown, has a printed circuit board 20 , a plurality of RGB LED units 22A - 22H and at least one control unit 24A - 24C (please refer 2 ) on.

The printed circuit board 20 is elongated, preferably rectangular, formed and has an end face, a back, two opposite broad sides and two opposite narrow sides. A plurality of RGB LED units 22A - 22H is on the front of the printed circuit board 20 formed, with the control units 24A - 24C on any other side of the printed circuit board 20 can be attached. In the embodiment according to 2 are these control units 24A - 24C for example, on the back of the printed circuit board 20 arranged. It is also possible to use these control units 24A - 24C on any other side of the printed circuit board 20 to arrange. The printed circuit board 20 is preferably made of a material with good thermal conductivity, for example a substrate made of aluminum or copper.

in the 3A is a plan view of the preferred embodiment of the light source according to the invention with light emitting diodes 2 shown. On the front of the printed circuit board 20 For example, there are a total of eight groups of RGB LED units 22A - 22H as a light source with LEDs 2 arranged, with each RGB LED unit 22A - 24 HOURS is executed with the same structure. As 4 can be taken, has an RGB LED unit 22A For example, a socket (not labeled in the drawing), a mounted on the base red LED (red LED) 30A , a green LED mounted on the base (green LED) 30B and a blue LED mounted on the base (blue LED) 30C on, wherein the anode (positive electrode) and the cathode (negative electrode) of the red LED 30A in each case by lead wires electrically to the terminals 32A . 34A are connected; the anode and the cathode of the green LED 30B are each electrically connected to the terminals by lead wires 32B . 34B connected and the anode and the cathode of the blue LED 30C are each electrically connected to the terminals by lead wires 32C . 34C connected.

In 3B is a bottom view of a preferred embodiment of a light source according to the invention with light emitting diodes 2 shown. On the back of the printed circuit board 20 According to this embodiment, a total of three groups of control units 24A - 24C arranged. The control unit 24A serves to control the driver currents of the eight red LEDs and has eight connection contacts, each connection contact in each case to the anode contact or cathode contact (eg 32A respectively. 34A ) of the red LEDs of the RGB LED units 22A - 22H connected. The control unit 24B is used to control the drive currents of the eight green LEDs and has eight connection contacts, each one the connection contact in each case to the anode contact or cathode contact (eg 32B respectively. 34B ) of the green LEDs of the RGB LED units 22A - 22H connected. The control unit 24C serves to control the driver currents of the eight blue LEDs and has eight connection contacts, each connection contact in each case to the anode contact or cathode contact (eg 32C respectively. 34C ) of the blue LEDs of the RGB LED units 22A - 22H connected. With the above-mentioned versions, the brightness of the red, green and blue LEDs of the total of eight groups of RGB LED units 22A - 22H each by the three groups of control units 24A - 24C optimally adjusted to stably control the color temperature of the light source with LEDs. In the above embodiment, the control units are each connected in series with each corresponding LED. It is also possible that the control units are connected in parallel with each corresponding LED.

It is possible that deviations in properties occur between all manufactured LEDs during manufacturing. In this case, the color temperature of each RGB LED unit changes 22A - 22H even under the same electrical excitation conditions (ie excited with the same drive current). A calibration process can be done after mounting the RGB LED units 22A - 22H are performed by their electrical contacts, wherein the characteristic data in a memory (not shown in the drawing, for example in a programmable read-only memory EEPROM) of the control units 24A - 24C get saved. After switching on the light source with LEDs 2 can the control units 24A - 24C read the characteristic data stored in the memory and thus the red, green and blue LEDs of the RGB LED units 22A - 22H each stimulate improved. In addition, each control unit 24A - 24C be implemented in an integrated control circuit, wherein the integrated control circuit can receive an external command for controlling the excitation condition for each LED. Since the drive current excites each LED according to the characteristic data, a stable color temperature can be obtained for each RGB LED unit 22A - 22H be ensured.

In 5A is a plan view of a preferred second embodiment of the light source according to the invention with light emitting diodes 2 shown. According to this preferred second embodiment, the RGB LED units 22A - 22H replaced by a plurality of two-color LED units, each two-color LED unit having at least one first LED 40A and at least one second LED 40B with a different color than the first LED 40A having. How out 5A The first LED is visible 40A via connection wires electrically to the connection contacts 42A . 44A connected and the second LED 40B is electrically connected via connecting wires to the connection contacts 42B . 44B connected.

In 6 is a bottom view of the preferred second embodiment of the light source according to the invention with light emitting diodes 2 shown. The constructed in this embodiment light source with LEDs 2 has at least two control units 50A . 50B on, with the control unit 50A to the connection contacts 42A . 44A the first LED 40A the two-color LED unit is electrically connected and the control unit 50B to the connection contacts 42B . 44B the second LED 40B the two-color LED unit is electrically connected. Each LED of each two-color LED unit may be operated according to the previously stored characteristic data by means of the control units 50A . 50B be driven. Since the drive current excites each LED according to the characteristic data stored in the memory, a stable color temperature can be obtained for each two-color LED unit 22 be ensured.

In 5B is a plan view of a preferred third embodiment of a light source according to the invention with light emitting diodes 2 shown. According to this preferred embodiment, the RGB LED units 22A - 22H are replaced by a plurality of single-color LED units (not shown in the drawing), each single-color LED unit having at least one LED 46 having. How out 5B The LED is visible 46 via connection wires electrically to the connection contacts 47 . 48 connected. Every LED 46 can be electrically excited by the control unit (not shown in the drawing) in accordance with the characteristic data previously stored in the memory to obtain a stable color temperature for each LED 46 sure.

in view of of the above has the light source according to the invention with LEDs optimal properties, quality deviations to overcome in manufacturing, to generating white Light or light of a different color with stable color temperature to enable.

In summary, a light emitting diode light source according to the invention comprises a printed circuit board having a plurality of side surfaces, a plurality of RGB LED units disposed on a side surface of the printed circuit board each having a red LED, a green LED, and a blue LED, and at least one at each the LEDs in the RGB LED units electrically connected control unit, wherein the control unit controls a drive current of the LED. Each of the RGB LED units emits white light with stable color temperature. The control unit moreover preferably has a memory for storing Driver power data for each LED.

The Names of the parts of the embodiments according to the present invention Invention and the drawings are merely illustrative of the preferred embodiments of the present invention and do not limit the scope of the present invention Invention. It is obvious that the embodiments described above executed in various ways can be without that deviate from the scope of the present invention must, e.g. limited The number of RGB LED units is not limited to just eight. main thing is that the numbers of control units the RGB LED units should correspond to the driver currents of all LEDs used optimally to stimulate electrically. Accordingly, the following claims, which form part of this invention, are deemed to be applicable are, also for all amendments the embodiments.

Claims (30)

Light source with light emitting diodes ( 2 ) comprising a printed circuit board 20 , a plurality of RGB LED units ( 22A - 22H ) and at least one control unit ( 24A - 24C ), characterized in that the printed circuit board ( 20 ) has a plurality of side surfaces; that the majority of RGB LED units ( 22A - 22H ) on a side surface of the printed circuit board ( 20 ) and each RGB LED unit ( 22A - 22H ) a red LED ( 30A ), a green LED ( 30B ) and a blue light emitting diode ( 30C ) having; and that the at least one control unit ( 24A - 24C ) to each LED ( 30A . 30B . 30C ) of the plurality of RGB LED units ( 22A - 22H ) for controlling the drive current of the respective light emitting diode ( 30A . 30B . 30C ) is electrically connected to each RGB LED unit ( 22A - 22H ) can each generate white light with stable color temperature. Light source with light emitting diodes ( 2 ) according to claim 1, characterized in that a cathode and an anode of each light emitting diode ( 30A . 30B . 30C ) each to two connection contacts ( 32A - 32C . 34A - 34C ) are electrically connected and that these connection contacts ( 32A - 32C . 34A - 34C ) to the respective tax units ( 24A - 24C ) are electrically connected. Light source with light emitting diodes ( 2 ) according to claim 1, characterized in that each control unit ( 24A - 24C ) a memory for storing drive current data for each light emitting diode ( 30A . 30B . 30C ) having. Light source with light emitting diodes ( 2 ) according to claim 1, characterized in that the at least one control unit ( 24A - 24C ) is an integrated control circuit. Light source with light emitting diodes ( 2 ) according to claim 1, characterized in that the printed circuit board ( 20 ) is made of a material with good thermal conductivity. Light source with light emitting diodes ( 2 ) according to claim 5, characterized in that the printed circuit board ( 20 ) is made of aluminum. Light source with light emitting diodes ( 2 ) according to claim 5, characterized in that the printed circuit board ( 20 ) is made of copper. Light source with light emitting diodes ( 2 ) according to claim 1, characterized in that it comprises a plurality of control units ( 24A - 24C ) for controlling red, green and blue light emitting diodes ( 30A . 30B . 30C ), wherein the control unit ( 24A ) each to the red light emitting diodes ( 30A ) of the RGB LED units ( 22A - 22H ) is electrically connected, the control unit ( 24B ) each to the green LEDs ( 30B ) of the RGB LED units ( 22A - 22H ) is electrically connected and the control unit ( 24C ) each to the blue light emitting diodes ( 30C ) of the RGB LED units ( 22A - 22H ) is electrically connected. Light source with light emitting diodes ( 2 ) according to claim 8, characterized in that the number of connection contacts of the control units ( 24A - 24C ) for controlling the red, green and blue light-emitting diodes ( 30A . 30B . 30C ) each equal to that of the RGB LED units ( 22A - 22H ). Light source with light emitting diodes ( 2 ) according to claim 8, characterized in that the number of connection contacts of the control units ( 24A - 24C ) for controlling the red, green and blue light-emitting diodes ( 30A . 30B . 30C ) each greater than that of the RGB LED units ( 22A - 22H ). Light source with light emitting diodes ( 2 ) according to claim 1, characterized in that the control units ( 24A - 24C ) each with the corresponding light emitting diode ( 30A . 30B . 30C ) are electrically connected in parallel. Light source with light emitting diodes ( 2 ) according to claim 1, characterized in that the control units ( 24A - 24C ) each with the corresponding light emitting diode ( 30A . 30B . 30C ) are electrically connected in series. Light source with light emitting diodes ( 2 ) according to claim 1, characterized in that each STEU unit ( 24A - 24C ) each having at least three terminal contacts to the respective drive currents of the red, green and blue light emitting diodes ( 30A . 30B . 30C ) to control. Light source with light emitting diodes ( 2 ) comprising a printed circuit board ( 20 ), a plurality of two-color LED units ( 22A - 22H ) and at least one control unit ( 24A - 24B ), characterized in that the printed circuit board ( 20 ) has a plurality of side surfaces; that the majority of two-color LED units ( 22A - 22H ) on a side surface of the printed circuit board ( 20 ) and each two-color LED unit ( 22A - 22H ) a first light emitting diode ( 40A ) with a first color and a second LED ( 40B ) having a second color different from the first color, and in that the at least one control unit ( 24A - 24B ) to each LED ( 40A . 40B ) of the plurality of two-color LED units ( 22A - 22H ) for controlling the drive current of the respective light emitting diode ( 40A . 40B ) is electrically connected so that each two-color LED unit ( 22A - 22H ) each can produce colored light with stable color temperature. Light source with light emitting diodes ( 2 ) according to claim 14, characterized in that a cathode and an anode of each light emitting diode ( 40A . 40B ) each to two connection contacts ( 42A - 42B . 44A - 44B ) are electrically connected and that these connection contacts ( 42A - 42B . 44A - 44B ) to the respective tax units ( 24A - 24B ) are electrically connected. Light source with light emitting diodes ( 2 ) according to claim 14, characterized in that each control unit ( 24A - 24B ) a memory for storing drive current data for each light emitting diode ( 40A . 40B ) having. Light source with light emitting diodes ( 2 ) according to claim 14, characterized in that the at least one control unit ( 24A - 24B ) is an integrated control circuit. Light source with light emitting diodes ( 2 ) according to claim 14, characterized in that the printed circuit board ( 20 ) is made of a material with good thermal conductivity. Light source with light emitting diodes ( 2 ) according to claim 18, characterized in that the printed circuit board ( 20 ) is made of aluminum. Light source with light emitting diodes ( 2 ) according to claim 18, characterized in that the printed circuit board ( 20 ) is made of copper. Light source with light emitting diodes ( 2 ) according to claim 11, characterized in that the control units ( 24A - 24B ) each with the corresponding light emitting diode ( 40A . 40B ) are electrically connected in parallel. Light source with light emitting diodes ( 2 ) according to claim 11, characterized in that the control units ( 24A - 24B ) each with the corresponding light emitting diode ( 40A . 40B ) are electrically connected in series. Light source with light emitting diodes ( 2 ) according to claim 11, characterized in that each control unit ( 24A - 24B ) each having at least two terminal contacts to control the drive currents of the first and second light-emitting diodes can. Light source with light emitting diodes ( 2 ) comprising a printed circuit board ( 20 ), a plurality of single color LED units ( 22A - 22H ) and a control unit ( 24A ), characterized in that the printed circuit board ( 20 ) has a plurality of side surfaces; that the majority of single color LED units ( 22A - 22H ) on a side surface of the printed circuit board ( 20 ) and each single-color LED unit ( 22A - 22H ) a light emitting diode ( 46 ) having; and that the control unit ( 24A ) to each LED ( 46 ) of the plurality of single-color LED units ( 22A - 22H ) for controlling the drive current of the respective light emitting diode ( 46 ) is electrically connected to allow each single-color LED unit ( 22A - 22H ) each can produce colored light with stable color temperature. Light source with light emitting diodes ( 2 ) according to claim 24, characterized in that a cathode and an anode of each light emitting diode ( 46 ) each to two connection contacts ( 47 . 48 ) are electrically connected and that these connection contacts ( 47 . 48 ) each to the control unit ( 24A ) are connected. Light source with light emitting diodes ( 2 ) according to claim 24, characterized in that the control unit ( 24A ) a memory for storing drive current data for each light emitting diode ( 46 ) having. Light source with light emitting diodes ( 2 ) according to claim 24, characterized in that the control unit ( 24A ) is an integrated control circuit. Light source with light emitting diodes ( 2 ) according to claim 24, characterized in that the printed circuit board ( 20 ) is made of a material with good thermal conductivity. Light source with light emitting diodes ( 2 ) according to claim 28, characterized in that the printed circuit board ( 20 ) is made of aluminum. Light source with light emitting diodes ( 2 ) according to claim 28, characterized in that the printed circuit board ( 20 ) is made of copper.