RU2353853C1 - Flexible tubular light source with effect of moving flashes - Google Patents

Abstract

FIELD: lighting.

SUBSTANCE: flexible tubular light source with the effect of moving flashes contains a transparent internal cover layer. Internal cover layer is a ribbon-like element, made in the form of flexible transparent plastic by extrusion-type formation. Ribbon-like element has inside the end-to-end lengthwise hole, two copper conductors, passing lengthwise on the side wall of the ribbon-like element and having the same length as the internal cover layer, open gap made lengthwise along the middle line in the lower part of the side wall of he internal cover layer. The flexible, tubular light source also contains several printed-circuit boards, each printed-circuit board is provided with several light-emitting diodes, corresponding to the number of series-connected limiting resistors and integrated microcircuit for controlling light-emitting diode. Each printed-circuit board is supplied with both ends of the connectors. Printed-circuit boards are connected to each other with cables sequentially, printed-circuit board power cables have a parallel connection with the copper conductors, and the signal cables on the printed-circuit board are connected with the controller sequentially. Printed-circuit boards are placed inside the end-to-end hole of the internal cover layer. Transparent external cover layer contains the internal cover layer and several printed-circuit boards; it also has the same length as the internal layer, and is made from flexible plastic by extrusion-type formation.

EFFECT: creation of a flexible tubular source of light with the functions of digital control of the display, providing regeneration of a signal, cascade connection and transmission of a signal without restrictions by distance.

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Description

BACKGROUND OF THE INVENTION

The present invention relates to decorative light sources. In particular, the present invention is a flexible tubular light source with a moving flash effect.

It is known and conventional in the art to use the digital display control function to control a screen, especially a large screen formed by light emitting diodes (LEDs). These devices display various images and signs and display various effects on the screen, including such as movement, catching-up lights and the like, thanks to the control of electrical circuits. However, this can only be used on large screens in which the image is created by scanning in rows and rows. For small screens or linear structures, the effects mentioned cannot be obtained. In this regard, a tubular LED light source was developed in which the screen module is simplified to a linear type and packaged in a translucent rigid tube. However, this type of tubular light source cannot be bent or cut, and the control signal requires a parallel interface, the input / output interface of the main multipoint communication control module has electric levels of transistor-transistor logic circuits (TTL), the signals of which are not suitable for long-distance transmission . In addition, the LED control integrated circuit cannot be used for cascade connection, that is, the signal cannot be transmitted on the same signal cable without restrictions.

The common properties of the screen and tube light source mentioned above are as follows: the on / off and light emission state in each LED emitter, pixel, is controlled by the main multipoint communication module and the integrated LED control chip, so that cascade signal transmission cannot be carried out. Thanks to the rapid development of LED technology, powerful LEDs appeared and new areas of application began to be developed. In order to provide the ability to bend and cut the illuminators, attempts were made to apply the digital display control technique in the field of flexible tubular light sources and to implement cascade connection and regeneration of the control signal.

A flexible LED screen is described in Chinese Patent No. 200320128741.5. In this patent, many elements equipped with LEDs form a flexible screen. However, the cascade connection and regeneration of the control signal are not disclosed in this patent. In fact, cascade connection, regeneration and transmission of a control signal without distance limitation cannot be achieved in accordance with this patent. In addition, the effect of moving flashes also cannot be realized with this patent.

There is a need to receive visual effects from a flexible tubular light source, such as an endless variety of glow patterns. Neither “duralight" with the spark effect, nor flexible neon light sources with uniform, consistent, bright and soft glow effects allow flexible control of light emission, in particular, the effect of successive lights can be obtained in a luminous ribbon using many elements, but the effect of successive lights between different LED emitters, that is, the effect of a moving flash, cannot be achieved. To ensure the effect of a moving flash, the on / off state of each LED emitter must be controlled independently, for this many control circuits would need to be added to a known flexible tube light source, that is, a “duralight” or flexible neon light source, which would entail an increase in size famous flexible light source. Obviously, a flexible light source in this case would lose its decorative function and, accordingly, applicability.

For this reason, there is an unmet market demand for a flexible tubular light source with digital display control with respect to turning on / off each LED emitter, which would create a moving flash effect when the rays of light from the LED emitters run one after another and provide signal regeneration , cascade connection and signal transmission without restriction on distance, and also would allow bending and cutting.

SUMMARY OF THE INVENTION

Taking into account the prior art and its associated limitations, an object of the present invention is to provide a flexible tubular light source with a digital display control with respect to turning on / off each LED emitter, which would create a moving flash effect when light rays from the LED emitters are traveling one after another, and provided signal regeneration, cascade connection and signal transmission without distance limitations, and would also allow bending and cutting.

To solve this problem, the present invention proposed a flexible tubular light source with the effect of a moving flash, containing:

transparent inner layer of the sheath, the inner layer of the sheath is a ribbon-like element made of flexible transparent plastic by extrusion molding, the ribbon-like element has a through longitudinal hole inside, two copper conductors running longitudinally in the side wall of the ribbon-like element and having the same length as the inner a shell layer, an open slit made longitudinally along the midline in the lower part of the side wall of the inner shell layer;

a plurality of printed circuit boards, each printed circuit board is provided with a plurality of LEDs, a corresponding number of terminating resistors connected in series and an integrated LED control chip, each printed circuit board is provided with wires at both ends, the printed circuit boards are connected with each other in series, the power wires of the printed circuit boards are connected in parallel with copper cores, the signal conductors on the printed circuit boards are connected in series with the controller, the signal conductors of the integrated circuit control LEDs are connected in series with the controller; printed circuit boards are located inside the through hole of the inner layer of the shell;

a transparent outer layer of the shell, comprising the inner layer of the shell and many printed circuit boards, the outer layer of the shell has the same length as the inner layer of the shell, and is made of flexible transparent plastic by extrusion molding.

The integrated LED control microcircuit is a microcircuit giving three high-current output signals, allowing a cascade connection and having shift registers and output registers.

The printed circuit board contains the main conductors, the main conductors of two adjacent printed circuit boards are connected to each other in parallel.

The circuit board further comprises capacitors and voltage stabilizing resistors.

The integrated LED control microcircuit is an integrated microcircuit made according to the technology of complementary metal oxide semiconductors (CMOS), which provides low energy consumption and high resistance to noise.

LED is a plane type LED.

LED is a conventional cubic colloidal LED.

LED is a multi-color LED.

Compared with the prior art, the flexible tube light source of the present invention has the following advantages: thanks to the printed circuit boards installed in the flexible tube and the integrated LED control ICs mounted on the printed circuit boards, the ability to control the on / off state of each emitter on the LED and to obtain an effect a moving flash, when the rays of light from the LED emitters run one after another, in addition, a flexible tubular light source is equipped with a central controller, due to which mu may be implemented visual effects such as infinite variety of kinds of luminescence; due to the fact that the integrated LED control microcircuit contains serial shift registers and output registers, signal regeneration, cascade connection and signal transmission without distance limitations are provided; due to the fact that a flexible tube is used to manufacture the light ribbon and each of the power wires of the printed circuit boards are connected in parallel with the copper conductors in the inner layer of the sheath, and the main conductors of two adjacent printed circuit boards are connected to each other in parallel, the flexible tubular light source of the present invention can be bent and can be cut in any place where the power wires of two adjacent printed circuit boards are connected to each other; in addition, the use of a flexible tube makes the flexible tubular light source very convenient for transportation, assembly and decoration. Accordingly, a flexible tubular light source providing a variety of decorative effects can be widely used for decorative lighting and can be freely controlled.

BRIEF DESCRIPTION OF THE DRAWINGS

The structural and functional features of the present invention will be better understood from the following description with reference to the accompanying drawings, illustrating embodiments of the invention. In the drawings:

Figure 1 depicts schematically the appearance of a flexible tubular light source in accordance with the implementation of the present invention;

Figure 2 depicts a schematic perspective view of a flexible tubular light source;

Figure 3 is a detailed view of the plot "A" shown in Figure 2;

4 is a schematic view of the inner layer of the shell;

5 is a view of the design of the connections between the printed circuit boards;

6 is a diagram of the electrical circuits of a flexible tubular light source in accordance with the implementation of the present invention;

7 is a schematic view of a flexible tubular light source in accordance with another embodiment of the present invention;

Fig. 8 is a sectional view of a known light source "duralight";

Fig.9 is a schematic depiction of a flexible tubular light source in use in accordance with the implementation of the present invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

As shown in FIGS. 1, 2 and 3, the flexible tubular light source comprises an inner shell layer 11, printed circuit boards 2 and an outer shell layer 12, a connector 4, a connecting wire 5, a controller 6, a switched power supply 7, and a plug 8 of the connector. The inner shell layer 11 and the outer shell layer 12 form a light source body 1. The inner layer 11 of the shell is a ribbon-like element made of flexible transparent plastic by extrusion molding, the ribbon-like element, as shown in FIG. 4, has a through-hole through the inside. The ribbon-like element contains two copper conductors 13, 14 extending longitudinally in its side wall. Two copper conductors 13, 14 have the same length as the inner layer 11 of the sheath. In addition, the open slot 15 is made longitudinally along the midline in the lower part of the side wall of the inner layer 11 of the shell. As shown in FIG. 5, the printed circuit boards are connected to each other in series, the printed circuit boards thus connected are inserted into the inner layer of the shell through the open slot 15. Each of the printed circuit boards 2 contains a plurality of LED emitters 21, a corresponding number of resistors 22 connected in series limiting electric current, and an integrated circuit 23 for controlling the LED. In this implementation, the base element is formed by three emitters on the LED, three series-connected resistors that limit the electric current, and an integrated microcircuit 23 for controlling the LED emitters. Two or more basic elements can be used to obtain the desired emitter density. Each circuit board has 3 wire busbars at both ends, as shown in FIG. The bus 3 consists of wires 31, 32, 34 and 35, as shown in FIG. 5, where 31 and 35 are the connecting wires of the power supply, 32, 33 and 34 are wires for transmitting signals, a time signal is transmitted via wire 32, by wire 33 the output resolution signal is transmitted, wire 34 - data signal. Printed circuit boards are connected to each other in series by these wires. Printed circuit boards 2 contain the main conductors. The main conductors of two adjacent printed circuit boards are connected to each other by connecting wires 31 and 35 of the power supply so that the main conductors of two adjacent printed circuit boards are connected in parallel. The main conductors connected in parallel by connecting wires 31 and 35 of the power supply are also connected to copper cores 13 and 14 in the inner layer 11 of the shell. As shown in FIGS. 3 and 6, the power supply connecting wire 31 is connected to the copper core 13 by a wire 131, and the power supply connecting wire 35 is connected to the copper core 14 by a wire 141. The signal conductors of the control integrated circuit 23 on each circuit board 2 connected to each other in series with wires 32, 33 and 34 of the signal transmission, are also connected to the controller 6 using the connector 4 and the connecting cable 5. Connector 4 is a multi-pin connector. The connecting cable 5 contains signal wires and power wires. To stabilize the glow of the LED emitter 21 and increase the life of the LEDs, capacitors 25 and a voltage stabilizing resistor 24 can be installed on the printed circuit board. The part of the circuit formed by the voltage stabilizing resistor 24 and the capacitor 25 can perform voltage stabilization and protection functions. All connected printed circuit boards with connecting wires are inserted into the through hole 16 of the inner layer 11 of the shell through the open slot 15 made in the lower part of the side wall of the inner layer 11 of the shell. Finally, the outer layer 12 of the shell is made of flexible transparent plastic by extrusion molding to enclose the inner layer 11 of the shell and the printed circuit boards contained therein. The outer sheath layer 12 has the same length as the inner sheath layer 11 and forms the sheath 1 of the light source.

6 is a circuit diagram of a flexible tubular light source in accordance with an embodiment of the present invention. The LED control integrated circuit 23 may be a chip providing three high-current output signals and allowing cascade connection. This microcircuit includes a serial shift register and an output register, the microcircuit is preferably made according to CMOS technology, which provides low energy consumption and high resistance to noise. The regulated DC power supply is connected to the copper cores 13 and 14 through the power supply 7, so the regulated DC power is supplied to the main conductors of each printed circuit board. After the input signal is fed to the LED integrated control chip of the first printed circuit board, the data signal is fed to the input of the serial shift register, after which the input signal is converted into two output signals. One of the two output signals is 3 bits of the parallel output signal, which, after conversion, is supplied as control currents to the three LEDs of the first printed circuit board. Another output signal is transmitted by the output register to the next circuit. The serial shift register and the output register are controlled by a time signal and operate on the leading edge of its pulse. The control signal is converted by the microcircuit and transmitted to the LED emitters. The control signal converted by the microcircuit is also used as an input signal for the next circuit, where the input signal is regenerated by means of an adjustable DC power supply in parallel with the previous circuit. Then the input signal is transmitted by the integrated control chip to the LED emitter and to the next circuit. During this process, the entire circuit provides amplification, regeneration, and cascade connection of signals, so that the signal can be transmitted arbitrarily far.

The LED emitter may be a flat-type LED, a conventional colloidal cubic-shaped LED, or a multi-color LED. In addition, so that the flexible tubular light source can be mounted bent in a vertical plane, another implementation shown in FIG. 7 can be applied. In this implementation, the printed circuit board 20 is vertical, the LED emitter on the printed circuit board 20 is a conventional cuboid-shaped colloidal LED emitter 201, the two leads of the LED emitter 201 are bent 90 ° upward after the LED emitter 201 is soldered into the printed circuit board 20, so that the LED emitter 201 is directed upward, as shown in FIG. 7, therefore, when bent in a vertical plane, the emitting surface of the LED emitter 201 is turned up.

Fig.8 depicts a cross section of a known device "duralight". The ribbon-like transparent plastic housing 110 is provided with at least two longitudinally laid wires 120 and 130 and has a longitudinal groove 140 or a plurality of side openings 150a, 150b, 150c, 150d and 150e for receiving a plurality of bulbs 160a, 160b and 160c therein and connecting wires 170a and 170b. The bulbs are connected in series and connected to the wires, a transparent plastic case is enclosed in a transparent plastic shell 180.

9 schematically depicts an example of the use of a flexible tubular light source. One or many flexible tubular light sources placed parallel to each other can be used for decoration and give the effect of moving lights. With the parallel arrangement of a large number of flexible tubular light sources 1, as shown in Fig. 9, these flexible tubular light sources can form various images or signs and create the effect of moving lights by controlling the signals of the controller 6, for example, as shown in Fig. 9, the letter “C” is reproduced in parallel with installed flexible tubular light sources.

The flexible tubular light sources of the present invention provide signal regeneration and cascade connection, signal transmission without distance limitations, the visual effect of the movement of lights. A flexible tubular light source provides excellent variety and flexibility of decorative lighting results. A flexible tubular light source can be bent and cut at a PCB junction, where the main conductors are connected in parallel with copper conductors, and can also be expanded by connecting with another flexible tubular light source.

Although the present invention has been described by way of its preferred implementation, a person skilled in the art will appreciate its various changes and modifications that are possible without going beyond the scope of the invention. It should be understood that this invention is not limited to its specific disclosure, but only by the claims.

Claims (8)

1. A flexible tubular light source with the effect of moving flashes, containing a transparent inner layer of the sheath, the inner layer of the sheath is a ribbon-like element made of flexible transparent plastic by extrusion molding, the ribbon-shaped element has a through longitudinal hole inside, two copper conductors running longitudinally in the side the wall of the ribbon-like element and having the same length as the inner layer of the shell, an open slit made longitudinally along the midline in the lower part of the side with shadows of the inner layer of the shell; a plurality of printed circuit boards, each printed circuit board is equipped with a plurality of light emitting diodes, a corresponding number of limiting resistors and an integrated light emitting diode control integrated circuit, each printed circuit board is provided at both ends with wires, the printed circuit boards are connected with each other in series, the power conductors of the printed circuit boards are connected in parallel with copper conductors, signal conductors on printed circuit boards are connected in series with the controller, conductors the signals of the integrated control circuit of the light emitting diodes are connected in series with the controller, the printed circuit boards are located inside the through hole of the inner shell layer; a transparent outer layer of the shell, comprising the inner layer of the shell and many printed circuit boards, the outer layer of the shell has the same length as the inner layer of the shell, and is made of flexible transparent plastic by extrusion molding. 2. The flexible tubular light source with the effect of moving flashes according to claim 1, in which the integrated circuit for controlling light emitting diodes is an integrated circuit giving three high-current output signals, allowing cascade connection and having shift registers and output registers. 3. The flexible tubular light source with the effect of moving flashes according to claim 1, in which the printed circuit board has main conductors, the main conductors of two adjacent printed circuit boards are connected to each other in parallel. 4. The flexible tubular light source with the effect of moving flashes according to claim 1, in which the circuit board further has capacitors and voltage stabilizing resistors. 5. The flexible tubular light source with the effect of moving flashes according to claim 1, wherein the integrated light emitting diode control microcircuit is an integrated microcircuit made by the technology of complementary metal oxide semiconductors, which provides low energy consumption and high noise immunity. 6. The flexible tubular light source with the effect of moving flashes according to claim 1, wherein the light emitting diode is a planar type light emitting diode. 7. The flexible tubular light source with the effect of moving flashes according to claim 1, in which the light emitting diode is a conventional light emitting diode with a colloidal fill of a cubic shape. 8. The flexible tubular light source with the effect of moving flashes according to claim 1, wherein the light emitting diode is a multicolor light emitting diode.

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