AT10294U1 - A FLEXIBLE TUBULAR LIGHT SOURCE - Google Patents

Description

2 AT010 294U1

The present utility model relates to decorative lighting, and more particularly to an improved flexible tubular light source for simulating neon light having continuous, uniform, colored and soft light.

The available flexible tubular light sources used as lighting have been widely used for garden architecture, commercial advertising and backyard decorations, etc. The advantages of the flexible tubular light sources are that the flexible tubular light sources are produced by automatic production, have low manufacturing cost, can be easily bent when used, connected and cut to extend the length and shorten, are durable in terms of punches, are safe and reliable and can be designed as a decoration pattern according to the requirements of the customer. The decorative effects of the flexible tubular light sources are wonderful and changeable. However, the disadvantages of such flexible tubular light sources are apparent, which include discontinuous illumination, no uniform light rays, not the neon light effect. The reason why the flexible tubular light sources can not function as continuously and uniformly as neon light is that the lighting elements inside the flexible tubular light source are a plurality of single point lights, such as mini-bulbs or LEDs, which are separately mounted and arranged.

The reason why neon lights are used as decorative lighting elements is that they have vibrant color, variety in colors, evenly distributed and soft light. The neon lights are therefore often used in doors, signs, billboards, dance clubs, bars, pubs and exterior walls of buildings, etc. However, the bad drawbacks of the neon lights are that the power consumption is high, the voltage is high, the cost is high and the outer glass tube is easily broken, that they are difficult to repair and transport, can not be bent to change the configuration , can not be cut, professional technicians need to install and repair, can not be easily protected and are not sure. Therefore, a search for a light as a replacement for neon light for many years.

For example, someone used to use a flexible tubular light source to replace neon light. A flexible plastic tubular light source (or soft neon light) has been launched. The flexible tubular plastic light source uses light-emitting diodes (LED) as lighting elements to avoid high power consumption, difficulty in maintenance, fragility and high voltage requirements. Because of the improvements, the improved flexible tubular light source is bendable, extendible, and has adaptability to accommodate various required shapes. However, because the interval between the adjacent LEDs is larger, the light emitted from each LED is not continuous, making it impossible for the improved flexible tubular light source to achieve the neon light effect. To solve the problem, a translucent cover is attached to the outer circumference of the flexible tubular light source to fog the light from the LEDs to produce a foggy effect like that of neon light. However, adding the translucent cover to the outer periphery of the flexible tubular light source increases the manufacturing cost. Further, after the addition of the translucent cover, the flexible tubular light source is not bendable and loses its adaptability to deformation.

Another flexible tubular light source made of acrylic resin has been put on the market, which can be bent after being heated and whose light beam is soft and continuous, a perfect replacement for the neon light. But this type of flexible tubular light source is still fragile at room temperature. In addition, this type of flexible tubular light source uses a soft circuit board as the electrical interconnection medium between elements and uses a method to fill in the enclosing material for positioning the elements on the circuit board, which is the 3 AT010 294U1

Manufacturing step and costs dramatically increases.

Referring to Fig. 12, a conventional flexible tubular light source has an elongated plastic core (110), two leads (120, 130), a plurality of longitudinal holes (140), or a plurality of transverse holes (150a, 150b, 150c, 150d, 150e) a plurality of light bulbs (160a, 160b, 160c) and connecting leads (170a, 170b) for connecting each light bulb (160a, 160b, 160c). A transparent cladding layer (180) is then molded outside the core.

When the core of the conventional flexible tubular light source includes the individual light sources in the longitudinal holes and the directions of the individual light sources are aligned along the axis of the core, the conventional flexible tubular light source becomes " horizontal type " called. When the core of the conventional flexible tubular light source includes the individual light sources in the transverse holes and the directions of the individual light sources are perpendicular to the axis of the core, the conventional flexible tubular light source becomes " vertical type " called. U.S. Patent 4,607,317 issued August 19, 1986 discloses an invention known as " non-neon light " referred to as. The invention is the vertical type of flexible tubular light source as described above. It has better safety, packaging, installation, use and maintenance features than any other neon light available. However, the invention can not solve the defect that the light from the point light source is not continuous. That is, this flexible tubular light source still uses the LEDs as the light source without any change to soften the dot-like effect of the LEDs. U.S. Patent 6,186,645 B1, issued February 13, 2001, discloses an invention referred to as a flexible lighting system and mounting arrangement. The invention is a flexible tubular light source of the horizontal type and has the ability to diffuse the light from the LEDs. However, the light from the LEDs is not softened enough and thus still no soft and continuous light is emitted when compared to a neon light in the marketplace. U.S. Patent No. 6,565,251 B2, issued May 20, 2003, discloses an invention referred to as a decorative tubular string of lights. The invention is an improved horizontal type flexible tubular light source and has a core and a cladding outside the core. The core and the mantle may have different shapes, such as circular, rectangular, oval or even wavy. At least one longitudinal space may be defined between the core and the shell so that the at least one longitudinal space can be filled with insulating fluid to enhance light scattering and reflection. Although this flexible tubular light source claims the ability to emit a soft and continuous light effect like that of neon light, there is no well-defined structure that shows how the light is reflected and / or refracted.

The main object of the present utility model is to provide an improved flexible tubular light source with a cladding which diffuses the light of the light emitting diodes to show a soft and continuous light. Furthermore, the improved flexible light source can be connected and cut to extend and shorten the length.

In order to achieve the above object, the flexible tubular light source of the present utility model has the following features:

A core is extruded from a soft material and has two main conduits oppositely received in one side of the core and a plurality of transverse holes formed separately in the other side of the core. 4 AT 010 294 1) 1

Multiple light emitting diodes (LEDs) are connected together by connecting wires and at least one current limiting resistor. The first and last connecting wires are connected to the main lines. The LEDs, the connecting wires and the current limiting resistor are mounted in the respective transverse holes.

A milky and translucent scattering body has a predetermined height and a predetermined width, has the same length as the core and is located at the top of the LEDs to diffuse the light emitted by the LEDs.

A cladding layer is extruded from soft plastic, has the same length as the core and covers the core, the diffuser body and the LEDs. The cladding layer has a curved top surface that covers the LEDs.

The flexible tubular light source of the present utility model further has an LED driver molded with the leads. The LED driver may be an AC / DC converter (AC to DC converter) or an LED current pulse driver.

The scattering body of the present utility model is preferably extruded, has the same length as the cladding layer, is milky and translucent, is made of PVC (polyvinyl chloride), is integrated with the cladding layer, and has a longitudinal hole.

The core of the present utility model has a reverse trapezoidal recess corresponding to the top of the LEDs.

The flexible tubular light source of the present utility model has the effect of uniform and continuous light rays simulating neon light, and can be mass-produced continuously and automatically at a low cost.

The invention will be explained in more detail with reference to the drawings.

Fig. 1 is a perspective view showing the flexible tubular light source of the present utility model;

Fig. 2 is a sectional view taken along the line A-A of Fig. 1, showing the internal structure of the flexible tubular light source of the present utility model;

Fig. 3 is a schematic perspective view showing the formation of a cladding outside the core and the scattering body on the top of the core;

Fig. 4 is a schematic view showing the lighting effect of the flexible tubular light source of the present utility model;

Fig. 5 is a perspective view showing the second embodiment of the flexible tubular light source of the present utility model;

Fig. 6 is a cross-sectional view of the flexible tubular light source taken along line B-B of Fig. 5;

Fig. 7 is a perspective view of the second embodiment of the flexible tubular light source of the present utility model extruded from an extrusion machine;

Fig. 8 is a schematic view showing the lighting effect of the flexible tubular light source of the second embodiment of the present invention;

Fig. 9 is a perspective view showing another embodiment of the flexible tubular light source of the present utility model;

Fig. 10 is a cross section of the flexible tubular light source taken along the line C-C of Fig. 9;

Fig. 11 shows three different structures inside the core of the present utility model;

Fig. 12 is a perspective view of a conventional flexible tubular light source; and 5 AT010 294U1

Fig. 13 is a schematic view showing the use of the flexible tubular light source of the present utility model.

Referring to the drawings, Fig. 1 is a perspective view showing the flexible tubular light source of the present invention, Fig. 2 is a cross section taken along the line AA of Fig. 1, showing the internal structure of the flexible tubular light source of the present utility model, and Figs Fig. 3 is a schematic perspective view showing the formation of a cladding outside the core and the scattering body on the top of the core.

The manufacturing process of the flexible tubular light source according to the present invention will be described below. Two main copper pipes (01a, 01b) pass through the extrusion machine (not shown). The extrusion machine automatically extrudes a core (02). The core (02) is made of soft and opaque plastic, usually made of soft and opaque, white or other colored PVC. The main lines are fixed in the core. The flexible tubular light source may have two, three or four main lines.

The core (02) has a plurality of transverse holes (03a, 03b, 03c, 03d) defined in one side of the core (02) for receiving respective light emitting diodes (LEDs) (04a, 04b) there. The main lines (01a, 01b) are received in the other side of the core (02), opposite the transverse holes (03a, 03b, 03c, 03d). The transverse holes can form one column, two columns or three columns.

As can be seen from Fig. 12, the transverse holes (150a, 150b, 150c, 150d, 150e) and the bulbs (160a, 160b, 160c) are connected to the leads (170a, 170b) of the bulbs between the main leads (120, 130 ) arranged. However, it can be seen from the illustration shown in Figs. 1 and 2 that because the two main lines (01a, 01b) on one side of the core (02) and the transverse holes (03a, 03b, 03c, 03d) on the other side of the core (02), the tensile force on each main pipe (01a, 01b) is equal when the flexible tubular light source is bent, as shown in Fig. 13, so that the difficulty of bending the flexible tubular light source and breakage of the core Main lines (01a, 01b) are avoided.

Due to the low power consumption, low temperature, high brightness and compactness of the LED, the amount of LEDs in the flexible tubular light source of the present utility model is increased, and the distance between adjacent LEDs is shortened without overheating to improve the brightness of the flexible tubular light source. As a result, it is possible that the brightness of the flexible tubular light source exceeds that of neon light. In the preferred embodiment of the present invention, the diameter of the LED is 3 to 5 mm, and the brightness of the LED is about 200 mcd (milli-candela). The distance between adjacent transverse holes is about 1/2 inch.

When the core (02) is formed, the LEDs (04a, 04b) are received in the transverse holes (03a, 03c) in the core (02). A plurality of transverse holes (03b, 03d) are located between adjacent LEDs (04a, 04b) for receiving connection lines (05) or current limiting resistors (06). The connection lines (05) connect the LEDs in series connection. The first connection line (07) and the last line (not shown) of the LED series cord are respectively connected to the main lines (01a, 01b) in the core (02).

When the LED series cord is filled with the core (02), the core (02) having a milky translucent member which is a scattering body (08) passes through a through hole (21) in the extrusion machine (20). With reference to Figure 3, a soft plastic (22), e.g. transparent PVC, extruded and covering the core (02) and the scattering body (08) to form a cladding layer (14) having the same length as the core (02). The cladding layer (14) has a curved top surface and is mounted on top of the diffuser body (08) 6 AT 010 294 U1 and the LEDs (04a, 04b) to simulate the light emitting surface of neon light.

Further, when the core (02) and the scattering body (08) pass through the through hole (21) in the extrusion machine (20), the scattering body (08) must be above the LEDs (04). Therefore, the LEDs (04) should be below the diffuser body (08) and best below the centerline of the diffuser body (08). This is common prior art, and unnecessary details are not described here.

Because the core (02) is made of opaque plastic, the light from the LEDs can not emit through the two sides of the core (02) when the LEDs are mounted in the transverse holes of the core. Therefore, the opaque core can shield the sidelight of the LEDs (04). In this way, the light of the LEDs (04) emits only from the top through the scattering body (08.)

It is known from the teaching that the width and height of the scattering body (08) are related to the brightness and the emission angle of the LEDs. If the LEDs have higher brightness or larger emission angles, the height and width of the scattering body are larger. If the LEDs have lower brightness or smaller emission angles, the height and width of the scattering body are smaller. The larger the width and the height of the scattering body, the weaker the brightness of the tubular light source according to the present utility model, but the point light effect is more removed. The smaller the width and the height of the scattering body, the stronger the brightness of the tubular light source according to the present utility model, but the point light effect is less removed. In a preferred embodiment of the present invention, each LED has a diameter of 3 to 5 mm, a brightness of 200 mcd and an emission angle of 45 °. The distance between the adjacent transverse holes is 1/2 inch. The scattering body (08) has a height (H) of 14 mm and a width (L) of 8 mm as shown in FIG. 2. Referring to Fig. 4, the light emitted from the LEDs is refracted by the cladding layer (14) and is refracted and scattered by the scattering body (08). The edges of the light of adjacent LEDs (04a, 04b, 04c, 04d) overlap to form overlap areas (12). The overlap areas (12) increase the brightness of the edges of the LEDs to almost the same brightness as in the central area of the LEDs. Therefore, the top surface of the LEDs (04), which is the curved upper surface (10) of the cladding layer (14), emits continuous and uniform light like the neon light.

When the cladding layer is formed, the main lines (01a, 01b) are electrically connected to a power supply cable (11). The connecting portion is covered by a plastic sleeve forming a joint (12) as shown in FIG. The ends of the core (02) and the cladding layer (14) are covered by a plastic sleeve which forms a plug (13). This is common prior art, and unnecessary details are not described here.

In order to improve the lighting effect of the present utility model, an LED driver (15) is injection-molded on the power supply cable (11) as shown in FIG. The LED driver can be an AC / DC converter to supply DC to the LEDs to stabilize the light from the LEDs and eliminate LED flicker. The converter usually includes four rectifier diodes or other, more accurate rectifier structures. This is common prior art, and unnecessary details are not described here. The LED driver may be a current pulse driver to provide current pulses to the LEDs to improve LED light efficiency and reduce energy costs. Therefore, the LED provides brighter light when energy costs are the same. Furthermore, the brightness of the flexible tubular light source is improved.

A second embodiment of the present utility model is shown in Figs. 5, 6, and 7, wherein the scattering body is not prefabricated when the LED cord is connected to the core (02).

Claims (7)

7 AT010 294 U1 is filled. The scattering material is integrated into the cladding material by the extrusion machine (16) and extruded as the core (02) passes through the through hole (17) in the extrusion machine (16) forming a scattering body (09) at the top of the core (02) and cladding layers (141) on the bottom and two sides of the core (02). The material (19) used to form the scattering body (09) and the cladding layer (141) is a soft, milky and translucent plastic, especially a soft, milky and translucent PVC. The scattering body (09) at the top of the core (02) has a height (H) of 14 mm and a width (L) of 8 mm. With continued reference to FIG. 8, the light from the LEDs is scattered and refracted by the scattering body (09). The edges of the light of adjacent LEDs (04a, 04b, 04c, 04d) overlap to form overlap areas (121). The overlap areas (12) improve the brightness of the edges of the LEDs to a value almost equal to that in the central area of the LEDs. A third embodiment is shown in Figs. 9 and 10, wherein a passage (091) is defined axially in the scattering body (090) at the top of the core (02) to save material. The scattering body (090) and the cladding layer (141) are integrated and extruded. Since the scattering effect of air within the passage (091) is less than that of the scattering body, the height (H1) and width (L1) of the scattering body (090) at the top of the core (02) should be as shown in Figs 10 disclosed embodiment be greater than the height (H) and the width (L) of the scattering body (09) in the embodiment disclosed in FIGS. 5 and 6. When the size of the passage (091) changes, the height (H1) and the width (L1) of the scattering body (090) should be changed accordingly. Referring to Fig. 11, the core (020) has a reverse trapezoidal recess in the core (020) corresponding to the top of the LEDs (04). The inclined sides of the inverted trapezoidal recesses in the core (020) reflect and focus the light emitted by the LEDs (04). Therefore, the light from the LEDs can be emitted only from the curved top surface (10) capable of emitting a continuous and soft light as well as neon light. The three sectional views, A1-A1, B1-B1, C1-C1, represent the first, second, and third preferred embodiments of the present utility model, respectively. Referring to Fig. 13, the flexible tubular light source of the present utility model is used to generate a neon light with the shape of the word " OPEN " to simulate. In use, the flexible tubular light source is appropriately cut to have a respective length. Then, the clamp (30) is used to firmly secure the sections of the flexible tubular light source to the board (31). It can be observed that from the top surface (10) of the flexible tubular light source, the light is continuous to emit a smooth and continuous illumination effect, which is the same as that emitted by a neon light. Furthermore, because of the simple production process, the manufacturing cost is low and there is no problem in mass production. Claims 1. A flexible tubular light source characterized by: a core (02) extruded from a soft material receiving two main leads (01a, 01b) in one side of the core (02) and a plurality of independently shaped transverse holes (03a, 03b, 03c , 03d) has formed opposite in the other side of the core (02); a plurality of light emitting diodes (LEDs) (04, 04a, 04b) connected together by interconnecting lines (05) and at least one current limiting resistor (06) to form a LED cord, the first and last wires having the main lines (01a, 01b) are connected and the LEDs (04, 04a, 04b), the connecting lines (05) and the current limiting resistor (06) in corresponding transverse holes (03a, 03b, 03c, 03d) attached are; a milky and translucent diffuser (08, 09, 090), which has the same length as the core (02) and is arranged on the upper side of the LEDs (04, 04a, 04b) in order to receive the light emitted by the LEDs (04, 04a, 04b) to scatter emitted light; and a cladding layer (14, 141) extruded from white plastic, which has the same length as the core (02) and the core (02), the diffuser (08, 09, 090) and the LEDs (04, 04a, 04b) and has a curved top surface for coupling out the light of the LEDs (04, 04a, 04b). io Flexible tubular light source according to claim 1, characterized by an LED driver (15), which is injection-molded on a power supply cable (11) is mounted. 3. Flexible tubular light source according to claim 2, characterized in that the LED driver (15) is an AC / DC converter (AC / DC converter). 15 4. Flexible tubular light source according to claim 2, characterized in that the LED driver (15) is an LED current pulse driver. 5. Flexible tubular light source according to claim 1, characterized in that the scattering body (09, 090) and the cladding layer (141) are integrally formed. 6. Flexible tubular light source according to claim 1, characterized in that the scattering body (08, 09, 090) is made milky, translucent and made of PVC (polyvinyl chloride). 25 7. Flexible tubular light source according to claim 5, characterized in that the scattering body (090) has a longitudinal, channel-shaped cavity (091). A flexible tubular light source according to claim 1, characterized in that the core (02) has an inverted trapezoidal recess in the top of the core (02) for converging the light of the LEDs (04, 04a, 04b). For this purpose 13 sheets of drawings 35 40 45 50 55