WO2010022588A1 - Flexible neon light - Google Patents

Abstract

A flexible neon light for uniformly emitting light comprises a flexible core (1) for transmitting light, a light emitting assembly arranged in the flexible core (1) and a covering layer (2) diffusing light and covering the outside of the flexible core (1). The light emitting assembly comprises several light emitting bodies (3) connected in series, in parallel or in series-parallel. A light diffusing sheath (4) is provided between the light emitting body (3) and the core (1).

Description

 Uniform light flexible neon light technology field

 The present invention relates to a neon lamp, and more particularly to a uniform flexible neon lamp that allows a neon to illuminate throughout the body. Background technique

 Neon light is a kind of lighting fixture that is filled with low-pressure helium gas in a glass tube and emits light by electronic electric stimulation. Since it relies on gas discharge to illuminate and the gas is evenly distributed within the glass tube, the neon illumination is very continuous and uniform with no viewing angle limitations. With its excellent luminous effect and brilliant color expression, neon lights have always occupied an important position in commercial lighting such as advertising lamps and decorative lights. However, because neon lamps use glass tubes as the main structure, they are fragile, packaging and transportation. Difficulties, once formed, can not be bent and can not be mass produced and other shortcomings.

 Subsequently, a hose lamp was formed, which was constructed with a core wire in the middle, a small hole in the core wire, a bulb placed in the hole, and a coating layer wrapped around the core wire to secure and protect the bulb. Products in the lighting market are also known as "Mei-resistant lamps" or "plastic hose lamps." The hose lamp is automatically extruded by the machine, so the production cost is low, and it is suitable for mass production. Because the flexible plastic is used to make the main structure, the product has the advantages of being able to bend the pattern according to the needs of the site, and also overcomes the neon light. Tube, fragile, difficult to transport and other shortcomings. However, the light source is point-shaped, does not have a continuous and uniform luminous effect of neon lights, and in some cases, it cannot completely replace the role of neon lights.

 In response to the above technical problems, the applicant has previously proposed a patent entitled "A Hose Improvement Structure of a Hose Lamp", Patent No. ZL2004100320665, also known as "Flexible Neon" on the market, which discloses a hose The improved structure of the lamp is provided with an astigmatism layer on the side of the existing lamp of the beautiful lamp. After the light emitted by the bulb is scattered by the astigmatism layer, the surface light source which becomes an elliptical point source is diverged on the surface of the astigmatism layer, and is accurately calculated. The pitch of the bulb and the thickness of the astigmatism layer are set such that the surface of the astigmatism layer emits a plurality of elliptical surface light sources superimposed into an illuminant in which the ray is continuously uniform. The patent solves the problem of light discontinuity of the existing hose lamp to a certain extent, but the structure is complicated and the manufacturing cost is high, and since the hose lamp has only one side illumination, it can only be spliced into a plane figure. , can not build a three-dimensional pattern. Although the Chinese Patent Publication No. CN201078601Y discloses a homogenizing energy-saving flexible neon lamp, which is mounted in the core wire along the axial direction of the core wire, and is provided in the core wire for the LED light axis. The positioning bracket is arranged to maintain proper spacing between the light-emitting diodes. Although the neon lamp of this structure can emit light through the whole body, there are still disadvantages such as the light source being spot-shaped and having no neon continuous and uniform illumination effect during use. . Summary of the invention

1

Confirmation The object of the present invention is to provide a uniform light-emitting neon lamp capable of 360-degree whole body illumination, high light-emitting efficiency, continuous uniform illumination effect, and arbitrarily curved shape in view of the above-mentioned problems and deficiencies.

 The technical solution of the present invention is implemented as follows:

 The uniform light flexible neon lamp of the present invention comprises a light transmissive flexible core wire, a light emitting component disposed in the flexible core wire, and an astigmatism coating layer wrapped around the flexible core wire, wherein the light emitting layer The assembly includes a plurality of illuminators connected in series or in parallel or in series and parallel, and is characterized in that a astigmatism sleeve having astigmatism is disposed between the illuminants and the core.

 The specific structure of the astigmatism sleeve can be set according to different installation requirements of the user. For the purpose of making the invention easier to process and install, the astigmatism sleeve can be an elongated astigmatism device disposed in the flexible core line along the axial direction. And a plurality of lateral holes for accommodating the illuminators are disposed on the astigmatism body, wherein the illuminants are respectively mounted in the lateral holes, and at the same time, in order to fix the positions of the illuminants and prevent the lamp legs from contacting each other. The occurrence of a short-circuit event and the prevention of light-shadowing due to insufficient light in the tail position of the illuminator, wherein the lateral hole is provided with a top portion of the illuminator for positioning the illuminants and guiding the light of the illuminator to The light guiding positioning ribs of the front end of the front illuminator; the astigmatism sleeves may be independent astigmatism sleeves respectively disposed on the illuminants, and the astigmatisms may be mounted on the illuminants in various ways. The astigmatism cover may be pre-made and sleeved on the illuminant, or may be coated on the illuminant by injection molding or integrated with the illuminant. Type. When the astigmatism sleeve is formed as a diffuser, in order to facilitate the electrical connection of the illuminators in the illuminating assembly, a wire trough may be disposed on the side wall of the diffuser. And the combination of the illuminant and the astigmatism sleeve and the flexible core wire can also be various. For example, a lateral hole can be arranged at intervals on the flexible core wire, and the illuminant body with the astigmatism cover is axially mounted along the flexible core wire. In the lateral hole, in order to fix the position of each illuminant and prevent the occurrence of a short-circuit event due to the contact of the lamp legs, the lateral hole of the flexible core wire is provided with positioning ribs for positioning the illuminants, The rear end portion of the small diffuser is correspondingly provided with a positioning groove that can be matched with the positioning rib; or a hollow flexible core wire can be directly used, and the above illuminants are installed at a certain interval after installing the astigmatism cover. Said in the axial through hole. Similarly, in order to fix the positions of the respective light-emitting bodies, to ensure uniform spacing of the respective illuminants and to prevent the occurrence of short-circuit events due to the contact of the lamp legs, a positioning spacer is provided at the interval between the illuminants. In order to prevent the formation of light shadows between the two illuminants, the above-mentioned locating spacer is formed as a light guiding spacer having a light guiding effect.

In order to effectively extend the service life of the above-mentioned light-emitting component, the above-mentioned light-emitting component may further include a finite current resistance, and in order to avoid the occurrence of shadow regions due to the overlap of the current limiting resistor and the illuminant, and to facilitate the installation of the present invention, two of the above-mentioned flexible core wires An axial slot for routing and receiving the current limiting resistor is provided between the illuminators. In order to make the operation of the present invention more convenient and to prevent the main light from blocking the front of the illuminator from affecting the neon light-emitting effect, the axial slot is preferably provided at a side offset from the axis of the flexible core. In order to further facilitate the installation of the present invention, the core wire is provided with an axial slit groove, and the illuminator is installed in the core wire through the axial slit groove after the astigmatism sleeve is set, and the current limiting resistor and the illuminating light are arranged. Body lamp foot A connecting wire is placed in the axial slot through the axial slit groove.

 In order to further enhance the astigmatism effect of the present invention so that the light of the present invention is more uniform during use, the above flexible core wire can be made into an astigmatism layer having an astigmatism effect in which an astigmatism medium is mixed.

 The invention adopts a structure in which a astigmatism sleeve with astigmatism is disposed between each illuminant and a core wire in a core wire of a lamp body coated with an astigmatism coating layer, so that the light emitted by each illuminant is diffused to the periphery by the astigmatism sleeve. After that, the astigmatism coating diffuses and mixes light to scatter into the three-dimensional space, so that the lamp body can not only achieve 360° whole body illumination, but also has high light extraction efficiency, continuous and uniform illumination effect, simple structure and low production cost. The arbitrary bending shape effectively solves the problems that the existing glass tube neon light is fragile, the packaging transportation is difficult, the bending is difficult, and the existing hose lamp is either a point light source or a single side continuous uniform illumination. And because the astigmatism sleeve of the present invention is formed by an independent diffuser that can be respectively placed on each illuminant or formed by an elongated astigmatism sleeve on which a plurality of illuminants can be accommodated, The user needs to install in different places, and at the same time, it is convenient to install the shape. The present invention also employs a structure in which an illuminant or/and a connecting wire through which a astigmatism sleeve can be placed, and an axial kerf slot through which the current limiting resistor is placed in the core wire is disposed on the core wire, so that the present invention Installation is more convenient and simple. Since the present invention also adopts the astigmatism layer structure in which the core wire is mixed with the astigmatism medium, it further ensures uniform and continuous illuminating of the whole body, and further improves the light-emitting brightness thereof. The invention can be widely applied to various decorative such as space suspension or three-dimensional pattern modeling.

 The invention will now be further described with reference to the accompanying drawings. DRAWINGS

 1 is a schematic structural view of Embodiment 1 of the present invention;

 2 is a schematic structural view of the astigmatism sleeve of FIG. 1;

 Figure 3 is a schematic longitudinal sectional view of Figure 1;

 Figure 4 is a schematic cross-sectional view of Figure 1;

 Figure 5 is a schematic structural view of Embodiment II of the present invention;

 Figure 6 is a schematic cross-sectional view of Figure 5;

 Figure 7 is a schematic view showing the connection structure of the two long strips of astigmatism sleeves in Figure 1

 Figure 8 is a schematic structural view of Embodiment III of the present invention;

 Figure 9 is a schematic longitudinal sectional view of Figure 8;

 Figure 10 is a schematic cross-sectional view of Figure 8;

 Figure 11 is a schematic structural view of Embodiment IV of the present invention;

 Figure 12 is a schematic structural view of Embodiment V of the present invention;

Figure 13 is a schematic structural view of Embodiment W of the present invention; Figure 14 is a schematic structural view of an embodiment Vfl of the present invention;

 Figure 15 is a schematic view showing the assembly of the illuminant and the small astigmatism in Figure 13;

 Figure 16 is a schematic view showing the assembly of the illuminator and the small diffuser in Figure 14. detailed description

As shown in FIG. 1 to FIG. 16 , the homo-optic flexible neon lamp of the present invention comprises a light-transmissive flexible core 1 , a light-emitting component mounted in the flexible core 1 , and a flexible core 1 The outer astigmatism coating layer 2, wherein the illuminating component comprises a plurality of illuminants 3 connected in series or in parallel or in series and parallel, so that the lamp body of the invention can emit 360 degrees through the body when in use. And the illuminating is uniform and continuous, and a astigmatism sleeve having a uniform light and an astigmatism is disposed between the illuminants 3 and the core wire I, so that the light emitted by each illuminant 3 is diffused to the periphery by the astigmatism sleeve and then passed through the core. The line 1 and the astigmatism cladding layer 2 are three-dimensionally dissipated outward, so that the lamp body can not only achieve 360° whole body illumination, but also has a uniform luminous effect, and has a simple structure and low production cost, and effectively solves the existing glass tube. The neon light is fragile, the packaging and transportation are difficult, the shape is not easy to bend, and the existing hose lamp is either a point source or a single side continuous uniform illumination. The above illuminant 3 can employ a small bulb, and a preferred embodiment thereof is to use a light emitting diode. The specific structure of the astigmatism sleeve can be set according to different installation requirements of the user, as shown in FIG. 1 to FIG. 2, in order to effectively save manufacturing cost and production time and make the installation of the invention more convenient, the astigmatism sleeve can be used as an axial direction. The structure of the elongated diffuser 7 accommodating the plurality of illuminants 3 in the flexible core 1 is arranged. In order to further enhance the reliability of the structure of the present invention, a plurality of lateral holes 71 accommodating the illuminators 3 are disposed on the elongated strips 7 , and the illuminants 3 are respectively mounted on the lateral holes 71 . Inside. In order to facilitate the positioning of the illuminants 3 and prevent the shadow of the tail of the illuminator 3 from being caused by insufficient light, the lateral hole 71 is provided with a light that can be placed at the tail of the illuminator 3 for the front end of the illuminator 3. Guided to the tail of the front illuminator 3 and the light guiding rib 72 for fixing the illuminant 3 described above. Preferably, the positioning ribs 72 are caught between the two lamp legs of each of the illuminants 3. Of course, a plurality of vertical holes for accommodating the illuminators 3 may be disposed on the elongated strips 7 , and the illuminators 3 may be vertically inserted into the vertical holes. When the illuminant 3 is vertically inserted in the vertical hole, the illuminant 3 generally adopts a light-emitting diode that is uniformly recessed toward the periphery and uniformly emits light. Further, the elongated strip-shaped diffuser 7 may be provided with a hollow tubular body structure having an axial through hole, and the illuminant 3 is axially disposed in the axial hole. In order to effectively extend the service life of the above-mentioned light-emitting component, the light-emitting component may further include a current limiting resistor 5, in order to avoid the occurrence of a shadow region due to the overlap of the current limiting resistor 5 and the illuminant 3, to improve the light-emitting efficiency of the lamp body, the above-mentioned lateral holes An axial groove 73 for routing and receiving the current limiting resistor 5 is provided between the 71 or the vertical holes. In order to further facilitate the mounting and to make the light emission of the lamp body more continuous and uniform, the axial groove 73 is preferably disposed at a side away from the axis of the elongated light diffusing body 7. When the flexible core wire 1 is made of a pre-made core wire, in order to facilitate the installation of the present invention, the core wire 1 is provided with an axial slit groove 14 which passes through the illuminant 3 after installation. The axial slit groove 14 is placed in the above-mentioned flexible core wire 1. A main conductor 8 is mounted in the lamp body, and the main conductor 8 is The first embodiment is arranged in two ways. The first embodiment is shown in Figure 1-4. The main conductor 8 is disposed on both sides of the core wire 1. The illuminant 3 is connected in series and then connected in parallel to the main conductor 8. The core wire 1 can be pre-wired. After the preparation, the long strips of astigmatism sleeve 7 are placed in the core wire 1 through the axial slit groove 14, and finally the astigmatism coating layer 2 is coated. The second way is as shown in FIG. 5 to FIG. 6. The main line 8 is disposed on both sides of the preset astigmatism sleeve 7, and the illuminants are connected in series and then connected in parallel to the main line 7, and the core line 1 can be pre-made. Then, the long strip astigmatism sleeve 7 is placed into the core wire 1 through the axial slit groove 14; the long astigmatism sleeve 7 on which the illuminant 3 is mounted can also be placed in a preset mold and directly extruded to form The core wire 1 is then coated with the astigmatism cladding layer 2. In order to further improve the processing efficiency, the long strip astigmatism sleeve 7 can be directly formed by using a prefabricated mold. As shown in FIG. 7, each of the long strips of astigmatism sleeves 7 that are processed and fabricated is electrically connected by wires 17. Or by means of male and female plugs, and then by gel bonding or by connecting the connected long strips of astigmatism sleeve 7 into a preset mold for direct injection molding and the like. As shown in FIGS. 8-16, the astigmatism sleeve may be an independent diffuser 4 attached to each of the illuminants 3 described above. The illuminating cover 4 may be mounted on the illuminant in various manners. For example, the astigmatism cover 4 may be pre-made and sleeved on the illuminant 3, or may be coated on the illuminant by injection molding. 3 is either formed integrally with the above-mentioned illuminator 3, and the like. When the astigmatism cover 4 is configured to cover the illuminator 3, the astigmatism cover 4 may be a horizontal cover body having an axial through hole 43 therein, and the illuminant 3 is mounted along the axial direction of the flexible core wire 1. In the through hole 43; the astigmatism cover 4 may also be a horizontal cover body having a longitudinal blind hole 43. The illuminant 3 is vertically inserted vertically in the blind hole 43 along the axis of the vertical flexible core 1 and many more. When the vertical insertion mode is adopted, the illuminant 3 preferably adopts a light-emitting diode which is concave at the top and uniformly emits light to the periphery. In order to facilitate the electrical connection of the illuminators 3 in the illuminating assembly, a wire slot 41 may be disposed on the side wall of the diffuser 4, and the leg connecting wires of the illuminants 3 pass through the wire chute 41 and An illuminant 3 is connected to form a light string. The illuminant 3 and the astigmatism sleeve and the flexible core 1 can be combined in various manners. As shown in FIG. 8, a plurality of lateral holes 1 1 can be arranged on the flexible core 1 at a certain interval. Each of the illuminants 3 and the diffuser 4 is mounted in the lateral hole 11. At the same time, in order to fix the position of each of the illuminants 3 and prevent the occurrence of a short-circuit event due to the contact of the illuminants 3 with each other, and prevent the shadow of the tail portion of the illuminator 3 from being caused by insufficient light, the transverse hole 1 1 of the flexible core 1 is The light guide positioning rib 12 is disposed at the tail of the illuminator 3 for guiding the light at the front end of the rear illuminator 3 to the tail portion of the front illuminator 3 and fixing the position of the illuminant 3 in the flexible core line I. The rear end portion of the astigmatism cover 4 is correspondingly provided with a positioning groove 42 that can match the light guiding positioning rib 12. In order to effectively extend the service life of the above-mentioned light-emitting component, the current limiting resistor 5 may be connected in series in the above-mentioned light string, and in order to avoid the occurrence of shadow regions due to the overlap of the current limiting resistor 5 and the illuminant 3, the light-emitting efficiency of the lamp body is improved and further For easy installation, an axial slot 13 for routing and receiving the current limiting resistor 5 is disposed between the transverse holes 1 1 on the flexible core 1 . In order to make it easier to install and prevent the choke resistor 5 from blocking the main light of the axially disposed illuminator 3, the axial slot 13 is disposed at a side deviating from the axis of the flexible core 1 . Moreover, since the current limiting resistor 5 is separately placed in the axial slot 13, it is also avoided that the lifetime of the illuminant 3 and the current limiting resistor 5 is too high to shorten the service life of each other. The event occurs, thereby extending the life of the lamp body as a whole. In order to make the installation of the present invention more convenient, the flexible core wire 1 is provided with an axial slit groove 14 communicating with the axial slot 13 through the shaft, and the current limiting resistor 5 and the light body connecting wire 9 of the illuminator 3 pass through the shaft. The slit groove 14 is placed in the axial groove 13. As shown in FIG. 11 to FIG. 14, the present invention can also provide an axial through hole 15 in the flexible core wire 1, that is, a hollow flexible core wire is used, and each of the above-mentioned illuminants 3 is mounted on the astigmatism cover 4 device. Inside the flexible core wire 1. Further, the number of rows of the illuminants 3 mounted in the flexible core 1 can be arbitrarily set according to the use, and as shown in FIGS. 11 to 12, only one column can be installed in the axial through hole 15 of the flexible core 1. The illuminant 3; as shown in FIG. 13, two illuminants 3 corresponding to or offset from the axis of the flexible core 1 may be mounted in the axial through hole 15, and the two rows of illuminators 3 emit light. As shown in FIG. 14 , three rows of illuminants 3 disposed around the axis of the flexible core 1 are mounted in the axial through hole 15 , and the three rows of illuminators 3 are correspondingly disposed, and the three rows of illuminators 3 are disposed. The angle of the optical axis is 120 degrees. In order to further enhance the structural reliability of the present invention, the outer insulating layer 31 is provided at the junction of the lamp leg and the electric wire of the above-mentioned illuminator 3. In order to fix the position of each of the illuminants 3, to ensure uniform spacing between the illuminants 3 and to prevent the occurrence of short-circuit events due to the contact of the lamp legs, the lateral spacers between the adjacent illuminators 3 are provided with positioning spacers 6, The positioning spacer 6 is provided with a wire hole 61 through which the connecting wire passes. In order to prevent light shadowing between the two illuminants 3 due to insufficient light, a preferred embodiment of the above-described positioning spacer 6 is a light guiding spacer made of a material in which an astigmatism medium is mixed. Further, the lateral distance L between the adjacent illuminants 3 and the distance H from the illuminant 3 to the outer surface of the cladding 2 satisfy a proportional relationship in which the neon luminance is continuously uniform. In order to make the lamp body emit light more uniformly, the distance L between adjacent two lateral illuminants 3 in the lamp body is 8-20 mm, and the distance H between the illuminant 3 and the outer surface of the cladding layer 2 is 4-1 lmm. In order to make the light-emitting effect of the lamp body more uniform and continuous, the distance L between two adjacent lateral light-emitting bodies 3 in the lamp body is 10-15 mm, and the distance H between the above-mentioned light-emitting body 3 to the outer surface of the cover layer 2 is 7-9 mm. . A preferred embodiment in an embodiment of the invention is L is 12-12.7 mm and H is 8-9 mm. In order to further enhance the astigmatism effect of the present invention so that the light of the present invention is more uniform in use, the above-mentioned flexible core 1 is formed as an astigmatism layer having an astigmatism effect in which an astigmatism medium is mixed. The astigmatism coating layer 2 can be made of a light-transmitting material having a embossing effect or a matte effect; in order to make the astigmatism effect and the processing convenient, the preferred embodiment of the astigmatism coating layer 2 is mixed with the astigmatism medium therein. The material is made of an astigmatism layer. A preferred embodiment of the astigmatism sleeve and the flexible core 1, the astigmatism coating layer is made of a flexible plastic or rubber in which at least one of titanium dioxide, barium titanate or phosphor is mixed. The light of the illuminant 3 is emitted after three times of astigmatism through the astigmatism sleeve and the flexible core 1 and the astigmatism cladding layer 2, and the astigmatism medium is disposed in the materials of the astigmatism sleeve and the astigmatism cladding layer 2 respectively, and the light is in the astigmatism sleeve and After the multiple refracting of the astigmatism material in the astigmatism coating layer, the light-emitting effect of the lamp body can be more uniform and continuous. The invention can be widely applied to various decorative such as space suspension or three-dimensional pattern modeling. '

 The invention has been described above for the convenience of the invention, and various modifications and modifications made by those skilled in the art that are skilled in the art are still within the scope of the invention.

Claims

 A uniform light flexible neon lamp comprising a light transmissive flexible core wire (1), a light emitting component disposed in the flexible core wire (1), and astigmatism wrapped around the flexible core wire (1) a cladding layer (2), wherein the light-emitting component comprises a plurality of illuminants (3) connected in series or in parallel or in series and parallel, characterized in that the illuminants are (3) An astigmatism sleeve with astigmatism is provided between the core wire (1). 2. The uniform light flexible neon lamp according to claim 1, wherein the astigmatism sleeve is disposed in the flexible core wire (1) along the flexible core wire (1) and can accommodate a plurality of illuminants ( 3) Long strip astigmatism (7).  The uniform light-flexible neon lamp according to claim 2, wherein the elongated stripe body (7) is provided with a plurality of lateral holes (71) for accommodating the illuminators (3), and the illuminating The body (3) is laterally mounted within the transverse bore (71).  The uniform light-flexible neon lamp according to claim 2, wherein the elongated strip-shaped diffuser (7) is spaced apart from each other by a plurality of vertical holes for accommodating the illuminators (3), and the illuminators ( 3) Vertically inserted in the vertical hole.  The homo-optic flexible neon lamp according to claim 3 or 4, characterized in that an axial groove for routing and receiving the current limiting resistor (5) is arranged between each of the lateral holes (71) or the vertical holes. (73).  6. The uniform light flexible neon lamp according to claim 3, characterized in that the lateral hole (71) is provided with a top portion of the illuminant (3) for guiding and fixing the illuminant (3). Guide light positioning ribs (72).  The uniform light flexible neon lamp according to claim 2, wherein the flexible core wire (1) is a hollow tubular body, and the flexible core wire (1) is provided with an axially tangential groove (14), An illuminant (3) to which the elongated astigmatism (7) is mounted is placed in the above-mentioned flexible core wire (1) through the axial slit groove (14). The homo-optic flexible neon lamp according to claim 1, characterized in that the astigmatism sleeve is a separate diffuser (4) respectively disposed on each of the illuminants (3). 9. The uniform light flexible neon lamp according to claim 8, wherein the astigmatism cover (4) is a horizontal cover body having an axial through hole (43) therein, and the illuminant (3) is flexible along the above The axial direction of the core wire (1) is placed in the through hole (43). 10. The uniform light flexible neon lamp according to claim 8, wherein the astigmatism cover (4) is a horizontal cover body having a longitudinal blind hole (43), and the illuminant (3) is perpendicular to the above The axial direction of the flexible core wire (1) is placed in the blind hole (43). 11. The uniform light flexible neon lamp according to claim 8, wherein each of the astigmatism masks (4) is coated on the illuminant (3) by injection molding or formed integrally with the illuminant (3). The overall structure.  The uniform light flexible neon lamp according to claim 8, wherein the side wall of the astigmatism cover (4) is provided with a wire groove (41), and the lamp foot connecting line of the illuminant (3) is The wireway (41) passes through and is connected to another illuminator (3) to form a light string. 13. The uniform light flexible neon lamp according to claim 8 or 9 or 10 or 11 or 12, characterized in that the flexible core wire (1) is provided with a plurality of transverse holes (11) spaced apart, and the above-mentioned sleeve is provided with a diffuser The illuminant (3) of (4) is mounted in the lateral hole (11).  14. The homo-optic flexible neon lamp according to claim 13, characterized in that the transverse hole (11) of the flexible core wire (1) is provided with a top portion of the illuminating body (3) for guiding and fixing The light guiding positioning rib (12) of the illuminant (3) is correspondingly provided with a positioning groove (42) matched with the light guiding positioning rib (12).  The homo-optic flexible neon lamp according to claim 13, characterized in that an axial slot (13) for routing and receiving the current limiting resistor (5) is disposed between each of the lateral holes (11).  The uniform light flexible neon lamp according to claim 14, wherein said axial slot (13) is disposed between said lateral holes (Π) and offset from a side of said flexible core (1) axis. .  The uniform light flexible neon lamp according to claim 15, wherein the flexible core wire (1) is provided with an axial slit groove (14) communicating with the axial slot (13), and the current limiting resistor (5) and the above-mentioned illuminant (3) lamp pin connection line (9) is placed in the axial slot (13) through the axial kerf slot (14).  18. A homo-optic flexible neon lamp according to claim 8 or 9 or 10 or 11 or 12, characterized in that said flexible core wire (1) is coated on said sleeve with a diffuser (4) by extrusion molding The cladding structure on the illuminant (3).  19. A homo-optic flexible neon lamp according to claim 8 or 9 or 10 or 11 or 12, characterized in that said flexible core wire (1) is a hollow tubular body, and said flexible core wire (1) is provided with an axial direction The kerchief (14), the illuminant (3) on which the astigmatism mask (4) is placed is placed in the flexible core wire (1) through the axial kerf slot (14). The uniform light flexible neon lamp according to claim 19, characterized in that the flexible core wire (1) is mounted with two rows of illuminants (3) corresponding to the axis of the flexible core wire (1). And the two columns of illuminants (3) The direction of light emission is opposite. The outer insulating layer (31) is provided at the junction of the lamp base and the electric wire of the above-mentioned illuminant (3). 21. The uniform light flexible neon lamp according to claim 19, characterized in that said flexible core wire (1) The illuminant (3) is arranged in three rows around the axis of the flexible core wire (1), and the three rows of illuminants (3) are correspondingly arranged, and the optical axis of the three rows of illuminants (3) is 120 degrees. An outer insulating layer (31) is disposed at a junction of the lamp leg and the electric wire of the illuminant (3). The uniform light flexible neon lamp according to claim 19, wherein a positioning spacer (6) is disposed at a lateral interval between each of the adjacent illuminants (3), and the positioning spacer (6) is disposed There is a wire hole (61) through which the connecting wires can pass. 23. A homo-optic flexible neon lamp according to claim 22, wherein said positioning spacer (6) is a light guiding spacer made of a material in which an astigmatism medium is mixed. 24. The uniform light flexible neon lamp according to claim 1, characterized in that the lateral distance (L) of the adjacent illuminants (3) and the distance from the illuminant (3) to the outer surface of the package (2) (H) The ratio between the two makes the neon light travel evenly proportional.  The homo-optic flexible neon lamp according to claim 24, characterized in that the distance (L) between the adjacent two lateral illuminators (3) is 8-20 mm, and the illuminant (3) to the cladding layer ( 2) The distance (H) of the outer surface is 4-15 nm. The homo-optic flexible neon lamp according to claim 25, characterized in that the distance (L) between the adjacent two lateral illuminators (3) is 10-15 mm, and the illuminant (3) to the cladding layer ( 2) The distance (H) of the outer surface is 7-9 mm. The homo-optic flexible neon lamp according to claim 1, characterized in that the flexible core wire (1) is an astigmatism layer having an astigmatism effect made of a material in which an astigmatism medium is mixed.  The homo-optic flexible neon lamp according to claim 1 or 27, wherein the astigmatism cladding layer (2) is an astigmatism layer made of a material in which an astigmatism medium is mixed. The homo-optic flexible neon lamp according to claim 28, characterized in that the astigmatism sleeve and the flexible core wire (1) and the astigmatism coating layer (2) are mixed with at least titanium dioxide, barium titanate or phosphor. One of the flexible plastic or rubber.