Abstract:
Optical fiber decorating lamp characterized by a bundle seat with a seat and a gear made by injection forming so that it can be installed at a partition board without any clip ring or the necessity of gluing the gear. The partition board holds the optical fiber decorating lamp in a small space, and all inner parts and components are hung on it without the height limitation of a support base.

Description:
BACKGROUND OF THE INVENTION 
     Optical fiber decorating lamps have been an excellent night atmosphere decoration for their novel, beautiful, wonderful and variable effects. 
     Generally, optical fibers are made into the form of flowers and leaves by connecting, cutting and coloring them to make an optical fiber decorating lamp which, when lit from its bottom, the profile of the leaves and flowers appear like stars in the sky. If a rotatable color filter driven by a motor is installed between the end of the optical fibers and light source, light of different colors will sparkle continuously or intermittently along the leaves and flowers profile. 
     However, the internal structure of the conventional optical fiber decorating lamp is complicated. Please refer to FIG. 2. The partition board (20) is independent from the support disc (21). The lamp socket partition board (22) and the connecting posts (23), (23&#39;) are installed separately too. Therefore, assembly of these components is difficult and wastes time. It is not economic. Generally, there are a few small heat dissipation holes (21b), (21b&#39;) around the bundle hole (21a) of the support disc (21) and just some hot air can dissipate through them. No cool air is able to enter them. Therefore, cooling is poor. 
     Generally, the conventional optical fiber decorating lamp has a smooth parabolic reflecting mirror (25) behind its light source (24) for concentrating light beams toward ends of the optical fibers. However, such a structure substantially always causes burning, bending, distortion and even melting of the ends of optical fibers and severely affects the light transmission efficiency of the optical fibers. The lighting effect of the optical fiber decorating lamp is thus impaired. 
     In order to preclude dislocation of the bundle seat (26), the conventional optical fiber decorating lamp has its bundle seat attached to a gear (26a). Assembly of this is difficult, and its reliability is low. Normally, two techniques are used: The bundle seat (26) is made with a stop ring (26b) at the end to attach to the gear (26a) after installing from the upper side of the partition board (20) by heat treatment so that the bundle seat (26) is fixed to the partition board (20), please refer to FIG. 3-A. Alternatively, the gear (27c) is formed as an integral part of the bundle seat (27) to stay within a clip ring (27b) on circular groove (27a) by inserting it from the upper side to the lower side of the partition board (20), please refer to FIG. 3-B. These procedures are complicated, and the reliability is low too. Neither of them are desirable. 
     SUMMARY OF THE INVENTION 
     The present invention provides an improved optical fiber decorating lamp structure which is a breakthrough against the limitations and defects of the conventional optical fiber decorating lamp structure, and eliminates complicated assembly procedures, high production cost, etc. of the conventional structure. It provides an optical fiber decorating lamp, of which the heat can be scattered quickly and the repair can be performed easily. 
     The present invention is mainly characterized by an improved bundle seat structure which includes a gear and is formed by injection. The bundle seat can be easily fixed to a partition board and without any clip ring or adhesion between the gear and the bundle seat. It will not dislocate, its assembly is easy, and its reliability is high. 
     The present invention is further characterized by an improved partition board which has the function of a support disc as used in the conventional structure, a bundle seat partition board, and the respective connecting posts. It occupies little space; it can be assembled easily, the internal parts of the optical fiber decorating lamp can be hund on it without being limited by the height of a support block, and the requirement of precise height of attendant connecting posts. 
     The present invention is further characterized by a structure which permits good cooling effect, allows air convection between the atmosphere and the interior space of the block, prevents burning, bending, distortion of the ends of optical fibers after prolonged exposure to a light source, the transmission of light of a given input light intensity at every part of the optical fibers being even. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 illustrates a conventional optical fiber decorating lamp. 
     FIG. 2 is a perspective view of the internal structure of an optical fiber decorating lamp according to the prior art. 
     FIG. 3-A is a schematic illustration of the assembly of a bundle seat for the conventional optical fiber decorating lamp. 
     FIG. 3-B is a schematic illustration of another assembly of a bundle seat for the conventional optical fiber decorating lamp. 
     FIG. 4 is exploded view of the internal structure of an embodiment according to the present invention. 
     FIG. 5 is a partly diagrammatic sectional view of the assembly of the internal structure of an embodiment according to the present invention. 
     FIG. 6 is a schematic illustration of the assembly of the bundle seat according to the present invention. 
     FIG. 7 is a perspective view of an embodiment of a lamp socket according to the present invention. 
     FIG. 8 is a schematic illustration of a partition board and a block according to the present invention. 
    
    
     DETAILED DESCRIPTION 
     As shown in the attached drawings, an improved structure of optical fiber decorating lamp according to the present invention comprises the following: 
     A partition board (1) has a body (1a) with a cylindrical projection (1b) at its center for holding a bundle seat (2), a hole (1c) for holding a color filter shaft (4a), and a plurality of connecting posts (1d), (1d&#39;) beneath the body (1a). A bottom plate (3) is to be fastened with screws (1e), (1e&#39;) beneath the connecting post (1d), (1d&#39;), a light shield (1f), see FIG. 3, beneath the board (1) to cover heat dissipation holes (10a) (FIG. 3) on a block (10). The aforesaid body (1a), a cylindrical projection (1b), hole (1c), connecting posts (1d), (1d&#39;) and the light shield (1f) can be made by a plastic injection forming process. 
     A bundle seat (2) has a body (2a), an end shaped like a gear (2d), and another end in the form of a wedge flange (2b), also a plurality of grooves (2c), (2c&#39;) in the body (2a) at the wedge flange (2b) to ease upward movement of the bundle seat (2) by allowing compressing of the wedge flange (2b) so that the bundle seat (2) can pass through the cylindrical projection (1b) and be moveably connected to the partition board (1). The body (2a), the wedge flange (2b), the grooves (2c), (2c&#39;) and the gear (2d) can also be made by a plastic injection forming process. 
     A bottom plate (3) is connected to the lower side of the connecting posts (1d), (1d&#39;) by means of the screws (1e), (1e&#39;) and has a positioning groove (3a) at its edge for positioning of a lamp socket (7). 
     A rotatable color filter (4) is fixed between the partition board (1) and motor (5), see FIG. 5. The motor (5) comprises a shaft (4a), and at it can be connected a plurality of other parts such as the transparent plastic color disc (4b) with different colors, a pinion (4c), and packings (4d), (4d&#39;). The transparent plastic color disc (4b) has patterns or stripes of different colors, located just beneath the bundle seat (2). The pinion (4c) is to drive the gear (2d) for rotating the bundle seat (2) as well as optical fibers (11) fixed to the bundle seat (2). One of the shaft (4a) is fixed in the hole (1c) of the partition board (1), and the other end is passing through the bottom plate (3) as driven by the motor (5). 
     The motor (5) with a reducing gear is fixed to the bottom plate (3) with an output shaft from the reducing gear (5b) coupled to the motor body (5a) to drive the color filter shaft (4a). 
     A bulb (6) is the light source of the present invention. 
     The lamp socket (7) is located on the connecting post (1d), with a sleeve (7a), see FIG. 7, which, after installation on the connecting post (1d), allows rotation of the lamp socket (7) around the connecting post (1d). It has a socket (7b) which can be bent 90° to facilitate replacement of the bulb (6). A plurality of reflecting mirrors (7d) is arranged in the socket (7b). They are conically different degrees are fixed arranged, or otherwise, in the socket (7b) in order to enhance the sparkling effect of the optical fiber decorating lamp and to minimize heat energy emitting toward the optical fiber (11), and to prevent burning of the optical fiber (11). The sleeve (7a) has a hook or arm (7e) for rotating the lamp socket (7). The hook (7e) has a stop pin (7f) for positioning within the groove (3a) on the bottom plate (3), so as to fix the lamp socket (7) in its normal position. 
     A transformer (8) is also fixed on the bottom plate (3) as a power source for the present invention (FIG. 5). 
     The above components from the inner parts of the present invention. The invention further comprises a housing composed of a cover (9) and a block (10), and a bundle (11) of optical fibers fixed to the bundle seat (2) to form a novel and improved optical fiber decorating lamp. 
     For assembly of the present invention, the partition board (1) and all other components to be fixed to it, is first placed on the recessed rim (10b) on the block (10), an optical fiber bundle (11) in the form of flowers and leaves are fixed to the bundle seat (2), and then the cover (9) is installed to complete the assembly. The heat dissipation holes (10a) on the block (10) covered by the light shielf (1f).