KR100381672B1 - Electronic-controlled fireworks lamp assembly and method of manufacturing the same - Google Patents

Abstract

TECHNICAL FIELD The present invention relates to a lamp assembly, and more particularly, to a lamp assembly and a method for manufacturing the same to simulate the explosion of a flower fire. The lamp assembly includes a release framework, a support ball, a spinning lever and a controller. The release framework is connected to the spinning lever through the support ball. The radiation lever to which the explosion lamp and the flash lamp are attached is bent into a shape sufficient to produce the effect of the flower explosion. The controller is connected with an ignition lamp, an explosion lamp and a flash lamp. Dedicated lamp assemblies can effectively simulate the explosion of a flower fire controlled by an electronic control system.

Description

ELECTRONIC-CONTROLLED FLOWER LAMP ASSEMBLY AND MANUFACTURING METHOD THEREOF {ELECTRONIC-CONTROLLED FIREWORKS LAMP ASSEMBLY AND METHOD OF MANUFACTURING THE SAME}

The present invention relates to a lamp assembly, and more particularly to a lamp assembly and a method for manufacturing the same that can simulate the explosion process of the flower fire.

Conventional flower flames are cardboard cylinders filled with gunpowder and oxidant that fly through the air and ignite to produce a multicolored flame. However, conventional flames have various problems such as high manufacturing costs, pollution of the environment, damage to life, even fire, and high probability of explosion and combustion during manufacture and transportation. As a result, many towns are forbidden to use flower lights, so the frenzied atmosphere of the festival is greatly reduced. There is a need for a flower fire that exhibits the same effects as a conventional flower fire, but which eliminates the above problems.

It is an object of the present invention to supply an electronically controlled flower lamp lamp assembly and a method of manufacturing the same that can simulate the entire explosive process of a conventional powder fire flower to replace the conventional powder fire flower.

1 is a schematic diagram of a structure according to a first embodiment of the present invention;

2 is a schematic view of the spinning lever structure according to the first embodiment of the present invention;

3 is a schematic diagram of a structure according to a second embodiment of the present invention;

4 is a schematic view of a spinning lever structure according to a second embodiment of the present invention.

5 is a schematic diagram of an integrated chip in accordance with the present invention.

6 is an electrical circuit diagram according to a first embodiment of the present invention.

7 is an electric circuit diagram according to a second embodiment of the present invention.

The object of the present invention is achieved by an electronically controlled flame lamp assembly comprising an emitting framework, a supporting ball, a radiating lever and a controller.

The release framework is connected to the spinning lever via a support ball, which is bent in a shape such as to exhibit the effect of a flower explosion. An explosion lamp and a flashing lamp are attached to the radiation lever. The controller is connected to a firing lamp, an explosion lamp and a flash lamp. Alternatively, the radiation lever may be a straight lever to which an explosion lamp and a flash lamp are attached. The release framework consists of a metal tube or metal support to which the ignition lamp is attached. The support ball is a spherical metal support having a plurality of mounting holes therein. The explosion lamp is disposed on at least three spherical layers radially outwardly from the center of the support ball. The spinning lever is connected to the support ball by inserting directly into the hole of the support ball. The manufacturing method of the electronically controlled flower lamp lamp assembly is as follows: The ignition lamp consists of colored tubes made of high-strength rigid plastics; several rows of illuminators are provided inside the colored tubes, the extension of which is guided to the outside. Both ends of the colored tubes are sealed with adhesive; these colored tubes alone can constitute the release framework or can be used in combination with the spinning lever; the emitting framework can be in the form of a block, lever or artistic model. Can be designed, and the emission framework can flash upward or not flash; the framework can also be colored lamps or colored cylinders provided with electrical wiring and controllers; At the center of the explosion, which provides a hole for the lever to pass through; the support ball creates a number of centers of explosion A plurality of positions may be provided on the lock release framework or the spin lever, and controllers within the release framework control these centers, allowing these centers to successfully explode and radiate. The shape of the spinning lever can be curved, straight and combinations thereof, which have different lengths so that they can be combined into various shapes such as spherical and fan shaped. The cross section of the spinning lever can be circular, flat or spherical. The explosion point is continuously exploded outwardly about the support ball, which support ball can be arranged on the spinning lever as well as on the top, middle and bottom of the lamp assembly and used for the second and third spinning. The ignition lamp is made of a rigid polycarbonate ester, the inner surface of which is provided with a refractive stripe. The explosion order of the lamps is that the ignition lamp on the emission framework is ignited from the bottom to the top until the center of the support ball is reached, then the radiation lamp is ignited outward from the center of the support ball, and then the flash lamp Flashes. The explosion operates to form a layer during the whole process, and the explosion cycle ends by the flash lamp finally flashing.

The present invention basically replaces the conventional gunpowder type flower fire by a specially manufactured flower lamp assembly to simulate the explosion process of the conventional flower fire using an electronic control system. Because the present invention is easy to use and operates safely, it can very effectively replace the traditional flower fire and can be used in various cities and provinces for decoration in festivals and important celebrations.

The invention will be described in more detail with reference to examples.

First embodiment

The spinning lever 3 is bent so as to form the shape of the trajectory in which the flower bursts along its length, and is inserted into the individual hole of the support ball 2. In addition, bulbs or tubular lamps of different colors are attached to individual spinning levers and separated into two types of lamps. One is an explosion lamp 5, the other is a flash lamp 6, which are arranged in a regular order. These bulbs or tubular lamps may be arranged to have a variety of specific configurations and may be provided on different spherical layers. The center of these spheres is the support ball. The number of layers composed of the explosion lamps 5 should be at least three. The more layers and the shorter the interval between the layers, the better the continuity of explosion of these lamps, and the more effective the simulation of a conventional flower flame becomes. Lamps of the same sphere (layer) are connected to each other so that the lamps of the above layers continue to ignite outward from the ball center. The flash lamp 6 is on the outer end of the radiation lever 3 and consists of a number of small bulbs and a stroboscope bulb. These flash lamps 6 are separated by two or more lines and controlled by the controller 7 to ignite alternately or simultaneously. The ignition lamp 4 is arranged in several parts on the emission framework and controlled by the controller such that the effect of igniting from the bottom to the top of the emission framework continues to move upward. Lifting of the release framework 1 with a lamp is achieved by assembly. The electronic controller 7 is connected with the ignition lamp 4, the explosion lamp 5 and the flash lamp 6, respectively. Finally, the ignition lamp 4 is ignited from the bottom to the top, and then the explosion lamp 5 is ignited in the order of A → B → C → A + B → A + B + C → B + C → C. During which the ignition lamp 4 remains off, after which the flash lamp 6 is ignited, during which the explosion lamp 5 remains off, and finally the flash lamp 6 is switched off. The ignition lamp 4 is then ignited again, after which the cycle is repeated over and over again.

Second embodiment

According to the present embodiment, the radiation lever 3 has an explosion lamp 5 in which A + A '→ B + B' → C + C '→ A + A' → A + B + B '→ A + B + C It is a linear lever arranged to ignite in the sequence + C '→ B + C + C' → C + C '→ C'. The ignition lamp 4, the explosion lamp 5 and the flash lamp 6 may consist of neon lamps, bulbs, bulb series, molded tubular lamps and strobe scope bulbs. The controller is based on the LM7295BP, a dedicated designed integrated circuit (IC), which is a dual in-line package encapsulated in plastic and manufactured using bi-polar and COMS compatible technologies. It operates at 3-18V and can output a large current enough to directly activate a solid relay. 6 illustrates the pin arrangement of the LM7259BP, where pins 24-27 are programming pins that can lock the output program by connecting to high and low potentials. The LM7259BP has 13 output pins divided into three groups. Referring to the first embodiment, the LM7259BP has the following features.

The first group includes output pins 1-6 for controlling the ignition lamp 4. When electricity is applied, these output pins 1-6 are pulled high in the order 1 → 2 → 3 → 4 → 5 → 6 to directly activate the solid relay so that the ignition lamp 4 is continuously ignited from bottom to top. You can output the level. The ignition speed of the ignition lamp can be changed by the values of RP1 and C1.

The second group includes output pins 7-10 that control the explosion lamp 5. When the ignition lamp 4 is ignited, 7 → 8 → 9 → 10 → 7 → 7 + 8 → 7 + 8 + 9 → 7 + 8 to ignite the explosion lamps 5A, 5B, 5C, and 5D, respectively. High levels are output in the following order: + 9 + 10 → 8 + 9 + 10 → 9 + 10 → 10. The ignition rate of the explosion lamp can be changed by adjusting the value of RP2. The third group includes output pins 11-13 for controlling the flash lamps. After the second group is turned off, the high levels are output in the order of 11 → 12 → 13 → 11 + 12 → 11 + 13 → 12 + 13 → 11 + 12 + 13 to ignite the flash lamp 6 at high speed. The flash frequency can be changed by adjusting the value of RP3.

After the third group has completed one cycle or several cycles, the IC is reset, and the process is repeated in the order of the first group-> second group-> third group.

In a second embodiment, the controller is based on the integrated circuit (IC) LH9855N, which is a double inline package encapsulated in plastic and manufactured using bipolar and COMS compatible technology. Fig. 7 shows the pin arrangement of the LH9855N, where pin 1 of the LH9855N is connected to the positive pole of the power supply, pins 2, 3 and 4 for the oscillation common terminal of the explosion lamp are connected to the oscillation resistor and the oscillation capacitor, and pins 5 to 12 is for the pulse output terminal of the ignition lamp 1-8, pins 14 to 19 are for the pulse output terminal of the ignition lamp 1-6, pin 13 is connected to the negative pole of the power supply, and pins 20, 21, 22 is a common oscillation terminal for the ignition lamp, and pins 23 and 24 are redundant pins.

After electricity is applied, pins 14-19 continuously output high-level pulses to activate the solid relay to ignite the ignition lamp 4, and after the ignition lamp is turned off, pins 5-12 are exploded as shown in FIG. To control the ignition of the lamp 5 + 6 → 7 + 8 → 9 + 10 → 11 + 12 → 5 + 6 → 5 + 7 + 8 → 5 + 7 + 9 + 10 → 5 + 7 + 9 + 11 + 12 → 7 + 9 + 11 + 12 → 9 + 11 + 12 → 11 + 12 → 12 to output high level, pins 5-12 are 5-A, 6- to A-D 'shown in FIG. Corresponding to A ', 7-B, 8-B', 9-C, 10-C ', 11-D, 12-D', respectively.

The control circuit can be configured according to different forms of explosion of the lamp using the prior art to execute the simulation more effectively.

Because the present invention is easy to use and operates safely, it can very effectively replace the traditional flower fire and can be used in various cities and provinces for decoration in festivals and important celebrations.

Claims (11)

Emitting framework, A supporting ball connected to the release framework, A radiating lever connected to the support ball and bent into a shape capable of causing an explosion effect of a flower fire, One or more ignition lamps attached to the emission framework, One or more flash lamps attached to the radiation lever, One or more explosion lamps attached to the spinning lever, and An electronic controller for electronically controlling the ignition sequence of the ignition lamp, the explosion lamp, and the flash lamp Electronic-controlled fireworks lamp assembly comprising an (electronic-controlled fireworks lamp assembly). In claim 1, And the radiation lever is a straight lever to which the explosion lamp and the flash lamp are attached. In claim 1, And said emitting framework is made of a metal tube or metal support to which said ignition lamp is attached. In claim 1, And the support ball is a spherical metal support having a plurality of holes therein. In claim 1, And the explosion lamp is disposed on at least three spherical layers radially outward from the ball center. In claim 1, And the spinneret assembly is connected to the support ball by inserting it directly into the hole of the support ball. The ignition lamp 4 consists of a colored tube made of high strength rigid plastic, A light emitter is provided inside the colored tube, and an extension line thereof is guided out of the colored tube. Both ends of the colored tube is sealed with an adhesive, The colored tubes constitute the emission framework itself, or are used in combination with the spinning lever, The release framework 1 is designed in the shape of a block, lever or artistic model, The emission framework generates no glare upwards or no glare upwards, The emission framework is a colored lamp or colored cylinder provided with electrical wiring and a controller, The support ball 2 is the center of the explosion in which a hole is provided for the radiation lever 3 to pass through, The support balls are provided in a plurality of positions on the release framework or the spinning lever to produce an effect of the explosion in a plurality of positions, A controller controls the explosion locations within the emission framework, allowing these explosion locations to explode and continuously radiate. Method of manufacturing an electronically controlled flower lamp lamp assembly. In claim 7, The shape of the spinning lever is curved, straight and combinations thereof or have different lengths, combined in various shapes such as spherical and fan-shaped, and the cross-sectional area of the lever is circular, planar or a specific spherical shape. Method of manufacturing an electronically controlled flower lamp lamp assembly. In claim 7, Explosions and flashes are centered around the support ball, continuously exploding outward, The support ball is disposed on the top, middle and bottom of the lamp assembly as well as the spinning lever for use in the second and third spinning. Method of manufacturing an electronically controlled flower lamp lamp assembly. In claim 7, Wherein said ignition lamp is made of rigid polycarbonate, and an inner surface of said ignition lamp is provided with a refractive stripe. In claim 7, The explosion of the flower lamp assembly An ignition lamp on the release framework is continuously ignited upwards from the bottom of the support ball towards the center, The radiation lamp is ignited outwardly from the center of the support ball toward both ends of the support ball, after which the flash lamp generates flashes, After the entire cycle continues for several floors, the flash lamp finally generates flashes, ending the explosion cycle. A method of manufacturing an electronically controlled flower lamp lamp assembly.