KR20030087795A - Electric firework apparatus - Google Patents

Abstract

According to the present invention, unlike the conventional explosive fireworks device, when two metal electrodes are contacted and short-circuited, a spark occurs at a contact portion having a relatively high contact resistance, and the tip of the contacted metal melts to form fine droplets by surface tension. It relates to an electric fireworks device, which uses the property of forming and emitting light as the droplets burn for a certain time.

Description

Electric firework apparatus

The present invention relates to an electric fireworks device, when two metal electrodes are contacted and short-circuited, a spark occurs at a contact portion having a relatively high contact resistance, and the ends of the contacted metal are melted to form fine droplets by surface tension. It relates to an electric fireworks device using the property that the droplets emit light while burning for a certain time.

Fireworks have long been used for information transmission signals and chasing down ghosts. Recently, its use is most often used for festivals. Conventional fireworks can be obtained by gunpowder, which has the advantage of being raised and spread widely according to the explosive power of the gunpowder, but the price is high, there is a risk of injury to people, the noise of explosion sound is high, there is a danger of fire, and the smell There are many disadvantages. Therefore, it is not suitable for use in small performances, households, parties, campings, etc. other than for large events outdoors.

The present inventors have solved the problem of the explosive fireworks device and developed a fireworks device that does not use gunpowder so that anyone can easily enjoy the fireworks when they want. When it is difficult to use the explosive fireworks display device, it can be used, for example, for performances such as music and theater, home use, party use, camping use and the like.

1 is an overall configuration of the present invention.

Figure 2a is a detailed view of the contact portion of the blowing fan and the conductive wire.

FIG. 2B is a simplified conceptual diagram of FIG. 2A; FIG.

3A is a shape diagram of a conductive wire.

3B is a shape diagram of a conductive wire.

Figure 4 is an inert gas cylinder for supplying an inert gas to the blower housing.

5A and 5B are detailed configuration diagrams of the conductive wires.

<Description of Drawing>

Blower fan 11, air outlet 13, blower housing 15, conductive wire 17, capstan 19, idle roller 21, power supply 23, 23 ', rotor blade 111, contact Plate 113, inert gas cylinder 29, metal pipes 31 and 31 ', inert gas generator 33 and 33'

<Overall Configuration>

1 is an overall configuration diagram of the present invention. It can be seen that the present invention has the structure of a blower as a whole. Each component is demonstrated.

Blower housing (15) with air outlet (13).

This type of blower is well known in the art to serve to suck the air from the side air inlet to strongly discharge it to the air outlet (13).

-Blower fan (11) rotating in the blower housing (15) and connected to the ground electrode.

1 shows that the rotary shaft of the blower fan 11 is grounded. In the present invention, it is only necessary to connect the ground to the blower fan 11, so that even if the ground is connected to the blower housing 15 surrounding the blower fan 11, the purpose of the present invention can be achieved, but It is more preferable in terms of operational stability to directly ground the rotary shaft bearing of the blower fan 11 in consideration of the spark generated by the bearing of the rotary shaft while the 11 is rotated.

Conductive wire 17 in contact with the rotor blades of the blowing fan 11.

Although the purpose of the present invention can be achieved by simply contacting the conductive wires 17 with the rotary blades of the blower fan 11, in Fig. 1, for convenience of construction, a through hole is made in the blower housing 15 and the housing through the hole. The conductive wire 17 is inserted from the outside to the inside. The conductive wire 17 should be in mechanical contact with the rotary blades of the blower fan 11. Thus, the ground electrode connected to the rotating shaft of the blowing fan 11 should also be connected to the conductive wire 17. The contact mechanism between the blowing fan 11 and the conductive wire 17 will be described later with reference to FIGS. 2A and 2B.

A capstan 19 and idle roller 21 for conveying the conductive wires 17 in contact with the rotary vanes of the blowing fan 11.

Capstan refers to the axis of rotation that feeds while keeping the tape speed of the tape recorder constant. Also in the present invention, the capstan 19 is used to supply the conductive wire 17 into the blower housing 15. Engaged with the capstan 19 is not the drive shaft, but the idle roller 21 for conveying the conductive wire 17 while rotating together by the capstan 19.

A power source 23 or 23 ′ which applies a voltage to the capstan 19.

As the ground electrode is connected to the rotation shaft of the blower fan 11, a voltage is applied to the conductive wire 17 through the capstan 19. As shown in FIG. 1, the power supply mode may be both a DC power source 23 and an AC power source 23 '.

<Contact of blower fan and conductive wire>

2A and 2B are detailed views of a contact portion of the blower fan 11 and the conductive wires 17. The contact plate 113 which connects all the rotary blades 111 of the blowing fan 11 is provided continuously over the circumference of the fan. The width W of the contact plate 113 is about 5 to 10 mm, and the width of the contact plate 113 should be determined in consideration of the contact area with the conductive wire 17 without causing great damage to the air volume due to the rotation of the rotary blade 111. This is because if the contact plate 113 is wider than necessary, the amount of air blown out by the rotation of the fan decreases. In addition, the conductive wire 17 is bent or bent, the contact with the contact plate 113 may be released. The distance D between the contact surface of the contact plate and the wire and the position surface of the capstan 19 and the idler roller 21 is to be as short as possible in order for the conductive wire 17 to directly contact the contact plate 113. ~ 10mm) is good. In the embodiment of the present invention, D = about 5 mm.

On the other hand, the conductive wire 17 supplied into the blower housing 15 by the capstan 19 is always in contact with the contact plate 113. The contact plate 113 is grounded through the rotation shaft of the blower fan 11, and a voltage V is applied to the conductive wire 17 through the capstan 19.

In order to secure a predetermined length or more of the conductive wire 17, it may be manufactured as shown in FIGS. 3A and 3B. Fig. 3A shows the wire wound on a spool, and Fig. 3B shows the conductive wire 17 wound in a spring form, such as soldering solder.

<Operation of the present invention>

Basically, in the present invention, when two metal electrodes are contacted and short-circuited, a spark occurs at a contact portion having a relatively high contact resistance, and the tip of the contacted metal melts to form a fine droplet by surface tension, and the droplet is formed for a certain time. It burns and emits light. It's easy to see how many sparks are generated when working with grinders or welding.

That is, in Fig. 2B, since the contact plate 113 is grounded and a voltage is applied to the conductive wire 17, sparks are generated at the contact point between the contact plate 113 and the conductive wire 17. And the conductive wire is melted at the end of the contact point to form a number of fine droplets in the liquid state. This spark is generated inside the blower housing 15 and the formed liquid droplets are strongly discharged to the atmosphere through the air discharge port 13 by the blower fan 11. The discharged liquid droplets are combusted for a certain period of time to generate a spark.

However, in order to maximize the fireworks effect in the present invention, it is preferable that the liquid metal droplets emit light after being discharged through the air discharge port 13. To this end, in the blower housing 15, combustion of the liquid droplets must be suppressed and the combustion must be delayed so that combustion occurs in the air only after being discharged to the outside of the housing.

To this end, a method of supplying an inert gas into the blower housing 15 by the inert gas cylinder 29 can be employed as shown in FIG. That is, when inert gas is supplied into the blower housing 15, combustion of liquid metal droplets formed in the blower housing 15 is suppressed, and after the droplets are discharged to the air discharge port 13, oxygen in the atmosphere is discharged. As the concentration increases, combustion may occur and shine.

On the other hand, it is more economical than the method of supplying the inert gas by the inert gas cylinder 29, and the conductive wire 17 is made to fill the inert gas generator 33 into the metal pipe 31 as shown in FIG. 5A. There is also a way. This is similar to putting a rosin paste inside the soldering solder. Inert gas generators are known as substances that generate He, carbon dioxide, and the like. On the other hand, as shown in FIG. 5B, it is also possible to produce the conductive wires 17 in such a manner that the inert gas generator 33 'covers the metal core 31'.

When the conductive wire 17 is used, since the concentration of the inert gas generated by the inert gas generator 33 or 33 'is large in the blower housing 15, combustion does not occur even when sparked, but liquid droplets of metal After being discharged into the atmosphere, the concentration of the inert gas gradually diminishes, and combustion occurs by oxygen in the atmosphere, causing a fireworks effect. Here, the time required for the formation of the metal droplets, the discharge from the housing, and the combustion may be very short and almost simultaneously. The larger the air volume of the blower fan 11 will be able to discharge the metal droplets away in a short time.

The conductive wire 17 may be implemented with a metal having a property of passing electricity. For example, iron, copper, aluminum and the like can be used. In addition, it is possible to generate flames of various colors by using a coloring alloy mixed with minerals or chemicals, and when a twisted wire of two or more metals is used, the combustion color of each metal is different due to different properties. As a wire, it can generate sparks of various colors.

According to the present invention, since the spark is generated by electricity rather than gunpowder, the consumables are cheaper than the explosive fireworks device, and are safe and have no noise and smell. In particular, small performances, power cafes, live restaurants, etc. can be more useful than the conventional fireworks display. With the upcoming five-day workweek, the level of play culture will be even higher, and this will drive the momentum and make the weekend break more enjoyable with the popular and practical electric fireworks system.

Claims (13)

Blower housing with air outlet, Blower fan rotating in the blower housing and connected to the ground electrode, Conductive wire in contact with the rotary blades of the blowing fan, Capstans and idle rollers for engaging the conductive wires to be brought into contact with the rotary blades of the blowing fan, An electric fireworks device comprising a power source applied to a conductive wire. The electric fireworks device according to claim 1, wherein the blower fan is grounded. The method according to claim 1, Further comprising a contact plate that is continuously installed over the entire circumference of the blowing fan to connect all the rotor blades of the blowing fan, And the conductive wire is inserted into the outside from the housing through a through hole formed in the blower housing and is in contact with the contact plate. 4. The electric fireworks device of claim 3, wherein the width W of the contact plate is about 5-10 mm. 4. The electric fireworks device according to claim 3, wherein the distance D between the contact surface of the contact plate and the wire and the position surface of the capstan and idler roller is about 2 to 10 mm. The electric fireworks device of claim 1, wherein the power is applied to the conductive wire through a capstan. The electric fireworks device according to any one of claims 1 to 6, wherein the conductive wire is wound around a spool. The electric fireworks device according to any one of claims 1 to 6, wherein the conductive wire is wound in a spring form. The electric fireworks device according to any one of claims 1 to 6, further comprising an inert gas supply cylinder for supplying an inert gas into the blower housing. The electric fireworks device according to any one of claims 1 to 6, wherein the conductive wire is filled with an inert gas generator in a metal tube. The conductive wire according to any one of claims 1 to 6, wherein the conductive wire An electric fireworks display, characterized in that the inert gas generator is coated around the metal core. The electric fireworks device according to any one of claims 1 to 6, wherein the conductive wire is made of a color alloy in which minerals or chemicals are mixed. The electric fireworks device according to any one of claims 1 to 6, wherein the conductive wire is a twisted wire of two or more metals.