DE102019119698A1 - Fireworks effect sleeve - Google Patents

Abstract

The present invention relates to a fireworks effect sleeve which has a cylindrical shape with a cylindrical jacket surface (6) which is closed at its ends with a respective closing element (3, 4) in a form-fitting and / or force-fitting manner. According to the present invention, the fireworks effect sleeve has predetermined breaking lines (7) in the cylinder jacket surface (6). Inside the fireworks case there is a decomposing charge. The decomposing charge and the wall thickness of the cylinder jacket surface (6) of the fireworks effect sleeve are matched to one another, especially in the area of the predetermined breaking lines (7) in the cylinder jacket surface, so that the fireworks effect jacket is broken down into individual parts by igniting the decomposing charge, which consist of the two closing elements (3, 4) exist as well as individual parts of the cylindrical surface of the fireworks effect sleeve (6) after their separation along the predetermined breaking lines (7). The individual parts of the cylinder jacket surface (6) of the fireworks effect sleeve have a maximum weight of 100 g after separation along the predetermined breaking lines (7). The weight of each of the two closing elements (3, 4) is less than the maximum weight of the individual parts of the cylinder jacket surface (6) of the fireworks effect sleeve after it has been dismantled along the predetermined breaking lines (7).

Description

The invention relates to a fireworks effect sleeve according to the preamble of claim 1.

Such fireworks effect cases are known as fireworks launch cases, cases or cartridges in various calibers and sizes.

Fireworks effect sleeves are known and usually consist of a cardboard or plastic tube with a plastic lid, sand, plaster of paris or clay and an aluminum ring. This is pressed with the effect charge inside the housing.

There are also completely manufactured cylindrical plastic housings known for filling. These plastic housings have a receptacle for the pre-burner and an attachable cover.

From the DE 83 02 584 U1 a large firework bomb with propellant charge is known. The large fireworks bombette consists of a sleeve closed at one end, in which at least one pyrotechnic effect set is arranged and a propellant charge is arranged at the free end of the sleeve.

From the DE 10 2009 018 727 B4 describes a bombette for the introduction of one or more active bodies. The bombette is formed from a malleable material which consists of one or more parts or segments which at least partially overlap in / at the ends. This allows the bombette to be shaped and is no longer a rigid part. The final shape takes place when it is installed in a cartridge case. After exiting the barrel, the bombette unfolds at its overlaps.

Generic fireworks effect cases are equipped with fragmentation charges for deploying and igniting the effect charge. They usually have a cylindrical shape and are closed with two closing elements at the two ends of the cylinder jacket surface. The decomposition charge and the effect charge are safely enclosed by this closed housing. This ensures that the substances contained in the explosive charges are not released into the environment before they are ignited. In addition, the decomposition charge and the effect charge are sealed against the ingress of substances, especially water. This prevents decomposition and degeneration of the mostly highly reactive explosive charges.

The invention is based on the object of optimizing the ignition of fireworks.

The object is achieved with a fireworks effect sleeve according to claim 1, which has a cylindrical shape with a self-contained cylinder jacket surface which is closed at its ends with a closing element in each case with a positive and / or non-positive fit. According to the invention, the fireworks effect sleeve has predetermined breaking lines in the cylinder jacket surface. Inside the fireworks case there is a decomposing charge. The decomposing charge and the wall thickness of the fireworks effect sleeve - especially in the area of the predetermined breaking lines in the cylinder jacket surface - are coordinated in such a way that the fireworks effect casing is broken down into individual parts by igniting the decomposing charge. These individual parts consist of the two closing elements as well as individual parts of the cylindrical surface of the fireworks effect sleeve after their separation along the predetermined breaking lines. The individual parts of the cylinder jacket surface of the fireworks effect sleeve have a maximum weight of 100 g after separation along the predetermined breaking lines. Furthermore, the weight of each of the two closing elements is below the maximum weight of the individual parts of the cylinder jacket surface of the fireworks effect sleeve after it has been dismantled along the predetermined breaking lines.

The predetermined breaking lines in the cylinder jacket surface of the fireworks effect sleeve are therefore advantageously designed in such a way that the fragmentation charge breaks the effect sleeve down into smaller residues. A predetermined breaking line can be created, for example, by perforating the cylinder jacket surface of the fireworks effect sleeve or by reducing the material thickness of the fireworks effect sleeve. Particularly advantageously, the dismantling by means of the dismantling charge can also include the complete or partial burning of the material of the fireworks effect sleeve, in particular also by the effect charge.

This dismantling is intended to ensure that the residues of the fireworks effect sleeve only fall on the ground as individual parts with a limited weight after the ignition. Also taking into account the height at which the fireworks effect sleeve is ignited and also taking into account the acceleration of the residues caused by the ignition of the decomposing charge, this prevents individual parts from falling to the earth with a large impulse (product of weight and speed). This also takes into account the safety requirements of large fireworks at public events.

In addition to the weight of the individual parts, their shape and the elasticity of the material also play a role. The shape may result in significant air resistance that slows down the corresponding individual part. This reduces the falling speed of the individual part. The The weight of the falling part increases its kinetic energy proportionally, with the kinetic energy of the falling part being converted into work of deformation. In order to avoid damage to property and / or personal injury, it is advantageous if the material is elastic. An individual part made of an elastic material can absorb part of the kinetic energy in its own deformation.

In the case of known fireworks effect sleeves, the closure proves to be particularly problematic. In the known fireworks effect sleeves, this consists for example of clay, clay or plaster of paris. When the decomposing charge is ignited, it can happen that such a closure made of clay, alumina or gypsum is not broken down into smaller residues, but falls in one piece to the earth. The comparatively high weight of the closing elements is problematic.

This is especially true if the closing element is not dismantled sufficiently. For example, it can happen that the decomposing charge is not able to dismantle the closure element due to aging processes, incorrect dosage or incorrect distribution within the fireworks effect sleeve. Another possibility is that the material of the closing element, for example in the event of errors in manufacture or storage, has an increased resistance to being dismantled by the dismantling charge.

It is advantageous to design the closing elements of the fireworks effect sleeve in the shape of a disk. The disc shape increases air resistance and thus advantageously reduces the maximum falling speed.

The maximum weight of each of the closing elements should particularly advantageously not exceed a maximum weight of 100 g. Even if the respective closing element is not dismantled by the decomposing charge, the weight of the closing elements remains limited.

By evenly breaking up the fireworks effect sleeve by the breaking charge, a better effect image can be achieved in a particularly advantageous manner. By igniting the decomposing charge, the effect charge, which is located inside the fireworks effect case, is ignited and distributed in the air. The effect charge provides the visual impression of the fireworks, namely the effect image. A particularly uniform ejection of the effect charge by the decomposing charge creates a spherical or circular overall impression of the effect image.

The ignition of the decomposing charge creates gases inside the fireworks effect sleeve, which break it down after a pressure increase inside the fireworks effect sleeve. When the gas is released, there is a bang. This bang is louder, the higher the pressure in the fireworks effect sleeve increases before it is dismantled. The volume of the bang can advantageously be reduced by facilitating the dismantling of the fireworks effect sleeve through predetermined breaking points and by closing the fireworks effect sleeve by means of the closing elements.

One embodiment of the fireworks effect sleeve according to claim 2 consists in the fact that the closing elements at the ends of the cylinder jacket surface are pressed with the cylinder jacket surface in a force-locking manner by the action of pressure.

The fireworks effect sleeve can be closed particularly advantageously by this pressing. This type of closure is particularly inexpensive. Additional fasteners, such as glue, are not necessarily required. In order to ensure a non-positive closure through the action of pressure, the outer diameter of the closing elements is larger than the inner diameter of the cylindrical surface of the fireworks effect sleeve. Due to the frictional connection of the closing elements, the pressure increase required to apply the effect charge can be achieved by the decomposing charge.

Here, the fastening of the closing elements can advantageously be further improved by additionally gluing them. The non-positive fastening of the closing elements then consists in fastening by means of the action of pressure and additionally in fastening by means of adhesive bonding. The bonding is particularly advantageously improved with this procedure because the effect of the adhesive is improved by the action of pressure.

It is particularly advantageous to use an adhesive that is biodegradable.

In an advantageous embodiment of the fireworks effect sleeve according to claim 3, the predetermined breaking lines of the fireworks effect sleeve are arranged circularly and / or in the radial direction along the cylinder jacket surface.

A particularly uniform dismantling of the fireworks effect sleeve into individual parts is thereby advantageously promoted. The effect pattern of the fireworks effect sleeve can be influenced via the predetermined breaking lines. The pressure resistance of the fireworks effect sleeve is reduced. The bang of the Fireworks become quieter because of the reduction in pressure built up in the fireworks effect sleeve.

In an advantageous embodiment of the fireworks effect sleeve according to claim 4, the closing elements are slipped over the ends of the cylinder jacket surface.

The fireworks effect sleeve is advantageously protected against moisture or mechanical damage, for example, by putting the two sleeves over it during transport.

Another embodiment of the fireworks effect case consists in that a black powder reservoir with a propellant charge is arranged at one end of the fireworks effect case.

The black powder reservoir contains the discharge charge that lets the fireworks effect shell rise. The delay charge or the delay fuse is also ignited, which, after a corresponding delay, when the fireworks effect case reaches the desired height, ignites the decomposing charge.

Fireworks effect shells are usually shot into the sky in mortars by igniting an ejection charge. These mortars can be put together to make batteries. The battery is filled with the discharge charge, for example black powder, and then the fireworks effect case is inserted into the mortar. The assignment of the black powder reservoir to the fireworks effect sleeve advantageously improves the output of the fireworks effect sleeve. The installation of the fireworks at the location of the planned fireworks is simplified, as there is no need to fill it up with black powder and the fireworks effect sleeve can be placed directly in the mortar with the ejector charge. By assigning the black powder reservoir to the fireworks effect sleeve, the height of the fireworks effect sleeve can be better controlled. This enables a more even filling with the discharge charge, which allows the fireworks effect sleeves to rise more evenly. It is also conceivable to use the amount of discharge charge to achieve different heights of rise. In the combination of several fireworks effect sleeves, the desired overall effect images can be achieved by controlling the height of rise by combining the effect images of the individual fireworks effect sleeves in their respective desired height.

A further embodiment of the fireworks effect charge consists in that the material of the cylinder jacket surface and / or the closing element of the fireworks effect charge consists wholly or partly of renewable raw materials.

These raw materials are advantageous for the environment, since they are distributed by the decomposing charge after the fireworks have been ignited and thus mostly remain at the location of the fireworks. It is particularly advantageous if the residues are compostable after ignition and decompose over time. In this case, when the closing elements are glued, it is particularly advantageous for their attachment if this adhesive is also biodegradable.

For example, the material of the cylinder jacket surface of the fireworks effect sleeve and the closing elements can consist of paper or cardboard.

The configuration of the fireworks effect sleeve according to claim 7 provides that at least one of the two closing elements has an opening through which a delay fuse is guided into the interior of the fireworks effect sleeve.

This delay cord serves as a delay charge for delaying the ignition of the decomposing charge after the ignition of the ejection charge. The delay is dimensioned in such a way that the desired effect image is generated in the desired height. The ignition can particularly advantageously take place at the apex of the trajectory of the fireworks effect sleeve.

An exemplary embodiment of the invention is described in more detail below with reference to drawings.

• 1 eine erfindungsgemäße Vorrichtung in Seitenansicht,
• 2 die Vorrichtung aus 1 in zusammengesetzter Form in Seitenansicht.

Show it:

• 1 a device according to the invention in side view,
• 2 the device off 1 in composite form in side view.

1 shows a cylinder surface 6th a fireworks effect pod.

IN the cylinder surface 6th are predetermined breaking lines 7th brought in. These run in a circle around the cylinder surface 6th around and in the radial direction of the cylinder jacket surface 6th .

This cylinder surface 6th is with a finishing element 3 and with a closing element 4th locked.

The final element 4th has an opening for the passage of a delay fuse.

One sleeve 1 is slipped over the fireworks effect sleeve and a sleeve at the lower end 2 is at the top.

The fireworks effect case is filled with the decomposing charge and the effect charge. This is not shown in the drawing.

A gunpowder reservoir 5 is filled with the discharge charge.

2 shows the arrangement in the assembled state.

The sleeve 1 and the sleeve 2 cover the fireworks effect sleeve.

The gunpowder reservoir 5 is attached to the bottom of the fireworks effect sleeve.

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 8302584 U1 [0005]
• DE 102009018727 B4 [0006]

Claims (7)

Fireworks effect sleeve which has a cylindrical shape> with a cylindrical surface (6),> which is closed at its ends with a respective closing element (3, 4) in a form-fitting and / or non-positive manner, characterized in that> the fireworks effect sleeve is in the cylinder surface (6 ) Has predetermined breaking lines (7),> that the fireworks effect sleeve has a decomposing charge in its interior,> the decomposing charge and the wall thickness of the cylinder surface (6) of the fireworks effect sleeve, especially in the area of the breaking lines (7) in the cylinder jacket surface, are matched to one another in such a way that the Fireworks effect sleeve is broken down into individual parts by igniting the decomposing charge, which consist of the two closing elements (3, 4) as well as individual parts of the cylinder surface of the fireworks effect sleeve (6) after their separation along the predetermined breaking lines (7),> whereby the individual parts of the cylinder surface (6) of the Fireworks effect sleeve after parting along the Sun. The breaking lines (7) have a maximum weight of 100 g,> and that the weight of each of the two closing elements (3, 4) does not exceed the maximum weight of the individual parts of the cylindrical surface (6) of the fireworks effect sleeve after it has been dismantled along the predetermined breaking lines (7). Fireworks effect sleeve after Claim 1 , characterized in that the closing elements (3, 4) at the ends of the cylinder jacket surface (6) are press-fitted with the cylinder jacket surface (6) by the action of pressure. Fireworks effect sleeve after Claim 1 or 2 , characterized in that the predetermined breaking lines (7) in the cylinder jacket surface (6) of the fireworks effect sleeve are arranged circularly and / or in the radial direction along the cylinder jacket surface (6). Fireworks effect sleeve according to one of the preceding claims, characterized in that the closing elements (3, 4) are slipped over the ends of the cylinder jacket surface (6). Fireworks effect case according to one of the preceding claims, characterized in that a black powder reservoir (5) with a propellant charge is arranged at one end of the fireworks effect case. Fireworks effect sleeve according to one of the preceding claims, characterized in that the material of the cylinder jacket surface (6) and / or the closing elements (3, 4) of the fireworks effect sleeve consists entirely or partially of renewable raw materials. Fireworks effect sleeve according to one of the preceding claims, characterized in that at least one of the two closing elements (3, 4) has an opening through which a delay fuse is guided into the interior of the fireworks effect sleeve.

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