EP1538418A1 - Sealed device for generating flames at events - Google Patents

Abstract

The system has a fuel indication device with a metering jet (6) connected to a hydrocarbon distribution network (3). A lighting device has a pair of electrodes (8) connected to a transformer. The distribution network and the transformer are embedded in an electrically insulated and insoluble resin (11) that is cast in a case (2). Interfaces of the case with the metering jet and the electrodes are made airtight by the resin. An independent claim is also included for a process for production of flames.

Description

The present invention relates to a system for producing flames, in particular for the production of pyrotechnic shows and / or aquatic or the realization of special effects.

More particularly, the present invention relates to a system flames production of great length, able to be immersed for produce flames on a surface of water.

The technical field of the invention is that of the production pyrotechnic effects and shows, as well as the design of devices for achieving such effects.

Currently, in amusement parks and other places where are pyrotechnic shows, the demand is growing for the performing shows combining aquatic and pyrotechnic effects and, in particular, the creation of flames on the surface of the water or associated with splashes of water jets.

We know, to date, different systems for producing flames by surprise on the surface of the water but these systems are not totally satisfactory.

Indeed, these systems use hazardous fuels, which are both explosive, even explosive, and pollutants. In addition, the systems used until now, have a material constitution that is inappropriate for repeated use in wet and / or aquatic environments and their protection against the constraints of such environments are insufficient.

A first known method for creating fire on the surface of the water is to diffuse combustible gas from the bottom of a filled basin of water, the gas bubbles formed by this diffusion being lit as and when as they appear on the surface of the water by a flame night light office.

If it allows to obtain very spectacular flame effects, this process has the disadvantage of having to be activated very gradually to avoid the risk of runaway and explosion of the gas diffused in the water. In addition, the flames obtained are of low height, of the order of 30cm to 1m, which is insufficient to obtain satisfactory effects.

According to a similar principle, the document WO 91/18240 A1 describes a method and apparatus for producing flames on a jet of water, in particular for ornamental fountains or for spectacles aquatic. This process consists in injecting combustible gas by through a tube or several feed tubes arranged at the inside of the nozzle forming the jet of water, the injected gas forming a very a large number of bubbles in said jet of water, an ignition device electric arc or flame being disposed outside the water jet to near its base, so as to ignite the gas bubbles at the exit of the water jet.

Such a flame production process presents a very large dangerous because of the use of fuel gas under pressure, which presents very high risks of explosion.

Finally, we know the production systems of flames with a device using a hydrocarbon jet ignited by an electric arc produced in known manner between two electrodes connected to a generator electric high voltage.

This type of flame production device is not designed for to be immersed and its arc ignition system does not work not properly when it is too close to the water. Indeed, humidity can produce short circuits that can cause the destruction of the electric firing circuit. In addition, static drops of water may form around one or both electrodes and constitute a insulation that prevents the electric arc from forming between these electrodes.

The present invention aims to provide a system of production and projection of flames of great length, that is to say at least 1 m, and up to 30 m, for the production of pyrotechnic be used for making flames on the surface of the water in any safety and without the disadvantages encountered with the devices of art prior.

The object of the invention is in particular to provide a system for producing flames that features a secure ignition system and waterproof and which can be immersed and / or used on the surface of a body of water without risk of deterioration or malfunction.

• un dispositif de projection d'un combustible comportant au moins un gicleur relié à au moins un réseau de distribution d'un combustible liquide sous pression, ledit gicleur étant apte à pulvériser un jet de combustible micronisé pour produire une flamme, de préférence de grande longueur; et
• un dispositif d'allumage comportant au moins une paire d'électrodes reliée à au moins un moyen d'alimentation électrique apte à alimenter au moins une dite paire d'électrodes afin de générer au moins un arc électrique entre au moins deux dites électrodes pour enflammer ledit jet de combustible micronisé, et
• un châssis formé par un boítier à l'intérieur duquel sont installés ledit dispositif de projection et ledit dispositif d'allumage, ledit gicleur et lesdites paires d'électrodes étant placés, au moins partiellement, à l'extérieur dudit boítier pour pouvoir produire une flamme,

   caractérisé en ce que le(s) dit(s) réseau(s) de distribution dudit dispositif de projection et le(s) dit(s) moyen(s) d'alimentation électrique dudit dispositif d'allumage sont noyés dans une résine électriquement isolante et insoluble coulée à l'intérieur dudit boítier de manière à étanchéifier ledit boítier contre l'humidité, les interfaces respectifs dudit boítier avec ledit gicleur et avec lesdites électrodes étant également rendues étanches par ladite résine.The present invention achieves these goals by a sealed and secure flame production system for the show comprising:

• a device for projecting a fuel comprising at least one nozzle connected to at least one distribution network of a pressurized liquid fuel, said nozzle being able to spray a micronized fuel jet to produce a flame, preferably of great length ; and
• an ignition device comprising at least one pair of electrodes connected to at least one electrical supply means capable of supplying at least one said pair of electrodes in order to generate at least one electric arc between at least two said electrodes for igniting said micronized fuel jet, and
• a frame formed by a housing inside which said projection device and said ignition device are installed, said nozzle and said pairs of electrodes being placed, at least partially, outside said housing to be able to produce a flame ,

characterized in that the said distribution network (s) of the said projection device and the said average electrical supply means (s) of the said ignition device are embedded in an electrically resin insulating and insoluble casting inside said housing so as to seal said housing against moisture, the respective interfaces of said housing with said nozzle and with said electrodes also being sealed by said resin.

Such a flame production system has the advantage of being perfectly waterproof thanks to the use of an insulating resin electrically that is poured into the chassis to occupy all the spaces empty spaces inside it, which allows its use in conditions of high humidity or immersion in water. this allows to adapt the system according to the invention to any installation configuration pyrotechnics for the production of flames on the surface of the water or in jets of water.

Electrically insulating resins are well known to humans of art, and therefore a large number of resins can be used to seal the system according to the invention. We will nevertheless prefer fast setting resins, very rigid after solidification, which make the less sensitive system during manipulations.

The system according to the invention can in particular be placed flush with the surface of the water on a floating structure or fixed on it, or to be immersed under the surface of the water, out of public view, and then emerged suddenly using a climbing machine to create flames coming out of the water by surprise.

Preferably, the fuel used is a hydrocarbon isoparaffinic liquid having a flash point greater than 50 °, of preferably greater than 60 °, and which is naturally biodegradable and odorless. Such a hydrocarbon has the advantage of having very few risk of explosion and, moreover, not to be polluting, thus allowing to avoid contaminating the waters and / or soils of the places where flames using the system according to the invention.

According to an advantageous characteristic, said ignition device of The system according to the invention is capable of generating a plurality of electric arcs, preferably at the periphery of said micronised fuel jet sprayed by said nozzle.

For this purpose, said ignition device advantageously comprises minus two pairs of electrodes capable of producing at least two so-called arcs electric. These electrodes, in a manner known to those skilled in the art, comprise an insulating part, for example ceramic, surmounted by a tip conductive tungsten. It is thus possible to improve the ignition of said fuel jet at the time of emission.

In order to further secure the ignition of a flame by at least one electric arc when emitting a fuel jet, it is particularly advantageous, when said ignition device comprises several pairs of electrodes, feeding said pairs of electrodes independently of each other.

This is why, in a preferred embodiment of the invention, said ignition device comprises at least two said means power supply capable of supplying each pair independently electrodes, so as to guarantee the presence of at least one arc at the moment the emission of said fuel jet.

In this way, the ignition problems encountered with the devices known from the prior art. So even if an electrode is faulty or isolated by a drop of water at the moment of the emission of the jet micronized fuel by said first nozzle, it is all from even lit by another electric arc produced between two other electrodes of the ignition system.

More preferably, the distance between the ends of the tips conductive two said electrodes of at least one pair of electrodes is between 0.5 to 1.5 cm, said ends of the tips said electrodes preferably being directed towards the longitudinal axis said first nozzle.

Here, the longitudinal axis of the nozzle means the axis passing through the center of the spray orifice of said nozzle, and directed according to a direction perpendicular to the plane of the surface of the housing in which are fixed said nozzle and said electrodes.

The respect of such a spacing between the ends of the tips of the electrodes is important to respect because this gap determines the possibility forming an electric arc between two electrodes. Moreover, the curvature of said ends towards the axis of the jet allows to ensure the production of an electric arc as close as possible to the jet of fuel when it is emitted by the said jet, and preferably at the periphery of said jet to ignite the latter despite the significant spraying pressure.

In a configuration where the ignition device of the system according to the invention comprises at least two pairs of electrodes, said electrodes are preferably advantageously arranged equidistant from the axis longitudinal of said first nozzle. Said electrodes may in particular delimit a "square" or a "rectangle" whose said jet occupies the center, said ends of the tips of said electrodes being directed towards center and preferably spaced at most 1.5 cm from each other.

For the production of flames of length greater than or equal to 5 m, it is necessary to spray the jet of hydrocarbon under a strong pressure above 20 bar, which sometimes makes the ignition difficult.

The sealed and secure flame production system according to the invention advantageously makes it possible to produce flames of a length between 0.5 and 30 m, preferably at least 5 m, preferably at least 10 m, with a fuel pressure greater than 20 bars.

More particularly, the system according to the invention makes it possible to for an average fuel pressure at said first nozzle 25 bar, flames of between 5 and 10 m in length, and for an average pressure of the order of 100 bars, flames of a length between 8 and 30 m, irrespective of the environment in which which said flames are made, whether on a surface of water or on dry ground.

• la figure 1 est une représentation schématique d'un mode de réalisation préférée du système selon l'invention;
• la figure 2 est une vue de dessus du dispositif d'allumage du système selon l'invention dans un second mode de réalisation préféré.

The constitution and operation of the flame production system according to the invention will emerge more clearly from the following detailed description of the invention, with reference to the appended figures in which:

• Figure 1 is a schematic representation of a preferred embodiment of the system according to the invention;
• Figure 2 is a top view of the ignition device of the system according to the invention in a second preferred embodiment.

With reference, firstly, in FIG. 1, the sealed system and secure production of flames 1 consists essentially of a housing 2 constituting a frame and two main subassemblies, to namely a device for projecting a fuel and a device ignition by electric arc.

The fuel projection device is composed mainly of a first nozzle 6 connected to a fuel distribution network 3 itself connected to a fuel tank not shown in FIG. 1. Said distribution network consists of fuel pipes. 3 ₁ admission of fuel from said tank to a filter 4 adapted to high pressures (of the type used in pressure cleaning systems) via a pump motor also not shown and distribution lines 3 ₂ able to convey the fuel fluid pressurized by said motor pump from the filter 4 to a solenoid valve 5, then to said nozzle 6.

The fuel used for the production of flames with the The system according to the invention is preferably a liquid fuel such as hydrocarbon. The hydrocarbons used can be of any known type in the production of pyrotechnic shows.

However, it is preferred to use an iso-paraffinic hydrocarbon liquid, including ISOPAR® L, produced and distributed by the company ExxonMobil Chemical, with a flash point greater than 60 ° C, therefore not very dangerous with regard to the risks of explosion. Moreover, it is a very volatile hydrocarbon, odorless and naturally biodegradable, which removes the risks of pollution of the soil and water of the places where are realized shows using the device of the invention.

The ignition device of the flame production system 1, in its simplest configuration, is, for its part, constituted of a means power supply such as a transformer 7, of the high voltage type, connected to a pair of electrodes 8 placed in the housing 2, near the nozzle 6 spraying the hydrocarbon to produce an arc and a flame when a hydrocarbon jet is emitted by the nozzle.

The transformer 7 and the solenoid valve 5 are respectively electrically connected, via a base 9, consisting of a terminal block or connectors for example, also placed in the housing 2 of the system 1, to a power source external electrical device to said device, switches 10 ₁ , 10 ₂ respectively for opening and closing the supply circuits of said solenoid valve 5 and said transformer 7.

The nozzle 6 used in the projection device of the system 1 according to the invention is preferably a high-pressure nozzle, made of steel, with a spraying orifice 6 ₁ made of tungsten, capable of working at pressures greater than 20 bar.

Such a nozzle 6 makes it possible to channel the flow of liquid hydrocarbon into a rectilinear fine jet, that is to say forming a small angle with respect to the axis ZZ 'passing through the center of the orifice 6, of the nozzle, under a pressure hydrocarbon content greater than 20 bar, so as to produce flames of length up to 30 m.

The pair of electrodes 8 of the ignition device consists of electrodes consisting of an insulating ceramic body 8 ₁ , partially embedded in the housing 2 and surmounted by a tip 8 ₂ tungsten conductor.

These electrodes 8 are placed such that the distance between their points 8 ₂ is between 0.5 cm and 1.5 cm, and preferably equidistant from the orifice 6 ₁ of the nozzle 6, so that an arc electrical occurs between their points 8 ₂ when the transformer 8 is electrically powered (the switch 10 ₂ being closed).

The hydrocarbon jet being sprayed by the nozzle 6 under a significant pressure greater than 20 bar, said electrodes 8 are arranged such that said electric arc formed between their peaks 8 _{2 does} not occur through said sprayed hydrocarbon jet but on the periphery of the latter in order to obtain an ignition of said jet which is reliable and secure. In order to obtain the formation of an arc between the ends of the tips 8 ₂ of the electrodes closest to the periphery of the micronized hydrocarbon jet with a facilitated and improved adjustment of the spacing of the electrodes, said ends of the latter are preferably folded at right angles and directed towards the longitudinal axis ZZ 'of the nozzle 6.

In order to completely isolate the various components of the system 1 according to the invention and make it completely sealed, a resin 11 is electrically insulating and insoluble in the housing 2 to flood all components. Suitable resin is, for example, a fast set resin comprising a diphenylmethane diisocyanate hardener, commonly used in the paint industry. Thus all of said hydrocarbon distribution network 3 and said ignition device and all the empty spaces are embedded and filled with resin inside the housing 2 as well as the interfaces between said housing 2 and the elements located in part inside and partly outside thereof, namely the nozzle 6 and the bodies 8 ₁ of the electrodes 8.

Preferably, the tightness and rigidity of the assembly between the bodies 8 ₁ of the electrodes and the housing 2 are guaranteed with the aid of a stainless steel cable gland.

The flame production system according to the invention is thus made perfectly waterproof against moisture and the introduction of liquid in the housing 2, which makes its use possible on or in the water for create flames on the surface of the water.

The system according to the invention can be implemented in a very simple by a single operator or, where appropriate, so automatic. In practice, the system 1 for producing flames can be placed on a floating support or fixed on a surface of water on which one wants to produce flames, or alternatively, on machinery ascensional installed under said surface of water and emerging the system 1 punctually to emit flames by surprise out of the water.

In each case, said system 1 is connected to a hydrocarbon reservoir through the inlet conduit 3 ₁ of the distribution network as well as an electrical firing device (not shown) connected to the base 9 to supply electricity to the transformer 7 and the solenoid valve 5 of the ignition device 4 and the distribution network respectively. A dosing motor pump, also not shown, supplies the system 1 with a hydrocarbon stream at a pressure of between 20 and 110 bar depending on the length of the desired flame.

Advantageously, to facilitate the adjustments of the hydrocarbon pressure and the nozzles, flame-generating devices specific to the desired flame type are produced. Thus, to produce flames with a height of between 0.5 m and 10 m, flame production systems operating at an average hydrocarbon pressure of 25 bar will be used, and to produce flames with a height of between 8 m and 25 m systems operating at an average pressure of 100 bar, said hydrocarbon pressure being regulated by pressure switches placed on the metering pump or downstream thereof on the inlet pipe 3 ₁ of the distribution network .

Introduced into the system via the intake duct 3 ₁₁ , the hydrocarbon stream first passes through the filter 4 to prevent the presence of any solid particles that may remain in the liquid, and is then fed through the distribution line 3 ₂ to the solenoid valve 5. This solenoid valve is closed when the switch 10 ₁ is open and therefore prevents the arrival of hydrocarbon up to the nozzle 6. Similarly, no electric arc is formed between the electrodes 8 as the transformer power switch _{2 2} of the transformer 7 is also open.

As soon as it is desired to produce a flame, an operator (or an automatic firing device, as the case may be) triggers, from the firing device, the closing of the switch 10 ₂ to feed the transformer 7 and the electrodes 8, so as to produce an electric arc between the points 8 ₂ of these electrodes. Shortly thereafter, the operator (respectively the automatic device) triggers the closing of the switch 10 ₁ to control the opening of the solenoid valve 5 and the admission of the pressurized hydrocarbon stream to the nozzle 6 where it is sprayed in the form of a rectilinear fine jet and ignited by the electric arc produced between the tips 8 ₂ of the electrodes 8 at the periphery of the jet at the spray orifice 6 _{1 of} said nozzle 6.

In a preferred embodiment, the system according to the invention has a secure ignition device allowing the production of several electric arcs independently of each other, so as to guarantee the presence of at least one arc during the emission of the jet of hydrocarbon through the jet 6.

For this purpose, for example, an ignition device such as represented in FIG. 2, comprising several pairs of electrodes, and preferably at least two pairs of identical electrodes 8a, 8b, said electrodes preferably equidistant from the longitudinal axis ZZ 'of the nozzle 6, and defining for example a "rectangle" around said nozzle 6.

However, other provisions of the pairs may be provided for of electrodes 8a, 8b, squared around the nozzle 6 or else both electrodes of the same pair superimposed.

Indeed, the electrodes do not necessarily have to be placed equidistant from each other to obtain a secure ignition system; the only constraint is that the conductive tips 8 ₂ two electrodes of the same pair of electrodes 8a, 8b are spaced from each other at most 1.5 cm in order to produce between them an electric arc, and that said electrodes are sufficiently close to the nozzle 6 so that said electric arc is produced at the periphery of the emission orifice 6 ₁ of the nozzle 6, and therefore at the periphery of the hydrocarbon jet when it is emitted for the fire.

Each pair of electrodes 8a, 8b is further powered by a independent transformer such as the transformer 7 described in Figure 1. The two pairs of electrodes being powered independently, we warn thus any failure of one of the generators and one ensures the production of minus one electric arc between at least two electrodes of the pairs 8a, 8b and the ignition of a flame during the emission of the hydrocarbon jet at the level of of the jet.

Claims (10)

A sealed and secure system (1) for producing flames for the show, comprising: a device for projecting a fuel comprising at least one nozzle (6) connected to at least one distribution network (3) of a pressurized liquid fuel, said nozzle being able to spray a micronized fuel jet to produce a flame preferably of great length; and an ignition device comprising at least one pair of electrodes (8, 8a, 8b) connected to at least one power supply means (7) capable of supplying at least one pair of electrodes in order to generate at least one an electric arc between at least two said electrodes for igniting said micronised fuel jet, and a frame formed by a housing (2) inside which said projection device and said ignition device are installed, said nozzle (6) and said pairs of electrodes (8, 8a, 8b) being placed, at least partially, outside said housing to be able to produce a flame, characterized in that the said distribution network (s) and said average power supply means (7) are embedded in an electrically insulating resin (11) and insoluble casting inside said housing (2) so as to seal said housing (1) against moisture, the respective interfaces of said housing (2) with said nozzle (6) and with said electrodes (8, 8a, 8b) being also sealed by said resin. A sealed and secure flame production system according to claim 1, characterized in that said ignition device is adapted to generate a plurality of electric arcs, preferably at the periphery of said micronised fuel jet sprayed by said nozzle (6). A sealed and secure flame production system according to claims 1 or 2, characterized in that said ignition device comprises at least two pairs of electrodes (8a, 8b) capable of producing at least two so-called electric arcs. Flame production system according to claim 3, characterized in that said ignition device comprises at least two said power supply means (7) capable of supplying said pairs of electrodes (8a, 8b) independently of one of the other, so as to ensure the presence of at least one arc at the time of emission of said fuel jet. Sealed and secure flame production system according to one of claims 1 to 4, characterized in that the distance between the ends of the conducting tips 8 ₂ of said two electrodes of a said pair of electrodes (8, 8a, 8b ) is between 0.5 and 1.5 cm, said ends of the tips of said electrodes preferably being directed towards the longitudinal axis ZZ 'of said first nozzle (6). A sealed and secure flame production system according to one of the preceding claims, characterized in that said electrodes are equidistant from the axis ZZ 'of said first nozzle (6). Sealed and secure flame production system according to one of the preceding claims, characterized in that it is capable of producing flames of a length of between 0.5 and 25 m, preferably at least 1 m, of more preferably at least 8 m, with a fuel pressure greater than 20 bar. A sealed and secure flame production system according to one of the preceding claims, characterized in that said fuel used is a liquid isoparaffinic hydrocarbon having a flash point greater than 50 ° C, preferably greater than 60 ° C. Process for producing flames for the show using a sealed and secure flame generation system (1) according to one of the preceding claims, characterized in that said system is installed at the water's edge on a floating or fixed structure. Process for producing flames for the show using a sealed and secure flame production system according to one of claims 1 to 8, characterized in that said system (1) is immersed under the surface of the water then emerged using an ascending machinery.

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