EP0158038A1 - Fog generator - Google Patents

Abstract

1. A preferably portable fog generator for producing and/or enhancing optical effects with a fog chamber which opens into an exhaust conduit, with a pump which is connected through liquid conduits on one hand to a tank outside the generator and, on the other hand, with the fog chamber, with a fog generator which transforms the liquid inside th fog chamber into an aerosol, a fan which conveys the aerosol from the fog chamber through the exhaust conduit out of the generator and a housing carrying and surrounding the aforenamed components, characterized in that within the fog chamber (1) there arranged several ultrasonic transducers (6) driven simultaneously with high-frequency oscillations and fed by one or several high-frequency generators (11, 13) which are screened by a material having good electrical conductivity, preferably aluminium, further a device for cooling the electrical components and that inside the fog generator, preferably between the fog chamber (1) and the exhaust conduit (2) a droplet separator (24) is arranged.

Description

The invention relates to a "fog generator according to the preamble of claim 1.

Such mist generators generate mist-like aerosols by atomizing a liquid that is present at the same time in a cloud chamber filled with air by means of several ultrasound sources.

These devices can be used in discotheques, theaters, bars and on stages, among other things, to create or enhance optical effects.

It is known that mist generators for producing mist-like aerosols either immerse pieces of dry ice in hot water, or evaporate aliphatic oils by heating and then quickly condense by mixing with cold air. In a third method, instead of the aliphatic oils, an aqueous, hygroscopic solution is evaporated and condensed (German Offenlegungsschrift DE 3126952 A1).

These known types of fog generator have the common disadvantages that a mostly lengthy heating process is required before the generators can generate fog, and that on walls, floors, ceilings and objects in Liquid separations take place in their surroundings by rondensation of the aerosols. In addition, with the fog generators, the dry ice uses an unpleasant cooling of the air layers near the ground and a considerable C0 ₂ enrichment of the air. The fog generators that use aliphatic oils produce hot and often flammable aerosols, the condensate of which promotes the rapid spread of fire in the event of a fire. The fog generators, which use hygroscopic, aqueous solutions, can reduce the air humidity, which may be harmful to health, while at the same time causing unpleasant odors. In addition, these aerosols mostly contain substances that are harmful to health.

Based on the aforementioned problem, the invention has for its object to provide a fog generator that generates large amounts of fog immediately after switching on, this fog must not contain any harmful substances, is not flammable and does not condense on objects in the vicinity of the generator.

According to the invention, these objects are achieved in that a plurality of ultrasonic transducers, which are operated simultaneously, are preferably arranged in a common cloud chamber.

The fog generator according to the invention enables a very large amount of atomized liquid to be produced immediately after the generator is switched on, since the ultrasound-emitting devices do not require lengthy heating-up or cooling-down processes for their operation and are only dependent on electrical energy, air and fog liquid. In addition, it is fundamentally possible to atomize liquids which are preferably non-toxic and non-flammable by exposure to ultrasonic vibrations are, so that health damage and fires, as with conventional fog generators, are no longer possible. At the same time, the ultrasonic atomization causes the formation of a relatively monodisperse aerosol, which naturally shows only a slight tendency to condense on objects in the vicinity of the generator.

In this connection, the fog generator according to the invention has, in particular, considerable advantages over other known devices which require long heating phases, produce oily or aqueous condensate residues or produce flammable and / or harmful aerosols.

A particularly advantageous embodiment of the invention for generating the ultrasonic vibrations consists in the fact that only one high-frequency generator supplies several ultrasonic transducers. The high-frequency generator can consist of a clock generator and several power output stages, each output stage being assigned to at least one ultrasound transducer. This embodiment has the advantage that the generator works with only one ultrasound frequency and that undesirable influences on the ultrasound transducers are avoided. At the same time, radio interference suppression that is necessary in any case is considerably simplified.

Another possibility is that each ultrasound transducer is assigned its own high-frequency generator. With this arrangement it is achieved that each ultrasonic transducer works independently and with optimal performance, and that the rest remain functional in the event of an electrical fault in a high-frequency generator. In addition, these high-frequency generators only need to generate a relatively low RF power, so that inexpensive electronic assemblies can be used here. According to a further embodiment of the invention, the ultrasonic transducers are attached to the bottom of the fog chamber by elastic parts. With this arrangement it is achieved that the ultrasonic transducers are only slightly damped by their holder and that only a small part of their vibration energy reaches the bottom of the fog chamber. As a result, the generated ultrasound energy can be transferred to the liquid without great losses, so that the generator is effective. At the same time, the elastic parts prevent liquid from leaking out of the cloud chamber due to their sealing function.

A particularly advantageous embodiment of the invention integrates the ultrasound transducers into a housing enclosing the high-frequency generator part, the sound-emitting surfaces of the ultrasound transducers being arranged in corresponding openings in the upper part of the high-frequency generator housing. At the same time, this wall of the housing is also part of the bottom of the cloud chamber, and the surfaces of the ultrasonic transducers can thus subject the liquid which is always present in the cloud chamber to high-frequency vibrations. This arrangement reduces the shielding problems that otherwise arise during the transmission of the high-frequency currents from the high-frequency generators to the ultrasound transducers, and this results in considerable material and assembly time savings.

In addition, it is advantageous to build the housing walls of the high-frequency generators from good electrically conductive material, preferably aluminum, for the purpose of good electrical radio interference suppression. Aluminum is particularly suitable here, since it is relatively inexpensive, easy to process and has good electrical and thermal conductivity.

According to a further embodiment of the invention, the liquid height above the ultrasound-emitting surfaces of the ultrasound transducers is constantly adjusted to at least 0.1 mm during operation by suitable control devices which act on the liquid pump. Suitable control devices can be, for example, sensors, light barriers or switches triggered by floats, which act directly or indirectly on the liquid pump, and thus adjust the liquid level in the cloud chamber such that the above-mentioned. Condition is met. This ensures that there is always enough liquid available for atomization, and that the ultrasonic transducers run dry and thus avoid damage to them.

In a further advantageous embodiment of the invention, the angle between the ultrasound-emitting surfaces of the ultrasound transducers and the surface of the liquid resting in the cloud chamber is less than 90 °, preferably the surfaces of the liquid and those of the ultrasound transducers are parallel to one another. This arrangement of the ultrasonic transducer surfaces ensures that an optimal efficiency of liquid atomization is achieved.

According to a further embodiment of the invention, the bottom of the fog chamber is designed as a collecting container for the liquid to be atomized and opens into a liquid channel at the lowest point. The advantage of this configuration is that the liquid splashes and condensate drops that constantly occur in the fog chamber during operation flow back to the ultrasonic transducers of the fog generator and can be atomized there again without losses.

In addition, it is advantageous to use a pump Let the liquid channel open into the cloud chamber at the lowest point of the cloud chamber floor; With this embodiment of the invention, the entire liquid can be emptied from the cloud chamber into an outer tank for transport purposes, for example by reversing the polarity of the pump. This prevents liquid from leaking out of the generator during transport.

A further advantageous embodiment of the invention consists in preferably using a self-priming liquid pump as the pump of the generator. As a result, an easily transportable and refillable external tank can be used as the liquid supply, which is connected to the pump on the suction side via a corresponding liquid channel.

According to a further embodiment of the invention, a filter is attached to at least one point in the liquid channel, preferably at the end that lies outside the generator housing. This filter can e.g. be designed as an immersion filter, which is inserted into an external tank and prevents contaminants from entering the liquid channels, the pump or the cloud chamber. This avoids unnecessary contamination of the cloud chamber and, at the same time, potential causes of faults.

In order to avoid the destruction of the ultrasonic transducers by running dry, it is expedient, according to a further embodiment of the invention, to install at least one sensor in the fog chamber which switches off at least a part of the fog generator, in particular the high-frequency generator or generators, when the liquid level falls below a predetermined level. This sensor can consist, for example, of a light barrier or a float switch which, when the liquid level drops in the fog chamber below a minimum height interrupts the power supply to the electrical components.

Furthermore, it is also advantageous if the same sensor, according to another embodiment of the invention, simultaneously triggers at least one optical and / or acoustic signal in addition to switching off electrical components. This alerts the user of the fog generator to a malfunction and e.g. prompted to refill the external liquid tank.

In a further advantageous embodiment of the invention, a droplet separator is located in the interior of the fog generator, which removes entrained liquid splashes and coarser fog droplets from the aerosol.

The droplet separator is expediently attached between the fog chamber and the discharge shaft, so that the air flow generated by the blower transports the aerosol generated in the fog chamber through the droplet separator before the aerosol leaves the generator.

In principle, it is possible to design the droplet separator as part of the cloud chamber. This arrangement according to the invention has the advantage that the liquid separated from the droplet separator immediately flows back to the bottom of the cloud chamber and is atomized again there.

Another possibility is to integrate the droplet separator into the discharge duct. With this arrangement according to the invention it is achieved that only a small and therefore inexpensive droplet separator is required, since already on the way that the aerosol travels from the cloud chamber to the blow-out shaft, a part of the entrained liquid particles in the fog generator to the Is deposited on the walls.

According to the invention, the bottom of the droplet separator has a slight slope in the direction of the outlet of the cloud chamber, so that the separated liquid flows back to the cloud chamber and is atomized again there.

The obstacles of the droplet separator deflecting the aerosol are designed according to the invention in such a way that they enable the separated fog liquid to return to the fog chamber, preferably through appropriate bores. It is also possible to remove the obstacles from the droplet separator inside the generator e.g. to be attached to the side walls in such a way that a free gap remains at the bottom of the separator through which the liquid can flow back to the cloud chamber.

According to the invention, the bottom of the blow-out shaft has a slight slope in the direction of the cloud chamber, so that condensing liquid in the blow-out shaft flows back to the cloud chamber and does not drip out of the generator, as is often the case with conventional generators. In addition, the liquid flowing back can be atomized again.

In a further advantageous embodiment of the invention, dust filters are arranged in the area of the air inlet openings of the blowers. This prevents dust or dirt particles from getting into the generator and in particular into the fog chamber, otherwise the function of the ultrasonic transducers or the sensors for controlling and monitoring the liquid level could be impaired. These dust filters can expediently be designed as paper or plastic filter inserts that are easy to change from the outside, so that they are regular can be exchanged.

The outlet openings of the air flow for cooling the electrical components in the interior of the mist generator are preferably arranged at right angles to the outlet shaft of the aerosol. This ensures that the air flow heated by the electrical parts of the generator does not mix with the aerosol, since this would impair the life of the aerosol.

fügten schematischen Zeichnung beispielsweise noch näher erläutert:

• Fig. 1 zeigt in schematischer Darstellung eine Skizze der funktionellen Zusammenwirkung der einzelnen Elemente des erfindungsgemäßen Nebelgenerators.
• Fig. 2 zeigt in schematischer Darstellung einen Teil des Nebelkammerbodens, der gleichzeitig auch Teil eines Hochfrequenzgenerators darstellt.

The fog generator according to the invention is based on the

added schematic drawing, for example, explained in more detail:

• Fig. 1 shows a schematic representation of a sketch of the functional interaction of the individual elements of the fog generator according to the invention.
• Fig. 2 shows a schematic representation of a part of the fog chamber floor, which is also part of a high frequency generator.

Throughout the drawing, the same reference symbols designate the same elements. All features shown are advantageous refinements of the exemplary embodiment.

1, there is a mist generator for generating liquid mist by means of several ultrasound sources from a mist chamber 1, the lower wall 17 of which is designed as a collecting container for the liquid 7 to be atomized. and which has at its lowest point an outlet 18 which opens into the liquid channel 4. The liquid channel 4 is connected to the pump 3, which pumps the liquid to be atomized from an external liquid tank into the fog chamber 1 via the liquid channel 5 and liquid filter 19. The external tank is not shown for the sake of simplicity. The liquid channel 5 breaks through an outer wall of the mist generator (not shown) and preferably has a filter 19 at the end Liquid channel 5 can be pumped into the cloud chamber 1. The bottom 17 of the fog chamber 1 is designed in such a way that there are openings at several points, in which the ultrasonic transducers 6 are installed by means of suitable elastic connecting parts 12. The elastic parts 12 simultaneously seal the bottom 17 against the ultrasonic transducer surfaces 15, so that no liquid 7 can escape here. The surfaces 15 of the ultrasonic transducers 6 are arranged such that they are constantly wetted by the liquid 7 and to the stationary liquid surface 16 are aligned in parallel. When the fog generator is installed horizontally, the sound-emitting surfaces 15 are preferably arranged horizontally, while the fog chamber floor 17 has a slight slope in the direction of the outlet 18. In addition, two sensors 20 and 21 are located in the fog chamber 1, for example on a side wall of the fog generator. The sensor 20 serves to control the pump 3 in order to regulate the level of the liquid 7 in the fog chamber 1. In the event of a fault, ie when the liquid level falls below a minimum, the sensor 21 switches off the high-frequency generators 11 and at the same time triggers the optical or acoustic signal transmitters 22 and 23. A blower 8, which is preferably arranged in the upper region of the fog chamber 1, sucks in air from outside through a dust filter 30 through corresponding openings in the generator housing 10 and generates an air flow in the direction of the arrow. The air mixes in the cloud chamber 1 with the liquid 7 atomized by the ultrasonic transducers 6, an aerosol being formed which, when flowing through the droplet separator 24, is freed of coarse droplets and liquid splashes at its obstacles 26, 27, 28 and then the fog generator through the exhaust duct 2. The bottom 25 of the droplet separator 24 and the bottom 29 of the blow-out chute 2 have a slight slope in the direction of the fog chamber 1, so that separated liquid can flow back to the fog chamber 1. For this purpose, the obstacle 27 of the droplet separator 24 is provided with holes 33 to allow the liquid to return.

Furthermore, a second fan 9 is arranged in the lower part of the fog generator, which draws in fresh air through a dust filter 31 and through openings in the rear wall of the fog generator, which is used to cool the electrical components, in particular the high-frequency generators 11, the ultrasonic transducers 6 and pump 3. The air flow heated in the process leaves the generator through the outlet openings 32 arranged in the side walls. The high-frequency generators 11 work simultaneously in the operating state and supply the ultrasonic transducers 6 with high-frequency alternating current. The ultrasonic transducers 6 convert this alternating current into mechanical vibrations, which are transmitted from the sound-emitting surfaces 15 to the liquid 7. Due to the effect of the ultrasonic vibrations, the liquid 7 is atomized into the finest droplets on the surface 16. Above the liquid surface 16, the liquid droplets mix in the cloud chamber 1 with the air which is always present there. The resulting aerosol is transported by the air flow that the blower 8 generates after passing through the droplet separator 24 through the blowout duct 2 from the mist generator. The liquid mist emerging from the discharge shaft 2 can be used for commercial purposes, in particular for displaying and / or enhancing optical effects.

Fig. 2 shows a schematic representation of an embodiment in which the fog chamber floor 17 is also a wall of the high-frequency generator 13. The ultrasonic transducers are accommodated in the housing 14 in such a way that the sound-emitting surfaces 15 are located in corresponding recesses in the bottom of the cloud chamber 17. The sound-emitting parts of the ultrasonic transducers are held and sealed by elastic parts 12. The elastic parts 12 prevent liquid from penetrating into the high-frequency generator 13 and that the ultrasonic energy is dissipated into the cloud chamber floor 17. In this embodiment of the invention, in addition to the electronic components of the high-frequency generator (not shown), the interior of the housing 14 also contains the ultrasound transducers (not shown) with their sound-emitting surfaces 15, which convert the alternating electrical currents into mechanical vibrations.

The invention further relates to a method for generating an effect mist according to the preamble of the main claim.

Effect nebulae are preferably generated in discotheques, theaters, film and television studios in order to improve the lighting effects in such rooms or to achieve certain mood effects.

In principle, two working methods are known. One is working with fog generators to generate fog-like aerosols, in which pieces of dry ice are immersed in hot water. This creates a mist consisting essentially of water, which causes an unpleasant cooling of the air layers near the ground and generates a considerable amount of CO ₂ in the air. In addition, the fog generated in this way is relatively heavy and therefore cannot be led into higher layers of the stage.

On the other hand, one works with fog liquids based on oil or glycol water, which are evaporated by heating and then quickly condensed by mixing with cold air. This method of operation has the disadvantage that, on walls, floors, ceilings and objects in the vicinity of the mist that forms, liquid is separated out by condensation. These nebets are relatively warm and therefore rise quickly and are therefore widely used areas not desired.

The invention has for its object to provide a method for generating an effect fog, with which a better stabilized fog than the previously known possibilities can be generated.

This object on which the invention is based is achieved in that a further fog generator is assigned to the fog generator working with an oil or glycol water-based fog liquid, which creates a fog-like aerosol based on air-water and possibly carbon dioxide, the two fog generated in this way introduced into each other, mixed and depending on the desired effect, the two types of fog can be dosed.

By the addition of the water droplets to the fog liquid droplets, a substantially more stable fog is achieved, and surprisingly it is additionally achieved that a fog is created which can be adjusted according to its chosen mixing ratio at any altitude on the stage or in the room, i.e. can be stabilized. In addition, the fog generated in this way may be less water and therefore no longer has the disadvantages of pure dry ice fog generators.

Finally, in addition to solving the object on which the invention is based, the method according to the invention achieves that the fog is generated both on the top and bottom of a stage, that is, it can be present including all intermediate layers, so that it can meet the wishes of practice in full, which was previously not possible and which was perceived as a serious disadvantage, but was accepted.

It is preferably further proposed according to the invention that an ultrasonic mist generator is used to generate the mist-like air-water aerosol. Such a mist generator enables a very large amount of atomized liquid to be produced immediately after the generator is switched on, since the ultra-switch-emitting devices do not require lengthy heating or cooling processes in their area and are only dependent on electrical energy, air and mist liquid. In addition, it is in principle also possible to atomize liquids which are preferably non-toxic and non-flammable by exposure to ultrasonic vibrations, so that damage to health and fires are no longer possible, as with conventional secondary generators.

At the same time, the ultrasonic atomization causes the formation of a relatively monodisperse aerosol, which naturally shows only a slight tendency to condense on objects in the vicinity of the generator.

According to a further essential feature of the invention, it is proposed that the two fog generators can be operated independently of one another, so that all mixing effects are possible. It is proposed that the two fog generators are combined in a single generator unit, so that a device is created with which all effects can be achieved, namely on the one hand the desired ground fog, on the other hand the desired high fog and finally by mixing the two, the desired stabilization of the Fog and the desired intermediate height of the generated fog.

Claims (28)

1. Preferably portable fog generator for displaying and / or amplifying optical effects with a fog chamber, which opens into a blow-out duct, with a pump that is connected by two liquid channels to a tank outside the generator and with the fog chamber, with several ultrasound sources apply high-frequency vibrations to the liquid inside the fog chamber, with a blower that conveys the aerosol from the fog chamber through a blow-out duct from the generator, a second blower for cooling the electrical parts and a housing that supports and encloses the components mentioned, characterized that a plurality of ultrasonic transducers (6), which are operated simultaneously, are preferably arranged in a common fog chamber (1). 2. Fog generator according to claim 1, characterized in that the ultrasonic sources consist of a high-frequency generator (13) which supplies several ultrasonic transducers (6). 3. Fog generator according to claim 1, characterized in that each of the ultrasonic transducers (6) is supplied by its own high-frequency generator (11-). 4. Mist generator according to one of claims 1 to 3, characterized in that the ultrasonic transducers (6) are fastened to the mist chamber floor (17) by elastic parts (12). 5. Fog generator according to one of claims 1 to 4, characterized in that at least one housing wall of the high-frequency generator (13) is at the same time part of the fog chamber floor (17). 6. Fog generator according to one of claims 1 to 5, characterized in that the housing walls of the high-frequency generators consist of electrically highly conductive material, preferably of aluminum. 7. Fog generator according to one of claims 1 to 6, characterized in that the liquid (7) on the ultrasound-emitting surfaces (15) of the ultrasound transducer (6) is at least 0.1 mm high during operation. 8. Fog generator according to one of claims 1 to 7, characterized in that the angle between the ultrasound-emitting surfaces (15) of the ultrasound transducer (6) and the surface (16) of the liquid (7) at rest in the fog chamber (1) is less than 90 °, and that the surfaces (15, 16) are preferably arranged parallel to one another. 9. Fog generator according to one of claims 1 to 8, characterized in that the bottom (17) of the fog chamber (1) is designed such that the liquid (7) collects at the outlet (18). 10. Fog generator according to claim 9, characterized in that one of the pump (3) come- the liquid channel (4) opens into the fog chamber (1) at the outlet (18) characterized by claim 9. 11. Mist generator according to one of claims 1 to 10, characterized in that the pump (3) of the generator is preferably a self-priming liquid pump. 12. Fog generator according to one of claims 1 to 11, characterized in that at least one point in the liquid channel (4,5) at least one filter (19) is attached, preferably at the end of the channel outside the area. nerator housing. 13. Fog generator according to one of claims 1 to 12, characterized in that in the fog chamber (1) a sensor (20) is attached, which is used directly or indirectly to control the liquid pump (3). 14. Fog generator according to one of claims 1 to 13, characterized in that in the fog chamber (1) at least one sensor (21) is attached, which falls below a minimum liquid level in the fog chamber (1) at least a part of the fog generator, in particular the or the high frequency generators (11, 13) switches off. 15. Fog generator according to one of claims 1 to 14, characterized in that in the fog chamber (1) at least one sensor (21) is attached, which falls below a minimum liquid level in the fog chamber (1) switches on at least one optical and / or acoustic signal device (22, 23). 16. Mist generator according to one of claims 1 to 15, characterized in that a droplet separator (24) is located inside the mist generator. 17. Mist generator according to claim 16, characterized in that the droplet separator (24) between the fog chamber (1) and the blow-out shaft (2) is attached. 18. Fog generator according to claim 16, characterized in that the droplet separator (24) is part of the fog chamber (1). 19. Mist generator according to claim 16, characterized in that the droplet separator (24) is part of the blow-out duct (2). 20. Mist generator according to claim 9 and according to one of claims 16 to 19, characterized in that the bottom (25) of the droplet separator (24) has a slight slope in the direction of the outlet (18). 21. Fog generator according to one of claims 16 to 19, characterized in that the aerosol deflecting obstacles (26, 27, 28) of the droplet separator (24) are designed so that they allow the return of the fog liquid to the fog chamber (1), preferably through appropriate holes (33). 22. Fog generator according to one of claims 1 to 21, characterized in that the bottom (29) of the blow-out shaft (2) in the direction of the fog chamber (1) has a slight slope. 23. Fog generator according to one of claims 1 to 22, characterized in that dust filters (30, 31) are arranged in the region of the air inlet openings of the blowers (8, 9). 24. Mist generator according to one of claims 1 to 23, characterized in that the openings (32) for the outlet of the air flow for cooling the electrical components are preferably arranged at right angles to the outlet shaft (2) of the aerosol. 25. A method for producing an effect fog for theaters, discotheques or the like. By evaporating a fog liquid based on oil or glycol water, characterized in that the fog generator working with a fog liquid is assigned a further fog generator, which is a fog-like aerosol based on air Water and possibly carbon dioxide are created, the two mists generated in this way being introduced into one another, mixed and, depending on the desired effect, the two types of mist can be metered. 26. The method according to claim 25, characterized in that an ultrasonic mist generator is used to generate the mist-like air-water aerosol. 27. The method according to claim 25 and 26, characterized in that the two fog generators can be operated independently. 28. Device for generating an effect mist using a mist generator for evaporating a mist liquid and a mist generator for producing an air-water aerosol, characterized in that the two mist generators are combined in a single generator assembly.

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