DE4235018C2 - Method and device for scaring aquatic life - Google Patents

Abstract

The invention relates to a method for scaring aquatic life, in particular fish, amphibious life or other aquatic life from predetermined areas by controlled initiation of detonations in water, in which sound, pressure and light waves are generated. DOLLAR A According to the invention it is provided that an explosive gas mixture is ignited to generate the detonations below the water surface, and that the components of the gas mixture are mixed at the location of the detonation.

Description

The present invention relates to a method of scaring Aquatic life, especially of fish, amphibious beings or other aquatic life, from predetermined areas through controlled Initiation of detonations in water, at which sound, pressure and light waves are generated, and on a device for performing this procedure.

Such a method is known from US 33 07 285. Described by the The aim of this procedure is to prevent fish that are caught in a fish net are caught, can escape from it when the net is closed. Here, shock waves are generated at the open end of the network, which the Fi to keep away from this open end. It is provided that sol che shock waves are generated by the ignition of small explosive charges.

The known method of keeping fish away from the open end of the net zes by detonating explosive charges has the disadvantage that it is difficult, explosive charges at predetermined depths as well as enough  ignite in quicker order to prevent the fish from escaping. Furthermore, the use of explosive charges is dangerous for the user in itself, which is important both when igniting and when transporting the Sprengla occur. The safety regulations that have to be complied with shape this Process is complex.

The present invention has for its object to provide a method for ver grief of aquatic life to indicate by which aquatic life be effectively kept away from predetermined areas of a body of water can, as well as a device for performing the method.

The object is achieved by a method with the features of Claim 1 and a device according to claim 5 solved. Advantageous further developments are the subject of Dependent claims.

The process according to the invention for scalding aquatic organisms is characterized in that an explosive gas mixture is ignited below the water surface, and in that the components of the gas mixture are mixed at the location of the detonations. The following advantages are achieved by generating the detonations by igniting an explosive gas mixture:
By mixing the components of the gas mixture at the location of the detonations, the strength, the location and the chronological sequence of the detonations are particularly easy to control. The strength of the detonations is determined in a simple manner by the amount of the gas mixture obtained by mixing the components. The location of the detonations is easily determined by determining the location of the mixing of the components. A sinking of finished explosive charges in the water, which is a hindrance to a rapid succession of detonations, is not required. The sequence of the detonations can be controlled directly by the mixing rate of the gases. The dangerous and, due to extensive safety regulations, complex and expensive transport of the explosive charges to the place of use is also eliminated, since the explosive gas mixture is only mixed at the location of the detonations.

An advantageous development of the invention provides that the components the gas mixture to lead to the site of the detonations. Be but is particularly advantageous if the gas components by water electrolysis be won. This has special rele with regard to security aspects relevance. There is no need for complex supply lines or storage for Sauer material / hydrogen. Another advantage is that you don't have to look it up needs whether the gas storage or gas storage are already empty and this need to be replaced. This has one in terms of operating costs positive impact.

The gas mixture is advantageously an oxygen was serstoff mixture. This has the advantage that the product of the chemical reacti on has no negative effects on the water, since the product of the che mix reaction is environmentally friendly.

It is advantageous if several detonations are spaced apart from one another take place so that a wall is created along which z. B. led a fish can be.

The inventive method also has the advantage that by controlled initiation of detonations under the sound, pressure and light wave strength is adjustable. So depending on the le in a body of water aquatic beings set the detonation strength accordingly become.

The object of the invention is also achieved in that at least one under the water surface chamber is provided, in which by Zün explosive gas mixture detonations can be generated with a  Exit opening through which sound, pressure and Light waves can be emitted, at least one feed line through which the com components of the gas mixture can be fed to the chamber, and an ignition unit, which is connected to a control unit, and through which the explosi ve gas mixture is ignitable.

The outlet opening of the chamber is expediently arranged in such a way that the waves emerging from the outlet opening towards a bottom are directed. This has the advantage that the primary direction of propagation is only on a certain area of a body of water is restricted and the body of water or the aquatic beings living in the water are not unduly affected become.

The chamber is advantageously connected to a first via a first feed line Gas container and ver via a second supply line with a second gas container prevented. This has the advantage that the explosive gas mixture is only in the chamber is mixed.

It can also be advantageous if an explosive gas mixture is already present mer is fed. In this case the chamber only needs one supply line. In However, this version must ensure that the explosive gas mixture is a has such a composition of the individual components that these under are half an explosion limit.  

There is expediently one in the flow path Gases from the gas tank to the chamber control units, which are operatively connected to a control unit. About the Control units in cooperation with the control unit the compositions of the explosi ven gas mixture and on the other hand the amount of gas mixture to be influenced. This has the advantage that the Detonation strength can be set differently.

It is advantageous if the device instead of with Provide gas containers with an electrolysis unit is. This has the advantage that the necessary gas mixture is provided by the electrolysis unit and no monitoring of the stock volume can be. Another advantage of electrolysis Unit is that the gas mixture components water Always provide substance and oxygen.

According to another thought, it is advantageous that Training device with sensors, the Senso ren are connected to the control unit. The Senso ren can be upstream of the chambers. The advantage this training is that an ignition only is solved when a aquatic creature passes by agreed water area is approaching. This has the advantage that preventive ignitions are not necessary.

Further advantages and features are based on two Described embodiments; shows

Fig. 1 shows a schematic structure of a first embodiment and

Fig. 2 shows a schematic structure of a second exemplary embodiment.

In Fig. 1 a first embodiment of a device is shown.

An electrolysis unit 14 is connected to a chamber 1 . The electrolysis unit 14 is shown schematically. In the electrolysis unit 14 , for. B. water is broken down into its chemical components. The gas components enter the same through openings in the chamber wall. The electrolysis unit 14 is connected to a direct current transformer 15 via an electrical line. The direct current transformer 15 is electrically connected to a control unit 16 .

The gases collected in the chamber 1 are ignited by means of an ignition device, which comprises an ignition unit 11 . The sound, pressure and light waves created by the ignition of the explosive Gasge mix come out of the chamber 1 via an outlet opening 17 .

The ignition unit 11 is electrically connected to an ignition transformer 12 . The mass is designated by 10 .

The ignition transformer 12 is electrically connected to the control unit 16 via a main switch 13 .

In FIG. 2, a second embodiment is shown a pre direction. The embodiment of FIG. 2 differs from that of FIG. 1 that instead of an electrolysis unit, the gas components from Gasbe containers 8 , 9 get into the chamber 1 via lines 18 , 19 .

The gas component hydrogen passes from a Gasbe container 8 via a pressure control unit 7 and feed line 6 to a safety valve 5 , which is arranged in the feed line 6 . With 4 in the feed line 6 arranged security stores are designated. The oxygen flows through an inlet valve 3 and a flame check valve 2 via a line 18 in the chamber 1st

Oxygen arrives from a storage container 9 via a line corresponding to the flow path of the hydrogen via the feed line 19 into the chamber 1 .

The ignition of the gas mixture takes place, as already explained for FIG. 1, via an ignition unit 11 , which is connected to an ignition transformer 12 . The ignition transformer 12 is connected via a main switch 13 to a control unit 16 , not shown.

The valves 3 , 5 and 7 are connected to the control unit 16 accordingly.

The chambers are located below the water surface and are distributed over the cross-section, so that a scare effect both upwards and from the side surfaces or from the target area one in Fra ge coming predetermined range or volumes possible.  

The device is preferably installed in side niches of building parts or in swimming pools ken.

The control unit 16 , which is not shown further, has an integrated circuit by means of which the electrolysis process is controlled.

According to the embodiment according to FIG. 2, the control unit 16 has an integrated circuit, through which the supply of the components is controlled in a suitable manner. The ignition device is connected to the control unit and controllable accordingly the gas supply. The firing order and the firing speed are controlled via the control unit 16 .

The voltage required to operate the device supply can be both from a mains voltage as well through a stationary energy supply system be put.

The device described above can be both stationary and can also be used mobile.

It goes without saying that the idea that the aquatic organisms can be scared away can also be applied to explosive media which are not liquid, as described above, but are liquid or solid. In the case of liquid or solid media, these are fed from suitable storage containers to chamber 1 .

Claims (9)

1. A method of scaring aquatic life, in particular of fish, amphibious or other aquatic life from pre-determined areas by controlled initiation of detonations in what water, in which sound, pressure, and light waves are generated, characterized in that for generation the detonations below the water surface, an explosive gas mixture is ignited, and that the components of the gas mixture are mixed at the location of the detonations. 2. The method according to claim 1, characterized in that the components of the gas mixture via feed lines to the site of the detonations become. 3. The method according to claim 1, characterized in that the components th of the gas mixture can be obtained by water electrolysis. 4. The method according to any one of claims 1 to 3, characterized in that an oxygen / hydrogen mixture is ignited. 5. Apparatus for carrying out the process for scalding water oils according to one of claims 1 to 4, characterized by at least one chamber ( 1 ) located below the water surface, in which detonations can be generated by ignition of an explosive gas mixture, with an outlet opening ( 17 ), through which sound, pressure and light waves generated during the detonations can be emitted, at least one feed line ( 18 ; 19 ), through which the components of the gas mixture can be fed to the chamber ( 1 ), and an ignition unit ( 11 ), which with a control unit ( 16 ) is connected, and through which the explosive gas mixture can be ignited. 6. The device according to claim 5, characterized in that the chamber ( 1 ) via a first feed line ( 18 ) with a first gas container ( 8 ) and via a second feed line ( 19 ) with a second gas container ( 9 ) is connected. 7. The device according to claim 6, characterized in that in the flow away of a gas from the gas container ( 8 ; 9 ) to the chamber ( 1 ) with the Steuerein unit ( 16 ) operatively connected control members ( 3 ; 5 ; 7 ) are arranged, by wel che the flow of the gas is controllable. 8. The device according to claim 5, characterized in that the device has an electrolysis unit ( 14 ) for generating gases which can form an explosive gas mixture. 9. Device according to one or more of the preceding claims, characterized in that sensors for detecting aquatic organisms are connected to the control unit ( 16 ).