PL226907B1 - Method for producing non-linear distribution of electric field intensity in the water environment and the system of electrodes for producing non-linear distribution of electric field intensity in the water environment - Google Patents

Description

Description of the invention

The subject of the invention is a method of producing a non-linear distribution of the electric field intensity in an aqueous environment and a system of electrodes for producing a non-linear distribution of the electric field intensity in an aqueous environment, intended for use in hydraulic engineering as a protective barrier preventing fish from entering water intakes and water outlets from hydrotechnical devices.

The method of controlling the behavior of fish and the device for controlling the behavior of fish in the aquatic environment is known from the international patent application No. WO 2007 058 554. The behavior of fish according to the method is governed by the impact on a non-uniform pulsed electric field with a non-linear impulse in the water environment. an intensity gradient with a direct current field superimposed on them with a specific configuration, the magnitude of the pulsed electric field intensity gradients, the length of the working pulses, their frequency and the interval between them being selected taking into account the required behavior of the fish. The device has an electrode system powered from the supply module, through the intermediate stage system, and the power module with a commutator, the elements of the system being connected to the electrode supply control system.

A method for producing a non-linear distribution of the electric field intensity in an aqueous environment and a device for generating a non-linear distribution of the electric field intensity in an aqueous environment are known from the patent description No. PL 214 028. The method consists in that between at least one vertical electrode with negative polarization and at least with one unit containing at least one vertical electrode with positive polarity, a pulsed electric field is created, the absolute value of which increases from the electrodes with positive polarity towards the electrodes with negative polarity. The non-linear distribution of the electric field intensity is obtained by differentiating the size of the active surface of the electrodes with negative polarity to the size of the active surface of the electrodes with positive polarity, which are currently involved in the conductivity of the electric current. The device has at least one vertical negative electrode electrically coupled to the at least one electrode assembly comprising at least one vertical positive electrode. At the upper end of each of the negative and positive polarization electrodes, a float element, preferably a buoyant buoy, is attached and disposed below the water level, while each lower end of the negative and positive polarization electrode is mounted flexibly and pivotally at the bottom. Moreover, the negative electrodes are connected with electric wires through the main electric cable, to the set of commutators feeding the negative electrodes, and the positive electrodes are connected with electric wires through the main electric cable to the set of commutators feeding the positive electrodes. In a variant of the device, the lower ends of the negative and positive electrodes are attached with ropes to a rope guided above the bottom of the tank, the rope being anchored by at least two anchors in the bottom of the tank and / or in the side walls of the water tank.

In the previous solutions, the behavior of fish is guided by creating an electric field in the aquatic environment, the lines of force of which run only parallel to the direction of water flow and the direction of fish movement. In some hydrotechnical structures, due to the construction of tunnels and channels through which water flows, as well as the speed of its flow, the generation of an electric field whose lines of force will run parallel to the direction of water flow and the direction of fish movement is technically seeing impossible.

The essence of the method according to the invention consists in the fact that between the at least one positively polarized electrode distant from the at least one negatively polarized electrode, at least one pulsed electric field is generated, forming an electric field curtain, in which the field force lines are preferably perpendicular to the flow direction. water and the direction of the fish.

Preferably, at least two electrodes are supplied from an independent pulse voltage source such that the electric field lines extend over the entire cross section of the water intake or water outlet.

Preferably, at least one positively polarized electrode is positioned opposite to at least one negatively polarized electrode spaced therefrom.

Preferably, the total active surface of the negatively polarized electrodes participating in the current conductivity at a given moment is greater than the total active surface of the positively polarized electrodes, and the total active surface of the electrodes participating in the conductivity of electric current is changed by connecting or disconnecting successive electrodes to an independent pulsed voltage source.

Preferably, along the direction of the water flow and the direction of the fish travel, at least two pulsed electric field curtains are created, the field force lines of adjacent curtains being formed by pairs of electrodes supplied from independent sources of pulsed voltage and directed opposite.

The essence of the electrode system according to the invention is that it has at least one positively polarized electrode spaced apart from the at least one negatively polarized electrode, which is connected to at least one independent source of pulsed voltage, the electrodes preferably being arranged perpendicular to the flow direction. the water and the direction of the fish moving along the water intake or outlet.

Preferably, the electrodes are mounted on opposite walls of a water turbine chamber, water conduit or tunnel, the length of the electrodes at least equal to the height and / or width of the water turbine compartment, water conduit or tunnel.

The device is intended for use in hydraulic engineering as a protective barrier preventing fish from entering water intakes and water outlets from hydrotechnical devices, in particular to protect the water turbine chamber. The use of electrodes fixed to the walls of the chamber allows the generation of a pulsed electric field in the water environment, the lines of force of which are perpendicular to the direction of water flow and the direction of fish movement, through the entire cross-section of the turbine chamber, tunnel or channel, which effectively protects them against fish entering.

The subject of the invention in an exemplary embodiment is shown in the drawing which shows the electrode system for producing a non-linear distribution of the electric field intensity in the water environment inside the turbine chamber.

P r z k ł a d 1

The method of producing a non-linear distribution of the electric field intensity in an aqueous environment consists in the fact that between the positively polarized electrode E1, distant by the width of the water turbine channel from the negatively polarized electrode E5, a pulsed electric field is generated, creating an electric field curtain, in which the field force lines are perpendicular to the direction of water flow and the direction of movement of fish. The pair of electrodes E1, E5 are supplied from an independent source of impulse voltage, and the electric field force lines run through the entire cross-section between the opposite electrodes E1, E5, and the width of the area through which the electric field force lines penetrate depends on the width of the electrodes E1 and E5 and the degree of curvature of the lines of force.

P r z k ł a d 2

The method of producing a non-linear distribution of the electric field intensity in the water environment is as in the first example, with the difference that the total active surface of the negatively polarized electrodes E5, E6 taking part in the current conductivity at a given moment is smaller than the total active surface of the positively polarized electrodes E1, E2, E3, while the total active surface of the electrodes E1, E2, E3, E5, E6 involved in the conductivity of the electric current is changed by connecting or disconnecting successive electrodes from an independent pulsed voltage source. The width of the area through which the electric field lines penetrate depends on the width of the electrodes involved in the conductivity of the current, the spacing between the positively polarized electrodes E1, E2, E3 and the spacing between the negatively polarized electrodes E5, E6 and the degree of curvature of the electric field force lines.

P r z k ł a d 3

The method of producing a non-linear distribution of the electric field strength in the aqueous environment is as in the first example, with the difference that along the direction of the water flow and the direction of the fish travel, impulse electric field curtains are created, the first curtain being produced by the fifth negatively polarized electrode. E5 and the first positively polarized electrode E1, while the second curtain is produced by the second negatively polarized electrode E2 and the sixth positively polarized electrode E6, the field force lines of the adjacent curtains are created by pairs of electrodes E5 and E1 as well as E2 and E6, supplied from two independent sources of pulse voltage and are directed opposite.

PL 226 907 B1

P r z k ł a d 4

The method of producing a non-linear distribution of the electric field strength in an aqueous environment is as in the first example, with the difference that it has four positively polarized electrodes E1, E2, E3, E4 and five negatively polarized electrodes E5, E6, E7, E8, E9. The width of the area through which the lines of force of the electric field penetrate is equal to the width of the electrodes involved in the conductivity of the current along with the size of the spacing between the positively polarized electrodes E1, E2, E3, E4 and negatively polarized electrodes E5, E6, E7, E8, E9 and the degree of curvature lines of force of the electric field.

P r z k ł a d 5

The method of producing a non-linear distribution of the electric field intensity in an aqueous environment is as in the first example, with the difference that there is one positively polarized electrode E1 and two negatively polarized electrodes E5 and E6. In this case, the width of the area through which the field force lines penetrate changes depending on the area under consideration. And so, with the positively polarized electrode E1 itself, it corresponds to the width of this electrode E1 and is increased by the curvature of the field force lines. On the other hand, as it moves away from the positively polarized electrode E1 towards the negatively polarized electrodes E5 and E6, its width increases. In the immediate vicinity of the negatively polarized electrodes E5 and E6, the width of this area corresponds to the sum of the widths of these electrodes E5 and E6, the size of the spacing between them and the value resulting from the curvature of the field force lines. As the process of current conduction involves one positively polarized electrode E1 and two negatively polarized electrodes E5 and E6, where the dimensions of all electrodes are identical, the highest electric field strength occurs in the immediate vicinity of the positively polarized electrode E1 and decreases as it approaches the electrodes negatively polarized E5 and E6.

P r z k ł a d 6

The method of producing a non-linear distribution of the electric field intensity in the aqueous environment is as in the first example, with the difference that the electrodes E5, E6, E7 are positively polarized, while the electrodes E1 and E2 are negatively polarized. The width of the area through which the electric field lines penetrate is determined as above, and the direction of the field force lines is opposite to the previous example. The greatest value of the electric field intensity occurs at the surfaces of the negatively polarized electrodes E1 and E2, and the value of the intensity of this field gradually decreases as it approaches the positively polarized electrodes E5, E6 and E7.

P r z k ł a d 7

The electrode system for producing a non-linear distribution of the electric field strength in an aqueous environment has a positively polarized electrode E1 spaced from the negatively polarized electrode E5, which are arranged perpendicular to the direction of water flow and the direction of movement of the fish. The electrodes E1, E5 are connected to one independent source of pulse voltage. Moreover, the electrodes E1, E5 are mounted opposite on the walls of the water turbine chamber, and the length of the electrodes E1, E5 is equal to the width of the chamber.

P r z k ł a d 8

The electrode system for producing a non-linear distribution of the electric field intensity in the water environment is made as in the seventh example, with the difference that it has the first pair of electrodes E5, E1, of which the negatively polarized electrode E5 and the positively polarized electrode E1 is connected to the first independent pulse voltage source and the second pair of electrodes E2, E6 has a negatively polarized electrode E2 and a positively polarized electrode E6 connected to a second independent pulse voltage source, the electric field force lines being formed by electrode pairs E5 and E1 and E2 and E6 supplied from two independent voltage sources pulse and are directed in the opposite direction.

P r z k ł a d 9

An electrode system for producing a non-linear distribution of the electric field intensity in an aqueous environment made as in the first example, with the difference that it has a pair of positively polarized electrodes E1 and a negatively polarized electrode E9 connected to an independent source of impulse voltage, the electric field lines being formed by the pair of electrodes E1 and E9 are situated at an angle less than 90 ° to the direction of water flow and the direction of movement of the fish.

PL 226 907 B1

P r z k ł a d 10

The electrode system for producing a non-linear distribution of the electric field intensity in the water environment is made as in the ninth example, with the difference that it has two pairs of electrodes, the first pair of which are connected to the first independent source of pulsed voltage, the first positively polarized electrode E1 and the ninth polarized electrode negative E9, and the second pair connected to the second independent pulse voltage source is the fourth negatively polarized electrode E4 and the fifth positively polarized electrode E5, the electric field force lines formed by both electrode pairs E1 and E9 and E4 and E5 are crossed and located at an angle less than 90 ° to the direction of water flow and the direction of fish movement, moreover, the directions of the electric field lines are opposite to each other.

The electrode system may have electrodes E1, E2, ..., E9, placed opposite on the walls of the chamber, tunnel or water channel, both horizontally and vertically, the length of the electrodes E1, E2, ..., E9 may be equal to the height or the width of the tunnel, as well as the electrodes may be longer and bent along the corners of the drawing of the water turbine chamber, the consecutive electrodes E1, E2, ..., E9 are galvanically isolated from each other.

Claims (9)

Patent claims 1. A method of producing a non-linear distribution of the electric field strength in an aqueous environment, which consists in supplying at least one positively polarized electrode and at least one negatively polarized electrode from a pulsed voltage source, characterized in that between at least one positively polarized electrode (E1 , E4, E3, E4) away from at least one negatively polarized electrode (E5, E6, E7, E8, E9), at least one pulsed electric field is generated, forming an electric field curtain, in which the field force lines are preferably perpendicular to the direction the flow of water and the direction of movement of fish. 2. The method according to p. The method of claim 1, characterized in that at least two electrodes (E1, E2, ..., E9) are supplied from an independent impulse voltage source such that the electric field lines extend through the entire cross section of the water intake or water outlet. 3. The method according to p. The method of claim 1, characterized in that at least one positively polarized electrode (E1) is positioned opposite to at least one negative electrode (E5) spaced therefrom. 4. The method according to p. 1, characterized in that the total active surface of the negatively polarized electrodes (E5, E6, E7, E8, E9) taking part in the current conductivity at a given moment is greater than the total active surface of the positively polarized electrodes (E1, E2, E3, E4) , the total active surface of the electrodes (E1, E2, ..., E9) involved in the conductivity of the electric current is changed by connecting or disconnecting successive electrodes (E1, E2, ..., E9) to an independent pulsed voltage source. 5. The method according to p. The method of claim 1, characterized in that at least two impulse curtains of electric field are created along the direction of the water flow and the direction of movement of the fish, whereby the field force lines of adjacent curtains are created by pairs of electrodes (E1, E2, ..., E9) powered by from independent sources of pulse voltage and are directed opposite. 6. An electrode system for producing a non-linear distribution of the electric field strength in an aqueous environment, comprising at least one positively polarized electrode and at least one negatively polarized electrode supplied from an independent pulse voltage source, characterized in that it has at least one positively polarized electrode (E1, E2 , E3, E4) away from at least one negatively polarized electrode (E5, E6, E7, E8, E9) which are connected to at least one independent pulse voltage source, the electrodes (E1, E2, ..., E9) ) are preferably arranged perpendicular to the direction of the water flow and the direction of movement of the fish along the water intake or outlet. 7. The system according to claim 1 The method of claim 6, characterized in that the electrodes (E1, E2, ..., E9) are mounted on opposite walls of the water turbine chamber, the length of the electrodes (E1, E2, ..., E9) being at least equal to the height and / or the width of the water turbine chamber. PL 226 907 B1 8. The system according to p. 6. The method according to claim 6, characterized in that the electrodes (E1, E2, ..., E9) are mounted on opposite walls of the water tunnel, the length of the electrodes (E1, E2, ..., E9) being at least equal to the height and / or width water tunnel. The system according to p. The method of claim 6, characterized in that the electrodes (E1, E2, ..., E9) are mounted on opposite walls of the water turbine chamber, the length of the electrodes (E1, E2, ..., E9) being at least equal to the height and / or the width of the water channel chamber.