KR20220057811A - Remote control underwater speaker of sunlight generating type - Google Patents

Abstract

The present invention relates to a sunlight generation-type remote underwater sound generator including: a float; a sound generation and output device detecting an underwater event occurrence situation and outputting a fish avoidance sound underwater; a driving control device controlling and driving the overall operation of the underwater sound generator; and a case where the float and the driving control device are installed. The sound generation and output device includes: a sound output unit outputting a sound underwater in a state of being positioned underwater by a wire connected to the case; and an event monitoring unit coupled to the sound output unit and detecting a movement within an underwater detection range in real time. The present invention is provided with a solar collector converting solar energy into electric energy and operates with a power source converting solar energy collected on the water by the solar collector into electric energy to perform power generation and supply. At the same time, the generator floating in an installation target area generates a fish-repelling fish avoidance sound underwater and propagates the sound depending on the underwater event situation.

Description

Solar power type remote underwater sound generator {REMOTE CONTROL UNDERWATER SPEAKER OF SUNLIGHT GENERATING TYPE}

The present invention relates to a photovoltaic power generation remote underwater sound generator, and more particularly, converts solar energy collected on water into electric energy and operates as a power source to supply and output a sound signal to the water according to an event situation It relates to a photovoltaic power generation remote underwater sound generator having an effective configuration for propagating and preventing loss.

In general, facilities such as power plants and factories take in the necessary water from the sea or river. There is a problem in that the flow of water is obstructed, thereby causing damage to facilities and death of fish.

Therefore, there is a need to develop a technology that can exterminate fish in the water or in the water around power plants and factory facilities. Disclosed is a prior art for preventing fish from flowing into a water intake part of a facility by generating a fish avoidance sound that is disliked.

In order to implement such a technology for combating marine life, an underwater acoustic generator that generates a fish avoidance sound in the water is required, and a floating body floating on the sea level capable of maintaining the underwater acoustic generator at a required underwater position needs to be used. When a battery is used as a power source in implementing the underwater sound generator, since a regular battery replacement operation must be performed, maintenance may be very cumbersome.

In general, foamed Styrofoam can be used as a material of the floating body, but in this case, there is a problem of causing marine pollution. A barrier net can be used to prevent fish from entering the installation area. If a barrier net is used, foreign substances floating in the water or in the water according to the flow of water are caught and the barrier net is damaged due to its weight or the problem of blocking the flow of water. In addition, when foreign substances caught in the blocking net are accumulated, there is a problem in that the floating body leaves the fixed place and is lost due to the flow, velocity, and weight of water.

Republic of Korea Patent Publication No. 10-1486437 (2015. 01. 26. Announcement).

The present invention has been developed to solve the problems of the prior art as described above, and it operates as a power source that converts solar energy collected on the water into electric energy and supplies it, while operating as a power source to output and propagate sound underwater according to the event situation. An object of the present invention is to provide an underwater sound generator.

Another object of the present invention is to provide a remote underwater sound generator capable of maximizing a fish repelling effect by outputting a fish avoidance sound in an optimal direction to an approaching fish.

In the present invention, in order to achieve the above object, it operates as a power source that converts solar energy collected while floating in a state in which a plurality of groups form a single or spaced group on the water surface of the installation target area and converts it into electric energy, Provided is an underwater sound generator that generates and propagates a fish avoidance sound underwater depending on an event situation in a state that is stretched underwater through a wire.

The underwater sound generating device 100 of the present invention is a buoy made of a volume and floating on the water surface, a sound generating output device that is located in the water and outputs a fish avoidance sound to the water by grasping the event occurrence situation in the water, underwater It is configured to include a driving control device for controlling and driving the overall operation of the sound generating device, and a case 170 in which the floating tool and the driving control device are installed. In the present invention, the sound generating output device is installed in combination with the sound output unit 210 for outputting sound underwater in a state of being located in the water by a wire connected to the case 170, and the sound output unit 210 to be installed in the water. It includes an event monitoring unit 220 that detects a movement within the detection range in real time.

In the present invention, the driving control device includes: a solar light collecting unit 120 that collects sunlight and converts it into electric energy; a power supply unit 130 that converts the electric energy supplied from the photovoltaic collecting unit 120 into operating power and supplies it immediately or after charging to an electrical operating part; a communication unit 140 for transmitting and receiving information including control signals, operation data, and sound data by accessing the remote control device through a communication network; a sound driving unit 150 for providing preset and stored sound including an amplifier circuit; The solar collection unit 120 and the power supply unit 130 control so that power generation, charging, and supply are made within a set level and rated capacity range, and when an event occurrence signal is applied, the sound driving unit 150 is operated to match the event Control unit 160 that controls the generation of sound signals, transmits operation state data to the remote control device through the communication unit 140, or receives uploading data including the control signal of the remote control device through the communication unit 140, stores and controls It may be composed of

In the present invention, the buoyancy 110 is a volume body having a shape in which a central through-path is formed in the center, and may be made of a hollow space volume or a filled block volume body. The case 170 is configured to include an upper fixed body 171 and a lower receptor 172 and a connecting body; The upper fixture is located on the upper part of the buoyancy and the lower receptor is located on the lower part of the sphere, and the connector passes through the central passage through the sphere, and the upper fixture and the lower receptor are connected to each other by the connector to form an integral body; The buoy 11 is positioned between the upper fixture and the lower receptor in the case and is installed to surround the connector; The solar light collecting unit is placed on the upper fixture and installed, so that the solar light collecting unit 120 is positioned on the uppermost part of the buoy. In particular, the power supply unit 130 , the communication unit 140 , the acoustic driving unit 150 , and the control unit 160 may be installed in the lower housing 172 of the case 170 .

In the present invention, the block volume constituting the sphere 110 is a volume obtained by foam injection molding of a mixture in which CaCO ₃ and TiO ₂ are added as functional components to EVA and PE, which are main components, and JTR blowing agent is added in a set ratio as a foaming inducing component. can be a chain

In the present invention, the control unit 160 may further perform a function of controlling the storage and transmission operations by converting the amount of sunlight, water temperature, water level, flow rate, and flow rate sensing signals into data when inputted.

In the present invention, a winding unit 180 for winding or unwinding the wire W by the rotation of the motor M in a state in which the wire W is wound may be further included, and the winding unit 180 is the case 170 . It may be installed in the lower receptor 172 of the.

In the present invention, the sound output unit 210 as a component located in the water is a housing-type case 211; a magnetic circuit including a stacked body of a magnet 213 and a top plate 214 stacked with a void and a center pole of an outer-shaped yoke 212 fixed to the inner central surface of the enclosure-type case 211; It may have a configuration including a diaphragm 216 for outputting sound by vibrating air while vibrating by the voice coil 215 that linearly moves (vibrates) in response to a magnetic force in a state drawn into the gap of the magnetic circuit.

In addition, in the present invention, the event monitoring unit 220 may include a detector for omnidirectionally detecting movement within a unit area, and an image collector for collecting images in a direction in which movement is detected through the detector. , further, the event monitoring unit 220 may include each sensor module for detecting the amount of sunlight, water temperature, water level, flow rate and flow rate.

In the present invention, the fixing part 230 is an anchor, and may be made of a weight body provided with a protrusion that is embedded and fixed in the underwater floor. Hanging from the wire wound on the mounting portion 190, the fixing portion 230 may have a configuration in which the fixing portion 230 is raised and lowered by winding or unwinding the wire.

In the present invention, the wire is a wire connecting the power supply unit 130, the sound output unit 210, and the event monitoring unit 220, and the sound driving unit 150, the sound output unit 210 and the control unit 160 and the event monitoring unit ( 220) may be formed of a waterproof electric wire cable in which the electric wire is buried.

The underwater sound generator according to the present invention outputs a fish avoidance sound having a sound wave that fish hates when a fish approaches in the water to prevent the fish from approaching, but converts solar energy collected from the water surface into electrical energy and operates By using it as a power source, continuous operation is achieved through self-generation without using a battery on the water or supplying power from the outside through a wire, thereby greatly reducing the manpower and cost for maintenance. is demonstrated

In addition, the underwater sound generating device according to the present invention has the advantage of being able to be stably positioned in the water without being lost due to the running water by the sound output unit for generating the sound by having a fixed part.

In particular, in the underwater sound generating device according to the present invention, the sound output unit is provided separately from the fixed part so that it can be individually raised and lowered in the water. The fish avoidance sound can be output at the location, thereby maximizing the fish repelling efficiency.

1 is a schematic diagram showing a state in which an underwater sound generating device according to an embodiment of the present invention is installed and operated.
2 is a schematic perspective view showing the configuration of an underwater sound generator according to an embodiment of the present invention.
3 is a schematic cross-sectional view showing in detail the configuration of the underwater sound generator shown in FIG.
4 is a schematic block diagram illustrating the configuration of an underwater sound generator according to an embodiment of the present invention in block units.
Figure 5 is a schematic cross-sectional view showing only the components located on the water in the underwater sound generating device according to another embodiment of the present invention further comprising a winding portion.
6 is a schematic diagram corresponding to FIG. 1 showing a state in which an underwater sound generating device according to another embodiment of the present invention further provided with a fixing part is installed and operated.
7 is a schematic block diagram corresponding to FIG. 4 showing the configuration of an underwater sound generating device according to another embodiment of the present invention, in which a fixing part is separately provided.
8 is a schematic diagram corresponding to FIG. 1 showing a state in which the underwater sound generating device of the present invention having the configuration of FIG. 7 is installed and operating.
9 and 10 are schematic perspective views of specific embodiments of the sound output unit, respectively.
11 is a schematic diagram showing an example of arranging the underwater sound generator of the present invention while forming a plurality of groups in the reservoir sluice area.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Although the present invention has been described with reference to the embodiment shown in the drawings, which is described as one embodiment, the technical idea of the present invention and its core configuration and operation are not limited thereby. For convenience, in the present specification including the claims, the solar power type remote underwater sound generator according to the present invention is abbreviated as "underwater sound generator 100".

1 is a schematic diagram showing a state in which an underwater sound generating device 100 according to an embodiment of the present invention is installed and operated in water. FIG. 2 is a schematic perspective view showing the configuration of the underwater sound generator 100 according to an embodiment of the present invention, and FIG. 3 is a schematic view showing the configuration of the underwater sound generator 100 shown in FIG. 2 in detail A cross-sectional view is shown. 4 is a schematic block diagram showing the configuration of the underwater sound generator 100 according to an embodiment of the present invention in block units.

As illustrated in FIG. 1 , the underwater sound generating device 100 of the present invention collects solar energy while floating singly or in a state in which a plurality of them form a group at an interval to collect electrical energy in the water of the installation target area. It is a device that generates and propagates a fish avoidance sound that fish hates depending on the event situation in the water. The underwater sound generating device 100 of the present invention includes a buoy 110 made of a volume body having a volume so as to generate buoyancy, and an underwater event (eg, approach of fish, Controls the overall operation of the sound generating and output device for generating sound by detecting the occurrence situation of other moving objects or approaching it, and the underwater sound generating device 100 including the sound generating output device And it is configured to include a drive control device for driving, and a case in which the floating tool and the drive control device are installed.

First, looking at the buoy 110 corresponding to the "water component" located in the water, as illustrated in the cross-sectional view of FIG. 3 , the buoy 110 may have a shape through which the center is penetrated. It may consist of a "space volume" having a volume of

The block volume constituting the sphere 110 is manufactured by foam injection molding using a mixture in which CaCO ₃ and TiO ₂ are added as functional components to EVA and PE, the main components, and JTR blowing agent is added in a set ratio as a foaming inducing component. it may have been When the buoy 110 is manufactured, EVA (ethylene-vinyl acetate) and PE (polyethylene; polyethylene) can be used as main components. EVA is a new chemical material combining ethylene and vinyl acetate, which is transparent, has adhesiveness and flexibility. PE has the advantage of being excellent, and as a thermoplastic general-purpose resin, it has excellent mechanical performance, moisture resistance, moisture resistance, cold resistance, chemical resistance, electrical insulation, and excellent moldability. PE can be applied to two types of low-density polyethylene with a low degree of crystallinity and high-density polyethylene with a high degree of crystallinity depending on the pressurization conditions of manufacture.

In manufacturing the sphere 110, ZnO and neoprene (neoprene) may be added. Neoprene is similar to synthetic organic compound (polymer) rubber with good elasticity and high molecular weight, and a simpler compound 2-chloro-1 , 3 - It is made by combining butadiene (chloroprene). Neoprene is more resistant to oil, solvents, heat and weathering than natural rubber. As such, when the buoy 110 is manufactured with a material containing expanded polyethylene (EPE) including EVA and PE as the main component, durability, moisture resistance, moisture resistance, cold resistance, and the like can be greatly improved.

When manufacturing the buoy 110, if CaCO ₃ (calcium carbonate; free calcium carbonate), a functional ingredient, is added, the above function can be further strengthened, and TiO ₂ (titanium dioxide; titanium dioxide) is further added as a strengthening ingredient. may contain. TiO ₂ is a molecule in which one titanium atom and two oxygen atoms are bonded, and has a molecular weight of 79.866 g/mol, and is a tasteless, odorless white powder. When titanium is exposed to air, it readily reacts with oxygen to form a titanium dioxide film. Because it is a relatively large sunscreen of 3.0~3.2eV, it absorbs light in the ultraviolet (ultraviolet wave) region and acts as a photocatalyst, oxidizing organic materials by radical reaction, and removing antibacterial and odors. It is possible. In the manufacture of the buoyancy 110, JTR foaming agent may be used as a foaming-inducing component, which is economical in manufacturing a foam due to a large amount of generated gas. In addition, it is also preferable to add ST-A, A-172, U/BLUE, and an odorless crosslinking agent during the manufacture of the buoyancy 110 .

In manufacturing the buoyancy 110 by foam injection molding, it is preferable to perform injection molding in an accurate shape by firstly performing foam injection molding in an incomplete shape and then cooling the mold to a complete shape secondarily. The buoyancy 110 may be made of a block volume body as mentioned above. By injection molding by controlling the temperature, time, and pressure conditions, the buoyancy 110 is manufactured as a high-density block volume body having no space therein, thereby providing durability and buoyancy of the buoyancy 110 . that can increase

The case 170 is configured to include an upper fixed body 171 and a lower receptor 172 and a connecting body. The upper fixture 171 is located on the upper part of the sphere 110 and the lower receptor 172 is located under the sphere 110. By this, the upper fixed body 171 and the lower receptor 172 are connected to each other to form a single member called the case 170 . That is, the upper fixed body 171 is located above, the lower receptor 172 is located below, and the upper fixed body 171 and the lower receptor 172 are connected by a vertical connection body to form an integral body 170 to form a case 170. is formed, and the buoyancy 110 is positioned between the upper fixed body 171 and the lower receptor 172 in the case 170 to surround the connector.

Next, the drive control device will be described. The driving control device is configured to include a solar light collecting unit 120 , a power supply unit 130 , a communication unit 140 , a sound driving unit 150 , and a control unit 160 .

The solar light collecting unit 120 is installed on the upper part of the buoy 110 as a configuration for collecting sunlight and converting solar energy into electrical energy. In the case of the embodiment illustrated in the drawing, the solar light collecting unit 120 is placed on the upper fixed body 171 of the case 170 and installed, so that the solar light collecting unit 120 is located on the uppermost part of the buoy 110 . Although not clearly shown in the drawings, the antenna of the communication unit 140 may be fixedly installed on the upper fixed body 171 . The solar light collecting unit 120 may have a configuration in which a plurality of solar cell modules are arranged in a matrix form at intervals. The solar cell (solar cell) module constituting the solar light collection unit 120 converts solar energy into electrical energy. An internal electric field generated and formed in the junction region may have a configuration in which electrons move to the N-type semiconductor and holes move to the P-type semiconductor to generate an electromotive force. The electrode to which the N-type semiconductor and the P-type semiconductor are attached becomes a negative electrode and a positive electrode, respectively, and takes a direct current. The sunlight collecting unit 120 is preferably protected by a transparent protective cover on the upper side.

The power supply unit 130 is a component that converts the electric energy supplied from the solar light collection unit 120 into operating power and immediately supplies it to the electrical operation part or supplies it after charging. Specifically, the solar light collection unit 120 applies It may be configured to include a power conversion circuit including a constant voltage circuit for converting the electrical energy to be operated power, and a charging circuit including a battery for charging the power.

The communication unit 140 is configured to communicate so that the underwater sound generating device 100 of the present invention can be operated through remote control. Specifically, it is connected to the remote control device through a communication network to control signals, operation data and sound data. It is a component that transmits and receives information including Communication unit 140, LoRa network (LoRa), NFC (near field communication) communication, Bluetooth communication, z wave communication, beacon communication, infrared communication, Wi-Fi communication, and mobile communication (eg, 3G, 4G, or 5G) communication) may include a communication module that performs an IoT function through at least one communication service. The communication unit 140 not only transmits and receives information data and control signals to and from a remote control device, but also when the underwater sound generating device 100 of the present invention is arranged in a group by gathering a plurality of each underwater sound generating device ( 100) to communicate and share information and control signals while performing a function of interworking.

The sound driving unit 150 is a component that drives to generate a preset and stored fish avoidance sound, and includes an amplifier (AMP) circuit for amplifying the stored sound source.

The control unit 160 controls the overall operation of the underwater sound generating device 100 according to the present invention, and the solar light collecting unit 120 and the power supply unit 130 generate power and charge and supply within the set level and rated capacity range. This is controlled to be performed, and when an event generating signal is applied, the sound driving unit 150 is operated to generate a sound signal matching the event, and the operation state data is transmitted to the remote control device through the communication unit 140 or remotely. The uploading data including the control signal of the control device is received through the communication unit 140 and stored and controlled. The control unit 160 may be implemented in the form of a control circuit including a microprocessor in which an algorithm or program for performing the above functions is mounted.

Specifically, the control unit 160 controls the solar light collection unit 120 and the power supply unit 130 to generate power, charge, and supply within a set level and rated capacity range. The control unit 160 determines the abnormal state, including the surge state, when energy above the set level and rated capacity is detected in the process of converting solar energy into electrical energy in the solar light collection unit 120 and blocks the inflow of electrical energy, and the power supply unit When the electrical energy provided to 130 detects more than a set level and rated capacity, it may block the inflow into the power circuit to protect the electrical circuit part.

When the event generation signal is applied, the control unit 160 operates the sound driving unit 150 to generate a sound matching the event. The control unit 160 detects data according to the occurrence of an event in the event monitoring unit 220 to be described later, for example, an object moving in water, collects image data of the detected object, and provides the provided image data to the fish stored in advance. The data is compared, and when the collected image data is a fish, the sound data stored corresponding to the fish is loaded and a fish avoidance sound is output through the sound output unit 210 to be described later.

In addition, the control unit 160 transmits the operation state data to the remote control device through the communication unit 140 or receives the uploading data including the control signal of the remote control device through the communication unit 140 to store and control it. Furthermore, the control unit 160 may also perform a function of controlling the storage and transmission operations by converting the sensing signals for the amount of sunlight, water temperature, water level, flow rate, flow rate, etc. into data when they are input. Accordingly, the control unit 160 may be implemented in the form of a control circuit including a microprocessor in which an algorithm or program capable of performing the above functions is mounted.

As such, the control unit 160 monitors the solar light collection and electrical energy conversion state of the solar light collection unit 120 , the use state and charging state of the electric energy supplied to the power supply unit 130 , and the event monitoring unit 220 . Information and status, the storage and use of the sound source of the sound output unit 210, the sound output state, and the overall operation state data of the device including the lifting state of the winding unit 180, which will be described later, are transmitted through the communication unit 140 to the remote control device , or receiving the uploading data including the control signal of the remote control device through the communication unit 140, storing and providing it as a control signal. In addition, when the detection signal for the amount of sunlight, water temperature, water level, flow rate, flow rate, etc. in the installed area is input from the corresponding sensor of the event monitoring unit 220, the control unit 160 converts it into data, stores it and transmits it to the remote control device to control

The drive control device is preferably located on the water surface rather than in the water. That is, the drive control device corresponds to the "water component". Each component of the drive control device may be located in the lower receptor (172). That is, in the case 170, the lower receptor 172 is located at the lower part of the buoy 110, and inside the lower receptor 172, the power supply 130, the communication unit 140, the sound driving unit 150 and the control unit ( 160) can be accommodated and provided.

In the underwater sound generating device 100 of the present invention, the winding unit 180 may be further included as a water component. 5 is a schematic cross-sectional view showing only the components located on the water in the underwater sound generating device 100 according to another embodiment of the present invention further comprising a winding unit 180 is shown. A wire W is wound around the winding unit 180, and the sound output unit 210 and the event monitoring unit are coupled to the lower end of the wire W by winding or unwinding the wire W under the control of the controller 160. After the 220 is lowered to a desired position, it is stopped, and the sound output unit 210 and the event monitoring unit 220 are recovered through the lifting and lowering. In the underwater sound generating device 100 of the present invention, the fixing part 230 may be provided at the lower part of the sound output unit 210. In this case, the fixing part 230 is the underwater floor by the operation of the winding unit 180. The sound output unit 210 may be lowered until it is embedded in the surface.

The winding unit 180 has a configuration to wind or unwind the wire W by the rotation of the motor M, and the winding unit 180 is a lower receptor located at the lower side of the case 170 as illustrated in FIG. 5 . It may be provided in a form accommodated inside the (172). At this time, in the winding unit 180, the wire W is wound around the winding roller. It is preferable that the motor (M) is installed to be protected with a waterproof structure in the lower inner side of the case 170, and at this time, the motor (M) is connected to the winding roller through a waterproof bearing. The above series of operations of the winding unit 180 is controlled by the control unit 160 .

Hereinafter, a sound generating output device provided in the underwater sound generating device 100 of the present invention will be described. The sound generating output device includes a sound output unit 210 and an event monitoring unit 220 as a component located in the water, that is, as a “underwater component”. Although it does not correspond to the sound generating output device, an additional fixing part 230 as an underwater component may be further provided in the underwater sound generating device 100 of the present invention.

6 is a schematic diagram corresponding to FIG. 1 showing a state in which the underwater sound generating device 100 according to the embodiment of the present invention provided with the fixing unit 230 installed directly on the sound output unit 210 is operating in the water. is shown. The sound output unit 210 constituting the sound generating output device is a member that is coupled to the lower end of the wire (W) connected to the case 170 and outputs sound underwater in a state in which it is stretched underwater, that is, it is a kind of water vapor speaker. As illustrated in FIG. 3 , the sound output unit 210 includes a housing-type case 211 , and a magnet stacked with a gap with the center pole of the outer-shaped yoke 212 fixed to the inner central surface of the housing-type case 211 . Vibration of air while shaking by a magnetic circuit including a laminate of 213 and a top plate 214, and a voice coil 215 that linearly moves (vibrates) in response to magnetic force while being drawn into the gap of the magnetic circuit It may have a configuration including a diaphragm 216 that generates sound and outputs sound. Of course, the sound output unit 210 is not limited to the above-described configuration, as long as it is a device capable of outputting sound in water, and may be configured by variously changing it.

The sound generating output device may further include an event monitoring unit 220 , and the event monitoring unit 220 is installed at the same position or adjacent to the sound output unit 210 in the water. As illustrated in the figure, the event monitoring unit 220 may be provided in a fixed state to the outside of the sound output unit 210 . The event monitoring unit 220 is a component that detects the motion of an object within a detection range in real time and grasps an event situation in the water. The event monitoring unit 220 may further perform a function of collecting an image of the detected moving body. Specifically, the event monitoring unit 220 may have a configuration including a detector for omnidirectionally detecting movement within a unit area, and an image collector for collecting images in a direction in which movement is detected through the detector. there is. The detector provided in the event monitoring unit 220 may be a sound wave sensor that detects a moving object, that is, a moving object in the detection area through transmission of sound waves and reception of reflected sound waves. It may consist of a fish finder (sonar) that acquires data on the scale). The detector may be a sensor (eg, a motion sensor) that recognizes a moving object in another method other than a sensor using sound waves. The image collector provided in the event monitoring unit 220 may be composed of an image capturing device such as an infrared camera, and may include an A/D converter that converts an analog image signal into digital image data, and through the image collector It collects surrounding images.

The event monitoring unit 220 may further include a sensor module that additionally detects the amount of sunlight, water temperature, water level, flow rate, flow rate, etc., through which the event monitoring unit 220 includes the amount of sunlight, water temperature, water level, flow rate and flow rate. Various environmental information of the installation area is collected and provided to the remote control device, and the remote control device uses it as environmental evaluation data. The sensor module for detecting the amount of sunlight, water temperature, water level, flow rate, flow rate, etc. may be installed in the event monitoring unit 220 located in the water, but it is also preferable to be mounted on the case 170 which is a water component.

As shown in FIGS. 4 and 6 , the present invention may further include a fixing unit 230 , wherein the fixing unit 230 is provided outside the sound output unit 210 or connected to a separate wire (W). It is provided as a component that exhibits a function of preventing the underwater sound generating device 100 of the present invention from being lost by being fixed to the underwater floor surface. When the fixing part 230 is fixed to the underwater floor, the underwater sound generating device 100 is fixed to a specific area without being washed away or flowing by the flow of water. In the case of the embodiment shown in FIG. 6 , the fixing unit 230 is provided under the sound output unit 210 .

Alternatively, the fixing unit 230 may be provided separately from the sound output unit 210 in the form of hanging on the wire W.

7 is a schematic block diagram corresponding to FIG. 4 showing the configuration of an underwater sound generating device 100 according to another embodiment of the present invention, which is separately provided with a fixing part 230, and in FIG. 8 A schematic diagram corresponding to FIG. 1 showing a state in which the underwater sound generating device 100 of the present invention having the configuration of 7 is installed and operating is shown. 7 and 8, the fixing part 230 is separately provided to elevate and descend by the wire (W). As shown in FIG. 7 for winding the wire W on which the fixing part 230 is suspended, a fixing winding part 190 may be further provided. As the wire (W) is wound or unwound by the operation of the fixing winding unit 190, the fixing unit 230 is raised and lowered. The fixing winding unit 190 may be installed in the lower housing 172 of the case 170 .

On the other hand, so that the fixing part 230 can be firmly fixed by being embedded in the underwater bottom, the specific shape of the fixing part 230 may be made of a weight body provided with protrusions that are embedded and fixed in the underwater bottom. In particular, the fixing part 230 may be formed in the form of an anchor. As described above, when the fixing unit 230 is provided separately from the sound output unit 210 and the event monitoring unit 220 , the sound output unit 210 and the event monitoring unit 220 are separated from the fixing unit 230 . Separately, they perform their respective functions while ascending and descending independently.

In configuring the sound output unit 210, the structure may be configured to easily generate sound in a desired direction. 9 and 10 are schematic perspective views of a specific embodiment of the sound output unit 210, respectively. In composing the sound output unit 210, both ends of the main body forming the sound output unit 210 are provided with brackets 240 having a '┏┓' shape, that is, an open part of the Hangul consonant 'C' faces downward. It is rotatably coupled to the bracket 240 so that the sound output unit 210 is rotated in a desired direction. As illustrated in the drawing, the event monitoring unit 220 may be fixedly installed on the bracket 240 . In the drawings, reference numeral 241 denotes a motor 241 for rotating the main body of the sound output unit 210 .

Hereinafter, a detailed operation form of the underwater sound generating device 100 according to the present invention will be described in summary.

In a place requiring installation, the underwater sound generating device 100 of the present invention is placed in a floating state. The float 110 is floated on the water surface, and at this time, a portion of the case 170 is exposed to the water surface. The sound output unit 210 and the event monitoring unit 220, which are underwater components connected to the wire (W), are located in the water in a state connected to the wire (W). In this state, when a fish approaches underwater, the event monitoring unit 220 detects the approach of the fish as a moving body, and the control unit 160 operates the sound driving unit 150 and the sound output unit 210 to By generating a fish avoidance sound, the fish will not be approached.

In the case of the underwater sound generating device 100 according to the present invention in this type of operation, the solar energy collected by the solar light collecting unit 120 is converted into electric energy and used as the operating power. Therefore, the underwater sound generating device 100 of the present invention is continuously and repeatedly operated through self-generation without using a battery or supplying power from the outside by wire, unlike the prior art. It has the advantage of reducing costs and manpower.

When the fixing part 230 is provided in the underwater sound generating device 100 of the present invention, the fixing part 230 is fixed to the underwater bottom surface, so that the underwater sound generating device 100 is floated away by the flow of water or does not flow. Without it, the state in which it was originally installed is maintained stably. The control unit 160 controls the winding unit 180 to unwind the wire W to lower the sound output unit 210 and the event monitoring unit 220. As shown in FIG. 6, the fixing unit 230 is In the case of the embodiment provided in the lower portion of the sound output unit 210, the control unit 160 continuously monitors the vertical downward load applied to the wire (W) while the sound output unit 210 is lowered. When the fixing part 230 reaches the bottom surface of the water, the vertical downward load is no longer applied to the wire (W). The control unit 160 continuously monitors the vertical downward load applied to the wire W while the sound output unit 210 is lowered as described above, and the control unit 160 continuously monitors the vertical downward load on the wire W. When it is recognized that this is not applied, it is considered that the fixing unit 230 has reached the bottom surface of the water and automatically stops the lowering operation of the wire W by the winding unit 180 .

On the other hand, as shown in FIG. 8, when the fixing unit 230 is separately provided in a form connected to the wire W that is raised and lowered by the fixing winding unit 190, underwater sound is generated at a place requiring installation. In a state in which the device 100 is placed and the float 110 is floating, the control unit 160 outputs a control signal to unwind the wire W wound on the fixing winding unit 190 to lower the fixing unit 230 into the water. It is then anchored to the bottom of the water to make it fixed. And by controlling the winding unit 180 to adjust the winding and unwinding of the wire W wound around the winding unit 180, the control unit 160 controls the sound output unit 210 and the event monitoring unit connected to the wire W. (220) is freely raised and lowered to the desired position to make the position. That is, in the case of the embodiment in which the fixing unit 230 is provided separately, the sound output unit 210 and the event monitoring unit 220 in a state in which the loss of the underwater sound generating device 100 is prevented by the fixing unit 230 . can be independently raised and lowered independently of the fixing unit 230 . Therefore, as described above, when it is confirmed that the fish approaches, the wire W is wound or unwound by the operation of the winding unit 180 to move the sound output unit 210 to an optimal position close to the approach position of the fish. By outputting a fish avoidance sound, the fish do not approach. As described above, the underwater sound generating device 100 of the present invention is provided with the fixing part 230 to prevent it from being washed away by the current, as well as to produce a fish avoidance sound in a state as close as possible to the approaching fish. It is possible to increase the efficiency of fish repelling significantly.

When the main body of the sound output unit 210 has a configuration rotatably coupled to the bracket 240 as in the embodiment described with reference to FIGS. 9 and 10 above, the event monitoring unit 220 detects an approaching fish. When the signal is transmitted to the control unit 160, the control unit 160 calculates the position of the approaching fish or the angle at which the fish approaches based on the event monitoring unit 220, and operates the motor 241 by the corresponding angle to make sound. In a state in which the main body of the output unit 210 is rotated with respect to the bracket 240 , a fish avoidance sound is output. That is, by outputting the fish avoidance sound in a state in which the sound output unit 210 is positioned in the most optimal direction for the repelling of fish, the fish repelling effect is further maximized.

11 is a schematic diagram showing an example of arranging the underwater sound generating device 100 of the present invention while forming a plurality of groups in the reservoir sluice area. As shown in FIG. 11, by arranging a plurality of underwater sound generating devices 100 of the present invention to form a group, the fish for a desired area (eg, reservoir sluice area, water supply port area of a power plant, etc.) You can completely block access. In particular, in arranging a plurality of underwater sound generators 100, it is possible to form a tip shape by dividing it into "Master" and "Slave", and through this, access of fish is further improved. It has a complete blocking effect.

100: underwater sound generator 110: buoy
120: solar collector 130: power supply
140: communication unit 150: sound driving unit
160: control unit 170: case
180,190: winding unit 210: sound output unit
220: event monitoring unit 230: fixed unit
240: bracket 241: motor
W: Wire M: Motor

Claims (8)

An underwater sound generator that generates and propagates a fish avoidance sound that fish hates depending on the event situation in the water while floating in the installation target area.
A buoy that is made of a volume and floats on the water surface, a sound generating output device that is located in the water and outputs a fish avoidance sound to the water by detecting the occurrence of an event in the water, a drive control device that controls and drives the overall operation of the underwater sound generator, and a case in which the float and the drive control device are installed;
The sound generating output device includes an audio output unit for outputting a sound to the water in a state located underwater by a wire connected to the case, and an event monitoring unit that is installed in combination with the sound output unit to detect a movement within a detection range underwater in real time. includes;
The driving control device includes: a solar light collecting unit that converts solar energy into electrical energy; and a power supply unit that converts the electric energy supplied from the solar light collection unit into operating power and supplies it immediately or after charging to an electrical operating part; A communication unit for transmitting and receiving information including control signals and data by connecting to a remote control device through a communication network, a sound driving unit for generating preset and stored sound, and the solar collector and the power supply unit within a set level and rated capacity range Controls power generation, charging, and supply. When an underwater event occurs, the acoustic driving unit is operated to control to generate a sound matching the event. Underwater sound generating device, characterized in that it comprises a control unit for receiving, storing and controlling the uploading data including the communication unit. The method of claim 1,
The event monitoring department
A detector that detects movement within a unit area in all directions;
Underwater sound generator comprising an image collector for collecting an image in a direction in which motion is detected through the detector. 3. The method of claim 1 or 2,
The case is configured to include an upper fixed body, a lower receptor and a connecting body;
The upper fixture is located in the upper part of the buoyancy and the lower receptor is located in the lower part of the sphere, and the connector passes through the central passage through the sphere, and the upper fixture and the lower receptor are connected to each other by the connector to form an integral body;
Bugu is located between the upper fixed body and the lower receptor in the case and is installed to surround the connecting body;
The solar light collecting unit is placed on the upper fixture and installed so that the solar light collecting unit is located at the top of the buoy;
The power supply unit, the communication unit, the sound driving unit and the control unit are underwater sound generating device, characterized in that accommodated in the lower receptor. 3. The method of claim 1 or 2,
A winding unit that winds or unwinds the wire to which the sound output unit is coupled by the rotation of the motor is further provided,
Underwater sound generating device, characterized in that the wire is wound or unwound by the operation of the winding unit, and the sound output unit is raised and lowered. 3. The method of claim 1 or 2,
The underwater sound generator, characterized in that it is provided in the sound output unit itself or is provided in a state connected to a wire and fixed to the underwater floor surface, further comprising a fixing part for preventing the underwater sound generator from being lost. 6. The method of claim 5,
The fixture is suspended from the wire,
An underwater sound generating device, characterized in that it further comprises a fixing winding part for elevating and lowering the fixing part by winding and unwinding the wire. 3. The method of claim 1 or 2,
sound output unit,
enclosed case;
a magnetic circuit including a stacked body of a top plate and a center pole of an outer-shaped yoke fixed to the inner central surface of the enclosure-type case, and a magnet stacked with a gap therebetween; and
The underwater sound generating device, characterized in that it has a configuration including a diaphragm for outputting sound by generating vibration of air while vibrating by a voice coil that moves linearly in response to a magnetic force in a state that is drawn into the gap of the magnetic circuit. 3. The method of claim 1 or 2,
The sound output unit is provided with a bracket having a shape in which the open part of the Hangul consonant "C" faces downward;
Both ends of the main body constituting the sound output unit are rotatably coupled to the bracket so that the sound output unit can be rotated in a desired direction;
When the event monitoring unit transmits a signal for detecting an approaching fish to the control unit, the control unit calculates the position of the approaching fish or the angle at which the fish approaches based on the event monitoring unit, and by operating the corresponding angle, the main body of the sound output unit is attached to the bracket. An underwater sound generator, characterized in that it outputs a fish avoidance sound in a state rotated for.

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