KR100950970B1 - Observation system for waterway on the seabed - Google Patents

Abstract

PURPOSE: By geographical of seafloor, collecting a geometrical information to a basis directly fired from seafloor a strain location survey to a sea water according to a submarine topography change and Sailing Direction format information confirming system conspicuously reduce the possibility about the interference of the sound wave and annihilation. CONSTITUTION: Sonar comprises the calling module and receive module. The management device comprises the information processing module, the location information DB, the fuse module, the geographic information DB and renewal module. The detecting apparatus(100) comprises the anchor, the gripper(120), the housing, the sound wave generation means, the controller(150) and battery(160) of the porosity concrete material. The calling module fires the sound wave of the sound wave generation means and sound wave having frequency of the other band. The receive module receives a message the sound wave of the calling module and sound wave of the detecting apparatus, the information processing module confirms each sound wave information of the detecting apparatus.

Description

Observation system for waterway on the seabed

The present invention precisely checks the topographical / geographical variations of the waterway and the topographical information naturally formed on the seabed, so that the deformation of the waterway according to the change of the seabed can be supplemented and updated in real time. It relates to a hydrographic information verification system.

The ocean is a treasure trove of resources, but most of the region is unexplored. This is due to the inadequate technical level of equipment to withstand water pressure at deep depths and the lack of topographic and geographical information on the seabed including the oceanic waterways.

In particular, in the case of marine equipment such as submarines are operated based on the topographic information of the sea floor, human access is virtually impossible in areas where there is no sea floor information.

In addition, even if the topographical / geographical information is collected from the sea floor that is accessible to humans, erosion and sedimentation of the sea floor by the continuously flowing seawater occur relatively faster than on the ground, requiring periodic updates to the sea floor information. It became.

In the past, a sonar such as a sonar was used to collect topographic and geographical information of the ocean floor. Sonar fires sound waves underwater and receives reflected sound waves and analyzes them to see information on the bottom.

However, the bottom of the sea was made of high-absorbent soil, and various seaweeds were planted on the surface, and the sound waves emitted from the sonar were easily lost. In addition, various large-scale fish and shellfish may also allow the sonar to be detected as a terrain while reflecting the sound waves emitted from the fish and shellfish.

Accordingly, the present invention has been made to solve the above problems, it is possible to increase the reliability of the bottom information obtained through the topographical / geographical information collection method of the sea floor using sound waves, which is required when The technical problem is to provide a system for measuring the strain of the ocean channel according to the change of the seabed topography and minimizing the marine pollution while minimizing the economic cost.

According to an aspect of the present invention,

A plurality of locking portions 113 protruding for binding to the sea surface is formed on the bottom, anchor 110 of the porous concrete material is formed on the top fixing projection 112; A pair of restraints 121 and a pair of restraints 121 are detachably engaged with the fixing protrusion 112 while being folded to be rotated by a hinge 122 to function as a forceps, and one of the pair of restraints 121. Electromagnet 123 to be mounted, a magnetized body 124 mounted on the other of the pair of restraint band 121 corresponding to the magnetic force of the electromagnet 123, and the restraint band 121 in contact with the fixing projection 112 A gripper 120 provided on one surface of the elastic body 125 to increase the binding force between the fixing protrusion 112 and the restraint band 121; The airtight buoyancy tank 131 is formed in the hollow, and the upper surface is closed while closing the buoyancy tank 131 with a cover 133 forming a flat surface, and rotatable with the gripper 120 via the hinge 122. A housing 130 connected; It emits sound waves while vibrating at a predetermined frequency, and is disposed on the upper surface of the cover 133, is fixed to the lifting platform 141 is moved to receive the water pressure is fixed to the cover 133 and movable, the conductive terminal 142 on the bottom Sound wave generating means 140 is elastically fixed to the elastic body 143; A controller 150 for controlling the driving of the sound wave generating means 140 and mounted on the buoyancy tank 131 of the housing 130; The gripper 120, the sound wave generation means 140, the controller 150 charges and supplies the power required for driving, mounted on the buoyancy tank 131 of the housing 130, spaced apart from the conducting terminal 142 A sensing device 100 formed of a battery 160 having a conducting stand 161 disposed to protrude so as to be in contact with the conducting terminal 142 when the sound wave generating unit 140 moves downward,

Transmission module 210 for emitting a sound wave having a frequency of a different band from the sound wave emitted from the sound wave generating means 140, and a receiving module 220 for receiving the sound wave emitted from the transmission module 210 and the sensing device 100 Sound wave detector (200) consisting of,

Check the sound wave information of the detection device 100 and the outgoing module 210 received by the sound wave detector 200, and calculate the numerical data as the position information on the bottom of the sea by calculating the GPS position of the probe (S) An information processing module 310; Location information DB 320 for storing numerical data identified in information processing module 310; A drawing module 330 showing an image of a sea bottom according to numerical data; A terrain information DB 350 for storing drawing image information data on the sea floor terrain; A management device (300) consisting of an update module (340) for completing the terrain information by linking the GPS information to the image, and updating and storing existing terrain information stored in the terrain information DB (350);

Strain measurement and channel topography information verification system of the sea channel according to the change of seabed topography, including.

Since the present invention can collect topographical / geographical information on the sea floor based on sound waves emitted directly from the sea floor, the possibility of interference and disappearance of the sound waves can be greatly reduced, and sound wave firing is completed. Since the sensing device can float and recover to the surface, it is possible to reduce the observation cost of the sea bottom through the recycling of equipment and minimize the possibility of marine pollution.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a view schematically showing a seabed observation through a confirmation system according to the present invention, Figure 2 is a block diagram showing a confirmation system according to the present invention, Figure 3 through a confirmation system according to the present invention It is a figure which shows the state of the secured bottom surface, and it demonstrates with reference to this.

Confirmation system according to the present invention is a plurality of sensing devices (100, 100 ', 100 "; collectively referred to as" 100 "below) distributed on the sea floor, the sound waves emitted by itself and the sound waves emitted from the sensing device 100 And a sound wave detector 200 for receiving the topographic information of the sea floor by receiving the sound wave, and a management device 300 installed on the probe S to analyze and process the information transmitted from the sound wave detector 200. do.

The sensing device 100 is a plurality of dogs are randomly distributed on the bottom surface of the submarine after being discharged from the probe (S) as shown, and has a sound wave emitting function by itself so that the sound wave detector 200 can receive Sound waves of a certain frequency continuously.

More specific structure of the sensing device 100 will be described in detail below.

The sound wave detector 200 is known, so that a public device 'sona' may be applied, and includes a transmission module 210 for generating and firing sound waves, and a receiving module 220 for receiving sound waves. At this time, the frequency of the sound wave transmitted from the transmitting module 210 and the frequency of the sound wave transmitted from the sensing device 100 should be made of different frequency bands for identification thereof. Of course, the sensing device 100 will emit sound waves of a unique frequency band for each sensing device 100 for identification with other sensing devices.

Since the detailed structure of the sound wave detector 200 is well-known and commonly used as described above, a detailed description of the design and structure of the sound wave detector 200 is omitted here.

The management device 300 is installed in the probe (S), and confirms and processes the information transmitted from the sound wave detector 200, the information processing module 310 for the information processing and the processed position information as data The numerical information is synthesized with the location information DB 320 for storing, the drawing module 330 for drawing the topography of the sea floor based on the location information processed by the information processing module 310, and the drawing bottom information. And an update module 340 for updating the existing bottom surface information, and a topographic information DB 350 for storing the updated bottom surface information.

The information processing module 310 calculates the distance from the sound wave detector 200 to the sensing device 100 by checking the intensity of the sound wave emitted from the sensing device 100. In this case, since the sound waves emitted from the sensing device 100 are emitted directly from the sensing device 100 rather than the reflected waves on the sea bottom, the accuracy of the reflected waves detected by the sound wave detector 200 is very high. Therefore, the information processing module 310 can accurately check the position of the sensing device 100 as shown in FIG. In addition, since the information processing module 310 confirms the position of the probe S through GPS, it is possible to estimate the position of the sensing device 100 with high reliability based on this.

On the other hand, the sound wave detector 200 receives the reflected wave for the sound wave emitted from the transmitting module 210 in the receiving module 220, and transmits the collection information to the information processing module 310. Of course, the information processing module 310 checks the collection information and calculates surface information of the sea floor on which the sensing device 100 is distributed.

The information collected by the sound waves emitted by the sound wave detector 200 itself is utilized as auxiliary information in the information collected by the sensing device 100. That is, as shown in FIG. 3, since the information collected by the sensing device 100 is represented by a bent topography rather than a smooth seabed, auxiliary information for correcting this is necessary.

The location information DB 320 stores final location information processed by the information processing module 310. The position information is numerical data obtained by the information processing module 310 and the collection information collected by the sensing device 100 and the sound wave detector 200 itself is linked to the GPS information, the location information DB 320 Can be recorded.

The drawing module 330 draws the topographical / geographical shape of the sea floor based on the positional information processed by the information processing module 310, and allows a three-dimensional shape of the sea bottom to be output through the three-dimensional drawing process.

The update module 340 completes the topographic information of the bottom by applying GPS information to the topographical image of the seabed surface, and if there is existing topographic information on the bottom, it can be updated with the newly completed topographic information. have.

The terrain information DB 350 stores the completed and updated terrain information in the update module 340. The terrain information recorded in the terrain information DB 350 may proceed with seabed exploration using mobile marine equipment such as a submarine. In addition, it may be used for positioning purposes such as various offshore drilling and mineral extraction.

Figure 4 is a cross-sectional view showing a sensing device of the confirmation system according to the present invention, Figure 5 is a cross-sectional view showing the operation of the sound wave generating means according to the present invention, it will be described with reference to this.

The sensing device 100 according to the present invention is disposed on the anchor 110, the gripper 120, the housing 130 connected to the anchor 110 via the gripper 120, and the upper surface of the housing 130. The sound wave generation means 140, the controller 150 for controlling the driving of the sound wave generation means 140, and the battery 160 for supplying power for driving the sound wave generation means 140 and the controller 150 Include.

The anchor 110 is a member having a sufficient density and load to allow the sensing device 100 to dive underwater, and may be made of concrete.

The anchor 110 is preferably a shape that can be quickly moved while minimizing the influence of seawater when submerged underwater after being discharged from the probe (S). Therefore, it would be better to form a streamline in the diving direction. In addition, the locking portion 113, such as a projection, should be formed on the bottom so that the current position can be held without slipping when it arrives at the inclined sea level.

On the other hand, since the anchor 110 remains on the sea bottom when the sensing device 100 is injured, it is preferable to form a structure that is easy to inhabit various fish and shellfish, and in consideration of this, various spaces are formed inside such as porous concrete Can be made.

Subsequently, the anchor 110 further includes a fixing base 111 and a fixing protrusion 112 for binding with the housing 130. Here, the fixing stand 111 is a belt for fixing the anchor 110, the body is fixed, the fixing protrusion 112 is a projection that is connected to the holder 111 to engage with the gripper 120. For reference, the fixing protrusion 112 may have a shape that can be easily separated from the gripper 120 when the function of the gripper 120 is stopped due to the discharge of the battery 160. Therefore, in the embodiment according to the present invention, the shape of the fixing protrusion 112 is tapered to the shape of the lower side, so that the side is tapered, a pair of restraints according to the side guide of the fixing protrusion 112 when the gripper 120 moves upward. Allow 121 to open naturally to each other.

The gripper 120 is a pair of restraints 121 are pivotally connected to the hinge 122 to be rotated to function as a forceps, and a pair of restraints 121 surrounds the fixing protrusion 112. While fixing, the gripper 120 and the fixing protrusion 112 are closely connected to each other.

On the other hand, the grip force of the gripper 120 required for close connection with the fixing protrusion 112 is generated from the magnetic force. In more detail, one of the pair of restraint bands 121 has an electromagnet 123 therein, and the other has a magnetization body 124 corresponding to the electromagnet 123 therein. Of course, the material of the restraint band 121 is a material capable of passing magnetic force while having a waterproof function, and the electromagnet 123 is built in the restraint band 121 so that electric power is supplied without contact with seawater. Will be performed. For reference, the restraint band 121 may be made of a synthetic resin material.

On the other hand, the magnetization body 124 in response to the attraction force in response to the magnetic force of the electromagnet 123, a metal, in particular, an excellent magnetic properties will be applied.

As a result, the electromagnets 123 and the magnetized bodies 124 respectively installed in the pair of restraint bands 121 are bonded to each other by mutual attraction, and the bonding force is utilized as the grip force on the fixing protrusion 112, thereby providing a gripper ( It is possible to achieve a close bond between the 120 and the fixing projection 112.

The gripper 120 according to the present invention may be provided with an elastic body 125 of a material having a high friction coefficient and elastic modulus on one surface of the gripper 120 integrated with the fixing protrusion 112. The elastic body 125 may further enhance the binding force between the fixing protrusion 112 and the gripper 120 to firmly connect the anchor 110 and the housing 130. For reference, the elastic body 125 may be a rubber material applied.

The housing 130 is a housing having a buoyancy tank 131 that is hollow and airtight, and the buoyancy tank 131 is filled with air as well as sound wave generation means 140, controller 150, and battery 160. do. Of course, the buoyancy tank 131 is made of airtight and waterproof, the electronic equipment will be able to prevent damage due to immersion.

On the other hand, it is preferable that the housing 130 has a solid shape in order to minimize resistance when diving of the sensing device 100. However, the shape of the housing 130 is not limited to the solid shape.

As described above, the buoyancy tank 131 has a sufficient buoyancy for the rise of the sensing device 100 while the air is filled. However, since the injury of the sensing device 100 is made after the separation with the anchor 110, the buoyancy of the buoyancy tank 131 is not sufficient for the injury of the anchor 110, when the anchor 110 is separated You must have enough buoyancy to rise.

Since the housing 130 has a sound wave generating means 140 for emitting sound waves on its upper surface, the housing 130 should have a flat surface and manages the controller 150 and the battery 160 mounted in the buoyancy tank 131. In order to achieve the opening and closing structure. To this end, the housing 130 has a cover 133 that can be opened and closed to form an upper surface of the housing 130. Here, the opening and closing structure of the cover 133 may be variously modified without departing from the scope of the following claims as long as the structure can presuppose a waterproof function such as a screw method or a press-fit method.

The non-drawn number "132" is a "panel" disposed in the buoyancy tank 131, and functions as a shelf capable of fixing and supporting equipment such as the controller 150.

The sound wave generating unit 140 generates a sound wave so that the sound wave detector 200 can receive sound waves of a unique frequency band, and a method of forcibly vibrating the diaphragm may be applied.

On the other hand, the sound wave generating means 140 must be turned on for the drive, before the discharge into the water. That is, the sound wave generating means 140 is to emit a sound wave of a predetermined frequency before the sensing device 100 reaches the sea bottom. This is because the sound wave generating means 140 consumes power to substantially emit sound waves from the bottom of the sea, and thus there is a limit to sufficient sea level observation, and especially when the bottom surface is observed in a deep sea area in consideration of this limitation. There is a disadvantage in that a battery 160 having a large charge amount should be used.

Therefore, the sound wave generating means 140 according to the present invention further includes a lift table 141 which is movably fixed to the cover 133 which is the upper surface of the housing 130 while moving under hydraulic pressure, and energizes the battery 160. The energization terminal 142 for is fixed to be shot by the ball body 143. In addition, the battery 160 may be formed with a power supply terminal 161 protruding from the power supply terminal 142.

As a result, the sensing device 100 discharged from the probe (S) receives an increasing pressure while submerging underwater, the pressure is applied to the lifting platform 141, which is the upper surface of the housing 130, downward down the platform 141. Move to. Of course, the conducting terminal 142, which is connected to the lifting table 141 and mediates power supply to the sound wave generating means 140, also moves downward to be in contact with the conducting table 161 of the battery 160. Therefore, the sound wave generating means 140 is made when the electricity is supplied to the battery 160, which is a power source for driving to the bottom, it is possible to achieve efficient power consumption.

For reference, the ballistic body 143 is to maintain a stable energized state regardless of the vertical movement of the platform 141, when the power supply 161 and the power supply terminal 142 is located within a predetermined interval.

The controller 150 controls the power supply to generate sound waves of a specific frequency band while controlling the driving of the sound wave generating means 140. The operator 150 may estimate the depth or temperature of the seawater at the point where the sensing device 100 is located. According to various observation environments and conditions, the frequency of the sound wave emitted by the sound wave generating unit 140 may be adjusted through the controller 150.

The battery 160 supplies power required for driving the gripper 120, the sound wave generating unit 140, and the controller 150. If the battery 160 can continuously supply constant power such as a general battery and a rechargeable battery, the battery 160 may be variously divided. Application of the embodiment will be possible.

6 to 9 are diagrams sequentially illustrating an operation of the sensing device, which will be described with reference to the drawings.

As shown in FIG. 6, the sensing device 100 discharged from the probe S moves under water by the load of the anchor 110 and moves to the sea bottom.

The submerged sensing device 100 is disposed on the bottom of the sea, as shown in FIG. At this time, the anchor 110 seated on the sea bottom is bound to the sea bottom via a load and a locking portion 113 protruding from the bottom to adhere to the current position.

On the other hand, the housing 130 connected to the gripper 120 via the hinge 122 maintains a horizontal state regardless of the position of the anchor 110. This is due to the air filled in the buoyancy tank 131 of the housing 130, the housing 130 will continue to receive the force to rise to the water as described above.

Subsequently, the controller 150 controls the sound wave generating means 140 to be continuously driven so as to continuously emit sound waves that the sound wave detector 200 can receive. Of course, the continuous driving of the sound wave generating means 140 will consume the power charged in the battery 160. In addition, since the gripper 120 that physically connects the anchor 110 and the housing 130 also receives power from the battery 160 and continues to drive, the power charged in the battery 160 continues even by the gripper 120. Will be consumed.

As shown in FIG. 8, when the charging power of the battery 160 is exhausted, the gripper 120 and the sound wave generating unit 140 are stopped. That is, the gripper 120 is extinguished the grip force necessary for the physical binding between the anchor 110 and the housing 130, the sound wave generating means 140 does not emit any more sound waves.

On the other hand, when the grip force of the gripper 120 is extinguished, the pair of restraint bands 121 engaged by the magnetic force of the electromagnet 123 are separated from each other and separated from the fixing protrusion 112.

As shown in FIG. 9, when the gripper 120 and the fixing protrusion 112 are separated from each other, the housing 130 floats due to buoyancy and eventually floats to the water surface. Of course, the floating housing 130 is collected by the probe S, and the anchor 110 remaining on the sea surface is utilized as a habitat for various fish and shellfish and aquatic plants.

1 is a view schematically showing the seabed observation through the identification system according to the present invention,

2 is a block diagram showing a confirmation system according to the present invention;

3 is a view showing a state of the seabed secured through the confirmation system according to the present invention,

4 is a cross-sectional view showing a sensing device of a confirmation system according to the present invention;

5 is a cross-sectional view showing the operation of the sound wave generating means according to the present invention,

6 to 9 are views sequentially showing the operation of the sensing device.

-Explanation of terms for main parts of attached drawings-

100, 100 ', 100 "; sensing 110; anchor 120; gripper

130; A housing 140; Sound wave generating means 150; controller

160; battery

Claims (1)

Sound wave detector (200) consisting of a transmitting module (210) for emitting sound waves, and a receiving module (220) for receiving sound waves emitted from the transmitting module (210): and the transmitting module (210) received by the sound wave detector (200). An information processing module 310 for confirming sound wave information of and checking numerical data which is position information on the sea bottom by calculating the GPS position of the probe S; Location information DB 320 for storing numerical data identified in information processing module 310; A drawing module 330 showing an image of a sea bottom according to numerical data; A terrain information DB 350 for storing drawing image information data on the sea floor terrain; Linking the GPS information to the image to complete the terrain information and management device 300 consisting of an update module 340 for updating and storing the existing terrain information stored in the terrain information DB 350: In strain measurement and channel topography information confirmation system of ocean channel, A plurality of anchoring portion 110 is formed on the bottom protruding for engaging with the sea bottom surface, the fixing projection 112 is formed on the top surface of the porous concrete material 110; A pair of restraints 121 and a pair of restraints 121 are detachably engaged with the fixing protrusion 112 while being folded to be rotated by a hinge 122 to function as a forceps, and one of the pair of restraints 121. Electromagnet 123 to be mounted, a magnetized body 124 mounted on the other of the pair of restraint band 121 corresponding to the magnetic force of the electromagnet 123, and the restraint band 121 in contact with the fixing projection 112 A gripper 120 provided on one surface of the elastic body 125 to increase the binding force between the fixing protrusion 112 and the restraint band 121; The airtight buoyancy tank 131 is formed in the hollow, and the upper surface is closed while closing the buoyancy tank 131 with a cover 133 forming a flat surface, and rotatable with the gripper 120 via the hinge 122. A housing 130 connected; It emits sound waves while vibrating at a predetermined frequency, and is disposed on the upper surface of the cover 133, is fixed to the lifting platform 141 is moved to receive the water pressure is fixed to the cover 133 and movable, the conductive terminal 142 on the bottom Sound wave generating means 140 is elastically fixed to the elastic body 143; A controller 150 for controlling the driving of the sound wave generating means 140 and mounted on the buoyancy tank 131 of the housing 130; The gripper 120, the sound wave generation means 140, the controller 150 charges and supplies the power required for driving, mounted on the buoyancy tank 131 of the housing 130, spaced apart from the conducting terminal 142 It further comprises a sensing device (100) disposed of the battery 160 having a current collector 161 protruding to contact the current supply terminal 142 when the movement of the sound wave generating unit 140 moves downward: The transmitting module 210 emits a sound wave having a frequency of a different band from the sound wave emitted from the sound wave generating means 140: The receiving module 220 receives the sound waves emitted by the detection device 100 together with the sound waves emitted by the transmission module 210: The information processing module 310 checks each sound wave information of the sensing device 110 together with the transmission module 210 received by the receiving module 220 of the sound wave detector 200: Strain measurement and channel topography information verification system of the sea channel according to the change of seabed topography.

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