KR102358791B1 - Movable inspecting system adopted in integrated plant for cleaning ship hull surface - Google Patents

Abstract

The present invention provides a movable inspecting system adopted in an integrated plant for cleaning the bottom of a ship. According to the present invention, the movable inspecting system is adopted in an integrated plant for cleaning the bottom of a ship including a floating structure having a predetermined length and a predetermined width to float on the sea. At least one between the front and the rear of the floating structure in a longitudinal direction is formed to be open so that a ship enters the floating structure. Also, a bottom part and both side surface parts in the floating structure are connected to be watertight so that a space is formed on an inner side. The movable inspecting system inspects an outer surface of the ship by a non-contact method before or after the outer surface of the ship is cleaned. The movable inspecting system adopted in an integrated plant for cleaning the bottom of a ship includes: a movable body unit placed in a lower part of the ship in the floating structure and moving in the longitudinal direction of the floating structure; and a plurality of inspecting units having one end connected to the movable body unit and the other end having an inspection unit mounted thereon to inspect the outer surface of the ship in the space, and comprising multi-joint robot arms. According to the present invention, it is possible to check the cleanliness just before and after the cleaning of the outer surface of a ship, thereby greatly reducing time and cost for inspection.

Description

{MOVABLE INSPECTING SYSTEM ADOPTED IN INTEGRATED PLANT FOR CLEANING SHIP HULL SURFACE}

The present invention relates to a mobile inspection system employed in an integrated ship-bottom cleaning plant, and specifically, to a ship-bottom cleaning integrated plant that can thoroughly inspect the condition and damage of the ship's outer surface before or after cleaning, even to a niche area. It relates to a mobile inspection system that becomes

In general, since a ship is operated in a state that the lower part of the hull is submerged in seawater, foreign substances such as various contaminants or various aquatic organisms such as water moss and barnacles may be attached to the bottom or side surface located in the water.

As such, various foreign substances and aquatic organisms attached to the hull not only damage the appearance of the ship, but also act as a resistance when the ship is operating and become a factor that lowers the speed of the ship, thus greatly increasing the fuel consumption of the ship. It is very important to periodically clean various foreign substances and aquatic organisms attached to the surface.

After cleaning various foreign substances and aquatic organisms attached to the hull, inspection work is performed to inspect the cleaning state or whether the hull is damaged.

Since the inspection of the bottom of the vessel is currently made up of two divers and the divers dive and inspect the bottom of the vessel with the naked eye, safety accidents occur every year, and the bottom of the vessel There is a problem that the working time for the inspection is about 3 hours and the working environment is poor.

In order to solve this problem, a number of patents have been proposed. Among them, Korea Registration Patent No. 10-1271615 'bottom inspection device of a ship' is a representative patent, which is installed at the bottom of a ship. A transparent watertight cover that becomes a transparent watertight cover, a monitoring unit including a camera rotatably mounted on the inside of the transparent watertight cover to monitor the bottom of the ship, and the monitoring unit and the transparent watertight cover mounted on the transparent watertight cover selectively to the inside and outside of the bottom of the ship Consists of a configuration including a lifting unit to move and a driving unit mounted to provide a rotational driving force to the monitoring unit, there is an effect that can easily check the state of attachment of foreign substances to the bottom of the ship.

However, there is a disadvantage that all areas cannot be solved unmanned because the area that can be mounted on the bottom and the area that can be accessed for the lift are limited.

In the end, a complex area called a niche area has a problem that depends on the work of divers.

In addition, in the case of the patent of Korea Patent No. 10-1873743 'Underwater imaging system for inspection of the bottom of a ship', it provides real-time image information captured while moving through an underwater mobile device, and accurate information on the bottom of the ship through the image information. It is effective in preventing accidents caused by divers every year, shortening working hours, and efficiently inspecting the bottom of the ship.

However, this is limited to underwater images and can only be inspected for appearance, and there is a problem in that it cannot be used if visibility is not secured due to deterioration of water quality in the port.

KR 10-1873743 B1 KR 10-1271615 B1

The present invention has been devised to solve the various problems of the prior art as described above, and is employed in an integrated bottom cleaning plant that can thoroughly inspect the condition of the exterior of the vessel and the presence or absence of damage to the crevice area before or after cleaning the exterior of the vessel. An object of the present invention is to provide a portable inspection system.

Another object of the present invention is to provide a mobile inspection system employed in a ship-bottom cleaning integrated plant that can check the cleaning status immediately before and after the cleaning of the exterior of the ship to check the performance of the cleaning operation and the presence or absence of damage to the hull.

In order to achieve the above objects, the present invention is made of a predetermined width and length and is floated on the sea, and at least one of the longitudinal direction front and rear is opened and closed so that a ship can enter and exit, and a space is formed inside. As a mobile inspection system that is employed in a ship-bottom cleaning integrated plant including a floating structure in which the bottom and both side surfaces are watertightly connected, the outer surface of the ship is inspected in a non-contact manner before or after cleaning of the outer surface of the ship, a movable body part located in the lower part of the ship in the floating structure and moving along the longitudinal direction of the floating structure; And one end is connected to the movable body portion, the other end is equipped with an inspection means to inspect the outer surface of the ship in the space, the inspection unit is made of a multi-joint robot arm is provided in plurality; Ship bottom cleaning, characterized in that it comprises a It provides a mobile inspection system employed in an integrated plant.

In this case, it is preferable that the inspection means include an external shape detection device for detecting damage to the naked eye of the ship, and a non-destructive testing device for checking the thickness and cracks of the ship.

In addition, the movable body portion, a pair of side portions disposed to be spaced apart from each other on the left and right sides of the vessel to face each other; and a bottom part connecting the lower ends of the pair of side parts.

In addition, the movable body portion may further include an inclined portion for obliquely connecting the pair of lower inner surfaces of the side portions and the upper surfaces of both sides of the bottom portion.

Meanwhile, rollers or rails may be respectively formed on the pair of side portions to be coupled to rails or rollers formed on both inner side surfaces of the floating structure.

In addition, a roller or rail may be formed on the bottom portion to be coupled to a rail or roller formed on the inner bottom surface of the floating structure.

It is preferable that dynamic position control devices (DP) including a function of controlling the speed fluctuations of both sides of the movable body part are provided on both sides of the bottom part, respectively.

In addition, it is preferable that the pair of side parts, the inclined part and the bottom part have an inspection part composed of a multi-joint robot arm.

In this case, one end of the inspection unit may be connected to a gap adjusting mechanism installed in the movable body unit.

The space control mechanism includes: a space control member comprising a cylinder fixed to the movable body part and a piston reciprocating linearly within the cylinder; and a multi-link member having one end connected to the piston and the other end connected to the inspection unit, and foldable according to the linear motion of the piston.

In this case, the gap control member may be configured to operate by receiving a signal according to the distance between the outer surface of the ship and the inspection unit sensed by the sensor installed in the inspection unit.

In another configuration, the present invention is made of a predetermined width and length and is floated on the sea, at least one of the front and rear in the longitudinal direction can be opened and closed so that the ship can enter and exit, and the bottom and both sides are formed so that a space is formed inside As a mobile inspection system that is employed in an integrated ship-bottom cleaning plant including a floating structure connected to an additional watertight, and inspects the exterior surface of the vessel in a non-contact manner before or after cleaning the exterior surface of the vessel, in the floating structure a movable body part located in the lower part of the ship and moving along the longitudinal direction of the floating structure; and an inspection unit that is installed in a plurality of the movable body part so as to be able to adjust the distance from the movable body part to the outer surface of the ship, and is composed of a lidar and a laser scanner and inspects the outer surface of the ship in the space. It provides a mobile inspection system employed in the integrated ship-bottom cleaning plant, characterized in that.

In this case, it is preferable that the inspection unit is supported by a predetermined support member, and the lower end of the support member is connected to a gap adjusting mechanism installed in the movable body part.

Such a gap adjusting mechanism includes: a space control member comprising a cylinder fixed to the movable body part and a piston reciprocating linearly within the cylinder; and a multi-link member having one end connected to the piston and the other end connected to the support member and foldable according to the linear motion of the piston.

In another configuration, the present invention is made of a predetermined width and length and is floated on the sea, and at least one of the front and rear in the longitudinal direction is opened and closed so that the ship can enter and exit, and the bottom and the bottom so that a space is formed inside. A mobile inspection system that is employed in a ship-bottom cleaning integrated plant including a floating structure in which both side surfaces are watertightly connected, and inspects the exterior surface of the vessel in a non-contact manner before or after cleaning the exterior surface of the vessel, in the floating structure a movable body part located at the lower part of the ship and moving along the longitudinal direction of the floating structure; and an inspection unit installed in a plurality of the movable body unit so as to be able to adjust the distance from the movable body unit to the outer surface of the vessel, and comprising an underwater light and an underwater camera to inspect the exterior surface of the vessel in the space; including, the inspection unit Provides a mobile inspection system employed in a bottom cleaning integrated plant, characterized in that the inspection result is transmitted to an integrated monitoring control system that remotely monitors and controls.

At this time, the inspection unit is supported by a predetermined support member, and the lower end of the support member is connected to a spacing adjusting mechanism installed in the movable body portion, and the spacing adjusting mechanism includes a cylinder fixed to the movable body portion and the cylinder. A gap control member consisting of a piston reciprocating in a straight line from the inside; and a multi-link member having one end connected to the piston and the other end connected to the support member and foldable according to the linear motion of the piston.

On the other hand, a cleaning unit for cleaning the outer surface of the vessel is installed in the movable body portion of the above-described movable inspection system, and the cleaning unit is at least in the form of an articulated robot arm equipped with a cleaning means at one end, a brush in a roll form, and a waterjet type. Either one can be done.

In addition, the inspection result inspected by the mobile inspection system is transmitted to the integrated monitoring control system provided in the ship-bottom cleaning integrated plant, and the integrated monitoring control system compares the inspection result with the original drawing of the ship and provides a comparison value to the user. made to be automatically transmitted.

Specific details of other embodiments are included in "Details for carrying out the invention" and the accompanying "drawings".

Advantages and/or features of the present invention, and methods of achieving them, will become apparent with reference to the various embodiments described below in detail in conjunction with the accompanying drawings.

However, the present invention is not limited to the configuration of each embodiment disclosed below, but may also be implemented in a variety of different forms, and each embodiment disclosed in this specification only makes the disclosure of the present invention complete, It is provided to fully inform those of ordinary skill in the art to which the invention pertains to the scope of the present invention, and it should be understood that the present invention is only defined by the scope of each claim.

According to the means for solving the above problems, the present invention has the following effects.

The present invention provides an inspection unit in the form of a multi-joint robot arm equipped with an inspection means, a laser scanner, a light, and a camera, so that the state of the exterior of the vessel and the presence or absence of damage can be thoroughly inspected to the gap region before or after cleaning of the exterior of the vessel. can have an effect.

In addition, the present invention has the effect of significantly reducing the time and cost required for inspection by simultaneously employing the inspection unit and the cleaning unit in the movable body part, so that the cleaning state can be checked immediately before and after the cleaning operation of the outer surface of the ship.

In addition, as an inspection means, the present invention performs underwater imaging equipment, sonar and multi-beam, etc., and external detection equipment, such as an eddy current detection test, ultrasonic detection test, or magnetic survey, to determine the visual damage of the ship, and the thickness of the ship and non-destructive testing equipment to identify cracks, etc., using non-destructive testing equipment for local areas where there is a possibility of partial problems after a macroscopic examination of the external surface of the ship using the appearance detection equipment. there is an effect

1 is a view showing a state in which a ship is located in a ship bottom cleaning integrated plant employing a mobile inspection system according to the present invention.
2 is a view showing a state in which the mobile inspection system according to the present invention is located inside the floating structure.
FIG. 3 is an enlarged view of part a of FIG. 2 .
4 is a view showing a first example of the inspection unit as showing a state in which the mobile inspection system according to the present invention is located inside the floating structure.
FIG. 5 is a view showing the mobile inspection system of FIG. 4 .
FIG. 6 is an enlarged view of a portion indicated by a circle in FIG. 4 .
7 is a view showing a state in which the movable inspection system according to the present invention is located inside the floating structure, and shows a second example of the inspection unit.
FIG. 8 is a view showing the mobile inspection system of FIG. 7 .
9 is an enlarged view of a portion indicated by a circle in FIG. 7 .

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

Before describing the present invention in detail, the terms or words used in this specification should not be construed as being unconditionally limited to their ordinary or dictionary meanings, and in order for the inventor of the present invention to explain his invention in the best way It should be understood that the concepts of various terms can be appropriately defined and used, and furthermore, these terms or words should be interpreted as meanings and concepts consistent with the technical idea of the present invention.

That is, the terms used herein are only used to describe preferred embodiments of the present invention, and are not used for the purpose of specifically limiting the content of the present invention, and these terms represent various possibilities of the present invention. It should be understood that the term has been defined taking into account.

In addition, in the present specification, it should be noted that, unless the context clearly indicates otherwise, the expression in the singular may include a plurality of expressions, and even if it is similarly expressed in plural, it may include the meaning of the singular. do.

When it is stated throughout this specification that a component "includes" another component, it does not exclude any other component, but further includes any other component unless otherwise stated. It could mean that you can.

Furthermore, when it is described that a component is "exists in or connected to" of another component, this component may be directly connected to or installed in contact with another component, and a certain It may be installed spaced apart by a distance, and in the case of being installed spaced apart by a certain distance, a third component or means for fixing or connecting the component to another component may exist, and now It should be noted that the description of the components or means of 3 may be omitted.

On the other hand, when it is described that a certain element is "directly connected" or "directly connected" to another element, it should be understood that the third element or means does not exist.

Likewise, other expressions describing the relationship between components, such as "between" and "immediately between", or "adjacent to" and "directly adjacent to", have the same meaning. should be interpreted as

In addition, in this specification, terms such as "one side", "other side", "one side", "other side", "first", "second", etc., if used, for one component, this single component It is used to be clearly distinguished from other components, and it should be understood that the meaning of the component is not limitedly used by such terms.

In addition, in the present specification, terms related to positions such as "upper", "lower", "left", and "right", if used, should be understood as indicating a relative position in the drawing with respect to the corresponding component, Unless an absolute position is specified with respect to their position, these position-related terms should not be construed as referring to an absolute position.

Moreover, in the specification of the present invention, terms such as “…unit”, “…group”, “module”, “device”, etc., if used, mean a unit capable of processing one or more functions or operations, which means hardware Alternatively, it should be understood that it may be implemented in software, or a combination of hardware and software.

In addition, in this specification, in specifying the reference numerals for each component in each drawing, the same component has the same reference number even if the component is indicated in different drawings, that is, the same reference throughout the specification. Symbols indicate identical components.

In the drawings attached to this specification, the size, position, coupling relationship, etc. of each component constituting the present invention are partially exaggerated, reduced, or omitted in order to convey the spirit of the present invention sufficiently clearly or for convenience of explanation. may be described, and therefore the proportion or scale may not be exact.

In addition, in the following, in describing the present invention, a detailed description of a configuration determined to unnecessarily obscure the gist of the present invention, for example, a detailed description of a known technology including the prior art may be omitted.

1 is a view showing a state in which a ship is located in a ship bottom cleaning integrated plant employing a mobile inspection system according to the present invention.

The mobile inspection system 20 employed in the ship-bottom cleaning integrated plant according to the present invention is located at the lower portion of the vessel S in the floating structure 10 and reciprocates along the longitudinal direction of the floating structure 10 while reciprocating the vessel ( S) Non-contact inspection of the exterior surface of the ship before or after cleaning the exterior surface.

The floating structure 10 is floated in the sea, and at least one of the front and rear in the longitudinal direction is provided to be openable and openable so that the vessel (S) can enter and exit the inside.

Such a floating structure 10 may be formed of concrete, steel, or composite material, and the bottom and side portions are watertightly connected so that a space is formed on the inside. A cross-section may be formed in a “∪” shape to surround the side and bottom of the hull.

In addition, a ballast part (not shown) capable of adjusting the degree to which the floating structure 10 is submerged in the sea level may be provided inside the floating structure 10, whereby the bottom of the floating structure 10 is at sea level to a predetermined depth. It is arranged to be submerged so that the vessel (S) can enter above the floor in the space.

The mobile inspection system 20 is installed inside the floating structure 10 to reciprocate linearly along the longitudinal direction of the floating structure 10, and serves to inspect the side and bottom surfaces of the vessel S in a non-contact manner. do.

Unexplained symbol E is a seawater inlet, and G is a seawater outlet.

In addition, the ship fixing system (F) may be formed in the form of a wire so that the ship (S) does not swing inside the floating structure (10).

FIG. 2 is a view showing a state in which the movable inspection system according to the present invention is located inside the floating structure, and FIG. 3 is an enlarged view of part a of FIG. 2 .

At least one of the front and rear of the floating structure 10 may be provided with an opening and closing door, and in the present specification, an example installed in the front and rear will be described.

The first opening and closing doors D1 and the second opening and closing doors D2 having a waterproof function are respectively installed in the front and rear of the floating structure 10, and the floating structure 10 during the cleaning of the ship bottom by the cleaning unit 28 before performing the inspection Prevents seawater from flowing out of the floating structure 10 of the inner space.

At this time, the first opening/closing door (D1) and the second opening/closing door (D2) may be configured in a hinged or sliding type. accept and it works.

That is, when the first opening/closing door D1 and the second opening/closing door D2 are configured in a hinged type, the first opening/closing door D1 and the second opening/closing door D2 are made of a pair, respectively, to the front and rear of the floating structure 10 . are located in each.

Taking the first opening and closing door D1 as an example, one end of the pair of first opening and closing doors D1 is coupled to both ends of the front end of the floating structure 10 by a hinge, respectively, when the pair of first opening and closing doors D1 are closed. The other end of the pair of the first opening and closing door (D1) is in contact with each other.

In this case, the first opening/closing door D1 and the floating structure 10 are connected by a piston-cylinder type first opening/closing device DT1, and as the piston of the first opening/closing device DT1 linearly moves with respect to the cylinder, The first opening/closing door (D1) may be configured to perform an opening/closing operation.

At this time, it is preferable that the other end abutting the pair of first opening and closing doors (D1) is waterproofed so as to be watertight.

The second opening and closing door D2 may also be configured similarly to the first opening and closing door D1, wherein the second opening and closing door D2 and the floating structure 10 are connected by a piston-cylinder type second opening and closing device DT2, As the piston of the second opening/closing device DT2 linearly moves with respect to the cylinder, the second opening/closing door D2 may be configured to open and close.

That is, the sensor installed in the first opening and closing door D1 and the second opening and closing door D2 senses the distance to the ship and transmits the detection signal to the first opening and closing device DT1 and the second opening and closing device DT2, so that the first The opening/closing device DT1 and the second opening/closing device DT2 may be operated.

On the other hand, the first rail (R1) is respectively formed on the inner side surfaces 12 of the floating structure 10 as described above, and on a pair of side portions 22a in the movable body portion 22 of the movable inspection system 20, respectively. The formed pair of first rollers K1 is coupled to the first rail R1.

In addition, a second rail R2 is formed on the inner bottom surface 14 of the floating structure 10, and a second roller ( K2) is configured to be coupled to the second rail (R2).

Of course, the first roller and the second roller are respectively formed on both side surfaces 12 and the bottom surface 14 of the floating structure 10, and both side portions 22a of the movable body part 22 in the movable inspection system 20) It is also possible to form the first rail and the second rail on the bottom portion 22b, respectively.

Accordingly, along the longitudinal direction of the floating structure 10, the movable body portion 22 of the movable inspection system 20 performs a linear reciprocating motion while inspecting the side and bottom surfaces of the vessel S.

In addition to the combined configuration of the rail and the roller, as long as the movable body 22 of the movable inspection system 20 can linearly reciprocate in the longitudinal direction of the floating structure 10, it does not matter what configuration it is made of.

In addition, a plurality of fixing bars may be formed as the ship fixing system (F) along the longitudinal direction on both inner side surfaces 12 of the floating structure 10, and these fixing bars are preferably made of a rubber material.

In addition, by allowing the fixing bar to come into contact with a part of a ship above sea level where there is no antifouling paint, it is possible to minimize environmental pollution caused by peeling of the antifouling paint.

Such a plurality of fixed bars are normally located inside the both sides 12 of the floating structure 10, and when the vessel S is located in the inner space of the floating structure 10, the signal of the integrated monitoring control system is received. It may be configured to protrude to the outside of the both sides 12 of the floating structure 10 to be in close contact with both sides of the vessel (S).

In addition, the floating structure 10 may be provided with a recovery system (R) for recovering the removed material including the veneer anchorage removed by the cleaning unit (28).

Briefly describing the recovery system R, in order to quickly and efficiently treat the contaminated water in the floating structure 10, the cleaning by-products may be chemically/physically submerged or floated to undergo a pretreatment process.

In the case of fine cleaning by-products, a chemical method is used to increase the size of the fine cleaning by-products by burying them with a chemical method. It is a method of processing by-products by causing the flow to occur by pushing up or down using

Aquatic organisms or macroscopic cleaning by-products may be collected by sweeping the particles that have sunk to the bottom with a broom-shaped device, sucked in through an inlet formed in the bottom of the floating structure 10, and then injected into the water treatment system.

In this way, the floating structure 10 may be provided with a water treatment system connected to the recovery system (R) to purify the removed material recovered by the recovery system (R) and discharge it into seawater.

Such a water treatment system may include a sterilizer and a filter.

As such, by providing the recovery system R and the water treatment system in the floating structure 10, various foreign substances and aquatic organisms removed after cleaning the bottom of the ship are recovered, treated with water, and discharged to seawater, thereby preventing the ecosystem from being disturbed.

4 is a view showing a state in which the mobile inspection system according to the present invention is located inside the floating structure, and is a view showing a first example of the inspection unit, FIG. 5 is a view showing the mobile inspection system of FIG. 4, FIG. 6 is It is an enlarged view of a portion indicated by a circle in FIG. 4 .

The movable inspection system 20 includes a movable body 22 and an inspection unit 24 .

The movable body part 22 is located at the lower part of the ship (S) in the floating structure (10) and moves along the longitudinal direction of the floating structure (10), spaced apart from the left and right sides of the ship (S) to face each other It may include a pair of side portions 22a and a bottom portion 22b connecting the lower ends of the pair of side portions 22a.

In addition, the movable body part 22 may further include an inclined part 22c for obliquely connecting the lower inner surface of the pair of side parts 22a and the upper surfaces of both sides of the bottom part 22b.

On the other hand, a first roller K1 may be formed on a pair of side portions 22a of the movable body 22 so as to be coupled to the first rails R1 formed on both inner side surfaces 12 of the floating structure 10, respectively. have.

In addition, a second roller K2 may be formed on the bottom 22b of the movable body 22 so as to be coupled to the second rail R2 formed on the inner bottom surface 14 of the floating structure 10 .

Dynamic position control devices DP are provided on both sides of the bottom 22b of the movable body 22, respectively.

The dynamic position control device (DP) includes a function to control the speed fluctuations on both sides of the movable body part 22 .

The dynamic position control device (DP) controls the mobile inspection system 20 to move at a desired speed by the operator, and is constant from left to right so that a yaw motion, that is, a Z-axis rotational motion, does not occur in the floating structure 10 . generate thrust.

This dynamic positioning device (DP) can be controlled by a plurality of thrusters, and can be applied to other roller driving methods and rail systems.

In addition, the inspection unit 24 made of the articulated robot arm 24a is located on the pair of side portions 22a, the inclined portions 22c and the bottom portion 22b of the movable body portion 22 .

Inspection unit 24 is made of a plurality of articulated robot arms (24a), one end is connected to the movable body portion 22, the other end is equipped with an inspection means (not shown) in the inner space of the floating structure (10) to inspect the exterior of the vessel.

As such, by forming the inspection unit 24 as the articulated robot arm 24a, it is possible to meticulously inspect even the niche area of the vessel.

In this case, the inspection means includes an external shape detection equipment for determining the visual damage of the vessel, and a non-destructive inspection equipment for identifying the thickness and cracks of the vessel.

Appearance detection equipment may be composed of underwater imaging equipment such as a laser scanner and camera, sonar, and multi-beam.

In addition, it is preferable that the non-destructive inspection equipment is an inspection equipment that performs an eddy current inspection, an ultrasonic inspection, or a magnetic inspection.

Accordingly, after macroscopically inspecting the external state of the vessel using the appearance detection equipment, the non-destructive inspection equipment is used to inspect the exact damage to the local area where there is a partial problem.

Non-destructive testing is a test that examines the presence or absence of defects without destroying the product.

Representative non-destructive inspection methods include ultrasonic inspection, magnetic particle inspection, eddy current inspection, and penetrant inspection.

Magnetic particle inspection and eddy current inspection by electromagnetic applications are widely used to inspect the surface layer of products, but of course, they cannot be applied to non-magnetic steel.

Penetration inspection is effective in detecting defects exposed on the surface.

The ultrasonic flaw detection method, which detects the reflection of ultrasonic waves from a defect, is mainly used widely for internal defect inspection.

Ultrasonic inspection is a test to obtain an initial shear modulus or Poisson's ratio by giving an ultrasonic wave to a test object and using the reflected wave.

In recent years, the detection of surface defects and surface layer defects has become easier due to the improvement and development of ultrasonic flaw detection devices including transducers.

Since the transmittance of ultrasonic waves is remarkably reduced when the grain size is rough, it may be difficult to apply not only to cast steels but also to austenitic forgings.

Also, in all of these flaw detection methods, it is necessary to pay attention to the fact that when the surface roughness of the product is rough, pseudo-indications are easily detected, and in ultrasonic flaw detection, the same phenomenon occurs depending on the shape of the product.

Eddy current inspection is a non-destructive test method that uses a coil to apply a temporally changing magnetic field (alternating current, etc.) to a conductor and detects defects by using the change in the eddy current generated in the conductor due to defects.

Magnetic inspection refers to an inspection that examines the presence or absence of defects inside a magnetic material by using the magnetic deformation that occurs due to the defect in the magnetic material.

On the other hand, one end of the inspection unit 24 may be connected to the interval adjusting mechanism 26 installed in the movable body portion 22 .

The spacing control mechanism 26 includes a cylinder (L) fixed to the movable body portion 22 and a spacing control member (26a) composed of a piston (P) reciprocating linearly within the cylinder (L); and a multiple link member ( 26b).

In this case, the gap control member 26a may be configured to operate by receiving a signal according to the distance between the inspection unit and the outer surface of the ship detected by the sensor installed in the inspection unit 24 .

7 is a view showing a state in which the mobile inspection system according to the present invention is located inside the floating structure, and is a view showing a second example of the inspection unit, FIG. 8 is a view showing the mobile inspection system of FIG. 7, FIG. It is an enlarged view of a portion indicated by a circle in FIG. 7 .

The mobile inspection system 20 employed in the integrated ship-bottom cleaning plant according to the present invention is made of a predetermined width and length and is floated on the sea, and at least one of the front and rear in the longitudinal direction can be opened and closed so that the vessel can enter and exit. As a mobile inspection system employed in a ship-bottom cleaning integrated plant including a floating structure 10 that is formed and watertightly connected to the bottom and both side surfaces to form a space inside, the mobile body part 22 and the inspection part 24 ) is included.

The movable body part 22 is located in the lower part of the ship in the floating structure 10 and is configured to move along the longitudinal direction of the floating structure.

The inspection unit 24 is installed in plurality in the movable body 22 so that the distance from the movable body 22 to the outer surface of the ship can be adjusted, and consists of a laser scanner 24b, a light and a camera 24c. and to inspect the exterior surface of the vessel within the interior space.

Laser scanners can be used in conjunction with underwater optical imaging when precise measurements in the water are required.

The laser is projected onto the subject in the form of dots, lines, and grids, and the laser is detected through image processing to measure the exact shape of the object.

Because this is an active system using a laser, there is relatively little interference from turbidity and ambient light compared to when using only a single underwater camera.

The light illuminates the exterior of the vessel being photographed by the camera.

The camera may be equipped with an angle adjusting device such as a servo motor that can change the angle of the camera according to the curvature of the bottom of the ship, and accordingly, the angle adjusting device such as the servo motor rotates at a convenient angle and the camera rotates at an appropriate angle This makes it possible to more accurately capture the necessary parts of the ship's exterior.

These lights and cameras have a watertight structure suitable for underwater photography.

Such an inspection unit 24 is supported by a plate-shaped support member (J), and the lower end of the support member (J) may be connected to a gap adjusting mechanism (26) installed in the movable body part (22).

At this time, the gap control mechanism 26, the cylinder (L) fixed to the movable body portion 22 and the cylinder (L), the distance control member (26a) consisting of a piston (P) reciprocating in a straight line; And one end is connected to the piston (P) of the gap control member (26a) and the other end is connected to the support member (J), a multiple link member made to be foldable according to the linear motion of the piston (P) of the gap control member (26a) (26b) may be included.

As described above, it is preferable that the plurality of inspection units 24 made of the laser scanner 24b, light and camera 24c are spaced apart from each other in the movable body unit 22 so as to face the outer surface of the ship.

On the other hand, a cleaning unit 28 for cleaning the outer surface of the vessel is installed in the movable body portion 22 of the above-described movable inspection system 20 as shown in FIG. 3 , and the cleaning unit 28 is a cleaning means at one end The mounted articulated robot arm may be formed in at least one of a shape, a roll-type brush, and a waterjet type.

Accordingly, there is an advantage in that the cleaning state of the vessel cleaned by the cleaning unit 28 and the presence or absence of damage can be immediately inspected through the inspection unit 24 .

In addition, the inspection results inspected by the mobile inspection system are transmitted to the integrated monitoring and control system provided in the integrated ship-bottom cleaning plant, and the integrated monitoring and control system records the original drawing of the ship (the design drawing of the original state of the vessel) and the inspection results. After comparative analysis, the comparison value is automatically transmitted to the user.

In the above, although several preferred embodiments of the present invention have been described with some examples, the description of various various embodiments described in the "Specific Content for Carrying Out the Invention" item is merely exemplary, and the present invention Those of ordinary skill in the art will understand well that the present invention can be practiced with various modifications or equivalents to the present invention from the above description.

In addition, since the present invention can be implemented in various other forms, the present invention is not limited by the above description, and the above description is intended to complete the disclosure of the present invention, and is generally It is to be understood that this is only provided to fully inform those with knowledge of the scope of the present invention, and that the present invention is only defined by each of the claims.

10: floating structure
12: inside both sides
14: inner bottom surface
R1: 1st rail
R2 : 2nd rail
D1 : 1st open/close door
D2 : 2nd opening and closing door
20: mobile inspection system
22: movable body part
24: inspection department
24a: articulated robot arm
24b: laser scanner
24c: Lights and Cameras
26: gap adjustment mechanism
26a: gap control member
26b: multi-link member
28 : Janitor

Claims (17)

It consists of a predetermined width and length and floats on the sea, and at least one of the front and rear in the longitudinal direction can be opened and closed so that a ship can enter and exit, and the bottom and both sides are watertightly connected to form a space inside As a mobile inspection system employed in a ship-bottom cleaning integrated plant including a floating structure that
a movable body part located at the lower part of the ship in the floating structure and moving along the longitudinal direction of the floating structure; and
One end is connected to the movable body portion, the other end is equipped with an inspection means to inspect the outer surface of the vessel in the space, and a plurality of inspection units made of articulated robot arms;
One end of the inspection part is connected to a gap adjusting mechanism installed in the movable body part,
The interval adjusting mechanism is characterized in that by receiving and operating a signal according to the distance between the inspection unit and the outer surface of the vessel sensed by the sensor installed in the inspection unit, to adjust the interval between the outer surface of the vessel and the inspection unit,
A mobile inspection system employed in an integrated ship-bottom cleaning plant.
The method according to claim 1,
The inspection means is characterized in that it comprises an external detection equipment for identifying the visual damage of the vessel, and a non-destructive inspection equipment for identifying the thickness and cracks of the vessel,
A mobile inspection system employed in an integrated ship-bottom cleaning plant.
The method according to claim 1,
The movable body part,
a pair of side portions spaced apart from each other on the left and right sides of the ship to face each other; and
A bottom part connecting the lower ends of the pair of side parts; characterized in that it comprises a,
A mobile inspection system employed in an integrated ship-bottom cleaning plant.
4. The method according to claim 3,
The movable body part,
It characterized in that it further comprises an inclined portion for obliquely connecting the pair of the lower inner surface of the side part and the upper surface of both sides of the bottom part,
A mobile inspection system employed in an integrated ship-bottom cleaning plant.
4. The method according to claim 3,
A roller or rail is respectively formed on the pair of side portions so as to be coupled to a rail or roller formed on both inner side surfaces of the floating structure,
Characterized in that a roller or rail is formed on the bottom so as to be coupled to a rail or roller formed on the inner bottom surface of the floating structure,
A mobile inspection system employed in an integrated ship-bottom cleaning plant.
4. The method according to claim 3,
Characterized in that a dynamic position control device (DP) including a function to control the speed fluctuations on both sides of the movable body part is provided on both sides of the bottom part, respectively,
A mobile inspection system employed in an integrated ship-bottom cleaning plant.
5. The method according to claim 4,
The pair of side parts, the inclined part and the bottom part, characterized in that the inspection part consisting of a multi-joint robot arm is located,
A mobile inspection system employed in an integrated ship-bottom cleaning plant.
delete The method according to claim 1,
The gap adjusting mechanism,
a space control member comprising a cylinder fixed to the movable body and a piston reciprocating linearly within the cylinder; and
One end is connected to the piston and the other end is connected to the inspection unit, and a multi-link member that is foldable according to the linear motion of the piston; characterized in that it comprises a,
A mobile inspection system employed in an integrated ship-bottom cleaning plant.
10. The method of claim 9,
The gap control member is characterized in that it is configured to operate by receiving a signal according to the distance between the outer surface of the ship and the inspection unit sensed by the sensor installed in the inspection unit,
A mobile inspection system employed in an integrated ship-bottom cleaning plant.
It consists of a predetermined width and length and floats on the sea, and at least one of the front and rear in the longitudinal direction can be opened and closed so that a ship can enter and exit, and the bottom and both sides are watertightly connected to form a space inside As a mobile inspection system employed in a ship-bottom cleaning integrated plant including a floating structure that
a movable body part located at the lower part of the ship in the floating structure and moving along the longitudinal direction of the floating structure; and
It includes a; a plurality of inspection units installed in the movable body portion to enable the distance adjustment from the movable body portion to the outer surface of the ship, and consisting of a lidar and a laser scanner to inspect the outer surface of the ship in the space; and
The inspection unit is supported by a predetermined support member,
The lower end of the support member is connected to a gap adjusting mechanism installed in the movable body portion,
The interval adjusting mechanism is characterized in that by receiving and operating a signal according to the distance between the inspection unit and the outer surface of the vessel sensed by the sensor installed in the inspection unit, to adjust the interval between the outer surface of the vessel and the inspection unit,
A mobile inspection system employed in an integrated ship-bottom cleaning plant.
delete 12. The method of claim 11,
The gap adjusting mechanism,
a space control member comprising a cylinder fixed to the movable body and a piston reciprocating linearly within the cylinder; and
One end is connected to the piston and the other end is connected to the support member, and a multi-link member that is foldable according to the linear motion of the piston; characterized in that it comprises a,
A mobile inspection system employed in an integrated ship-bottom cleaning plant.
It consists of a predetermined width and length and floats on the sea, and at least one of the front and rear in the longitudinal direction can be opened and closed so that a ship can enter and exit, and the bottom and both sides are watertightly connected to form a space inside As a mobile inspection system employed in a ship-bottom cleaning integrated plant including a floating structure that
a movable body part located at the lower part of the ship in the floating structure and moving along the longitudinal direction of the floating structure; and
It includes a; a plurality of inspection units installed in the movable body portion to enable distance adjustment from the movable body portion to the outer surface of the ship, and comprising an underwater light and an underwater camera to inspect the exterior surface of the ship in the space; and
The inspection unit is supported by a predetermined support member,
The lower end of the support member is connected to a gap adjusting mechanism installed in the movable body portion,
The interval adjusting mechanism controls the distance between the outer surface of the ship and the inspection unit by receiving and operating a signal according to the distance between the inspection unit and the outer surface of the vessel sensed by the sensor installed in the inspection unit,
The result inspected by the inspection unit is characterized in that it is transmitted to an integrated monitoring control system that monitors and controls remotely,
A mobile inspection system employed in an integrated ship-bottom cleaning plant.
15. The method of claim 14,
The gap adjusting mechanism,
a space control member comprising a cylinder fixed to the movable body and a piston reciprocating linearly within the cylinder; and
One end is connected to the piston and the other end is connected to the support member, and a multi-link member that is foldable according to the linear motion of the piston; characterized in that it comprises a,
A mobile inspection system employed in an integrated ship-bottom cleaning plant.
1 to 7. The method according to any one of claims 9 to 11 and 13 to 15,
A cleaning unit for cleaning the outer surface of the vessel is installed in the movable body portion,
The cleaning unit is characterized in that it is made of at least one of a multi-joint robot arm type equipped with a cleaning means at one end, a roll type brush, and a water jet type,
A mobile inspection system employed in an integrated ship-bottom cleaning plant.
1 to 7. The method according to any one of claims 9 to 11 and 13 to 15,
The inspection result inspected by the mobile inspection system is transmitted to the integrated monitoring and control system provided in the integrated ship-bottom cleaning plant, and the integrated monitoring and control system compares the inspection result with the original drawing of the ship and automatically transmits the comparison value to the user. characterized in that it is made to
A mobile inspection system employed in an integrated ship-bottom cleaning plant.

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