CN111977510A - Buoy guarantee operation system and operation process thereof - Google Patents

Abstract

The buoy support operation system is combined with the buoy support operation system through the ship body, the buoy support operation system is quickly moved to the buoy design position through the ship body, the combination of the buoy support operation system and the buoy can be realized through the locking device, the lifting action of the lifting frame on the steering frame can be realized through the lifting frame and the electric block on the truss, the conversion of the buoy from the vertical state to the horizontal state can be realized through the steering frame of the steering device, and the transverse movement and the longitudinal movement of the buoy on the deck can be realized through the structure of the truss and the guide rail and the electric block on the truss, so that the maintenance, the label removal and the label setting of the buoy are realized. The invention realizes the intellectualization and mechanization of the buoy guarantee operation, thereby changing the traditional low-efficiency operation mode, reducing the labor intensity of staff, reducing the buoy operation risk, improving the safety and efficiency of the operation, reducing the operation cost and saving the energy consumption.

Description

Buoy guarantee operation system and operation process thereof

Technical Field

The invention relates to the field of buoy guarantee, in particular to a buoy guarantee operation system and an operation process thereof.

Background

The general buoy guaranteeing operation mainly refers to maintenance operation, buoy removing operation and buoy setting operation of buoys, and the achieving targets of the operations are different. The maintenance operation aims to realize the replacement of the buoy floating drum in the sea area of the set point, the sinking stones are remained in the water, and the equipment on the buoy operation ship is used for capturing, lifting, falling, chain releasing, shifting and the like, so that the operation aim of replacing the buoy floating drum is realized; the buoy removing operation aims at mainly removing buoys in a sea area of a marking point, and comprises removing of buoy buoys, anchor chains and sinking stones, and the buoy buoys, the anchor chains and the sinking stones are captured, lifted, laid down, chain-off, shifted, lifted and the like through equipment on a buoy operation ship, so that the buoy removing operation aim is achieved; the buoy setting operation aims at realizing buoy setting of a sea area of a marking point, and comprises buoy floating drums, anchor chains and sinking stones, and the buoy floating drums, the anchor chains and the sinking stones are shifted, chained, erected, placed down, thrown and the like through equipment on a buoy operating ship, so that the marking operation is realized.

The existing buoy guaranteeing operation at home and abroad is generally in a deck crane operation mode, the operation is completed through technical links such as labeling, hooking, lifting, chain releasing and the like, most of the operation needs manual work, great safety risks exist, all operation equipment is difficult to coordinate, and the intelligent degree is very low.

Disclosure of Invention

The invention provides a buoy guaranteeing operation system which is simple in structure, safe and convenient to operate and control and low in buoy guaranteeing operation labor intensity and an operation process thereof, and aims to solve the technical problems that the existing buoy guaranteeing operation is difficult to operate and control, high in labor intensity and low in safety performance.

According to an aspect of the present invention, there is provided a buoy tender operation system installed on a hull, the buoy tender operation system including a guide rail installed on a deck of the hull, a truss installed on the guide rail, and a steering apparatus, the truss is movably arranged on the guide rail, a beam is arranged on the truss, the beam is movably provided with an electric hoist, the steering device is arranged at the edge of the deck of the ship body and comprises a hinged seat, a telescopic cylinder and a steering frame, the hinged seat and the telescopic cylinder are respectively arranged on the deck, the bottom of the bogie is respectively hinged with the hinged seat and the telescopic rod of the telescopic cylinder, and guide rails are arranged on two sides of the bogie, a lifting frame is movably arranged on the guide rails, and a locking device matched with the appearance of the buoy is arranged on the lifting frame.

Preferably, on the basis of the scheme, the locking device comprises two clamping arms arranged on the lifting frame, each clamping arm comprises an arc-shaped part and a linear part, the arc-shaped parts are connected with the linear parts, the linear parts are oppositely arranged and movably arranged on the lifting frame through driving of a driving cylinder, and the two clamping arms are oppositely arranged to form a circular ring structure.

On the basis of the scheme, the arc-shaped part is preferably provided with a limit groove matched with the buoy.

On the basis of the scheme, preferably, the lifting frame is provided with a motor, the output end of the motor is provided with a friction wheel, and the friction wheel is in contact with the outer edge surface of the buoy.

On the basis of the scheme, the truss preferably comprises a bearing frame and cross beams, rollers are arranged at the bottom of the bearing frame and are matched with the guide rails, the bearing frame is connected with the cross beams through the two cross beams, and longitudinal beams are arranged between the cross beams.

On the basis of the scheme, preferably, the longitudinal beam is fixedly provided with an electric winch.

On the basis of the scheme, preferably, the bottom of the truss is provided with an electric gear walking mechanism matched with the guide rail.

On the basis of the scheme, preferably, the deck is further provided with a plurality of carrier rollers, the carrier rollers are arranged in two rows, and the carrier rollers are arranged opposite to two ends of the bogie.

On the basis of the scheme, preferably, the top of the lifting frame is provided with a stopper.

The invention also provides a buoy guaranteeing operation process, which comprises the following steps:

step A1, driving the ship body to run to the buoy set position based on the buoy set position, and driving the truss to move to the edge of the deck;

step A2, driving a bogie to be perpendicular to the end face of the deck, and moving a hoisting frame on the bogie to a set position;

step A3, driving a locking device on the lifting frame to be combined with the buoy, and driving the truss frame to move to a set position on the bogie through an electric hoist on the truss frame and the lifting frame;

step A4, controlling the bogie to rotate to enable the bogie to be parallel to a deck, retreating the truss in the process of falling, and controlling the winding and unwinding actions of the steel wire rope by the electric hoist in a constant tension state;

step A5, the buoy can be moved to any designated position on the deck by controlling the electric hoist moving transversely on the truss and the movement of the truss on the guide rail.

The buoy support operation system is combined with the buoy support operation system through the ship body, the buoy support operation system is quickly moved to the buoy design position through the ship body, the combination of the buoy support operation system and the buoy can be realized through the locking device, the lifting action of the lifting frame on the steering frame can be realized through the lifting frame and the electric block on the truss, the conversion of the buoy from the vertical state to the horizontal state can be realized through the steering frame of the steering device, and the transverse movement and the longitudinal movement of the buoy on the deck can be realized through the structure of the truss and the guide rail and the electric block on the truss, so that the maintenance, the label removal and the label setting of the buoy are realized.

According to the invention, through the design and use of the special operation equipment for buoy guarantee, the intellectualization and mechanization of buoy guarantee operation are realized, so that the traditional low-efficiency operation mode is changed, the labor intensity of workers is reduced, the buoy operation risk is reduced, the operation safety and efficiency are improved, the operation cost is reduced, and the energy consumption is saved.

Drawings

FIG. 1 is a front view of a buoy assurance process system of the present invention;

FIG. 2 is a top view of the buoy assurance operation system of the present invention;

FIG. 3 is a partial view of the buoy assurance operation system of the present invention;

FIG. 4 is a front view of a truss of the present invention;

FIG. 5 is a top view of a truss of the present invention;

FIG. 6 is a first state view of the float steering apparatus of the present invention;

FIG. 7 is a second state of the float steering apparatus of the present invention;

FIG. 8 is a top view of the float locking device of the present invention;

FIG. 9 is a front view of the float locking device of the present invention;

FIG. 10 is a side view of the float locking device of the present invention

Fig. 11 is a block diagram of a float safeguard operation flow of the present invention.

Detailed Description

The following detailed description of embodiments of the present invention is provided in connection with the accompanying drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

Referring to fig. 1 in combination with fig. 2 and 3, a buoy tender operation system of the present invention is installed on a ship body 10, and when in use, the buoy tender operation system is quickly close to a buoy waiting operation position by using the quick movement of the ship body 10 according to a set position.

The buoy-based operation system comprises a guide rail 11 arranged on a deck of a ship body 10, a truss 20 arranged on the guide rail 11 and a steering device 30, wherein the guide rail 11 is arranged in parallel at intervals along the length direction of the ship body 10, and the bottom of the truss 20 is movably arranged on the guide rail 11, so that the truss 20 can move on the guide rail 11 to realize the longitudinal movement of the truss 20 on the deck.

The guide rail 11 of the invention can be a rack, the bottom of the truss 20 is provided with an electric gear walking mechanism matched with the rack, and the electric gear walking mechanism is driven by a motor to realize the horizontal movement of the truss 20 on the guide rail 11.

Referring to fig. 4 and 5, the girder 20 of the present invention is provided with a beam 24, the beam 24 is installed along the width direction of the deck of the hull 10, and the beam 24 is provided with an electric block 27 so that the electric block 27 can move in the width direction of the deck.

As shown in fig. 6 and 7, the buoy steering device 30 is further installed at the edge of the deck, the steering device 30 comprises a hinge seat 31, a telescopic cylinder 32 and a steering frame 35, the hinge seat 31 and the telescopic cylinder 32 are installed on the deck between the two guide rails 11, the hinge seat 31 and the telescopic cylinder 32 are respectively arranged at intervals, the telescopic cylinder 32 is located at one side far away from the edge of the deck, and the bottom of the steering frame 35 is respectively connected with the hinge seat 31 and the telescopic cylinder 32.

Specifically, two adapter seats 33 are arranged on the deck, the two adapter seats 33 are arranged at intervals in the width direction of the deck, two steering seats 34 are also arranged at the bottom of a bogie 35, the bottom of a telescopic rod is hinged to the adapter seats 33, the tail end of the telescopic rod of a telescopic cylinder 32 is hinged to the steering seats 34, and the bottom of the other end of the bogie 35 is hinged to the deck through a hinge seat 31.

When the telescopic rod of the telescopic cylinder 32 performs telescopic motion, the bogie 35 is driven to rotate around the hinge seat 31, so that the conversion between the vertical direction and the horizontal direction of the bogie 35 is realized.

The electric winch 28 is fixedly arranged on the longitudinal beam, the guide rails 36 are arranged on two sides of the bogie 35, the lifting frame 50 is movably arranged on the guide rails 36, the lifting frame 50 is connected with the electric winch 28 on the truss 20, and the lifting frame 50 can be driven to move up and down in the guide rails 36 of the bogie 35 under the action of the electric winch 28.

In order to further increase the moving stroke of the buoy on the bogie 35, the bogie 35 of the present invention is a rectangular frame-shaped structure, the telescopic bracket 37 is installed on the bogie 35, the slide way is installed on the telescopic bracket 37, and the lifting frame 50 is movably connected with the slide way.

The buoy locking device 40 matched with the buoy in shape is arranged on the lifting frame 50 of the invention, and the locking device 40 can realize the fixation and the release of the buoy, thereby realizing the combination or the release of the buoy and the buoy guarantee operation system of the invention.

As shown in fig. 8, and referring to fig. 9 and 10, the float locking device 40 of the present invention includes two latch arms 41 mounted on the lifting frame 50, the latch arms 41 are formed of an arc portion 42 and a straight portion 43, the arc portion 42 is connected to the straight portion 43, the straight portion 43 is slidably connected to the lifting frame 50 and driven by a driving cylinder mounted on the lifting frame 50, and the two latch arms 41 are disposed opposite to each other, and a circular structure having an open end is formed by the arc portions 42 of the two latch arms 41.

When the buoy assurance operation system of the invention is close to the buoy, the driving cylinder drives the clamp arms 41 to open towards both sides, the neck of the buoy is accommodated in the gap between the two clamp arms 41 by utilizing the gap between the clamp arms 41, and then the driving cylinder drives the clamp arms 41 to close towards the middle, so that the gap between the two open and closed positions is matched with the neck of the buoy, thereby realizing the fixation and locking of the buoy. The float is disengaged from the locking device 40 in a manner opposite to the clamping operation of the float and will not be described in detail herein.

It should be noted that, in order to ensure the stability of the float in the movement process and prevent the float from rotating and falling off the mark, the invention also provides a limit groove 44 matched with the float on the arc part 42, and the limit groove 44 is clamped with the convex part on the outer circular surface of the float, so that the clamping and the positioning of the float can be realized.

Preferably, the lifting frame 50 is further provided with a motor 51, the output end of the motor 51 is provided with a friction wheel 52, the friction wheel 52 is in contact with the outer peripheral surface of the buoy, when in use, the motor 51 works to drive the friction wheel 52 to rotate, and the friction contact between the friction wheel 52 and the buoy drives the buoy to rotate, so that the relative position between the protruding part on the buoy and the limiting groove 44 is changed, the combination of the limiting groove 44 and the protruding part on the buoy is realized, and the clamping between the buoy and the locking device 40 is realized, and preferably, a rubber layer is arranged on the outer peripheral surface of the friction wheel 52 to prevent the surface of the buoy from being damaged when the friction wheel 52 is in friction with the outer peripheral surface of the buoy.

Preferably, in order to ensure that the force applied to the buoy is uniform, the lifting frame 50 of the present invention is provided with two motors 51, and the two motors 51 are respectively arranged on the lifting frame 50 in a straight shape, so as to ensure that the force applied to the buoy is uniform when the buoy rotates.

The locking device 40 of the present invention is vertically installed with the lifting frame 50, and the lifting frame 50 of the present invention is further installed with a lifting ring connected with the electric winch 28, so that when the buoy is in the sea, the lifting frame 50 can be pulled by the electric winch 28 to slide on the bogie 35 or the telescopic bracket 37, thereby realizing the buoy to move to the vertical position on the deck in the sea.

Referring to fig. 2, the truss 20 of the present invention includes a supporting frame 21 and two beams 24, a roller 25 is installed at the bottom of the supporting frame 21, the roller 25 is adapted to the rail 11, the supporting frame 21 is connected to the two beams 24, and a longitudinal beam 26 is installed between the beams 24, wherein the supporting frame 21 is composed of a triangular frame 22 and a connecting beam 23, the triangular frame 22 is in a right triangle shape, two ends of the connecting beam 23 are respectively connected to the top and the bottom of the triangular frame 22 to form a quadrilateral structure, the roller 25 is installed at the bottom of the supporting frame 21 and movably connected to the rail 11, a motor 51 drives the roller 25 to rotate to drive the truss 20 to move on the rail 11, thereby realizing the truss 20 to move in the length direction of the deck, the two beams 24 are parallelly erected at two ends of the two supporting frames 21, and the longitudinal beam 26 is installed between the two beams 24, and the longitudinal beams 26 may be two or one.

In the invention, the transverse beam 24 is provided with the electric hoist 27 which moves transversely, the longitudinal beam 26 is movably provided with the electric hoist 28, when in use, the electric hoist 27 can realize the movement of the buoy in the width direction of the deck, the electric hoist 28 can realize the movement of the buoy in the height direction, and the electric hoist, the truss 20, the guide rail 11, the telescopic bracket 37 and the lifting frame 50 can realize the movement of the buoy in the length direction of the deck.

The deck of the present invention is further provided with a plurality of carrier rollers 60, preferably, the carrier rollers 60 are divided into two rows, and the two rows of carrier rollers 60 are arranged opposite to the two ends of the bogie 35, when the buoy moves to the side away from the edge of the deck under the action of the telescopic bracket 37 through the steering device 30, the buoy moves to the carrier rollers 60, and under the support of the carrier rollers 60, the movement of the buoy in the length direction of the deck can be realized by combining the electric winch 28 on the truss 20 and the telescopic bracket 37 on the bogie 35.

Preferably, the locking device 40 is movably connected with the locking device 40, and the top of the lifting frame 50 is provided with a stopper 61, after the buoy is locked by the locking device 40, when the locking device 40 is lifted to the position of the stopper 61, the position can be automatically prompted by the stopper 61, wherein the stopper 61 can be a mechanical structure baffle or an electrical sensor.

In order to realize the full-automatic treatment of the buoy-guaranteed operation system, driving parts related to the invention, such as a motor 51, a hydraulic cylinder, an electric hoist 28, an electric hoist 27 and the like are internally provided with a stroke detection device to obtain the output quantity of the driving parts, collect the output quantity, send the output quantity to a control center in a wireless or wired mode, and perform deviation correction according to set parameters through the control center to realize feedback regulation of the driving parts. Certainly, in order to ensure the accuracy of the control, the invention does not exclude that a displacement sensor is arranged on the guide rail 11, displacement sensors are arranged on the cross beam 24, the longitudinal beam 26, the telescopic bracket 37 and the lifting frame 50, an angle sensor is arranged on the steering device 30, actual motion parameters are respectively collected and sent to the control center, and the control center compares the actual parameters with design parameters to obtain the deviation between the control and the actual operation, so that the feedback adjustment is carried out to achieve the purpose of accurate control.

Referring to fig. 11, the present invention further provides a buoy assurance process, which includes the following steps:

step A1, driving the hull 10 to move to the buoy setting position based on the buoy setting position, and driving the truss 20 to move to the deck edge;

step A2, driving the bogie 35 to be perpendicular to the deck end face, and moving the lifting frame 50 to a set position on the bogie 35;

step A3, driving the locking device 40 on the lifting frame 50 to combine with the buoy, and driving the truss 20 to move to the set position on the bogie 35 through the electric hoist 27 on the truss 20 and the lifting frame 50;

step A4, controlling the bogie 35 to rotate, so that the bogie 35 is parallel to the deck, the truss 20 retreats in the process of falling, and the electric winch 28 controls the winding and unwinding action of the steel wire rope in a constant tension state.

Step A5, the buoy can be moved to any designated position on the deck by controlling a transverse moving electric hoist and a longitudinal moving gear-driven travelling mechanism on the truss.

The following describes in detail specific procedures of the buoy maintenance operation, buoy removal operation, and buoy tagging operation of the buoy assurance operation system according to the present invention.

Maintenance operation of buoy

The buoy tender utilizes a dynamic positioning system to reverse access to the buoy. The center of the opening of the locking device 40 on the lifting frame 50 of the present invention is aligned with the center line of the buoy floating drum, the lifting frame 50 is lowered to a designated depth, the buoy floating drum is sleeved by the locking device 40, so that the buoy floating drum is positioned at the center of the lifting frame 50, and the lifting frame 50 is slowly lifted.

The motor 51 on the lifting frame 50 drives the friction wheel 52 to rotate, and the friction wheel 52 can drive the buoy to rotate, so that the protrusion on the outer circular surface of the buoy is aligned with the limiting groove 44 on the locking device 40. When the relative position of the buoy and the lifting frame 50 accurately corresponds, the lifting frame is continuously lifted, so that the buoy floating drum is correctly placed at a specified position in the lifting frame 50, and the locking device 40 is started to lock the floating drum.

And lifting the lifting frame 50, wherein the lifting frame 50 is always positioned in the slide way at the stern in the lifting process. When the lifting frame 50 is lifted to the limiter 61, the lifting frame is automatically stopped, meanwhile, the limiting hydraulic bolt is inserted, the lifting frame 50 is locked at the upper limiting position, the lifting frame and the buoy floating drum are prevented from naturally sliding down when being placed, and then the buoy floating drum is laid down through contraction of the telescopic rod.

The truss 20 on the deck moves towards the bow in the process of falling, and meanwhile, the hoisting winch controls the winding and unwinding action of a steel wire rope of the winch in a constant tension state, so that the buoy floating drum is safely and stably laid on the falling mechanism. After the buoy floating drum is laid flat, the telescopic hydraulic cylinder positioned in the telescopic bracket 37 extends out, the telescopic bracket 37 is pushed forwards continuously, the buoy floating drum is driven to move towards the direction of the bow, and the purpose of bringing the traction anchor chain to the deck is achieved. The electric hoist 27 on the deck is matched with a hoisting anchor chain, the anchor chain below the tail end shackle on the saddle chain connecting ring is placed into a chain holding device positioned in the middle position of the stern part, the chain holding device is closed, the anchor chain is locked, the tail end shackle is unlocked, the floating drum of the buoy is hoisted by the electric hoist 28 on the truss 20, a hoisting rigging is hung, two slings respectively hook the upper hoisting ring and the lower hoisting ring of the floating drum, the floating drum of the buoy is hoisted, the steel wire rope hoisted by the floating drum is stressed, the connecting buckle between the steel wire rope of the electric hoist 27 on the deck truss 20 and the hanging bracket of the floating drum is disconnected, the locking device 40 on the hanging bracket 50 is disconnected, the travelling crane is started to move forwards, the floating drum of the buoy is disconnected from the special lifting appliance.

The deck truss 20 moves to the upper part of the new buoy floating drum on the track, the electric hoist 27 is hung, the new buoy floating drum is moved and placed in the lifting frame 50 to accurately fall, and the floating drum locking device 40 is locked. The wire rope connected with the electric hoist 27 is connected with the lifting frame 50, the anchor chain is connected, and the chain holding device is opened. The telescopic bracket 37 of the lowering device is recovered to the limit position, the hydraulic cylinder extends out to push out to erect the buoy floating drum, the electric hoist 27 of the truss 20 lifts the hanger 50, the hydraulic bolt retracts, the hanger 50 is lowered to the specified position and then the locking device 40 is released, the hanger 50 is continuously lowered to be completely separated from the buoy floating drum, the ship moves forwards, and buoy replacement, namely buoy maintenance operation, is completed.

Second, buoy removing operation

The buoy removes the process and the operation is maintained the same with the buoy, treat the buoy on the ship fixed back, shift the anchor chain to the sincere chain ware that sets up at the stern portion port with electric block 28 on the driving a vehicle and lock, be connected to the setting on the anterior reel wire rope who plays anchor winch of stern portion deck, open sincere chain ware, start anchor winch and receive the anchor chain, combine the antedisplacement of boats and ships to make the heavy stone break earth, stop when heavy stone basic water goes out to receive the chain, shift to and lift by electric block 28 on the driving a vehicle and hang heavy stone to the assigned height, the deck jack-up driving that moves forward, remove the heavy stone and place to the assigned position and deposit, accomplish buoy and remove the mark operation.

Third, buoy marking operation

The buoy working ship arrives at the sea area of the labeling point, the traveling crane is moved to the anchor chain storage point, the electric hoist 28 is used for hoisting the anchor chain to the stern, the electric hoist 28 is used for hoisting the terminal anchor chain to be connected with the sinking stone, the end of the anchor chain is locked in the larboard anchor chain device, and the end of the anchor chain to be connected with the floating drum is locked in the anchor chain device in the middle of the stern. And moving the traveling crane to a sunk stone storage point, lifting the sunk stone by using an electric hoist 28, moving the sunk stone backwards to the front of the port chain clamping device, and connecting the sunk stone and the anchor chain. The deck crane moves above the new buoy drum, the hoisting rigging is hung, the buoy drum moves and is placed in the hoisting frame 50 to accurately fall, and the buoy drum locking device 40 is locked. And connecting a steel wire rope of a lifting winch with the lifting bracket 50, connecting an anchor chain, and opening a chain holding device in the middle of the stern. The retractable support 37 is laid down and recovered to the limit position, the hydraulic cylinder is turned over to push out the floating drum standing buoy, the lifting winch lifts the hanger 50, the hydraulic bolt returns, the floating drum hanger is lowered to the specified position and then the locking device 40 is released, the hanger 50 is continuously lowered to be completely separated from the floating drum buoy, and the ship moves forwards. The traveling crane moves to the position above the sunken stone, lifts the sunken stone to a specified height by using the electric block 28, moves backwards, moves the sunken stone to an outboard specified area, combines with ship moving operation to enable the sunken stone and the buoy buoying drum to leave a proper distance, avoids mutual collision, starts the disc type chain throwing device to throw the sunken stone into an underwater specified position, and finishes buoy marking operation.

The invention relates to a buoy guarantee operation system and an operation process thereof.A ship body 10 is combined with the buoy guarantee operation system, the buoy guarantee operation system is quickly moved to a buoy design position by the ship body 10, the combination of the buoy guarantee operation system and a buoy can be realized by the locking device 40, the lifting action of a lifting frame 50 on a bogie 35 can be realized by the lifting frame 50 and an electric hoist 27 on a truss 20, the conversion of the buoy from a vertical state to a horizontal state can be realized by combining the bogie 35 of a steering device 30, and the transverse movement and the longitudinal movement of the buoy on a deck can be realized by the structures of the truss 20 and a guide rail 11 and the electric hoist 28 on the truss 20, so that the maintenance, marking and marking of the buoy are realized.

According to the invention, through the design and use of the special operation equipment for buoy guarantee, the intellectualization and mechanization of buoy guarantee operation are realized, so that the traditional low-efficiency operation mode is changed, the labor intensity of workers is reduced, the buoy operation risk is reduced, the operation safety and efficiency are improved, the operation cost is reduced, and the energy consumption is saved.

Finally, the method of the present application is only a preferred embodiment and is not intended to limit the scope of the present invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides a buoy guarantee operating system installs on the hull, its characterized in that, buoy guarantee operating system is including installing guide rail on the hull deck, installing truss on the guide rail and steering gear, the truss is portable to be installed on the guide rail, be equipped with the crossbeam on the truss, electric block has been installed to the crossbeam is portable, steering gear installs the deck edge of hull, steering gear is including articulated seat, telescoping cylinder and bogie, articulated seat with the telescoping cylinder is installed respectively on the deck, the bottom of bogie respectively with articulated seat with the telescopic link of telescoping cylinder is articulated, the guided way has been installed to the both sides of bogie, the movable type has erect the gallows on the guided way, play be equipped with on the gallows with the locking device of buoy appearance adaptation.

2. The buoy safe operation system as claimed in claim 1, wherein the locking device comprises two locking arms mounted on the lifting frame, the locking arms are formed by an arc-shaped portion and a straight portion, the arc-shaped portion is connected with the straight portion, the two straight portions are oppositely arranged and movably mounted on the lifting frame by a driving cylinder, and the two locking arms are oppositely arranged to form a circular ring structure.

3. The buoy safe operation system as claimed in claim 2, wherein the arc portion is provided with a limit groove adapted to the buoy.

4. The buoy safe operation system as claimed in claim 2, wherein the lifting frame is provided with a motor, the output end of the motor is provided with a friction wheel, and the friction wheel is in contact with the outer edge surface of the buoy.

5. The buoy safe operation system as claimed in claim 1, wherein the truss includes a bearing frame and a cross beam, the bottom of the bearing frame is provided with rollers, the rollers are matched with the guide rails, the bearing frame is connected with the cross beam through the two cross beams, and a longitudinal beam is arranged between the cross beams.

6. The buoy safe operation system as claimed in claim 5, wherein the longitudinal beam is fixedly provided with an electric winch.

7. The buoy safe operation system as claimed in claim 1, wherein the bottom of the truss is provided with an electric gear walking mechanism matched with the guide rail.

8. The buoy safe operation system as claimed in claim 1, wherein the deck is further provided with a plurality of idlers, the idlers are arranged in two rows, and the idlers are arranged opposite to both ends of the bogie.

9. The buoy assurance system of claim 1, wherein the top of the lifting frame is provided with a stopper.

10. The buoy guaranteeing operation process is characterized by comprising the following steps of:

step A1, driving the ship body to run to the buoy set position based on the buoy set position, and driving the truss to move to the edge of the deck;

step A2, driving a bogie to be perpendicular to the end face of the deck, and moving a hoisting frame on the bogie to a set position;

step A3, driving a locking device on the lifting frame to be combined with the buoy, and driving the truss frame to move to a set position on the bogie through an electric hoist on the truss frame and the lifting frame;

step A4, controlling the bogie to rotate to enable the bogie to be parallel to a deck, retreating the truss in the process of falling, and controlling the winding and unwinding actions of the steel wire rope by the electric hoist in a constant tension state;

step A5, the buoy can be moved to any designated position on the deck by controlling the electric hoist moving transversely on the truss and the movement of the truss on the guide rail.

Images