CN212287643U

CN212287643U - Long-distance mechanical arm device for shallow underwater operation

Info

Publication number: CN212287643U
Application number: CN202022167710.7U
Authority: CN
Inventors: 杨向前; 刘书杰; 范白涛; 周超; 王彬; 王名春; 郭华; 郑清华; 张甫
Original assignee: Beijing Research Center of CNOOC China Ltd; CNOOC China Ltd
Current assignee: Beijing Research Center of CNOOC China Ltd; CNOOC China Ltd
Priority date: 2020-09-28
Filing date: 2020-09-28
Publication date: 2021-01-05
Anticipated expiration: 2030-09-28

Abstract

The utility model discloses a long-distance mechanical arm device for shallow water underwater operation, which comprises a driving base, a mechanical arm assembly and a control system; the mechanical arm is provided with a plurality of joint points which are arranged at intervals along the length direction of the arm, each joint point has a rotational degree of freedom, and the near end of the mechanical arm is connected to the driving base and can perform sliding movement and/or rotational movement on the driving base; the manipulator assembly is connected to the far end of the manipulator through a conversion joint and is used for underwater operation; control system is connected with drive base, arm and manipulator subassembly for drive base, arm and manipulator subassembly provide power and control, the utility model discloses a control system controls drive base and arm motion to change manipulator subassembly's position and orientation, realize the underwater operation of remote control lower different positions, can reduce the cost of labor, reduce staff's personal safety risk coefficient.

Description

Long-distance mechanical arm device for shallow underwater operation

Technical Field

The utility model relates to a device that is used for underwater operation among the offshore oil development process, in particular to a long distance mechanical arm device for shallow water underwater operation.

Background

In the offshore oil development process, when an underwater production system is used for offshore oil field development, a diver is required to submerge underwater sometimes to assist in completing the installation and later-stage detection and maintenance work of an underwater Christmas tree, an underwater wellhead, an underwater pipeline and an underwater valve, the labor cost is high, and the personal safety risk coefficient of personnel is high.

Disclosure of Invention

To the above problem, the utility model aims at providing a long distance mechanical arm device for shallow water underwater operation, the staff can control this long distance mechanical arm device service arm and carry out the underwater operation, can reduce the cost of labor, reduces staff's personal safety risk coefficient.

In order to achieve the above object, the utility model discloses a following technical scheme, a long distance mechanical arm device for shallow water underwater operation, its characterized in that: the robot comprises a driving base, a mechanical arm assembly and a control system;

the mechanical arm is provided with a plurality of joint points which are arranged at intervals along the length direction of the mechanical arm, each joint point has a rotation degree of freedom, the proximal end of the mechanical arm is connected to the driving base, and the mechanical arm can perform sliding movement and/or rotation movement on the driving base;

the manipulator assembly is connected to the far end of the mechanical arm through a conversion joint and is used for underwater operation;

the control system is connected with the driving base, the mechanical arm and the mechanical arm assembly and used for providing power and control for the driving base, the mechanical arm and the mechanical arm assembly.

In some embodiments, the mechanical arm comprises a plurality of sections of mechanical arm bodies hinged in sequence from a proximal end to a distal end, each section of mechanical arm body adopts a sealed box structure, a hinge joint point is formed between every two adjacent sections of mechanical arm bodies, a first driving part is arranged between every two adjacent sections of mechanical arm bodies, the first driving part is used for driving the mechanical arm body of the latter section of the two adjacent sections of mechanical arm bodies to rotate relative to the rotation axis of the hinge joint point between the two adjacent sections of mechanical arm bodies, and the two adjacent first driving parts are arranged in a different side; the first section of mechanical arm body located at the near end of the mechanical arm is hinged to the driving base to form a hinge point, and a second driving piece is arranged between the first section of mechanical arm body and the driving base and used for driving the mechanical arm to rotate relative to the rotation axis of the hinge point.

In some embodiments, the driving base includes a sliding beam, a base slidably connected to the sliding beam, a rotating base rotatably disposed on the base, a third driving member driving the base to slidably move along the sliding beam, and a fourth driving member driving the rotating base to rotate on the base, and the proximal end of the mechanical arm is hinged to the rotating base.

In some embodiments, each of the first driving members includes two second hydraulic cylinders, the two second hydraulic cylinders are symmetrically disposed between two adjacent sections of the arm body, the cylinder body of the second hydraulic cylinder is hinged to the arm body of the previous section, and the telescopic rod of the second hydraulic cylinder is hinged to the arm body of the next section.

In some embodiments, the second driving member includes two first hydraulic cylinders symmetrically disposed between the proximal end of the mechanical arm and the driving base, the cylinder bodies of the first hydraulic cylinders are hinged to the driving base, and the telescopic rods of the first hydraulic cylinders are hinged to the mechanical arm.

In some embodiments, the third drive employs a hydraulic or electric or rack and pinion drive mechanism; the fourth driving part adopts a hydraulic motor.

In some embodiments, a high-definition camera is configured on the manipulator assembly.

In some embodiments, the long range arm apparatus can be mounted on a surface vessel or drilling platform.

The utility model adopts the above technical scheme, it has following advantage: the utility model provides a long distance mechanical arm device, including the drive base, the arm, manipulator subassembly and control system, the manipulator subassembly passes through the switching and connects the distal end of installing at continuous many joints arm, and control system is the drive base, arm and manipulator subassembly provide power and control, and the staff controls drive base and arm motion through control system to change manipulator subassembly's position and orientation, realize the underwater operation of different positions under the remote control, can reduce the cost of labor, reduce staff's personal safety risk coefficient.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic structural view of the robot arm body of the present invention.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings and examples. It is to be understood, however, that the drawings are provided for a better understanding of the invention and that they are not to be interpreted as limiting the invention.

As shown in fig. 1 and 2, the utility model provides a long-distance mechanical arm device for shallow underwater operation, which comprises a driving base 1, a mechanical arm 2, a mechanical arm assembly 3 and a control system;

the proximal end of the mechanical arm 2 is connected to the driving base 1, and the mechanical arm 2 can perform sliding motion and/or rotating motion on the driving base 1; the mechanical arm 2 is provided with a plurality of joint points which are arranged at intervals along the length direction of the arm, and each joint point has a rotational degree of freedom; the manipulator assembly 3 is connected to the far end of the mechanical arm 2 through a conversion joint 4, and the manipulator assembly 3 is used for underwater operation; the control system is connected with the driving base 1, the mechanical arm 2 and the mechanical arm assembly 3 and used for providing power and control for the driving base 1, the mechanical arm 2 and the mechanical arm assembly 3.

In the above embodiment, preferably, the mechanical arm 2 includes a plurality of sections of arm bodies 21 sequentially hinged from a proximal end to a distal end, each section of arm body 21 adopts a sealed box structure, a hinge joint point is formed between every two adjacent sections of arm bodies 21, a first driving member is arranged between every two adjacent sections of arm bodies 21, the first driving member is used for driving the arm body 21 of the latter section of the two adjacent sections of arm bodies 21 to rotate relative to the rotation axis of the hinge joint point between the two adjacent sections of arm bodies 21, and the two adjacent first driving members are arranged in a different side; the first section of mechanical arm body 21 located at the near end of the mechanical arm 2 is hinged on the driving base 1 to form a hinge point, and a second driving part is arranged between the first section of mechanical arm body 21 and the driving base 1 and used for driving the mechanical arm 2 to rotate relative to the rotation axis of the hinge point.

In the above embodiment, the driving base 1 preferably comprises a slideway beam (not shown), a base 11 slidably connected to the slideway beam, a rotating base 12 rotatably disposed on the base 11, a third driving member for driving the base 11 to slidably move along the slideway beam, and a fourth driving member for driving the rotating base 12 to rotate on the base 11, and the proximal end of the mechanical arm 2 is hinged to the rotating base 12.

In the above embodiment, preferably, each first driving member includes two second hydraulic cylinders 6, the two second hydraulic cylinders 6 are symmetrically disposed between two adjacent sections of the arm bodies 21, the cylinder body of the second hydraulic cylinder 6 is hinged to the arm body 21 of the previous section, and the telescopic rod of the second hydraulic cylinder 6 is hinged to the arm body 21 of the next section.

In the above embodiment, preferably, the second driving member includes two first hydraulic cylinders 5, the two first hydraulic cylinders 5 are symmetrically disposed between the first section of the arm body 21 of the robot arm 2 and the driving base 1, the cylinder bodies of the first hydraulic cylinders 5 are hinged on the driving base 1, and the telescopic rods of the first hydraulic cylinders 5 are hinged on the first section of the arm body 21 of the robot arm 2.

In the above embodiments, the third drive member may preferably employ a hydraulic, electric or rack and pinion drive mechanism.

In the above embodiment, preferably, the fourth driving member may employ a hydraulic motor.

In the above embodiment, it is preferable that a high-definition camera be arranged on the manipulator assembly 3 to observe and process a work object at a close distance.

In the above embodiment, preferably the apparatus is mounted on a surface vessel or drilling platform on which personnel manually operate the robotic arm apparatus via a control system.

In the above embodiment, the robot assembly 3 is preferably an existing device for performing underwater operations, such as a hydraulic torque wrench, a hydraulic stretching tool, a hydraulic pushing tool, etc., and the adapter 4 is an existing connecting adapter to facilitate the connection between the robot assembly 3 and the continuous multi-joint robot 2.

The utility model discloses a use as follows: the control system controls the third driving part to operate according to underwater operation requirements, the second driving part drives the base 11 to perform sliding motion on the slideway beam, the rotating base 12 moves on the slideway beam along with the base 1, the fourth driving part operates to drive the rotating base 12 to rotate relative to the base 11, so as to drive the mechanical arm 2 to perform sliding and rotating motion on the driving base 1, change the spatial position and orientation of the mechanical arm 2 and the mechanical arm component 3 connected with the distal end of the mechanical arm, then, control the two first hydraulic cylinders 5 and the two second hydraulic cylinders 6 between every two adjacent mechanical arm bodies 21 to perform telescopic motion, change the included angles between different mechanical arm bodies 21, change the position and orientation of the mechanical arm component 3 on the distal end of the mechanical arm 2, realize underwater operation at different positions under remote control, meet the requirements of underwater operation at different positions, and reduce labor cost, and the personal safety risk coefficient of the working personnel is reduced.

The utility model discloses in the mechanical arm body 21 can be for the standard design, the mechanical arm body 21 of different positions can be exchanged and used, the number of sections of the mechanical arm body 21 on the continuous multi-joint mechanical arm 2 can be increased or reduced according to the length difference of the required mechanical arm of operation, the number of fourth driving pieces is correspondingly increased or reduced, and the connection between the mechanical arm body 21 and the first driving piece, the driving mode are not changed; the mechanical arm body 21 adopts a sealed box structure, the sealed box structure can prevent corrosion inside the box body under the marine working environment, and meanwhile, the hollow sealed box structure can provide certain buoyancy for the whole mechanical arm when working in water, so that the operation load of the whole mechanical arm is reduced.

The present invention has been described only with reference to the above embodiments, and the structure, arrangement position and connection of the components may be changed. On the basis of the technical scheme of the utility model, the all sides according to the utility model discloses the principle is all not excluded to the improvement that individual part goes on or the transform of equivalence the utility model discloses a protection scope is outside.

Claims

1. The utility model provides a long distance mechanical arm device for shallow water underwater operation which characterized in that: the robot comprises a driving base, a mechanical arm assembly and a control system;

2. A long-reach boom apparatus for shallow water underwater operations as claimed in claim 1, wherein: the mechanical arm comprises a plurality of mechanical arm bodies which are sequentially hinged from a near end to a far end, each mechanical arm body adopts a sealed box structure, a hinge joint point is formed between every two adjacent mechanical arm bodies, a first driving piece is arranged between every two adjacent mechanical arm bodies and is used for driving the mechanical arm body of the latter section of the two adjacent mechanical arm bodies to rotate relative to the rotation axis of the hinge joint point between the two adjacent mechanical arm bodies, and the two adjacent first driving pieces are arranged in a different side manner; the first section of mechanical arm body located at the near end of the mechanical arm is hinged to the driving base to form a hinge point, and a second driving piece is arranged between the first section of mechanical arm body and the driving base and used for driving the mechanical arm to rotate relative to the rotation axis of the hinge point.

3. A long-reach boom apparatus for shallow underwater operations as claimed in claim 1 or 2, wherein: the drive base includes the slide roof beam, and sliding connection is in base on the slide roof beam rotates the setting and is in rotating base on the base drives the base is followed slide roof beam sliding motion's third driving piece, and drive rotating base is in base pivoted fourth driving piece, the near-end of arm articulates on rotating base.

4. A long-reach boom apparatus for shallow water underwater operations as claimed in claim 2, wherein: each first driving piece comprises two second hydraulic cylinders, the two second hydraulic cylinders are symmetrically arranged between two adjacent sections of the mechanical arm bodies, the cylinder bodies of the second hydraulic cylinders are hinged to the mechanical arm body of the previous section, and the telescopic rods of the second hydraulic cylinders are hinged to the mechanical arm body of the next section.

5. A long-reach boom apparatus for shallow water underwater operations as claimed in claim 2, wherein: the second driving part comprises two first hydraulic cylinders, the two first hydraulic cylinders are symmetrically arranged between the near end of the mechanical arm and the driving base, the cylinder bodies of the first hydraulic cylinders are hinged to the driving base, and the telescopic rods of the first hydraulic cylinders are hinged to the mechanical arm.

6. A long-reach boom apparatus for shallow water underwater operations as claimed in claim 3, wherein: the third driving part adopts a hydraulic or electric or gear and rack driving mechanism; the fourth driving part adopts a hydraulic motor.

7. A long-reach boom apparatus for shallow water underwater operations as claimed in claim 1, wherein: and the manipulator assembly is provided with a high-definition camera.

8. A long-reach boom apparatus for shallow water underwater operations as claimed in claim 1, wherein: the long-distance mechanical arm device can be installed on a surface ship or a drilling platform.