CN110715725A

CN110715725A - Ship platform comprehensive state evaluation, fault prediction and health management system

Info

Publication number: CN110715725A
Application number: CN201911043312.XA
Authority: CN
Inventors: 郭建; 王朝红; 徐坤鹏; 张沪生
Original assignee: SHANGHAI ZHIMI TECH ENGINEERING INST Co Ltd
Current assignee: SHANGHAI ZHIMI TECH ENGINEERING INST Co Ltd
Priority date: 2019-10-30
Filing date: 2019-10-30
Publication date: 2020-01-21

Abstract

The invention belongs to the technical field of ship fault prediction, and particularly relates to a ship platform comprehensive state assessment, fault prediction and health management system which comprises a vibration analyzer body and a lead, wherein a movable groove is formed in the left side of the inner wall of the vibration analyzer body, a working groove is formed in the outer side of an extrusion block, a fixed groove is formed in the left side of the outer wall of the vibration analyzer body, the lead is connected to the upper end of the vibration analyzer body, positioning grooves are formed in the upper side and the lower side of a wire take-up shell, and a fixed cylinder is installed on the left side of the inner wall of the wire take-up shell. This boats and ships platform integrated state aassessment, failure prediction and health management system has designed the structure that has linkage extrusion function, has solved the inconvenient problem of gripping of traditional device, has designed the structure that has rolling locate function, has solved the inconvenient problem of adjusting wire rod length of traditional device, has designed the structure that has the absorption safeguard function simultaneously, has solved the fixed shakiness of traditional device and the poor problem of safeguard effect.

Description

Ship platform comprehensive state evaluation, fault prediction and health management system

Technical Field

The invention relates to the technical field of ship fault prediction, in particular to a comprehensive state evaluation, fault prediction and health management system for a ship platform.

Background

Boats and ships are important water transport means, through the use to boats and ships, make things convenient for people to move on water, in the boats and ships use, often need carry out comprehensive state to various equipment on the boats and ships platform and aassessment the while to the trouble forecast to make things convenient for people to provide the guarantee to the health of boats and ships whole operation.

The vibration analysis appearance can carry out the probability to the vibration frequency of equipment, thereby further judge the trouble that equipment exists, but traditional vibration analysis appearance needs the user to grip the observation to equipment for a long time in the use, easily lead to equipment to grip the unstability, and traditional vibration analysis appearance can not adjust the length of cable, lead to detecting the time measuring to the detection point of department far away, can't effectively install the use to vibration analysis appearance, traditional vibration analysis appearance adsorbs fixedly through the magnetite in the installation use, lead to in fixed process detection portion and detection face receive the striking, lead to equipment life to reduce, simultaneously easily lead to the detection point skew in the vibrations that are detected equipment operation in-process, influence the testing result.

In conclusion, the existing vibration analyzer has the defects of inconvenience in holding, inconvenience in adjusting the length of the wire, instability in fixing and poor protection effect during operation. In order to solve the problems, innovative design is urgently needed on the basis of the original vibration analyzer.

Disclosure of Invention

The invention aims to provide a comprehensive state evaluation, fault prediction and health management system for a ship platform, and aims to solve the problems of inconvenience in holding, inconvenience in adjusting the length of a wire rod, instability in fixing and poor protection effect in the background art.

In order to achieve the purpose, the invention provides the following technical scheme: a ship platform comprehensive state assessment, fault prediction and health management system comprises a vibration analyzer body and a lead, wherein a movable groove is formed in the left side of the inner wall of the vibration analyzer body, a pressing block is arranged on the inner side of the movable groove, an extrusion block is connected to the right end of the pressing block, a working groove is formed in the outer side of the extrusion block, the working groove is formed in the middle of the inner side of the vibration analyzer body, an extrusion groove is formed in the outer side of the tail end of the extrusion block, a fixing groove is formed in the left side of the outer wall of the vibration analyzer body, a movable rod is mounted on the inner side of the fixing groove, an extrusion groove is formed in the right side of the movable rod, a sponge rod is mounted on the left side of the movable rod, the lead is connected to the upper end of the vibration analyzer body, a wire collecting shell is connected to the lower portion of the lead, a function groove is formed, the upper side and the lower side of the wire winding shell are provided with positioning grooves, positioning rods are arranged on the inner sides of the positioning grooves and are arranged inside the rod grooves, the rod grooves are arranged on the upper side and the lower side of the outer wall of the vibration analyzer body, the left side of the inner wall of the wire winding shell is provided with a fixed cylinder, the right side of the fixed cylinder is provided with a working bearing, the right side of the working bearing is provided with an inner movable cylinder, the outer side of the inner movable cylinder is provided with an outer movable cylinder, the outer wall of the outer movable cylinder is fixedly provided with a positioning block, the outer side of the positioning block is connected with a fixed block, the fixed block is fixedly arranged on the right side of the inner wall of the wire winding shell, the tail end of the wire is provided with a joint, the outer part of the joint is provided with a sleeve, the inner part of the sleeve is provided with a working cylinder, and the magnet is mounted on the right side of the joint.

Preferably, the movable groove and the pressing block are in sliding connection, and the pressing block and the extrusion block are in clamping connection.

Preferably, the extrusion blocks are symmetrically arranged about the central line of the pressing block, and the extrusion blocks are in sliding connection with the working grooves.

Preferably, the extrusion block and the extrusion groove are in clamping connection, and the shapes of the tail end of the extrusion block and the longitudinal section of the extrusion groove are both right-angled trapezoids.

Preferably, the movable rod and the fixed slot are connected in a sliding manner, and the movable rod is connected with the sponge rod in a rotating manner through a rotating bearing connected with the movable rod and the sponge rod.

Preferably, the fixed cylinder is rotationally connected with the inner movable cylinder through a working bearing, and the inner movable cylinder is in sliding connection with the outer movable cylinder.

Preferably, the positioning block is arranged at an equal angle relative to the center line of the outer movable cylinder, and the positioning block is connected with the fixing block in a clamping manner.

Preferably, the sleeve and the joint are in a nested connection and the mandrel is equiangularly disposed about a centerline of the sleeve.

Preferably, the working barrel is in interference connection with the leather plug, and the working barrel is communicated with the bottom of the sucker.

Compared with the prior art, the invention has the beneficial effects that: the comprehensive state evaluation, fault prediction and health management system for the ship platform adopts a novel structural design, designs a structure with a linkage extrusion function, solves the problem that a traditional device is inconvenient to hold, designs a structure with a winding positioning function, solves the problem that the traditional device is inconvenient to adjust the length of a wire rod, simultaneously designs a structure with an adsorption protection function, and solves the problems that the traditional device is unstable to fix and has a poor protection effect;

1. the device has the advantages that a user supports hands against one side, close to the vibration analyzer body, of the sponge rod and pushes the sponge rod forwards, movement of the hands of the user on the device is achieved, the pressing block is further pressed, sliding of the pressing block in the movable groove is achieved, the pressing block extrudes the inclined plane of the extrusion block, the extrusion block slides in the working groove, the extrusion block extrudes the inclined plane of the extrusion groove, the movable rod slides in the fixed groove, the movable rod drives the sponge rod to extrude the back of the hand of the user, and therefore the device is prevented from slipping, and the problem that the traditional device is inconvenient to hold is solved;

2. the outer movable cylinder is pulled to the right side in fig. 3, the outer movable cylinder slides on the inner movable cylinder, the outer movable cylinder drives the positioning block and the fixing block to be separated from clamping, the outer movable cylinder is further rotated, the outer movable cylinder drives the inner movable cylinder to rotate, the inner movable cylinder winds and winds the wires, the outer movable cylinder is pulled to reset through a spring connected with the outer movable cylinder and the inner movable cylinder, the outer movable cylinder drives the positioning block and the fixing block to be clamped, and therefore the position of the inner movable cylinder is fixed, the position of the wires on the inner movable cylinder is fixed, and the problem that the length of the wires cannot be adjusted conveniently in a traditional device is solved;

3. adsorb the casing of check out test set through the magnetite, wherein sucking disc and holding surface contact, the sucking disc promotes the working barrel and moves on connecting, the sense terminal on connecting with detect the face contact, the buffering is absorbed in the spring that the in-process sucking disc collaborative working barrel and joint are connected to the joint and the collision between the face of detection, further control the sleeve, the sleeve extrudees the sucking disc, the sucking disc further adsorbs fixedly to the position between face of contact and the joint, thereby realize the installation of butt joint, the fixed shakiness of traditional device and the poor problem of protecting effect have been solved.

Drawings

FIG. 1 is a schematic front view of the present invention;

FIG. 2 is a schematic view of the front cross-sectional structure of the movable rod of the present invention;

FIG. 3 is a schematic side view of the cross-sectional structure of the present invention;

FIG. 4 is a schematic view of a front cross-sectional view of a positioning block according to the present invention;

FIG. 5 is an enlarged view of the structure at A in FIG. 3 according to the present invention;

FIG. 6 is a front sectional view of the sleeve according to the present invention.

In the figure: 1. a vibration analyzer body; 2. a movable groove; 3. a pressing block; 4. extruding the block; 5. a working groove; 6. extruding a groove; 7. a movable rod; 8. fixing grooves; 9. a sponge bar; 10. a wire; 11. a functional groove; 12. a wire take-up shell; 13. positioning a groove; 14. positioning a rod; 15. a rod groove; 16. a fixed cylinder; 17. a working bearing; 18. an inner movable cylinder; 19. an outer movable barrel; 20. positioning blocks; 21. a fixed block; 22. a joint; 23. a sleeve; 24. a working barrel; 25. a suction cup; 26. a plug of leather; 27. a magnet is provided.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-6, the present invention provides a technical solution: a ship platform comprehensive state assessment, fault prediction and health management system comprises a vibration analyzer body 1, a movable groove 2, a pressing block 3, an extrusion block 4, a working groove 5, an extrusion groove 6, a movable rod 7, a fixed groove 8, a sponge rod 9, a lead wire 10, a functional groove 11, a take-up shell 12, a positioning groove 13, a positioning rod 14, a rod groove 15, a fixed cylinder 16, a working bearing 17, an inner movable cylinder 18, an outer movable cylinder 19, a positioning block 20, a fixed block 21, a joint 22, a sleeve 23, a working cylinder 24, a sucking disc 25, a leather plug 26 and a magnet 27, wherein the left side of the inner wall of the vibration analyzer body 1 is provided with the movable groove 2, the inner side of the movable groove 2 is provided with the pressing block 3, the right end of the pressing block 3 is connected with the extrusion block 4, the outer side of the extrusion block 4 is provided with the working groove 5, the working groove 5 is arranged in the middle of the inner side of the vibration analyzer body 1, and, a fixed groove 8 is arranged on the left side of the outer wall of the vibration analyzer body 1, a movable rod 7 is arranged on the inner side of the fixed groove 8, a squeezing groove 6 is arranged on the right side of the movable rod 7, a sponge rod 9 is arranged on the left side of the movable rod 7, a lead 10 is connected to the upper end of the vibration analyzer body 1, a wire receiving shell 12 is connected to the lower portion of the lead 10, a function groove 11 is arranged on the left side of the wire receiving shell 12, the function groove 11 is arranged on the back of the vibration analyzer body 1, positioning grooves 13 are arranged on the upper side and the lower side of the wire receiving shell 12, positioning rods 14 are arranged on the inner sides of the positioning grooves 13, the positioning rods 14 are arranged inside the rod grooves 15, the rod grooves 15 are arranged on the upper side and the lower side of the outer wall of the vibration analyzer body 1, a fixed cylinder 16 is arranged on the left side of the inner wall of the wire, an outer movable barrel 19 is installed on the outer side of the inner movable barrel 18, a positioning block 20 is fixed on the outer wall of the outer movable barrel 19, a fixing block 21 is connected to the outer side of the positioning block 20, the fixing block 21 is fixed on the right side of the inner wall of the wire winding shell 12, a connector 22 is installed at the tail end of the wire 10, a sleeve 23 is arranged outside the connector 22, an inner installation working barrel 24 of the sleeve 23 is arranged inside the sleeve 23, a suction disc 25 penetrates through the right side of the working barrel 24, a leather plug 26 is installed on the left side of the inside of the working barrel 24, a magnet 27 is arranged on the inner side of the sleeve 23, and the magnet 27 is.

In the embodiment, the movable groove 2 is in sliding connection with the pressing block 3, and the pressing block 3 is in clamping connection with the extruding block 4, so that the pressing block 3 can effectively move in the movable groove 2, and the pressing block 3 can effectively extrude the extruding block 4, so that a structure with an extruding and fixing function on the device can effectively operate;

the extrusion blocks 4 are symmetrically arranged about the central line of the pressing block 3, and the extrusion blocks 4 are in sliding connection with the working groove 5, so that the extrusion blocks 4 can effectively move in the working groove 5, and the extrusion blocks 4 can further drive the movable rods 7 on the device to move;

the extrusion block 4 is connected with the extrusion groove 6 in a clamping manner, and the tail end of the extrusion block 4 and the longitudinal section of the extrusion groove 6 are both in a right trapezoid shape, so that the extrusion block 4 can effectively move after being extruded, and the extrusion block 4 can effectively extrude the inclined surface of the extrusion groove 6, so that the movable rod 7 is further driven to move;

the movable rod 7 is in sliding connection with the fixed groove 8, the movable rod 7 is in rotating connection with the sponge rod 9 through a rotating bearing formed by the movable rod 7 and the sponge rod 9, the movable rod 7 can effectively move in the fixed groove 8, the movable rod 7 can effectively drive the sponge rod 9 to move, and the sponge rod 9 can effectively rotate relative to the movable rod 7 through the rotating bearing;

the fixed cylinder 16 is in rotating connection with the inner movable cylinder 18 through the working bearing 17, the inner movable cylinder 18 is in sliding connection with the outer movable cylinder 19, the design ensures that the inner movable cylinder 18 can effectively rotate relative to the fixed cylinder 16 through the working bearing 17, so that the inner movable cylinder 18 can effectively wind the lead 10, and meanwhile, the outer movable cylinder 19 can effectively move on the inner movable cylinder 18, so that a structure with a positioning function on the device can effectively operate;

the positioning block 20 is arranged at an equal angle relative to the center line of the outer movable cylinder 19, and the positioning block 20 and the fixing block 21 are in clamping connection, so that the fixing block 21 can effectively fix the position of the outer movable cylinder 19 through the positioning block 20, and the lead 10 on the inner movable cylinder 18 are further fixed;

the sleeve 23 and the joint 22 are connected in a nested manner, and the working cylinder 24 is arranged at an equal angle relative to the central line of the sleeve 23, so that the sleeve 23 can effectively move on the joint 22, and the working cylinder 24 is connected with a structure with an adsorption fixing function and can effectively operate;

the working barrel 24 and the leather plug 26 are in interference connection, the bottom of the working barrel 24 is communicated with the bottom of the sucking disc 25, the leather plug 26 can effectively seal the working barrel 24 due to the design, and air inside the sucking disc 25 can effectively flow in the working barrel 24.

The working principle is as follows: when the device is used, firstly, the vibration analyzer body 1 on the device is powered on, wherein the vibration analyzer body 1 is the prior mature technology and is well known by the technical personnel in the field, and the detailed description is not provided herein;

when the vibration analyzer body 1 needs to be held, a user supports a hand against one side of the sponge rod 9 close to the vibration analyzer body 1 and pushes the sponge rod 9 forwards, the sponge rod 9 rotates through a rotary bearing connected with the movable rod 7, when a palm moves to the position of the pressing block 3, the pressing block 3 is pressed, the pressing block 3 slides in the movable groove 2, the pressing block 3 extrudes the inclined plane of the extrusion block 4, the extrusion block 4 slides in the working groove 5, the extrusion block 4 extrudes the inclined plane of the extrusion groove 6, the movable rod 7 slides in the fixed groove 8, and the movable rod 7 drives the sponge rod 9 to extrude the back of the hand of the user, so that the device is prevented from slipping;

when a conducting wire 10 on the device needs to be wound, an outer movable barrel 19 is pulled to the right side in fig. 3, the outer movable barrel 19 slides on an inner movable barrel 18, the outer movable barrel 19 drives a positioning block 20 and a fixing block 21 to be disengaged, the outer movable barrel 19 is rotated, the outer movable barrel 19 drives an inner movable barrel 18 to rotate, the inner movable barrel 18 winds and winds the conducting wire 10, the inner movable barrel 18 rotates relative to the fixing barrel 16 through a working bearing 17, when the winding length of the upper conducting wire 10 needs to be fixed, the outer movable barrel 19 is loosened, a spring connected with the outer movable barrel 19 and the inner movable barrel 18 pulls the outer movable barrel 19 to reset, the outer movable barrel 19 drives the positioning block 20 and the fixing block 21 to be engaged, so that the position of the inner movable barrel 18 is fixed, and the position of the conducting wire 10 on the inner movable barrel 18 is fixed;

when the wire-receiving shell 12 on the device needs to be disassembled, the positioning rod 14 is pulled, wherein the positioning rod 14 and the rod groove 15 are in sliding connection, the longitudinal section of the positioning rod 14 is in a right trapezoid shape, the positioning rod 14 is connected with the positioning groove 13 in a clamping way, the positioning rod 14 slides in the rod groove 15, the positioning rod 14 is separated from the positioning groove 13, the wire collecting shell 12 is pulled, wherein the wire-receiving shell 12 and the functional groove 11 are nested and connected, the wire-receiving shell 12 is separated from the functional groove 11, therefore, the wire collecting shell 12 is disassembled, when the wire collecting shell 12 needs to be installed, the wire collecting shell 12 is inserted into the functional groove 11, the wire collecting shell 12 extrudes the inclined surface of the positioning rod 14, the positioning rod 14 slides in the rod groove 15, when the positioning rod 14 is aligned with the positioning slot 13, the spring connected with the positioning rod 14 and the rod slot 15 pushes the positioning rod 14 to reset, and the positioning rod 14 is clamped with the positioning slot 13, so that the wire collecting shell 12 is installed;

when the joint 22 and the detection surface on the device need to be installed, the detection surface is cleaned, the tail end of the joint 22 is close to the surface to be detected, the magnet 27 adsorbs a shell of the detection device, the suction disc 25 is in contact with the supporting surface, the suction disc 25 pushes the working cylinder 24 to move on the joint 22, the detection end on the joint 22 is in contact with the detection surface, the suction disc 25 cooperates with a spring connected with the working cylinder 24 and the joint 22 to absorb and buffer collision between the joint 22 and the detection surface in the process, the sleeve 23 is pressed towards the detection surface, the sleeve 23 extrudes the suction disc 25, air in the suction disc 25 is exhausted to the outside of the suction disc 25, air pressure difference is generated between the suction disc 25 and the detection surface, and the suction disc 25 further fixes the position between the contact surface and the joint 22, so that the joint 22 is installed.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a state evaluation, failure prediction and health management system are synthesized to boats and ships platform, includes vibration analysis appearance body (1) and wire (10), its characterized in that: the vibration analyzer is characterized in that a movable groove (2) is formed in the left side of the inner wall of a vibration analyzer body (1), a pressing block (3) is arranged on the inner side of the movable groove (2), an extrusion block (4) is connected to the right end of the pressing block (3), a working groove (5) is formed in the outer side of the extrusion block (4), the working groove (5) is formed in the middle of the inner side of the vibration analyzer body (1), an extrusion groove (6) is formed in the outer side of the tail end of the extrusion block (4), a fixing groove (8) is formed in the left side of the outer wall of the vibration analyzer body (1), a movable rod (7) is installed on the inner side of the fixing groove (8), an extrusion groove (6) is formed in the right side of the movable rod (7), a sponge rod (9) is installed on the left side of the movable rod (7), a lead (10) is connected to the upper end of the vibration analyzer body, and the left side of the wire winding shell (12) is provided with a functional groove (11), the functional groove (11) is arranged at the back of the vibration analyzer body (1), the upper and lower sides of the wire winding shell (12) are provided with positioning grooves (13), the inner sides of the positioning grooves (13) are provided with positioning rods (14), the positioning rods (14) are arranged in rod grooves (15), the rod grooves (15) are arranged at the upper and lower sides of the outer wall of the vibration analyzer body (1), the left side of the inner wall of the wire winding shell (12) is provided with a fixed cylinder (16), the right side of the fixed cylinder (16) is provided with a working bearing (17), the right side of the working bearing (17) is provided with an inner movable cylinder (18), the outer side of the inner movable cylinder (18) is provided with an outer movable cylinder (19), the outer wall of the outer movable cylinder (19) is fixed with a positioning block (20), and the outer side of the positioning block (20) is connected with a, fix block (21) simultaneously and fix the right side at receipts line shell (12) inner wall, joint (22) are installed to the end of wire (10), and the outside that connects (22) is provided with sleeve (23) to internally mounted working barrel (24) of sleeve (23), sucking disc (25) have been run through on the right side of working barrel (24), and leather plug (26) are installed in the inside left side of working barrel (24), the inboard of sleeve (23) is provided with magnetite (27), and magnetite (27) are installed on the right side that connects (22).

2. The comprehensive state evaluation, fault prediction and health management system for a ship platform according to claim 1, wherein: the movable groove (2) is in sliding connection with the pressing block (3), and the pressing block (3) is in clamping connection with the extrusion block (4).

3. The comprehensive state evaluation, fault prediction and health management system for a ship platform according to claim 1, wherein: the extrusion blocks (4) are symmetrically arranged relative to the central line of the pressing block (3), and the extrusion blocks (4) are in sliding connection with the working groove (5).

4. The comprehensive state evaluation, fault prediction and health management system for a ship platform according to claim 1, wherein: the extrusion block (4) is connected with the extrusion groove (6) in a clamping manner, and the tail end of the extrusion block (4) and the longitudinal section of the extrusion groove (6) are both in a right trapezoid shape.

5. The comprehensive state evaluation, fault prediction and health management system for a ship platform according to claim 1, wherein: the movable rod (7) is connected with the fixed groove (8) in a sliding mode, and the movable rod (7) is connected with the sponge rod (9) in a rotating mode through a rotating bearing formed by the movable rod (7) and the sponge rod (9) in a rotating mode.

6. The comprehensive state evaluation, fault prediction and health management system for a ship platform according to claim 1, wherein: the fixed cylinder (16) is rotationally connected with the inner movable cylinder (18) through a working bearing (17), and the inner movable cylinder (18) is in sliding connection with the outer movable cylinder (19).

7. The comprehensive state evaluation, fault prediction and health management system for a ship platform according to claim 1, wherein: the positioning block (20) is arranged at an equal angle relative to the central line of the outer movable cylinder (19), and the positioning block (20) is connected with the fixing block (21) in a clamping manner.

8. The comprehensive state evaluation, fault prediction and health management system for a ship platform according to claim 1, wherein: the sleeve (23) and the joint (22) are connected in a nested mode, and the working barrel (24) is arranged in an equiangular mode relative to the center line of the sleeve (23).

9. The comprehensive state evaluation, fault prediction and health management system for a ship platform according to claim 1, wherein: the working barrel (24) is in interference connection with the leather plug (26), and the bottom of the working barrel (24) is communicated with the bottom of the sucker (25).