CN113617589B - Grid-shaped graphite coating equipment based on ship flexible resistance strain gauge - Google Patents

Abstract

The invention relates to the field of ship intellectualization, in particular to grid-shaped graphite coating equipment based on flexible resistance strain gages of ships. The technical problems to be solved are as follows: provided is a grid-shaped graphite coating device based on flexible resistance strain gages of ships. The technical proposal is as follows: a grid-shaped graphite coating device based on flexible resistance strain sheets of ships comprises a bottom plate assembly, a support and the like; the bottom plate component is fixedly connected with the support. The invention realizes that the metal connecting piece is transmitted to the basal layer, then, a layer of graphite is coated on the basal layer, the graphite coating is formed into a shape similar to a Z shape, then, the graphite coating is formed into a shape similar to a pi shape, the operation is repeated according to the same working principle, and then, the grid-shaped graphite coating is formed, pouring sealant is dripped on the upper surface of the basal layer, and an upper covering layer is formed by solidification, so that the grid-shaped graphite coating can be deformed synchronously and equivalently, and the strain quantity of the grid-shaped graphite coating can be accurately tested.

Description

Grid-shaped graphite coating equipment based on ship flexible resistance strain gauge

Technical Field

The invention relates to the field of ship intellectualization, in particular to grid-shaped graphite coating equipment based on flexible resistance strain gages of ships.

Background

At present, in the prior art, a traditional resistance strain gauge sensitive grid is wound by a constantan wire or a nichrome wire, although the precision is higher, the deformation capacity is very small, and the resistance strain gauge can not be tested on objects with large deformation, such as rock vibration caused by explosion and beam column steel bars when bending or stretching damage occurs.

In summary, there is a need to develop a grid-like graphite coating apparatus based on flexible resistance strain gages for ships to overcome the above-mentioned problems.

Disclosure of Invention

In order to overcome the defects that in the prior art, a traditional resistance strain gauge sensitive grid is wound by constantan wires or nichrome wires, although the precision is higher, the deformation capacity is very small, and the traditional resistance strain gauge can not be tested on an object with large deformation such as rock vibration caused by explosion and beam column steel bars when bending or stretching damage occurs, and in addition, the traditional resistance strain gauge has larger rigidity no matter a substrate or the sensitive grid, and can not accurately test the strain capacity of the object with rigidity smaller than the rigidity of the traditional resistance strain gauge, such as a rubber sleeve for a ground stress test, due to uncooled deformation, the technical problems to be solved are that: provided is a grid-shaped graphite coating device based on flexible resistance strain gages of ships.

The technical proposal is as follows: a grid-shaped graphite coating device based on flexible resistance strain sheets of ships comprises a bottom plate assembly, a coating unit, a glue dripping unit, a control screen, a support, a first conveyor belt, support legs, anti-slip pads, a collecting box and a handle; the bottom plate component is fixedly connected with the coating unit; the bottom plate component is rotationally connected with the glue dropping unit; the bottom plate component is fixedly connected with the support; the bottom plate component is fixedly connected with the first conveyor belt; the bottom plate component is fixedly connected with the four groups of supporting legs; the bottom plate component is contacted with the collecting box; the coating unit is fixedly connected with the glue dripping unit; the glue dropping unit is fixedly connected with the first conveyor belt; the support is fixedly connected with the control screen; the four groups of support legs are fixedly connected with the four groups of anti-skid pads respectively; the collecting box is fixedly connected with the handle; the coating unit coats a layer of graphite on the basal layer to form a grid-shaped graphite coating, and the glue dripping unit drips pouring sealant on the upper surface of the basal layer of the grid-shaped graphite coating formed by the coating unit, and the pouring sealant is solidified to form an upper covering layer.

Further, the device also comprises a conveying unit, wherein the conveying unit comprises a second conveying belt, a first supporting frame, a first electric push rod, a first wedge plate, a second wedge plate and a first spring; the second conveyor belt is fixedly connected with the bottom plate assembly; the second conveyor belt is fixedly connected with the first supporting frame; the first support frame is fixedly connected with the first electric push rod; the first electric push rod is fixedly connected with the first wedge plate; the second conveyor belt is in sliding connection with the second wedge plate; the second wedge plate is fixedly connected with the first spring; the first spring is fixedly connected with the second conveyor belt.

Further, the coating unit comprises a motor, a first transmission shaft, a first straight gear, a second transmission shaft, a first connecting rod, a first connecting frame, a first fixing frame, a second connecting rod, a first sliding block, a second fixing frame, a second supporting frame, a first automatic telescopic pen, a third connecting rod, a second sliding block, a third supporting frame, a second automatic telescopic pen, a first fixing plate, a first sliding rod, a second spring, a first wedge block, a second wedge block, a third spring, a first sliding plate, a fourth supporting frame, a third automatic telescopic pen, a second connecting frame, a third fixing frame, a fourth connecting rod, a third sliding block, a fifth supporting frame, a fourth automatic telescopic pen, a fifth connecting rod, a fourth sliding block, a fourth fixing frame, a fifth automatic telescopic pen, a second sliding rod, a fourth spring, a third wedge block, a fourth wedge block, a fifth spring, a second sliding plate, a sixth supporting frame, a sixth automatic telescopic pen, a rubber and a seventh supporting frame; the motor is fixedly connected with the bottom plate assembly; the motor is fixedly connected with the first transmission shaft; the first transmission shaft is rotationally connected with the bottom plate assembly; the first transmission shaft is fixedly connected with the glue dropping unit; the first transmission shaft is fixedly connected with the first straight gear; the first straight gear is meshed with the second straight gear; the second spur gear is fixedly connected with a second transmission shaft; the second transmission shaft is rotationally connected with the bottom plate assembly; the second transmission shaft is fixedly connected with the first connecting rod; the first connecting rod is rotationally connected with the first connecting frame; the first connecting frame is fixedly connected with the first fixing frame; the first fixing frame is rotationally connected with the second connecting rod; the second connecting rod is rotationally connected with the first sliding block; the first sliding block is in sliding connection with the second fixing frame; the second fixing frame is fixedly connected with the bottom plate assembly; the first sliding block is fixedly connected with the second supporting frame; the second support frame is rotationally connected with the first automatic telescopic pen; the first fixing frame is rotationally connected with the third connecting rod; the third connecting rod is rotationally connected with the second sliding block; the second sliding block is in sliding connection with the second fixing frame; the second sliding block is fixedly connected with the third supporting frame; the third support frame is fixedly connected with the second automatic telescopic pen; the second fixing frame is fixedly connected with the first fixing plate; the second fixing frame is in sliding connection with the first sliding rod; the second fixing frame is fixedly connected with a second spring; the first sliding rod is fixedly connected with the second spring; the first sliding rod is fixedly connected with the first wedge block; the side part of the first wedge block is provided with a second wedge block; the second wedge block is fixedly connected with the third spring; the third spring is fixedly connected with the second fixing frame; the second wedge block is fixedly connected with the first sliding plate; the first sliding plate is in sliding connection with the bottom plate assembly; the first sliding plate is fixedly connected with the fourth supporting frame; the fourth supporting frame is in sliding connection with the rubber; the fourth supporting frame is rotationally connected with the third automatic telescopic pen; the first connecting rod is rotationally connected with the second connecting frame; the second connecting frame is fixedly connected with the third fixing frame; the third fixing frame is rotationally connected with the fourth connecting rod; the fourth connecting rod is rotationally connected with the third sliding block; the third sliding block is in sliding connection with the fourth fixing frame; the third sliding block is fixedly connected with the fifth supporting frame; the fifth supporting frame is rotationally connected with the fourth automatic telescopic pen; the first fixing plate to the third automatic telescopic pen are provided with the same parts by taking the middle section of the rubber as a center shaft; the third fixing frame is rotationally connected with the fifth connecting rod; the fifth connecting rod is rotationally connected with the fourth sliding block; the fourth sliding block is in sliding connection with the fourth fixing frame; the fourth fixing frame is fixedly connected with the bottom plate assembly; the fourth sliding block is fixedly connected with the seventh supporting frame; the seventh support frame is rotationally connected with the fifth automatic telescopic pen; the fourth fixing frame is in sliding connection with the second sliding rod; the fourth fixing frame is fixedly connected with a fourth spring; the second sliding rod is fixedly connected with the fourth spring; the second sliding rod is fixedly connected with the third wedge block; the side part of the third wedge block is provided with a fourth wedge block; the fourth wedge block is fixedly connected with the fifth spring; the fifth spring is fixedly connected with the bottom plate assembly; the fourth wedge block is fixedly connected with the second sliding plate; the second sliding plate is in sliding connection with the bottom plate assembly; the second sliding plate is fixedly connected with the sixth supporting frame; the sixth support frame is rotationally connected with a sixth automatic telescopic pen; the sixth support frame is in sliding connection with the rubber; the second slide bar to the seventh support frame are provided with the same components by taking the middle section of the rubber as a center shaft.

Further, the glue dropping unit comprises a first driving wheel, a second driving wheel, a telescopic rod, a third spur gear, a second fixing plate, a second electric push rod, a third transmission shaft, a fifth fixing frame, a screw rod and a glue dispenser; the first transmission shaft is fixedly connected with the first transmission wheel; the first driving wheel is in driving connection with the second driving wheel through a belt; the second driving wheel is fixedly connected with the telescopic rod; the telescopic rod is rotationally connected with the bottom plate assembly; the telescopic rod is fixedly connected with the third straight gear; the telescopic rod is rotationally connected with the second fixed plate; the second fixing plate is fixedly connected with the second electric push rod; the second electric push rod is fixedly connected with the bottom plate assembly; the side part of the third straight gear is provided with a third transmission shaft; the third transmission shaft is rotationally connected with the fifth fixing frame; the fifth fixing frame is fixedly connected with the first conveyor belt; the third transmission shaft is fixedly connected with the screw rod; the screw rod is rotationally connected with the fifth fixing frame; the screw rod is screwed with the dispensing machine; the glue dispenser is in sliding connection with the fifth fixing frame; the first driving wheel to the glue dispenser is provided with the same components by taking the middle section of the rubber as a center shaft.

Further, the first wedge block and the second wedge block which are symmetrically arranged are opposite to the first wedge block and the second wedge block.

Further, the third wedge block and the fourth wedge block which are symmetrically arranged are opposite to the third wedge block and the fourth wedge block.

Further, a tooth hole matched with the third straight gear is arranged in the third transmission shaft.

Further, a chute matched with the second wedge-shaped plate is arranged in the second conveyor belt.

The beneficial effects of the invention are as follows:

(1) In order to solve the problems that in the prior art, a traditional resistance strain gauge sensitive grid is wound by constantan wires or nichrome wires, although the precision is high, the deformation capacity is very small, and the traditional resistance strain gauge can not be tested on an object with large deformation such as rock vibration caused by explosion and beam column steel bars when bending or stretching damage occurs.

(2) When in use, the grid-shaped graphite coating equipment based on the flexible resistance strain sheet of the ship is placed at a position to be used, so that four groups of support legs and four groups of anti-skid pads are kept horizontal, then an external power supply is connected, and the starting is controlled by a control screen on a support; firstly, a worker places a rectangular metal connecting piece in a conveying unit on a bottom plate assembly, meanwhile, a soft insulating substrate layer is placed on a first conveying belt, then the metal connecting piece is conveyed into the substrate layer by the conveying unit, then the substrate layer is conveyed into a coating unit by the first conveying belt, then a layer of graphite is coated on the substrate layer by a pencil by the coating unit to form a grid-shaped graphite coating, then pouring sealant is dripped on the upper surface of the substrate layer by a glue dripping unit, an upper covering layer is formed by solidification, and finally the glass is collected into a collecting box on a handle by the worker.

(3) The invention realizes that the metal connecting piece is transmitted to the basal layer, then, a layer of graphite is coated on the basal layer, the graphite coating is formed into a shape similar to a Z shape, then, the graphite coating is formed into a shape similar to a pi shape, the operation is repeated according to the same working principle, and then, the grid-shaped graphite coating is formed, pouring sealant is dripped on the upper surface of the basal layer, and an upper covering layer is formed by solidification, so that the grid-shaped graphite coating can be deformed synchronously and equivalently, and the strain quantity of the grid-shaped graphite coating can be accurately tested.

Drawings

FIG. 1 is a first perspective view of the present invention;

FIG. 2 is a schematic view of a second perspective structure of the present invention;

FIG. 3 is a schematic perspective view of a conveying unit according to the present invention;

FIG. 4 is a schematic view showing a partial perspective structure of a transfer unit according to the present invention;

FIG. 5 is a schematic perspective view of a coating unit according to the present invention;

fig. 6 is a schematic perspective view of a first portion of the coating unit of the present invention;

fig. 7 is a schematic perspective view of a second portion of the coating unit of the present invention;

fig. 8 is a schematic perspective view of a third portion of the coating unit of the present invention;

fig. 9 is a schematic perspective view of a fourth portion of the coating unit of the present invention;

FIG. 10 is a schematic perspective view of a dispensing unit according to the present invention;

FIG. 11 is a schematic view of a part of a three-dimensional structure of a glue dropping unit according to the present invention;

fig. 12 is an enlarged view of zone B of the present invention.

Reference numerals: 1_floor assembly, transfer unit, coating unit, glue dropping unit, 5_control screen, 6_support, 7_first conveyor, 8_leg, 9_skid pad, 10_collector, 11_handle, 201_second conveyor, 202_first support frame, 203_first electric push rod, 204_first wedge plate, 205_second wedge plate, 206_first spring, 301_motor, 302_first drive shaft, 303_first spur gear, 304_second spur gear, 305_second drive shaft, 306_first link, 307_first connection frame, 308_first mount, 309_second link, 310_first slide, 311_second mount, 312_second support frame, 313_first auto-telescopic pen, 314_third link, 315_second slide, 316_third support frame, 317_second auto-telescopic pen, 318_first fixed plate, 319_first slide bar, 320_second spring, 321_first wedge, 322_second wedge, 323_third spring, 324_first slide, 325_fourth carriage, 326_third self-expanding pen, 327_second carriage, 328_third mount, 329_fourth link, 330_third slider, 331_fifth carriage, 332_fourth self-expanding pen, 333_fifth link, 334_fourth slider, 335_fourth mount, 336_fifth self-expanding pen, 337_second slide bar, 338_fourth spring, 339_third wedge, 340_fourth wedge, 341_fifth spring, 342_second slide, 343_sixth carriage, 344_sixth self-expanding pen, 345_rubber, 346_seventh carriage, 401_first drive wheel, 402_second drive wheel, 403_expansion link, 404_third spur gear, 405_second fixed plate, 406_second electric push rod, 407_third transmission shaft, 408_fifth fixing frame, 409_screw rod and 410_dispenser.

Detailed Description

The invention is further described below with reference to the drawings and examples.

Examples

The grid-shaped graphite coating equipment based on the flexible resistance strain sheet of the ship comprises a bottom plate assembly 1, a conveying unit, a coating unit, a glue dripping unit, a control screen 5, a support 6, a first conveying belt 7, support legs 8, an anti-slip pad 9, a collecting box 10 and a handle 11, wherein the bottom plate assembly is shown in fig. 1-2; the bottom plate component 1 is fixedly connected with the conveying unit; the bottom plate component 1 is fixedly connected with the coating unit; the bottom plate component 1 is rotationally connected with the glue dropping unit; the bottom plate component 1 is fixedly connected with the support 6; the bottom plate component 1 is fixedly connected with the first conveyor belt 7; the bottom plate component 1 is fixedly connected with four groups of support legs 8; the bottom plate assembly 1 is in contact with the collection box 10; the coating unit is fixedly connected with the glue dripping unit; the glue dropping unit is fixedly connected with the first conveyor belt 7; the support 6 is fixedly connected with the control screen 5; the four groups of support legs 8 are fixedly connected with four groups of anti-skid pads 9 respectively; the collecting box 10 is fixedly connected with the handle 11; the coating unit coats a layer of graphite on the basal layer to form a grid-shaped graphite coating, and the glue dripping unit drips pouring sealant on the upper surface of the basal layer of the grid-shaped graphite coating formed by the coating unit, and the pouring sealant is solidified to form an upper covering layer.

Working principle: when the flexible resistance strain foil grid-shaped graphite coating equipment based on the ship is used, the grid-shaped graphite coating equipment based on the flexible resistance strain foil grid-shaped graphite coating equipment is placed at a position to be used, four groups of support legs 8 and four groups of anti-slip pads 9 are kept horizontal, then a power supply is externally connected, and the starting is controlled through a control screen 5 on a support 6; firstly, a rectangular metal connecting piece is placed in a conveying unit on a bottom plate assembly 1 by a worker, meanwhile, a soft insulating basal layer is placed on a first conveying belt 7, then the metal connecting piece is conveyed into the basal layer by the conveying unit, then the basal layer is conveyed into a coating unit by the first conveying belt 7, then a layer of graphite is coated on the basal layer by a pencil through the coating unit to form a grid-shaped graphite coating, then pouring sealant on the upper surface of the basal layer by a glue dropping unit, curing to form an upper covering layer, and finally collecting the upper covering layer into a collecting box 10 on a handle 11 by the worker.

According to fig. 3-4, the conveyor further comprises a conveying unit, wherein the conveying unit comprises a second conveying belt 201, a first supporting frame 202, a first electric push rod 203, a first wedge plate 204, a second wedge plate 205 and a first spring 206; the second conveyor belt 201 is fixedly connected with the bottom plate assembly 1; the second conveyor belt 201 is fixedly connected with the first supporting frame 202; the first supporting frame 202 is fixedly connected with the first electric push rod 203; the first electric push rod 203 is fixedly connected with the first wedge plate 204; the second conveyor belt 201 is in sliding connection with the second wedge plate 205; the second wedge plate 205 is fixedly connected with the first spring 206; the first spring 206 is fixedly connected with the second conveyor belt 201.

Firstly, a worker places a metal connecting piece in a second conveyor belt 201, meanwhile, a soft insulating substrate layer is placed on a first conveyor belt 7, then, the metal connecting piece is conveyed into the substrate layer, the second conveyor belt 201 starts to drive the metal connecting piece to move onto a second wedge-shaped plate 205, then, when the first conveyor belt 7 operates to convey the substrate layer to the lower part of the second wedge-shaped plate 205, a first electric push rod 203 on a first support frame 202 starts to drive a first wedge-shaped plate 204 to move downwards, then drives the second wedge-shaped plate 205 to move, further, a first spring 206 is extruded, further, the metal connecting piece on the second wedge-shaped plate 205 is conveyed onto the substrate layer, then, the substrate layer is conveyed into a coating unit through the first conveyor belt 7, and the conveying unit realizes conveying of the metal connecting piece into the substrate layer.

As shown in fig. 5 to 9, the coating unit includes a motor 301, a first transmission shaft 302, a first spur gear 303, a second spur gear 304, a second transmission shaft 305, a first link 306, a first connection frame 307, a first fixing frame 308, a second link 309, a first slider 310, a second fixing frame 311, a second support frame 312, a first automatic telescopic pen 313, a third link 314, a second slider 315, a third support frame 316, a second automatic telescopic pen 317, a first fixing plate 318, a first slide bar 319, a second spring 320, a first wedge 321, a second wedge 322, a third spring 323, a first slide plate 324, a fourth support frame 325, a third automatic telescopic pen 326, a second connection frame 327, a third fixing frame 328, a fourth link 329, a third slider 330, a fifth support frame 331, a fourth automatic telescopic pen 332, a fifth link 333, a fourth slider 334, a fourth fixing frame 335, a fifth automatic telescopic pen 336, a second slider 337, a third wedge 337, a fourth wedge 340, a fifth spring 341, a sixth support frame 342, a seventh slide bar 346, and a seventh slide bar 346; the motor 301 is fixedly connected with the bottom plate assembly 1; the motor 301 is fixedly connected with the first transmission shaft 302; the first transmission shaft 302 is rotatably connected with the bottom plate assembly 1; the first transmission shaft 302 is fixedly connected with the glue dropping unit; the first transmission shaft 302 is fixedly connected with a first straight gear 303; the first spur gear 303 is meshed with the second spur gear 304; the second spur gear 304 is fixedly connected with a second transmission shaft 305; the second transmission shaft 305 is rotatably connected with the bottom plate assembly 1; the second transmission shaft 305 is fixedly connected with the first connecting rod 306; the first link 306 is rotatably connected to the first link 307; the first connecting frame 307 is fixedly connected with the first fixing frame 308; the first fixing frame 308 is rotatably connected with the second connecting rod 309; the second connecting rod 309 is rotatably connected with the first slider 310; the first sliding block 310 is in sliding connection with the second fixing frame 311; the second fixing frame 311 is fixedly connected with the bottom plate assembly 1; the first sliding block 310 is fixedly connected with the second supporting frame 312; the second supporting frame 312 is rotatably connected with the first automatic telescopic pen 313; the first fixing frame 308 is rotatably connected with the third connecting rod 314; the third connecting rod 314 is rotationally connected with the second sliding block 315; the second slider 315 is slidably connected with the second fixing frame 311; the second sliding block 315 is fixedly connected with the third supporting frame 316; the third support 316 is fixedly connected with the second automatic telescopic pen 317; the second fixing frame 311 is fixedly connected with the first fixing plate 318; the second fixing frame 311 is in sliding connection with the first sliding rod 319; the second fixing frame 311 is fixedly connected with the second spring 320; the first sliding rod 319 is fixedly connected with the second spring 320; the first slide bar 319 is fixedly connected with the first wedge block 321; the side of the first wedge block 321 is provided with a second wedge block 322; the second wedge block 322 is fixedly connected with the third spring 323; the third spring 323 is fixedly connected with the second fixing frame 311; the second wedge block 322 is fixedly connected with the first sliding plate 324; the first slide plate 324 is in sliding connection with the base plate assembly 1; the first sliding plate 324 is fixedly connected with the fourth supporting frame 325; the fourth supporting frame 325 is in sliding connection with the rubber 345; the fourth supporting frame 325 is rotatably connected with the third automatic telescopic pen 326; the first link 306 is rotatably connected with the second link 327; the second connecting frame 327 is fixedly connected with the third fixing frame 328; the third fixing frame 328 is rotationally connected with the fourth connecting rod 329; the fourth connecting rod 329 is rotationally connected with the third sliding block 330; the third slider 330 is slidably connected with the fourth fixing frame 335; the third sliding block 330 is fixedly connected with the fifth supporting frame 331; the fifth supporting frame 331 is rotatably connected with the fourth automatic telescopic pen 332; the first fixing plate 318 to the third automatic telescopic pen 326 are provided with the same components by taking the middle section of the rubber 345 as a central shaft; the third fixing frame 328 is rotatably connected with the fifth connecting rod 333; the fifth connecting rod 333 is rotationally connected with the fourth slider 334; the fourth slider 334 is slidably connected with the fourth fixing frame 335; the fourth fixing frame 335 is fixedly connected with the bottom plate assembly 1; the fourth slider 334 is fixedly connected with the seventh supporting frame 346; the seventh support 346 is rotatably connected to the fifth automatic telescopic pen 336; the fourth fixed frame 335 is slidably connected with the second sliding rod 337; the fourth fixing frame 335 is fixedly connected with a fourth spring 338; the second slide bar 337 is fixedly connected with the fourth spring 338; the second slide bar 337 is fixedly connected with the third wedge 339; the side of the third wedge 339 is provided with a fourth wedge 340; the fourth wedge 340 is fixedly connected with the fifth spring 341; the fifth spring 341 is fixedly connected with the bottom plate assembly 1; the fourth wedge 340 is fixedly connected with the second slide 342; the second slide 342 is slidably connected to the base plate assembly 1; the second sliding plate 342 is fixedly connected with the sixth supporting frame 343; the sixth supporting frame 343 is rotatably connected with the sixth automatic telescopic pen 344; the sixth supporting frame 343 is slidably connected with the rubber 345; the second slide bar 337 to the seventh support frame 346 are provided with the same components with the middle section of the rubber 345 as the center axis.

Then, the first conveyor belt 7 conveys the substrate layer with the metal connecting piece to the position right below the second fixing frame 311 and the fourth fixing frame 335, then, all the parts on the first connecting frame 307 move downwards through the first automatic telescopic pen 313 and the second automatic telescopic pen 317 and two groups of third automatic telescopic pens 326, at this time, the motor 301 starts to drive the first transmission shaft 302 to rotate, the first transmission shaft 302 rotates to drive the glue dripping unit to rotate, simultaneously, the first transmission shaft 302 rotates to drive the first straight gear 303 to rotate, the first straight gear 303 rotates to drive the second transmission shaft 305 to rotate, the second transmission shaft 305 rotates to drive the first connecting rod 306 to rotate, and then all the parts on the second connecting frame 327 move upwards through the lever principle, at this time, the first connecting frame 307 moves to drive the second connecting rod 309 to move downwards through the first fixing frame 308, the second connecting rod 309 moves to drive the first sliding block 310 to slide along the second fixing frame 311, and then drive the first automatic telescopic pen 313 on the second supporting frame 312 to move, and then the first automatic telescopic pen 313 moves to drive the first automatic telescopic pen 326 to move, and simultaneously, the first automatic telescopic pen 314 moves to drive the first sliding rod 314 to move, and then the first automatic telescopic pen is driven by the first connecting rod 313 moves to move, and the first automatic telescopic pen is coated with the first connecting rod is coated with the first graphite layer 313, and then, the first automatic telescopic pen is coated on the substrate layer is coated by the first connecting rod is formed, and the first automatic telescopic pen is coated with the first graphite layer is coated by the first automatic telescopic pen 314, and the first automatic telescopic pen is moved by the first connecting rod is moved by the first automatic telescopic pen 314, and then, the first automatic telescopic pen is coated by the first connecting rod is coated with the first graphite, the first graphite is coated with the first graphite. And then the second spring 320 is extruded, and then the first wedge 321 is driven to move, and the first wedge 321 moves to drive the second wedge 322 to move, and then the third spring 323 is stretched, and then the second wedge 322 moves to drive the first slide plate 324 to move, and then the third automatic telescopic pen 326 on the fourth support frame 325 is driven to move, and simultaneously the corresponding third automatic telescopic pen 326 moves reversely, and further coats graphite on the basal layer, so that the graphite coating forms a shape similar to a Z, and then the fourth automatic telescopic pen 332, the fifth automatic telescopic pen 336 and the two groups of sixth automatic telescopic pens 344 coat graphite on the basal layer, the motor 301 starts to drive the first transmission shaft 302 to rotate reversely, and then all parts on the first connection frame 307 move upwards, and all parts on the second connection frame 327 move downwards, the second connecting frame 327 moves downwards to drive all the components on the third fixing frame 328 to move downwards, so as to drive the fourth connecting rod 329 and the fifth connecting rod 333 to move downwards at the same time, so that the fourth connecting rod 329 moves to drive the third sliding block 330 to move along the fourth fixing frame 335, so as to drive the fourth automatic telescopic pen 332 on the fifth supporting frame 331 to move, so as to coat graphite on the basal layer, meanwhile, the third fixing frame 328 moves to drive the fifth connecting rod 333 to move, so as to drive the fourth sliding block 334 to move, so as to drive the fifth automatic telescopic pen 336 on the seventh supporting frame 346 to move, so as to coat graphite on the basal layer, and the fourth sliding block 334 drives the second sliding rod 337 to move, so as to squeeze the fourth spring 338, and the second sliding rod 337 moves to drive the third wedge 339 to move, so as to drive the fourth wedge 340 to stretch the fifth spring 341, further, the fourth wedge 340 moves to drive the second slide plate 342 to move, further drive the sixth automatic telescopic pen 344 on the sixth support frame 343 to move, meanwhile, the sixth support frame 343 moves to drive the rubber 345 to move, further clean redundant graphite, meanwhile, the corresponding sixth automatic telescopic pen 344 moves in the direction to coat graphite on the substrate layer, at this time, the graphite coated by the sixth automatic telescopic pen 344 is connected with the graphite coated by the third automatic telescopic pen 326, the graphite coated by the corresponding sixth automatic telescopic pen 344 and the graphite coated by the third automatic telescopic pen 326 are symmetrically arranged to relatively move away, further, the graphite coating forms a similar pi-shaped form at this time, the substrate layer is driven to continuously move by the first conveyor belt 7, the graphite coating is further coated on the substrate layer with the same work away, the coating unit realizes that one layer of graphite is coated on the substrate layer, the graphite coating forms a similar Z-shaped form, then the graphite coating forms a similar pi-shaped form, and the graphite coating repeatedly operates with the same work principle, and forms the graphite coating in the grid-shaped form.

According to fig. 10-12, the glue dropping unit comprises a first driving wheel 401, a second driving wheel 402, a telescopic rod 403, a third straight gear 404, a second fixing plate 405, a second electric push rod 406, a third transmission shaft 407, a fifth fixing frame 408, a screw rod 409 and a glue dispenser 410; the first transmission shaft 302 is fixedly connected with a first transmission wheel 401; the first driving wheel 401 is in driving connection with the second driving wheel 402 through a belt; the second driving wheel 402 is fixedly connected with the telescopic rod 403; the telescopic rod 403 is rotatably connected with the bottom plate assembly 1; the telescopic rod 403 is fixedly connected with a third straight gear 404; the telescopic rod 403 is rotatably connected with the second fixing plate 405; the second fixing plate 405 is fixedly connected with the second electric push rod 406; the second electric push rod 406 is fixedly connected with the bottom plate assembly 1; the side part of the third straight gear 404 is provided with a third transmission shaft 407; the third transmission shaft 407 is rotatably connected with the fifth fixing frame 408; the fifth fixing frame 408 is fixedly connected with the first conveyor belt 7; the third transmission shaft 407 is fixedly connected with a screw rod 409; the screw rod 409 is rotatably connected with the fifth fixing frame 408; screw 409 is screwed with dispenser 410; the glue dispenser 410 is slidably connected with the fifth fixing frame 408; the first driving wheel 401 to the dispenser 410 are provided with the same components by taking the middle section of the rubber 345 as the central axis.

Then, after the grid-shaped graphite coating is formed on the substrate layer by the coating unit, pouring sealant on the upper surface of the substrate layer by the glue dispenser 410, solidifying to form an upper covering layer, driving the first driving wheel 401 to rotate by the rotation of the first driving shaft 302, driving the second driving wheel 402 to drive the telescopic rod 403 to rotate by the rotation of the first driving wheel 401, driving the third spur gear 404 to rotate by the rotation of the telescopic rod 403, then, starting the second electric push rod 406 to control the telescopic rod 403 to stretch by the second fixing plate 405, further controlling the meshing of the third spur gear 404 and the tooth holes in the third driving shaft 407, when the third spur gear 404 is meshed with the tooth holes in the third driving shaft 407, driving the third driving shaft 407 to rotate by the rotation of the third driving shaft 407, driving the lead screw 409 to rotate, driving the glue dispenser 410 to move along the fifth fixing frame 408, simultaneously starting the operation of the glue dispenser 410, and simultaneously, starting the corresponding glue dispenser 410 to operate, further pouring the pouring sealant on the upper surface of the substrate layer, solidifying to form the upper covering layer.

The first wedge block 321 and the second wedge block 322 which are symmetrically arranged are opposite to the first wedge block 321 and the second wedge block 322.

The first wedge block 321 and the second wedge block 322 which are symmetrically arranged can be made to move in opposite directions to the first wedge block 321 and the second wedge block 322, and further, the graphite moves in opposite directions.

The third wedge 339 and the fourth wedge 340 are symmetrically disposed in opposite directions from the third wedge 339 and the fourth wedge 340.

The third wedge 339 and the fourth wedge 340 which are symmetrically arranged may be made to move in opposite directions to the third wedge 339 and the fourth wedge 340, thereby making the graphite move in opposite directions.

The third transmission shaft 407 is provided with a tooth hole matched with the third spur gear 404.

The third transmission shaft 407 and the third spur gear 404 can be connected and driven, and the on-off can be controlled through the second electric push rod 406.

The second conveyor belt 201 is provided with a chute matching the second wedge plate 205.

The second wedge plate 205 may be caused to slide in the second conveyor belt 201, thereby moving the metal connector onto the substrate layer.

The foregoing is merely exemplary of the present invention and is not intended to limit the present invention. All equivalents and alternatives falling within the spirit of the invention are intended to be included within the scope of the invention. What is not elaborated on the invention belongs to the prior art which is known to the person skilled in the art.

Claims (7)

1. A grid-shaped graphite coating device based on flexible resistance strain sheets of ships comprises a bottom plate assembly (1), a first conveyor belt (7), support legs (8) and a collecting box (10); the bottom plate component (1) is fixedly connected with the first conveyor belt (7); the bottom plate component (1) is fixedly connected with four groups of supporting legs (8); the bottom plate component (1) is contacted with the collecting box (10); the method is characterized in that: the device also comprises a coating unit and a glue dripping unit; the bottom plate component (1) is fixedly connected with the coating unit; the bottom plate component (1) is rotationally connected with the glue dropping unit; the coating unit is fixedly connected with the glue dripping unit; the glue dropping unit is fixedly connected with the first conveyor belt (7); the coating unit coats a layer of graphite on the basal layer to form a grid-shaped graphite coating, and the glue dripping unit drips pouring sealant on the upper surface of the basal layer of the grid-shaped graphite coating formed by the coating unit, and the pouring sealant is solidified to form an upper covering layer;

the coating unit comprises a motor (301), a first transmission shaft (302), a first straight gear (303), a second straight gear (304), a second transmission shaft (305), a first connecting rod (306), a first connecting frame (307), a first fixing frame (308), a second connecting rod (309), a first sliding block (310), a second fixing frame (311), a second supporting frame (312), a first automatic telescopic pen (313), a third connecting rod (314), a second sliding block (315), a third supporting frame (316), a second automatic telescopic pen (317), a first fixing plate (318), a first sliding rod (319), a second spring (320), a first wedge block (321), a second wedge block (322), a third spring (323), a first sliding plate (324), a fourth supporting frame (325), a third automatic telescopic pen (326), a second connecting frame (327), a third fixing frame (328), a fourth connecting rod (329), a third sliding block (330), a fifth supporting frame (331), a fourth automatic telescopic pen (332), a fifth connecting rod (333), a fourth sliding block (334), a fourth automatic telescopic pen (335), a fourth wedge block (337), a fourth wedge block (338), a fourth wedge block (340) and a fourth wedge block (339), A fifth spring (341), a second slide plate (342), a sixth supporting frame (343), a sixth automatic telescopic pen (344), a rubber (345) and a seventh supporting frame (346); the motor (301) is fixedly connected with the bottom plate assembly (1); the motor (301) is fixedly connected with the first transmission shaft (302); the first transmission shaft (302) is rotationally connected with the bottom plate assembly (1); the first transmission shaft (302) is fixedly connected with the glue dropping unit; the first transmission shaft (302) is fixedly connected with the first straight gear (303); the first straight gear (303) is meshed with the second straight gear (304); the second spur gear (304) is fixedly connected with a second transmission shaft (305); the second transmission shaft (305) is rotationally connected with the bottom plate assembly (1); the second transmission shaft (305) is fixedly connected with the first connecting rod (306); the first connecting rod (306) is rotationally connected with the first connecting frame (307); the first connecting frame (307) is fixedly connected with the first fixing frame (308); the first fixing frame (308) is rotationally connected with the second connecting rod (309); the second connecting rod (309) is rotationally connected with the first sliding block (310); the first sliding block (310) is in sliding connection with the second fixing frame (311); the second fixing frame (311) is fixedly connected with the bottom plate assembly (1); the first sliding block (310) is fixedly connected with the second supporting frame (312); the second supporting frame (312) is rotationally connected with the first automatic telescopic pen (313); the first fixing frame (308) is rotationally connected with the third connecting rod (314); the third connecting rod (314) is rotationally connected with the second sliding block (315); the second sliding block (315) is in sliding connection with the second fixing frame (311); the second sliding block (315) is fixedly connected with the third supporting frame (316); the third support frame (316) is fixedly connected with the second automatic telescopic pen (317); the second fixing frame (311) is fixedly connected with the first fixing plate (318); the second fixing frame (311) is in sliding connection with the first sliding rod (319); the second fixing frame (311) is fixedly connected with the second spring (320); the first sliding rod (319) is fixedly connected with the second spring (320); the first sliding rod (319) is fixedly connected with the first wedge block (321); the side part of the first wedge block (321) is provided with a second wedge block (322); the second wedge block (322) is fixedly connected with the third spring (323); the third spring (323) is fixedly connected with the second fixing frame (311); the second wedge block (322) is fixedly connected with the first sliding plate (324); the first sliding plate (324) is in sliding connection with the bottom plate assembly (1); the first sliding plate (324) is fixedly connected with the fourth supporting frame (325); the fourth supporting frame (325) is in sliding connection with the rubber (345); the fourth supporting frame (325) is rotationally connected with the third automatic telescopic pen (326); the first connecting rod (306) is rotationally connected with the second connecting frame (327); the second connecting frame (327) is fixedly connected with the third fixing frame (328); the third fixing frame (328) is rotationally connected with the fourth connecting rod (329); the fourth connecting rod (329) is rotationally connected with the third sliding block (330); the third sliding block (330) is in sliding connection with the fourth fixed frame (335); the third sliding block (330) is fixedly connected with the fifth supporting frame (331); the fifth supporting frame (331) is rotationally connected with the fourth automatic telescopic pen (332); the first fixing plate (318) to the third automatic telescopic pen (326) are provided with the same components by taking the middle section of the rubber (345) as a central shaft; the third fixing frame (328) is rotationally connected with the fifth connecting rod (333); the fifth connecting rod (333) is rotationally connected with the fourth sliding block (334); the fourth sliding block (334) is in sliding connection with the fourth fixing frame (335); the fourth fixing frame (335) is fixedly connected with the bottom plate assembly (1); the fourth sliding block (334) is fixedly connected with the seventh supporting frame (346); the seventh supporting frame (346) is rotationally connected with the fifth automatic telescopic pen (336); the fourth fixing frame (335) is in sliding connection with the second sliding rod (337); the fourth fixing frame (335) is fixedly connected with a fourth spring (338); the second sliding rod (337) is fixedly connected with the fourth spring (338); the second slide bar (337) is fixedly connected with the third wedge block (339); the side part of the third wedge block (339) is provided with a fourth wedge block (340); the fourth wedge block (340) is fixedly connected with the fifth spring (341); the fifth spring (341) is fixedly connected with the bottom plate assembly (1); the fourth wedge block (340) is fixedly connected with the second sliding plate (342); the second sliding plate (342) is in sliding connection with the bottom plate assembly (1); the second sliding plate (342) is fixedly connected with the sixth supporting frame (343); the sixth supporting frame (343) is rotationally connected with the sixth automatic telescopic pen (344); the sixth supporting frame (343) is in sliding connection with the rubber (345); the second slide bar (337) to the seventh support frame (346) are provided with the same parts by taking the middle section of the rubber (345) as the center axis.

2. The grid-like graphite coating equipment based on ship flexible resistance strain gauge according to claim 1, wherein the equipment comprises: the glue dropping unit comprises a first driving wheel (401), a second driving wheel (402), a telescopic rod (403), a third spur gear (404), a second fixing plate (405), a second electric push rod (406), a third transmission shaft (407), a fifth fixing frame (408), a screw rod (409) and a glue dispenser (410); the first transmission shaft (302) is fixedly connected with the first transmission wheel (401); the first driving wheel (401) is in driving connection with the second driving wheel (402) through a belt; the second driving wheel (402) is fixedly connected with the telescopic rod (403); the telescopic rod (403) is rotationally connected with the bottom plate assembly (1); the telescopic rod (403) is fixedly connected with a third straight gear (404); the telescopic rod (403) is rotationally connected with the second fixed plate (405); the second fixing plate (405) is fixedly connected with the second electric push rod (406); the second electric push rod (406) is fixedly connected with the bottom plate assembly (1); a third transmission shaft (407) is arranged at the side part of the third straight gear (404); the third transmission shaft (407) is rotationally connected with the fifth fixing frame (408); the fifth fixing frame (408) is fixedly connected with the first conveyor belt (7); the third transmission shaft (407) is fixedly connected with a screw rod (409); the screw rod (409) is rotationally connected with the fifth fixing frame (408); the screw rod (409) is screwed with the glue dispenser (410); the dispensing machine (410) is in sliding connection with the fifth fixing frame (408); the first driving wheel (401) to the dispenser (410) is provided with the same components by taking the middle section of the rubber (345) as the center axis.

3. A ship-based flexible resistance strain gage grating graphite coating apparatus according to any one of claims 1 to 2, characterized in that: the device also comprises a conveying unit, wherein the conveying unit comprises a second conveying belt (201), a first supporting frame (202), a first electric push rod (203), a first wedge-shaped plate (204), a second wedge-shaped plate (205) and a first spring (206); the second conveyor belt (201) is fixedly connected with the bottom plate assembly (1); the second conveyor belt (201) is fixedly connected with the first supporting frame (202); the first supporting frame (202) is fixedly connected with the first electric push rod (203); the first electric push rod (203) is fixedly connected with the first wedge-shaped plate (204); the second conveyor belt (201) is in sliding connection with the second wedge plate (205); the second wedge plate (205) is fixedly connected with the first spring (206); the first spring (206) is fixedly connected with the second conveyor belt (201).

4. The grid-shaped graphite coating equipment based on ship flexible resistance strain gages according to claim 1, wherein the first wedge block (321) and the second wedge block (322) which are symmetrically arranged are opposite to the first wedge block (321) and the second wedge block (322).

5. The grid-like graphite coating apparatus based on flexible resistance strain gages of a ship according to claim 1, wherein the third wedge (339) and the fourth wedge (340) are symmetrically arranged in opposite directions to the third wedge (339) and the fourth wedge (340).

6. A grid-like graphite coating apparatus based on flexible resistance strain foils for ships according to claim 2, characterized in that the third transmission shaft (407) is provided with perforations matching the third spur gear (404).

7. A grid-like coating graphite apparatus based on flexible resistance strain foils for ships as claimed in claim 3, characterized in that a chute is provided in the second conveyor belt (201) matching the second wedge plate (205).