CN116476986A - Equipment capable of improving stability of marine disaster monitoring instrument - Google Patents

Abstract

The invention belongs to the technical field of marine disaster monitoring, in particular to equipment capable of improving the stability of a marine disaster monitoring instrument, aiming at the problem that the monitoring equipment is impacted by fishes due to long-time independent operation of the monitoring equipment, so that the stability of the monitoring equipment is low, meanwhile, accumulated sundries exist on the sea surface part, and the normal of the monitoring equipment is easily influenced. The equipment capable of improving the stability of the marine disaster monitoring instrument disclosed by the invention has the advantage of improving the stable use of the monitoring equipment in independent operation on the sea surface.

Description

Equipment capable of improving stability of marine disaster monitoring instrument

Technical Field

The invention relates to the technical field of marine disaster monitoring, in particular to equipment capable of improving stability of a marine disaster monitoring instrument.

Background

Marine disasters are disasters that occur on the sea or coast due to abnormal or drastic changes in the natural environment of the sea. The ocean disasters mainly comprise disastrous ocean waves, sea ice, red tides, tsunamis and storm tides; the disastrous phenomena related to the ocean and the atmosphere are also the 'el nino phenomenon and the lanina phenomenon', typhoons and the like. There are more storms on the ocean, and there are more storms, and can cause natural disasters when the wind speed is higher, wash out higher seawave with the sea, the seawave strikes the building, cause the building to damage and lift the sea vessel etc. therefore monitor the ocean in advance, so that can effectively take precautions when there are great storms on the ocean.

In the use process of the existing marine disaster monitoring equipment, the existing marine disaster monitoring equipment works alone for a long time to cause the fish to strike the monitoring equipment, so that the stability of the monitoring equipment is low, meanwhile, accumulated sundries exist in the sea surface part, and the normal use of the monitoring equipment is easily affected.

Disclosure of Invention

The invention discloses equipment capable of improving stability of marine disaster monitoring instruments, and aims to solve the technical problems that monitoring equipment in the background art is independently operated for a long time, so that fishes strike the monitoring equipment, the stability of the monitoring equipment is low, accumulated sundries exist in a sea surface part, and normal use of the monitoring equipment is easily affected.

The invention provides equipment capable of improving stability of marine disaster monitoring instruments, which comprises a floating platform, wherein a driving assembly is arranged at the bottom of the floating platform and comprises a hollow floating plate, a partition plate is fixedly connected to one side of the hollow floating plate, mounting holes I are formed in one side of the partition plate and one side of the hollow floating plate, the interiors of the two mounting holes I are connected with a same main rotating shaft through bearings, a reciprocating rotating gear is fixedly connected to the outside of the main rotating shaft, a mounting hole II is formed in one side of the partition plate, a rotating shaft is connected to the interior of the mounting hole II through bearings, a T-shaped toothed plate is fixedly connected to the outside of the rotating shaft, a mounting groove is formed in one side of the T-shaped toothed plate, a roller is connected to the interior of the mounting groove in a sliding manner, one side of the partition plate is fixedly connected with a mounting seat, one side of the mounting seat is fixedly connected with a driving motor, a driving end of the driving motor is connected with a rotating rod through a coupler, one side of the rotating rod and one side of the roller is provided with a mounting hole III, the interiors of the two mounting holes III are connected with the same rotating shaft through bearings, the outside of the main rotating shaft is fixedly connected with a mounting frame, one side of the rotating shaft is fixedly connected with a guide plate, one side of a guide plate is connected with a cutting guide plate, and the guide plate is fixedly connected to one side of a cutting round rail is connected to the opposite side of a cutting round rail, and is connected to the round frame.

Through being provided with and driving the subassembly, when monitoring facilities is in sea alone operation, at this moment through starting driving motor, drive the rotary rod through driving motor and rotate, gyro wheel on the rotary rod drives the reciprocal horizontal migration of T type pinion rack, drive reciprocal rotatory gear drive main pivot reciprocal rotation through T type pinion rack, thereby make main pivot drive the installation circle frame drive the reciprocal rotatory removal of silk ribbon, thereby drive the shoal of fish to monitoring facilities bottom, avoid monitoring facilities in the use, the shoal attacks monitoring facilities, the installation circle frame is at reciprocal rotation in-process simultaneously, drive the cutting piece through branch and reciprocate in the guide rail, thereby pile up debris and cut on the sea, thereby promote the steady use of this monitoring facilities in sea alone operation through driving the subassembly.

In a preferred scheme, a support is fixedly connected to one side of the floating platform at equal intervals, and an energy-saving adjusting assembly is arranged on one side of the support and comprises a mounting platform.

In a preferred scheme, one side of the mounting platform is fixedly connected with a limiting seat, one side of the limiting seat is provided with a mounting hole IV, the inside of the mounting hole IV is connected with a circular tube through a bearing, the outside of the circular tube is fixedly connected with a toothed plate II, one side of the mounting platform is fixedly connected with a screw motor I, and the screw motor I is meshed with the toothed plate II.

In a preferred scheme, the inside of pipe is connected with the axis of rotation through the bearing, and the outside fixedly connected with pinion rack one of axis of rotation, and one side fixedly connected with lead screw motor two of mounting platform, lead screw motor two meshes with pinion rack one.

In a preferred scheme, the outside fixedly connected with fixed block of pipe, and the mounting hole five has all been seted up to the both sides of fixed block, and the inside of two relative mounting holes five is connected with same rotatory round bar through the bearing, and the outside fixedly connected with conical gear one of rotatory round bar.

In a preferred scheme, the outside fixedly connected with installation head of rotatory pole, and the one side fixedly connected with universal board of installation head, one side fixedly connected with solar panel of universal board, the outside fixedly connected with conical gear two of axis of rotation, conical gear two meshes with conical gear one, and one side fixedly connected with collection can of mounting platform.

Through being provided with energy-conserving adjusting part, monitoring facilities is when sea alone operation, collect the electric energy through the solar energy electroplax that sets up, thereby guarantee this monitoring facilities normal use, simultaneously can drive pinion rack two through starting lead screw motor, thereby make pinion rack two drive the pipe rotatory, make the pipe drive fixed block rotatory, simultaneously can drive pinion rack one through starting lead screw motor two and rotate, make pinion rack one drive the axis of rotation rotatory, thereby make the axis of rotation drive bevel gear two rotate, bevel gear two drive bevel gear one rotate and make the rotatory round bar of drive rotatory, through adjusting the orientation of the solar energy electroplax on the universal board, thereby make solar energy electroplax face the sun direction all the time, thereby promote the effect of collecting the electric energy.

In a preferred embodiment, a balance assembly is provided on one side of the floating platform, and the balance assembly includes a chute.

In a preferred scheme, two balance weights are connected in a sliding mode in the sliding groove, a mounting hole six is formed in one side of one balance weight, and a rotating shaft II is connected in the mounting hole six through a bearing.

In a preferred scheme, the outside fixedly connected with of pivot two adjusts the pole, and one side fixedly connected with servo motor of floating platform, servo motor's drive end passes through the coupling joint and adjusts one side of pole.

Through being provided with balance assembly, this monitoring facilities is in alone operation, when the unrestrained to the floating platform that strikes, can drive the regulation pole through starting servo motor and rotate for adjust the pole and drive the balancing piece and remove to the striking end in the spout, thereby aggravate the weight that the floating platform suffered the striking end, thereby guarantee the stability of this monitoring facilities.

In a preferred scheme, one side of a plurality of the supports is fixedly connected with the same fixed platform, and one side of the fixed platform is respectively fixedly connected with a wind vane and a remote transmission control box.

Therefore, the equipment capable of improving the stability of the marine disaster monitoring instrument has the beneficial effect of improving the stable use of the monitoring equipment in independent operation on the sea surface.

Drawings

FIG. 1 is a schematic diagram of the main structure of a device for improving the stability of a marine disaster monitoring instrument according to the present invention;

FIG. 2 is a schematic side view of a device for improving stability of a marine disaster monitoring apparatus according to the present invention;

FIG. 3 is a schematic diagram of a driving assembly of a device for improving stability of a marine disaster monitoring apparatus according to the present invention;

FIG. 4 is a schematic diagram of a driving assembly of a device for improving stability of a marine disaster monitoring apparatus according to the present invention;

FIG. 5 is a schematic diagram of an energy-saving adjusting assembly of a device for improving stability of a marine disaster monitoring apparatus according to the present invention;

FIG. 6 is a schematic diagram of a part of an energy-saving adjusting assembly of a device for improving the stability of a marine disaster monitoring instrument according to the present invention;

fig. 7 is a schematic diagram of a balance component structure of a device for improving stability of a marine disaster monitoring apparatus according to the present invention.

In the figure: 1. a floating platform; 2. a bracket; 3. a fixed platform; 4. a wind vane; 5. a remote transmission control box; 6. a driving assembly; 601. a hollow floating plate; 602. a guide rail; 603. cutting the sheet; 604. a support rod; 605. installing a round frame; 606. driving the silk ribbon; 607. a main rotating shaft; 608. a mounting base; 609. a partition plate; 610. a rotation shaft; 611. t-shaped toothed plates; 612. a driving motor; 613. a rotating rod; 614. a roller; 615. a first rotating shaft; 616. a reciprocating rotary gear; 7. an energy-saving adjusting component; 701. a mounting platform; 702. a limit seat; 703. an energy collection box; 704. a screw motor I; 705. a screw motor II; 706. a solar panel; 707. a universal plate; 708. a round tube; 709. a rotating shaft; 710. a toothed plate I; 711. a toothed plate II; 712. a fixed block; 713. rotating the round rod; 714. a first conical gear; 715. a second bevel gear; 716. a mounting head; 8. a balancing assembly; 801. a chute; 802. a balance weight; 803. a servo motor; 804. an adjusting rod; 805. and a second rotating shaft.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

The equipment capable of improving the stability of the marine disaster monitoring instrument disclosed by the invention is mainly applied to long-time independent operation of the monitoring equipment, so that fishes strike the monitoring equipment, the stability of the monitoring equipment is low, meanwhile, accumulated sundries exist in the sea surface part, and the normal use scene of the monitoring equipment is easily influenced.

Referring to fig. 1, fig. 2, fig. 3 and fig. 4, a device capable of improving stability of marine disaster monitoring instruments, including floating platform 1, the bottom of floating platform 1 is provided with drives subassembly 6, and drive subassembly 6 includes cavity floating plate 601, the inside fixedly connected with division board 609 of cavity floating plate 601, and division board 609 has all offered mounting hole one with one side of cavity floating plate 601, and the inside of two mounting holes one is connected with same main pivot 607 through the bearing, and the outside fixedly connected with reciprocating rotary gear 616 of main pivot 607, mounting hole two has been offered to one side of division board 609, and the inside of mounting hole two is connected with rotation axis 610 through the bearing, and the outside fixedly connected with T type pinion rack 611, and the mounting groove has been offered to one side of T type pinion rack 611, and the inside sliding connection of mounting groove has gyro wheel 614, one side fixedly connected with mount pad 608 of division board 609, and one side fixedly connected with driving motor 612, and one side of driving motor 612 has 613 through the coupling connection, and the rotary rod has all offered mounting hole three with one side of gyro wheel 607, and two inside is connected with rotation axis 605 through bearing mounting hole 605, and one side of guide frame 605 is connected with track 602, equal distance to one side of cut round support frame 602 is fixed with track 602, equal distance to one side of cut round support frame is fixed.

Specifically, the main rotating shaft 607 drives the installation circular frame 605 to drive the driving ribbon 606 to reciprocate, so that the shoal of fish at the bottom of the monitoring equipment is driven, the shoal of fish is prevented from attacking the monitoring equipment in the use process of the monitoring equipment, and meanwhile, the installation circular frame 605 drives the cutting blade 603 to reciprocate in the guide track 602 through the supporting rod 604 in the reciprocating rotation process, so that sundries accumulated on the sea surface are cut.

In a specific application scenario, when the monitoring device independently works on the sea surface, at this time, the driving motor 612 is started, the driving motor 612 drives the rotary rod 613 to rotate, the roller 614 on the rotary rod 613 drives the T-shaped toothed plate 611 to reciprocate horizontally, the T-shaped toothed plate 611 drives the reciprocating rotary gear 616 to drive the main rotary shaft 607 to reciprocate, so that the main rotary shaft 607 drives the mounting circular frame 605 to drive the driving ribbon 606 to reciprocate, the fish shoals at the bottom of the monitoring device are driven, the monitoring device is prevented from being attacked by the fish shoals in the using process, meanwhile, the mounting circular frame 605 drives the cutting blade 603 to reciprocate in the guide rail 602 through the supporting rod 604 in the reciprocating rotation process, and accordingly sundries accumulated on the sea surface are cut, and stable use of the monitoring device in the independent sea surface operation is promoted through the driving assembly 6.

The T-shaped toothed plate 611 is meshed with the reciprocating rotary gear 616, and the cutting blade 603 is slidably connected to the inside of the guide rail 602, so that the mounting circular frame 605 and the cutting blade 603 move simultaneously through the supporting rod 604.

Referring to fig. 1 and 5, a bracket 2 is fixedly connected to one side of a floating platform 1 at equal distance, and an energy-saving adjusting assembly 7 is provided to one side of the bracket 2, and the energy-saving adjusting assembly 7 includes a mounting platform 701.

Referring to fig. 5 and 6, a limit seat 702 is fixedly connected to one side of the mounting platform 701, a mounting hole four is formed in one side of the limit seat 702, a circular tube 708 is connected to the inside of the mounting hole four through a bearing, a toothed plate two 711 is fixedly connected to the outside of the circular tube 708, a screw motor one 704 is fixedly connected to one side of the mounting platform 701, and the screw motor one 704 is meshed with the toothed plate two 711.

Referring to fig. 5 and 6, a rotating shaft 709 is connected to the inside of the circular tube 708 through a bearing, a toothed plate one 710 is fixedly connected to the outside of the rotating shaft 709, a screw motor two 705 is fixedly connected to one side of the mounting platform 701, and the screw motor two 705 is meshed with the toothed plate one 710.

Referring to fig. 5 and 6, a fixing block 712 is fixedly connected to the outside of the circular tube 708, mounting holes five are formed on both sides of the fixing block 712, the same rotary round rod 713 is connected to the inside of the two opposite mounting holes five through bearings, and a first bevel gear 714 is fixedly connected to the outside of the rotary round rod 713.

Referring to fig. 5 and 6, the outer part of the rotary round bar 713 is fixedly connected with a mounting head 716, one side of the mounting head 716 is fixedly connected with a universal plate 707, one side of the universal plate 707 is fixedly connected with a solar electric plate 706, the outer part of the rotary shaft 709 is fixedly connected with a second conical gear 715, the second conical gear 715 is meshed with the first conical gear 714, and one side of the mounting platform 701 is fixedly connected with an energy collecting box 703.

Specifically, the screw motor two 705 drives the toothed plate one 710 to rotate, so that the toothed plate one 710 drives the rotation shaft 709 to rotate, so that the rotation shaft 709 drives the bevel gear two 715 to rotate, and the bevel gear two 715 drives the bevel gear one 714 to rotate, so as to drive the rotary round bar 713 to rotate.

In a specific application scenario, when the monitoring device works alone on the sea surface, electric energy is collected through the solar electric plate 706, so that normal use of the monitoring device is guaranteed, meanwhile, the first lead screw motor 704 can be started to drive the second toothed plate 711 to rotate, the second toothed plate 711 can drive the round tube 708 to rotate, the round tube 708 can drive the fixed block 712 to rotate, meanwhile, the second lead screw motor 705 can be started to drive the first toothed plate 710 to rotate, the first toothed plate 710 can drive the rotating shaft 709 to rotate, the rotating shaft 709 can drive the second bevel gear 715 to rotate, the second bevel gear 715 can drive the first bevel gear 714 to rotate, the rotating round rod 713 is driven to rotate, and the direction of the solar electric plate 706 on the universal plate 707 is regulated, so that the solar electric plate 706 always faces the sun direction, and the effect of collecting electric energy is improved.

It should be noted that, the screw motor two 705 is meshed with the toothed plate one 710, the screw motor one 704 is meshed with the toothed plate two 711, and the bevel gear one 714 is meshed with the bevel gear two 715.

Referring to fig. 1 and 7, one side of the floating platform 1 is provided with a balance assembly 8, and the balance assembly 8 includes a chute 801.

Referring to fig. 7, two weights 802 are slidably connected to the inside of the sliding groove 801, and a mounting hole six is formed on one side of one of the weights 802, and a rotation shaft two 805 is connected to the inside of the mounting hole six through a bearing.

Referring to fig. 1 and 7, an adjusting rod 804 is fixedly connected to the outside of the second rotary shaft 805, a servo motor 803 is fixedly connected to one side of the floating platform 1, and the driving end of the servo motor 803 is connected to one side of the adjusting rod 804 through a coupling.

Specifically, the servo motor 803 drives the adjusting lever 804 to rotate, so that the adjusting lever 804 drives the balance block 802 to move to the impact end in the chute 801.

In a specific application scenario, when the monitoring equipment is operated alone and the wind and waves strike the floating platform 1, the servo motor 803 can be started to drive the adjusting rod 804 to rotate through the servo motor 803, so that the adjusting rod 804 drives the balance block 802 to move to the striking end in the sliding groove 801, the weight of the striking end suffered by the floating platform 1 is increased, and the stability of the monitoring equipment is ensured.

It should be noted that, the balance weight 802 is slidably connected to the sliding groove 801 on the floating platform 1, and one of the balance weight 802 is controlled by the adjusting rod 804.

Referring to fig. 1 and 2, one side of the plurality of brackets 2 is fixedly connected with the same fixed platform 3, and one side of the fixed platform 3 is respectively and fixedly connected with a wind vane 4 and a remote transmission control box 5.

Working principle: when in use, when the monitoring equipment solely works on the sea surface, wind speed is monitored through the wind vane, meanwhile, the monitoring data is transmitted through the remote transmission control box 5, meanwhile, the driving motor 612 is started, the driving motor 612 drives the rotary rod 613 to rotate, the roller 614 on the rotary rod 613 drives the T-shaped toothed plate 611 to reciprocate horizontally, the T-shaped toothed plate 611 drives the reciprocating rotary gear 616 to drive the main rotary shaft 607 to reciprocate, so that the main rotary shaft 607 drives the mounting circular frame 605 to drive the driving ribbon 606 to reciprocate, thereby driving the fish shoal at the bottom of the monitoring equipment, avoiding the monitoring equipment from attacking the monitoring equipment in the use process, simultaneously, the mounting circular frame 605 drives the cutting blade 603 to reciprocate in the guide track 602 through the supporting rod 604 to cut sundries accumulated on the sea surface, the stable use of the monitoring equipment in independent operation on the sea surface is promoted by the driving component 6, the electric energy is collected by the arranged solar electric plate 706, so that the normal use of the monitoring equipment is ensured, meanwhile, the toothed plate II 711 can be driven to rotate by starting the screw motor I704, so that the toothed plate II 711 drives the round tube 708 to rotate, the round tube 708 drives the fixed block 712 to rotate, meanwhile, the toothed plate I710 can be driven to rotate by starting the screw motor II 705, the toothed plate I710 drives the rotating shaft 709 to drive the rotating shaft 709 to rotate, the conical gear II 715 drives the conical gear I714 to rotate, the rotating round rod 713 is driven to rotate, the solar electric plate 706 always faces the sun direction by adjusting the orientation of the solar electric plate 706 on the universal plate 707, so that the effect of collecting the electric energy is promoted, when wind and waves strike the floating platform 1, the adjusting rod 804 can be driven to rotate by starting the servo motor 803, and the adjusting rod 804 can drive the balance block 802 to move to the impact end in the sliding groove 801 by the servo motor 803, so that the weight of the impact end suffered by the floating platform 1 is increased, and the stability of the monitoring equipment is ensured.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims (10)

1. The equipment capable of improving stability of marine disaster monitoring instruments comprises a floating platform (1), and is characterized in that a driving component (6) is arranged at the bottom of the floating platform (1), the driving component (6) comprises a hollow floating plate (601), a partition plate (609) is fixedly connected to one side of the hollow floating plate (601), one side of the partition plate (609) is provided with a first mounting hole, one main rotating shaft (607) is connected to the inside of the first mounting hole through a bearing, the outside of the main rotating shaft (607) is fixedly connected with a reciprocating rotating gear (616), one side of the partition plate (609) is provided with a second mounting hole, the inside of the second mounting hole is connected with a rotating shaft (610) through a bearing, the outside of the rotating shaft (610) is fixedly connected with a T-shaped toothed plate (611), one side of the T-shaped toothed plate (611) is provided with a mounting groove, one side of the partition plate (609) is fixedly connected with a mounting seat (608), one side of the partition plate (609) is fixedly connected with a motor (612), one side of the mounting seat (608) is fixedly connected with a motor (612), one side of the motor (612) is connected with a third rotating shaft (613) through a bearing, one side of the driving end (613) is connected with the third rotating shaft (614), the outside fixedly connected with installation circle frame (605) of main pivot (607), and one side equidistance fixedly connected with of installation circle frame (605) drives ribbon (606), the outside fixedly connected with guide rail (602) of floating platform (1), and the inside sliding connection of guide rail (602) has cutting piece (603), and cutting piece (603) and the relative one side equidistance fixedly connected with branch (604) of installation circle frame (605).

2. The device for improving stability of marine disaster monitoring instrument according to claim 1, wherein a support (2) is fixedly connected to one side of the floating platform (1) at equal distance, and an energy-saving adjusting assembly (7) is arranged on one side of the support (2), and the energy-saving adjusting assembly (7) comprises a mounting platform (701).

3. The device capable of improving stability of marine disaster monitoring instruments according to claim 2, wherein one side of the mounting platform (701) is fixedly connected with a limiting seat (702), one side of the limiting seat (702) is provided with a mounting hole four, the inside of the mounting hole four is connected with a circular tube (708) through a bearing, the outside of the circular tube (708) is fixedly connected with a toothed plate two (711), one side of the mounting platform (701) is fixedly connected with a screw motor one (704), and the screw motor one (704) is meshed with the toothed plate two (711).

4. The device for improving stability of marine disaster monitoring instrument according to claim 3, wherein the inside of the circular tube (708) is connected with a rotating shaft (709) through a bearing, the outside of the rotating shaft (709) is fixedly connected with a toothed plate I (710), one side of the mounting platform (701) is fixedly connected with a screw motor II (705), and the screw motor II (705) is meshed with the toothed plate I (710).

5. The device for improving stability of marine disaster monitoring equipment according to claim 4, wherein the outer part of the circular tube (708) is fixedly connected with a fixed block (712), mounting holes five are formed in two sides of the fixed block (712), the inner parts of the two opposite mounting holes five are connected with the same rotary round rod (713) through bearings, and a conical gear one (714) is fixedly connected with the outer part of the rotary round rod (713).

6. The device for improving stability of marine disaster monitoring equipment according to claim 5, wherein the outer part of the rotary round rod (713) is fixedly connected with a mounting head (716), one side of the mounting head (716) is fixedly connected with a universal plate (707), one side of the universal plate (707) is fixedly connected with a solar electric plate (706), the outer part of the rotary shaft (709) is fixedly connected with a bevel gear II (715), the bevel gear II (715) is meshed with the bevel gear I (714), and one side of the mounting platform (701) is fixedly connected with an energy collecting box (703).

7. The device for improving the stability of marine disaster monitoring equipment according to claim 6, wherein a balance assembly (8) is arranged on one side of the floating platform (1), and the balance assembly (8) comprises a chute (801).

8. The device for improving stability of a marine disaster monitoring instrument according to claim 7, wherein two balance blocks (802) are slidably connected in the chute (801), one side of one balance block (802) is provided with a mounting hole six, and a rotating shaft two (805) is connected in the mounting hole six through a bearing.

9. The device for improving stability of marine disaster monitoring instrument according to claim 8, wherein an adjusting rod (804) is fixedly connected to the outside of the second rotating shaft (805), a servo motor (803) is fixedly connected to one side of the floating platform (1), and a driving end of the servo motor (803) is connected to one side of the adjusting rod (804) through a coupling.

10. The device for improving the stability of marine disaster monitoring instruments according to claim 9, wherein one side of the plurality of brackets (2) is fixedly connected with the same fixed platform (3), and one side of the fixed platform (3) is respectively and fixedly connected with a wind vane (4) and a remote transmission control box (5).