CN110525611B

CN110525611B - Dive equipment of floating fast

Info

Publication number: CN110525611B
Application number: CN201910928971.5A
Authority: CN
Inventors: 楼碧云
Original assignee: Ruian Blue Whale Diving Equipment Co Ltd
Current assignee: Ruian Blue Whale diving equipment Co., Ltd
Priority date: 2019-09-28
Filing date: 2019-09-28
Publication date: 2020-06-05
Anticipated expiration: 2039-09-28
Also published as: JP6811925B1; JP2021054386A; CN110525611A

Abstract

A dive equipment that floats fast, includes the fuselage, the fuselage includes the power chamber, the power chamber is interior to contain the power unit that provides operating power for equipment, the fixed motor that is equipped with of power intracavity top end wall, the fixed first pivot that is equipped with of motor top end face, the fixed blade that is equipped with in the first pivot, the fixed second pivot that is equipped with of motor bottom end face, the fixed first spout that is equipped with in power chamber, the equipment of the invention will produce a large amount of oxygen and water through the mixture of hydrogen peroxide and manganese dioxide, can provide urgent help to the user under emergency, and a large amount of gas can inflate the gasbag in the equipment simultaneously and make its inflation, bring equipment to the surface of water fast under gasbag and helical blade dual function, and the equipment is inside to have the storing chamber and can carry counter weight or monitoring instrument, and make abundant response sensitive, has higher integration degree, meanwhile, the operation is simple, and the process is safe and quick.

Description

Dive equipment of floating fast

Technical Field

The invention relates to the field of submersibles, in particular to a diving rapid floating device.

Background

Under the condition that the human beings progressively explore to the ocean, suitable exploration equipment has greatly made things convenient for the human demand of gathering or playing to dive, but the ocean is an unknown field, has all threatened to seeker's safety moment, can float fast when taking place the accident in order to guarantee the user, or can float fast when accomplishing to seabed transportation detector, can make equipment float fast according to the buoyancy of sea water, consequently need design a dive and float equipment fast and solve above-mentioned problem.

Disclosure of Invention

The invention aims to provide a diving rapid floating device, which is a high-efficiency integrated device capable of rapidly floating the device out of the water surface by utilizing the buoyancy of seawater, and has sensitive response and rich functions.

The invention is realized by the following technical scheme.

A diving rapid floating device comprises a machine body, wherein the machine body comprises a power cavity;

the power cavity is internally provided with a power mechanism for providing working power for equipment, a motor is fixedly arranged on the top end wall in the power cavity, a first rotating shaft is fixedly arranged on the top end face of the motor, blades are fixedly arranged on the first rotating shaft, a second rotating shaft is fixedly arranged on the bottom end face of the motor, a first sliding groove is fixedly arranged in the power cavity, a first sliding block is arranged in the first sliding groove in a sliding manner, an external connection block is arranged between the top end wall of the first sliding groove and the motor, and a first open slot is fixedly arranged in the external connection block;

a reaction cavity is arranged in the bottom end wall of the power cavity, a reaction mechanism for generating gas is arranged in the reaction cavity, isolation blocks are fixedly arranged at the left end and the right end of the reaction cavity, a second sliding groove is fixedly arranged on the inner side of each isolation block, a second sliding block is slidably arranged in each second sliding groove, a manganese dioxide block in contact with the end face of the inner side of each second sliding block is slidably arranged on the inner side of each second sliding groove, and isolation sheets for preventing the manganese dioxide block from entering the reaction cavity are fixedly arranged on the inner sides of the manganese dioxide blocks;

the reaction chamber bottom end wall is fixedly provided with a storage chamber, the storage chamber is internally provided with a storage mechanism for carrying and releasing a balance weight, the storage chamber left and right end wall bottom ends are fixedly provided with supporting blocks, a third rotating shaft is arranged in the supporting blocks in a rotating mode, and a matching plate capable of blocking the storage chamber is fixedly arranged on the third rotating shaft.

Further, the power mechanism comprises the power cavity, the motor is fixedly arranged on the top end wall in the power cavity, the first rotating shaft is fixedly arranged on the top end face of the motor, the blades are fixedly arranged on the first rotating shaft, the second rotating shaft is fixedly arranged on the bottom end face of the motor, a third sliding groove is fixedly arranged on the bottom end wall of the second rotating shaft, and an electromagnet is fixedly arranged at the top end of the third sliding groove.

Further, rotate on the power cavity bottom end wall and be equipped with the fourth pivot that extends from top to bottom, the fixed fourth spout that is equipped with in the fourth pivot, it is equipped with first connecting rod to slide in the fourth spout, first connecting rod can slide in the third spout, first connecting rod with connect between the fourth spout bottom end face and be equipped with first spring, be located the power cavity the fixed reel that is equipped with in the fourth pivot.

Further, the power intracavity is fixed to be equipped with first spout, it is equipped with to slide in the first spout first slider, first spout top wall with be equipped with between the motor the external piece, external piece internal fixation is equipped with first open slot, first open slot internal rotation is equipped with the fifth pivot, the fixed reversing wheel that is equipped with in the fifth pivot, first slider with the reel connect between the reversing wheel and be equipped with first line.

Further, the reaction mechanism comprises the reaction cavity, isolation blocks are fixedly arranged at the left end and the right end of the reaction cavity, the inner side of each isolation block is fixedly provided with the second sliding groove, the second sliding block is arranged in the second sliding groove in a sliding mode, a second spring is connected between the second sliding block and the outer end face of the second sliding groove, and the inner side of the second sliding groove is slidably provided with the manganese dioxide block in contact with the inner side end face of the second sliding block.

Further, the fixed being equipped with of manganese dioxide piece inboard blocks the manganese dioxide piece gets into the reaction chamber isolated piece, the fixed fifth spout that is equipped with in isolated piece outside, the fifth spout with the intercommunication is equipped with hydraulic pipeline between the second spout, it is equipped with the third slider to slide in the fifth spout, the third slider with connect between the terminal surface in the fifth spout and be equipped with the third spring, be equipped with hydrogen peroxide solution in the reaction chamber, be located in the reaction chamber the fixed stirring piece that is equipped with in the fourth pivot, be located in the fourth pivot the fixed through-hole that is equipped with of stirring piece upside, fourth pivot bottom end wall with the through-hole connection is equipped with the second open slot.

Further, the storage mechanism comprises the storage cavity, the bottom ends of the left end wall and the right end wall of the storage cavity are fixedly provided with the supporting blocks, the third rotating shaft is arranged in the supporting blocks in a rotating mode, and the matching plate capable of blocking the storage cavity is fixedly arranged on the third rotating shaft.

Further, end wall bottom mounting is equipped with the slide rail about the storing chamber, the slide rail bottom mounting is equipped with the stopper, in the slide rail with cooperation board fixed connection is equipped with the arc pole, the fixed cooperation piece that is equipped with in arc pole top, the slide rail outside is fixed to be equipped with walks the line hole, cooperation piece with be located between the first slider walk the fixed second line that is equipped with of line hole.

Further, the storing intracavity is equipped with the balancing weight, storing chamber top end wall internal fixation is equipped with compressed air bag, the fixed piece that draws that is equipped with of compressed air bag bottom face, draw the piece with it is equipped with the third line to connect between the balancing weight, the compressed air bag internal fixation is equipped with the inflation block, be equipped with the inflation chamber in the inflation block, the inflation block top with the inflation chamber intercommunication is equipped with gas line, gas line stretches into in the second open slot and blocks up the through-hole.

The invention has the beneficial effects that: the equipment of the invention generates a large amount of oxygen and water by mixing hydrogen peroxide and manganese dioxide, can provide emergency help for users in emergency, meanwhile, a large amount of gas can inflate the air bag in the equipment to expand the air bag, and the equipment is quickly brought to the water surface under the dual actions of the air bag and the helical blade, and the storage cavity arranged in the equipment can carry a balance weight or a monitoring instrument, so that the equipment has rich response and high integration degree, and is simple to operate, safe and quick in process.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a mechanical schematic of an embodiment of the present invention;

FIG. 2 is an enlarged schematic view of A in FIG. 1;

FIG. 3 is an enlarged schematic view of B of FIG. 1;

fig. 4 is an enlarged schematic view of C in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-4, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The diving rapid floating device described in conjunction with fig. 1-4 comprises a device body 10, wherein the device body 10 includes a power chamber 29, a power mechanism 90 for providing working power for the device is contained in the power chamber 29, a motor 30 is fixedly arranged on a top end wall in the power chamber 29, a first rotating shaft 31 is fixedly arranged on a top end surface of the motor 30, a blade 32 is fixedly arranged on the first rotating shaft 31, a second rotating shaft 47 is fixedly arranged on a bottom end surface of the motor 30, a first sliding chute 19 is fixedly arranged in the power chamber 29, a first sliding block 17 is slidably arranged in the first sliding chute 19, an external connection block 28 is arranged between the top end wall of the first sliding chute 19 and the motor 30, and a first open slot 27 is fixedly arranged in the external connection block 28;

a reaction cavity 33 is formed in the wall of the bottom end of the power cavity 29, a reaction mechanism 91 for generating gas is arranged in the reaction cavity 33, isolation blocks 11 are fixedly arranged at the left end and the right end of the reaction cavity 33, a second sliding chute 16 is fixedly arranged on the inner side of each isolation block 11, a second sliding block 14 is slidably arranged in each second sliding chute 16, a manganese dioxide block 13 in contact with the end face of the inner side of each second sliding block 14 is slidably arranged on the inner side of each second sliding chute 16, and isolation sheets 12 for preventing the manganese dioxide block 13 from entering the reaction cavity 33 are fixedly arranged on the inner sides of the manganese dioxide blocks 13;

the bottom end wall of the reaction cavity 33 is fixedly provided with a storage cavity 35, the storage cavity 35 is internally provided with a storage mechanism 92 for carrying and releasing a balance weight, the bottom ends of the left and right end walls of the storage cavity 35 are fixedly provided with supporting blocks 55, a third rotating shaft 56 is rotatably arranged in the supporting blocks 55, and a matching plate 57 capable of blocking the storage cavity 35 is fixedly arranged on the third rotating shaft 56.

The power mechanism 90 includes the power cavity 29, the top end wall in the power cavity 29 is fixedly provided with the motor 30, the top end surface of the motor 30 is fixedly provided with the first rotating shaft 31, the first rotating shaft 31 is fixedly provided with the blades 32, the bottom end surface of the motor 30 is fixedly provided with the second rotating shaft 47, the bottom end wall of the second rotating shaft 47 is fixedly provided with a third sliding chute 49, the top end of the third sliding chute 49 is fixedly provided with an electromagnet 48, the bottom end wall of the power cavity 29 is rotatably provided with a fourth rotating shaft 37 extending up and down, the fourth rotating shaft 37 is fixedly provided with a fourth sliding chute 53, the fourth sliding chute 53 is slidably provided with a first connecting rod 50, the first connecting rod 50 can slide into the third sliding chute 49, a first spring 54 is connected between the bottom end surfaces of the first connecting rod 50 and the fourth sliding chute 53, the fourth rotating shaft 37 in the power cavity 29 is fixedly provided with a reel 51, the power cavity 29 internal fixation is equipped with first spout 19, it is equipped with to slide in first spout 19 first slider 17, first spout 19 top end wall with be equipped with between the motor 30 connect the piece 28 outward, connect the piece 28 internal fixation outward and be equipped with first open slot 27, first open slot 27 internal rotation is equipped with fifth pivot 26, the fixed reversing wheel 25 that is equipped with on the fifth pivot 26, first slider 17 with reel 51, connect between the reversing wheel 25 and be equipped with first line 24, open motor 30, motor 30 opens the drive first pivot 31 rotates, first pivot 31 rotates and drives blade 30 rotates, blade 30 rotates and drives equipment and dives in the sea downstream, when needs come-up, manually opens electromagnet 48, electromagnet 48 opens and makes through magnetic force first connecting rod 50 upwards slides and gets into in solo tiger third spout 49, at this time, the motor 30 is turned on to drive the second rotating shaft 47 to rotate, the second rotating shaft 47 rotates to drive the fourth rotating shaft 37 to rotate through the first connecting rod 50, the fourth rotating shaft 37 rotates to drive the reel 51 to rotate, the reel 51 rotates to drive the reversing wheel 25 to rotate through the first wire 24, and at this time, the first sliding block 17 slides upwards under the pulling force of the first wire 24.

The reaction mechanism 91 comprises the reaction cavity 33, isolation blocks 11 are fixedly arranged at the left end and the right end of the reaction cavity 33, the second chute 16 is fixedly arranged on the inner side of each isolation block 11, the second slide block 14 is slidably arranged in each second chute 16, a second spring 15 is connected between each second slide block 14 and the outer end face of each second chute 16, the manganese dioxide block 13 in contact with the inner end face of each second slide block 14 is slidably arranged on the inner side of each second chute 16, the isolation sheet 12 for preventing the manganese dioxide block 13 from entering the reaction cavity 33 is fixedly arranged on the inner side of each manganese dioxide block 13, a fifth chute 22 is fixedly arranged on the outer side of each isolation block 11, a hydraulic pipeline 18 is communicated between each fifth chute 22 and the corresponding second chute 16, a third slide block 21 is slidably arranged in each fifth chute 22, and a third spring 20 is connected between each third slide block 21 and the inner end face of each fifth chute 22, the reaction cavity 33 is internally provided with hydrogen peroxide 34, the fourth rotating shaft 37 positioned in the reaction cavity 33 is fixedly provided with a stirring block 62, the fourth rotating shaft 37 is positioned on the upper side of the stirring block 62 and is fixedly provided with a through hole 38, the bottom end wall of the fourth rotating shaft 37 is connected with the through hole 38 and is provided with a second open slot 40, the first sliding block 17 slides upwards to extrude the third sliding block 21, the third sliding block 21 slides inwards due to extrusion, the third sliding block 21 slides inwards to enable the second sliding block 14 to slide inwards through the hydraulic pipeline 18, the second sliding block 14 slides inwards to drive the manganese dioxide block 13 to burst the isolation sheet 12 into the reaction cavity 33, at the moment, the fourth rotating shaft 37 rotates to drive the stirring block 62 to rotate, the stirring block 62 rotates to enable the hydrogen peroxide 34 in the reaction cavity 33 to be fully contacted with the manganese dioxide block 13, the hydrogen peroxide 34 is fully contacted with the manganese dioxide block 13 to generate oxygen, and the generated oxygen enters the second open slot 40 through the through hole 38.

The storage mechanism 92 comprises the storage cavity 35, the bottom ends of the left and right end walls of the storage cavity 35 are fixedly provided with the supporting blocks 55, the supporting blocks 55 are rotatably provided with the third rotating shaft 56, the third rotating shaft 56 is fixedly provided with the matching plate 57 capable of blocking the storage cavity 35, the bottom ends of the left and right end walls of the storage cavity 35 are fixedly provided with the slide rails 59, the bottom ends of the slide rails 59 are fixedly provided with the limiting blocks 58, the slide rails 59 are fixedly connected with the matching plate and provided with the arc-shaped rods 60, the top ends of the arc-shaped rods 60 are fixedly provided with the matching blocks 61, the outer sides of the slide rails 59 are fixedly provided with the wire passing holes 63, the second wires 23 are fixedly arranged between the matching blocks 61 and the first slide blocks 17 and positioned in the wire passing holes 63, the storage cavity 35 is internally provided with the balancing weight 36, the top end wall of the storage cavity 35 is, draw the piece 44 with it is equipped with third line 45 to connect between the balancing weight 36, the internal fixation of compressed air bag 43 is equipped with aerifys piece 41, it aerifys chamber 42 to be equipped with in the piece 41, aerify 41 top with it is equipped with inflation duct 39 to aerify the chamber 42 intercommunication, inflation duct 39 stretches into in the second open slot 40 and blocks up through-hole 38, first slider 17 upwards slides and passes through line second line 23 makes cooperation piece 61 pushes under the effect of gravity arc pole 60, arc pole 60 removes and makes cooperation board 57 clockwise turning, cooperation board 57 clockwise turning makes and opens storage chamber 35, balancing weight 36 falls from in the storage chamber 35 this moment, balancing weight 36 falls through third line 45 pulling draw piece 44, draw piece 44 pulling compressed air bag 43, compressed air bag 43 slides downwards and makes inflation piece 41 slide downwards, the inflation block 41 slides downwards to drive the inflation pipeline 39 to slide downwards so that the through hole 38 is communicated with the inflation cavity 42 through the inflation pipeline 39, the pulling block 44 pulls the compression air bag 43 to automatically fall off, the compression air bag 43 is filled with oxygen to turn over the device, and at the moment, the device quickly floats upwards through the expanded compression air bag 43 and the blades 32.

Sequence of mechanical actions of the whole device:

1. in the initial state, the electromagnet 48 is closed, the first connecting rod 50 is not in contact with the second rotating shaft 47 under the tension of the first spring 54, the second spring 15 pulls the second sliding block 14 to prevent the manganese dioxide block 13 from breaking through the insulating sheet 12, and the second spring 20 extends the third sliding block 21 outwards;

2. starting a motor 30, starting the motor 30 to drive the first rotating shaft 31 to rotate, driving the blade 30 to rotate by rotating the first rotating shaft 31, driving the equipment to move downwards in the sea for diving by rotating the blade 30, when the equipment needs to float upwards, manually starting the electromagnet 48, starting the electromagnet 48 to enable the first connecting rod 50 to slide upwards through magnetic force to enter a third chute 49 of the cable tiger, starting the motor 30 to drive the second rotating shaft 47 to rotate at the moment, driving the fourth rotating shaft 37 to rotate through the first connecting rod 50 by rotating the second rotating shaft 47, driving the reel 51 to rotate by rotating the fourth rotating shaft 37, driving the reversing wheel 25 to rotate through the first line 24 by rotating the reel 51, and enabling the first sliding block 17 to slide upwards under the pulling force of the first line 24 at the moment;

3. the first sliding block 17 slides upwards to extrude the third sliding block 21, the third sliding block 21 slides inwards under extrusion, the third sliding block 21 slides inwards to enable the second sliding block 14 to slide inwards through the hydraulic pipeline 18, the second sliding block 14 slides inwards to drive the manganese dioxide block 13 to crash the isolation sheet 12 and enter the reaction cavity 33, at the moment, the fourth rotating shaft 37 rotates to drive the stirring block 62 to rotate, the stirring block 62 rotates to enable the hydrogen peroxide 34 in the reaction cavity 33 to be fully contacted with the manganese dioxide block 13, the hydrogen peroxide 34 is fully contacted with the manganese dioxide block 13 to generate oxygen, the generated oxygen enters the second open slot 40 through the through hole 38, and the equipment integration degree is high;

4. the first sliding block 17 slides upwards to enable the matching block 61 to push the arc-shaped rod 60 under the action of gravity through the second line 23, the arc-shaped rod 60 moves to enable the matching plate 57 to rotate clockwise, the matching plate 57 rotates clockwise to open the storage cavity 35, at this time, the balancing weight 36 falls from the storage cavity 35, the balancing weight 36 falls to enable the pulling block 44 to be pulled through the third line 45, the pulling block 44 pulls the compression air bag 43, the compression air bag 43 slides downwards to enable the inflation block 41 to slide downwards, the inflation block 41 slides downwards to drive the inflation pipeline 39 to slide downwards to enable the through hole 38 and the inflation cavity 42 to be communicated through the inflation pipeline 39, the pulling block 44 pulls the compression air bag 43 to fall off automatically, the compression air bag 43 is filled with oxygen to enable the device to turn over, and at this time, the device quickly floats upwards through the inflated compression air bag 43 and the blade 32, the automation degree of the equipment is high, the transmission fit of each mechanism is tight, and the kinetic energy utilization rate is high.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. The utility model provides a dive equipment of floating up fast, includes the fuselage, its characterized in that: the machine body comprises a power cavity;

2. The submersible rapid floatation device of claim 1, wherein: the power mechanism comprises the power cavity, the motor is fixedly arranged on the top end wall in the power cavity, the first rotating shaft is fixedly arranged on the top end face of the motor, the blades are fixedly arranged on the first rotating shaft, the second rotating shaft is fixedly arranged on the bottom end face of the motor, a third sliding groove is fixedly arranged on the bottom end wall of the second rotating shaft, and an electromagnet is fixedly arranged at the top end of the third sliding groove.

3. The submersible rapid floatation device according to claim 2, characterized in that: the power cavity bottom end wall is provided with a fourth rotating shaft which extends up and down in a rotating mode, a fourth sliding groove is fixedly formed in the fourth rotating shaft, a first connecting rod is arranged in the fourth sliding groove in a sliding mode, the first connecting rod can slide into the third sliding groove, a first spring is connected between the first connecting rod and the bottom end face of the fourth sliding groove, and a reel is fixedly arranged in the fourth rotating shaft in the power cavity.

4. A submersible rapid ascent apparatus according to claim 3, characterised in that: the power intracavity is fixed to be equipped with first spout, it is equipped with to slide in the first spout first slider, first spout top wall with be equipped with between the motor connect the piece outward, connect the internal fixation of piece to be equipped with first open slot, first open slot internal rotation is equipped with the fifth pivot, the fixed switching-over wheel that is equipped with in the fifth pivot, first slider with the reel connect between the switching-over wheel and be equipped with first line.

5. The submersible rapid floatation device of claim 1, wherein: reaction mechanism includes the reaction chamber, both ends are fixed to be equipped with isolated piece about the reaction chamber, isolated piece inboard is fixed to be equipped with the second spout, it is equipped with to slide in the second spout the second slider, the second slider with it is equipped with the second spring to connect between the outer terminal surface of second spout, the inboard slide of second spout be equipped with the contact of second slider medial extremity manganese dioxide piece.

6. A submersible rapid ascent apparatus according to claim 3, characterised in that: the fixed stop that is equipped with of manganese dioxide piece inboard manganese dioxide piece gets into the reaction chamber isolated piece, the fixed fifth spout that is equipped with in isolated piece outside, the fifth spout with the intercommunication is equipped with hydraulic pipeline between the second spout, it is equipped with the third slider to slide in the fifth spout, the third slider with connect between the terminal surface in the fifth spout and be equipped with the third spring, be equipped with hydrogen peroxide solution in the reaction chamber, be located in the reaction chamber the fixed stirring piece that is equipped with in the fourth pivot, be located in the fourth pivot the fixed through-hole that is equipped with of stirring piece upside, fourth pivot bottom end wall with the through-hole is connected and is equipped with the second open slot.

7. The submersible rapid floatation device of claim 1, wherein: the storage mechanism comprises a storage cavity, the bottom ends of the left end wall and the right end wall of the storage cavity are fixedly provided with the supporting blocks, the third rotating shaft is arranged in the supporting blocks in a rotating mode, and the matching plate capable of blocking the storage cavity is fixedly arranged on the third rotating shaft.

8. The submersible rapid floatation device of claim 7, wherein: end wall bottom mounting is equipped with the slide rail about the storing chamber, the slide rail bottom mounting is equipped with the stopper, in the slide rail with cooperation board fixed connection is equipped with the arc pole, the fixed cooperation piece that is equipped with in arc pole top, the fixed wiring hole that is equipped with in the slide rail outside, the cooperation piece with be located between the first slider wiring hole internal fixation is equipped with the second line.

9. The submersible rapid floatation device of claim 6, wherein: the storing intracavity is equipped with the balancing weight, storing chamber top end wall internal fixation is equipped with compressed air bag, the fixed piece that draws that is equipped with of compressed air bag bottom face, draw the piece with it is equipped with the third line to connect between the balancing weight, the compressed air bag internal fixation is equipped with the pump block, be equipped with in the pump block and aerify the chamber, pump block top with it is equipped with gas filled tube to aerify the chamber intercommunication, gas filled tube stretches into in the second open slot and blocks up the through-hole.