CN110834792B - Bionic transport case for improving survival rate of sardines - Google Patents

Abstract

The invention discloses a bionic transportation box for improving survival rate of sardines, which comprises a bionic box, wherein two storage cavities are symmetrically arranged in the bionic box from left to right, an inner cavity is arranged between the two storage cavities, water-isolating cavities are symmetrically arranged on the left side wall and the right side wall of the inner cavity, a transmission cavity is arranged on the lower side of the storage cavity, a transmission motor drives a transmission shaft to rotate, then drives double rows of belt pulleys and a single row of belt pulley to rotate, further drives a fan shaft to rotate, then drives a fan to rotate, sucks external air into a one-way valve, and further inputs the air into water through an air guide tube.

Description

Bionic transport case for improving survival rate of sardines

Technical Field

The invention relates to the field of transport containers, in particular to a bionic transport case for improving survival rate of sardines.

Background

At present, with the development of society, the improvement of living standard of people substances enables people of special products in various regions to taste, in long-distance transportation of sardines, fishermen often use catfishes to keep the vitality of the sardines so as to improve the survival rate of the sardines, but in the traditional transportation, real catfishes still cause certain damage to the sardines in the transportation process and reduce the income of the fishermen, in the longer transportation, the fishing time is longer, the sardines need to be fed for many times in the middle, but the transportation time and the transportation cost can be increased in the process of stopping feeding, and the situation that the sardines cannot be fed at any time is caused by the fact that the people cannot stop at will, so that the bionic transportation box for improving the survival rate of the sardines needs to be invented.

Disclosure of Invention

The invention aims to provide a bionic transport case for improving survival rate of sardines, and aims to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a bionic transportation box for improving survival rate of sardines comprises a bionic box, wherein two storage cavities are symmetrically arranged in the bionic box from left to right, an inner cavity is arranged between the two storage cavities, water-isolating cavities are symmetrically arranged on left and right side walls of the inner cavity, a transmission cavity is arranged on the lower side of each storage cavity, and a bionic device is arranged between the transmission cavity and the storage cavity;

the bionic device comprises a transmission motor fixedly installed on the bottom wall of the transmission cavity, a transmission shaft which is rotatably connected with the top wall of the transmission cavity is in power connection with the upper side of the transmission motor, the transmission shaft extends upwards to penetrate through the top wall of the transmission cavity to enter the inner cavity and is rotatably connected with the bottom wall of the inner cavity, a triangular block is fixedly arranged on the upper side of the transmission shaft, an annular cavity is formed in the triangular block, thin rods are connected in the annular cavity in a sliding mode in a bilateral symmetry mode, the other side of each thin rod is fixedly provided with the bionic catfish, one side, far away from the inner cavity, of each storage cavity is provided with a fan cavity, a feeding cavity is arranged on the lower side of each fan cavity, and a discharge port is communicated between each feeding cavity and the;

the bionic box is characterized in that an oxygen supply device is arranged between the fan cavity and the transmission cavity, a bottom wall cavity is arranged on the bottom wall of the feeding cavity, a feeding device is arranged between the bottom wall cavity and the feeding cavity, a hydraulic cavity is arranged on one side, close to the storage cavity, of the bottom wall cavity, a communicating cavity is communicated between the two hydraulic cavities, a hydraulic device is arranged between the communicating cavity and the hydraulic cavity, a top block is fixedly arranged on the upper side of the bionic box, a motor cavity is arranged in the top block, rotating cavities are symmetrically arranged on the left side wall and the right side wall of the motor cavity, and a sealing device is arranged between the rotating cavity and the motor cavity.

Preferably, the oxygen supply device comprises auxiliary shafts which are bilaterally and symmetrically rotationally connected with the upper side wall and the lower side wall of the transmission cavity, each auxiliary shaft extends upwards to penetrate through the top wall of the transmission cavity to enter the bottom wall cavity and is rotationally connected with the bottom wall of the bottom wall cavity, each auxiliary shaft extends upwards to penetrate through the top wall of the feeding cavity to enter the fan cavity and is rotationally connected between the bottom wall of the fan cavity and the top wall of the feeding cavity, double rows of belt wheels are fixedly arranged on the transmission shaft, a single row of belt wheels corresponding to the double rows of belt wheels are fixedly arranged on each auxiliary shaft, a belt is connected between the single row of belt wheels and the double rows of belt wheels, universal wheels fixedly connected with the front side wall and the rear side wall of the fan cavity are rotationally connected on the upper sides of the auxiliary shafts, a bionic fan shaft is rotationally connected in the direction of each universal wheel close to one side face of the, and a one-way valve is fixedly arranged at the communication part of each fan cavity and the storage cavity, and an air guide pipe is fixedly arranged in the storage cavity of each one-way valve.

Preferably, the feeding device comprises a feeding plate which is connected with the inner wall of the feeding cavity in a sliding manner and is rotationally connected with auxiliary shafts, each auxiliary shaft is fixedly provided with a worm wheel in the bottom wall cavity, each bottom wall cavity is connected with a slide block in a sliding manner, each water-stop cavity is connected with water-stop plates which are butted with the upper side wall and the lower side wall of the thin rod in a vertically symmetrical and sliding manner, a compression spring is connected between one side surface of each water-stop plate and one side wall of each water-stop cavity, each slide block is internally provided with a worm cavity, the front side wall and the rear side wall of each worm cavity are rotationally connected with a worm shaft, the front side of each worm shaft is fixedly provided with a worm which can be meshed with the worm wheel, the rear side of each worm shaft is fixedly provided with a meshing gear, one side of each meshing gear, which is far away from the worm wheel, is meshed with a lifting plate which is slidably connected, one side of each discharge port is fixedly provided with a discharge platform.

Preferably, the hydraulic device comprises a hydraulic motor fixedly installed in the communicating cavity, the hydraulic motor is in bilateral symmetry and is in power connection with a threaded shaft, a sliding pipe in sliding connection with the inner wall of the communicating cavity is in threaded connection with each threaded shaft, a hydraulic plate is in sliding connection with each hydraulic cavity, a pushing plate in sliding connection between one side wall of the bottom wall cavity and one side wall of the hydraulic cavity is fixedly arranged on one side face of each hydraulic plate, and each pushing plate is fixedly connected with the corresponding sliding block.

Preferably, the closing device comprises a door plate which is hinged to the top block in a bilateral symmetry mode and used for closing the storage cavity, a door plate motor is fixedly arranged on the bottom wall of the motor cavity, a motor shaft is connected to the upper side of the door plate motor in a power mode, a threaded pipe is connected to the motor shaft in a threaded mode, the front side wall and the rear side wall of the rotating cavity are rotatably connected with a rotating shaft, an upper side hinged plate which is connected with the rotating shaft in a rotating mode is fixedly arranged in the threaded pipe in the bilateral symmetry mode, and each upper side hinged plate is hinged to.

In conclusion, the beneficial effects of the invention are as follows: according to the invention, the survival rate of the sardines is improved by simulating the mode of adding the catfishes in the process of transporting the sardines, the real catfishes are replaced by the bionic catfishes, so that the effect of recycling can be achieved, the damage of the catfishes to the sardines in the process of transporting can be reduced, and the sardines can be fed by the feeding device in the process of driving by stopping the vehicle midway in consideration of the requirement of feeding the sardines for feeding in the traditional long-distance transport vehicle, so that the transportation time and the transportation cost are reduced, and the function can not be started in the process of short-distance transportation, so that the popularization is worthy.

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 schematic overall sectional front view of a bionic transportation box for improving survival rate of sardines according to the invention;

FIG. 2 is an enlarged view taken at A of FIG. 1 in accordance with the present invention;

FIG. 3 is a cross-sectional view taken along line B-B of FIG. 2 in accordance with the present invention;

fig. 4 is a cross-sectional view taken along the direction C-C in fig. 1 according to the present invention.

Detailed Description

All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations where mutually exclusive features or steps are mutually exclusive.

Any feature disclosed in this specification (including any accompanying claims, abstract and drawings), may be replaced by alternative features serving equivalent or similar purposes, unless expressly stated otherwise. That is, unless expressly stated otherwise, each feature is only an example of a generic series of equivalent or similar features.

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.

Referring to fig. 1-4, an embodiment of the present invention is shown: a bionic transport case for improving survival rate of sardines comprises a bionic case 20, wherein two storage cavities 73 are symmetrically arranged in the bionic case 20 in the left-right direction, an inner cavity 70 is arranged between the two storage cavities 73, a water-isolating cavity 69 is symmetrically arranged on the left side wall and the right side wall of the inner cavity 70, a transmission cavity 40 is arranged on the lower side of the storage cavity 73, a bionic device 101 is arranged between the transmission cavity 40 and the storage cavity 73, the bionic device 101 comprises a transmission motor 42 fixedly arranged on the bottom wall of the transmission cavity 40, a transmission shaft 41 rotatably connected with the top wall of the transmission cavity 40 is in power connection with the upper side of the transmission motor 42, the transmission shaft 41 upwards extends to penetrate through the top wall of the transmission cavity 40, enters the inner cavity 70 and is rotatably connected with the bottom wall of the inner cavity 70, a triangular block 71 is fixedly arranged on the upper side of the transmission shaft 41, an annular cavity 65 is arranged in the triangular block 71, and, the other side of each slender rod 66 is fixedly provided with a bionic catfish 72, one side of each storage cavity 73, which is far away from the internal cavity 70, is provided with a fan cavity 25, the lower side of each fan cavity 25 is provided with a feeding cavity 24, a discharge hole 74 is communicated between each feeding cavity 24 and the storage cavity 73, an oxygen supply device 102 is arranged between the fan cavity 25 and the transmission cavity 40, the bottom wall of each feeding cavity 24 is provided with a bottom wall cavity 45, a feeding device 103 is arranged between the bottom wall cavity 45 and the feeding cavity 24, one side of each bottom wall cavity 45, which is close to the storage cavity 73, is provided with a hydraulic cavity 53, a communication cavity 61 is communicated between the two hydraulic cavities 53, a hydraulic device 104 is arranged between the communication cavity 61 and the hydraulic cavity 53, the upper side of the bionic box 20 is fixedly provided with a top block 76, a motor cavity 38 is arranged in the top block 76, and the left and right side walls of the motor cavity 38 are symmetrically provided with rotating cavities 34, a sealing device 105 is arranged between the rotating cavity 34 and the motor cavity 38.

In addition, in one embodiment, the oxygen supply device 102 includes auxiliary shafts 21 which are bilaterally symmetrically and rotatably connected to the upper and lower side walls of the transmission cavity 40, each auxiliary shaft 21 extends upward to penetrate through the top wall of the transmission cavity 40 to enter the bottom wall cavity 45 and is rotatably connected to the bottom wall of the bottom wall cavity 45, each auxiliary shaft 21 extends upward to penetrate through the top wall of the material supply cavity 24 to enter the fan cavity 25 and is rotatably connected between the bottom wall of the fan cavity 25 and the top wall of the material supply cavity 24, two rows of pulleys 43 are fixedly arranged on the transmission shaft 41, a single row of pulleys 22 corresponding to the two rows of pulleys 43 are fixedly arranged on each auxiliary shaft 21, a belt 44 is connected between the single row of pulleys 22 and the two rows of pulleys 43, a universal wheel 28 fixedly connected to the front and rear side walls of the fan cavity 25 is rotatably connected to the upper side of each auxiliary shaft 21, a shaft 27 is rotatably connected to the direction of each universal wheel 28 close to one side surface of the bionic box, a fan 26 is fixedly arranged on each fan shaft 27, a one-way valve 29 is fixedly arranged at the communication part of each fan cavity 25 and the storage cavity 73, an air duct 31 is fixedly arranged in the storage cavity 73 of each one-way valve 29, the transmission motor 42 drives the transmission shaft 41 to rotate, then drives the double-row belt wheels 43 and the single-row belt wheels 22 to rotate, thereby driving the auxiliary shaft 21 to rotate, further driving the fan shaft 27 to rotate, then driving the fan 26 to rotate, sucking the outside air into the one-way valve 29, and further inputting the air into water through the air duct 31.

In addition, in one embodiment, the feeding device 103 includes a feeding plate 48 slidably connected to an inner wall of the feeding chamber 24 and rotatably connected to the auxiliary shafts 21, each of the auxiliary shafts 21 has a worm wheel 46 fixedly disposed in the bottom wall chamber 45, each of the bottom wall chambers 45 has a sliding block 59 slidably connected thereto, each of the water blocking chambers 69 has a water blocking plate 67 slidably connected thereto in an up-down symmetrical manner, the upper and lower side walls of the thin rod 66 abut against each other, a pressing spring 68 is connected between one side wall of each of the water blocking plates 67 and one side wall of the water blocking chamber 69, each of the sliding blocks 59 has a worm chamber 50 disposed therein, each of the front and rear side walls of the worm chamber 50 has a worm shaft 56 rotatably connected thereto, a worm 57 engageable with the worm wheel 46 is fixedly disposed on a front side of each of the worm shaft 56, an engaging gear 58 is fixedly disposed on a rear side of each of the worm shaft 56, a lifting plate 51 slidably connected to an inner wall of the worm chamber 50 is engaged with one side of each of the engaging gear 58 remote from, the top surface of the lifting plate 51 abuts against the bottom surface of the feeding plate 48, a discharging table 75 is fixedly arranged on one side of each discharging port 74, the worm gear 46 rotates to drive the worm 57 to rotate, so as to drive the worm shaft 56 to rotate, and then drive the meshing gear 58 to rotate, so as to drive the lifting plate 51 to move upwards, and then drive the feeding plate 48 to move upwards, so that the feed in the feeding plate 48 is poured into the storage cavity 73 through the discharging ports 74 and the discharging tables 75.

In addition, in one embodiment, the hydraulic device 104 includes a hydraulic motor 64 fixedly installed in the communication chamber 61, the hydraulic motor 64 is connected with threaded shafts 63 in a bilateral symmetry manner, each threaded shaft 63 is connected with a sliding tube 62 in a sliding manner with the inner wall of the communication chamber 61 in a threaded manner, a hydraulic plate 54 is connected in each hydraulic chamber 53 in a sliding manner, a pushing plate 55 connected in a sliding manner between one side wall of the bottom wall chamber 45 and one side wall of the hydraulic chamber 53 is fixedly arranged on one side surface of each hydraulic plate 54, each pushing plate 55 is fixedly connected with the corresponding slide block 59, when feed delivery is required, the hydraulic motor 64 is opened to drive the threaded shaft 63 to rotate, so that the sliding tube 62 moves in a direction away from the hydraulic motor 64, and hydraulic oil in the communication chamber 61 is squeezed into the hydraulic chamber 53, thereby pushing the hydraulic plate 54 to move, further pushing the pushing plate 55 and the sliding block 59 to move, and further the worm 57 is meshed with the worm wheel 46.

In addition, in one embodiment, the closing device 105 includes a door plate 30 hinged to the top block 76 in a bilateral symmetry manner for closing the storage cavity 73, a door plate motor 39 is fixedly arranged on the bottom wall of the motor cavity 38, a motor shaft 37 is dynamically connected to the upper side of the door plate motor 39, a threaded pipe 36 is screwed to the motor shaft 37, a rotating shaft 35 is rotatably connected to the front and rear side walls of the rotating cavity 34, upper hinge plates 33 rotatably connected to the rotating shaft 35 are fixedly arranged on the left and right sides of the threaded pipe 36 in a bilateral symmetry manner, a lower hinge plate 32 hinged to the door plate 30 is hinged to one side of each upper hinge plate 33, and when the door plate 30 needs to be opened, the door plate motor 39 is opened to drive the motor shaft 37 to rotate and further drive the threaded pipe 36 to descend and further drive the right side of the upper hinge plate 33 to ascend, and, thereby facilitating catching the sardines.

In the initial state, the door panel 30 is in the state of closing the storage chamber 73, and the slider 59 is in the side close to the hydraulic chamber 53.

When sardines need to be transported, the sardines anti-theft storage cavity 73 is sealed through the door plate 30, the transmission motor 42 is opened to drive the transmission shaft 41 to rotate, then the double-row belt wheel 43 and the single-row belt wheel 22 are driven to rotate, the auxiliary shaft 21 is driven to rotate, the fan shaft 27 is driven to rotate, then the fan 26 is driven to rotate to suck outside air into the one-way valve 29, the air is input into water through the air duct 31 to ensure oxygen supply, meanwhile, the transmission shaft 41 rotates to drive the triangular block 71 to rotate, so that the thin rod 66 is driven to move up and down and left and right, meanwhile, the water baffle plate 67 moves up and down in the water baffle cavity 69 to prevent water in the storage cavity 73 from flowing into the inner cavity 70, when sardiness need to be supplied for long-distance transportation, the hydraulic motor 64 is opened to drive the threaded shaft 63 to rotate, so that the sliding pipe 62 moves in the, thereby squeeze the hydraulic oil in the communicating chamber 61 to the hydraulic chamber 53, and then push the hydraulic plate 54 to move, and then push the pushing plate 55, the slider 59 to move, and then the worm 57 meshes with the worm wheel 46, then the worm wheel 46 rotates and drives the worm 57 to rotate, thereby drive the worm shaft 56 to rotate, and then drive the meshing gear 58 to rotate, thereby drive the lifting plate 51 to move upwards, and then drive the feeding plate 48 to move upwards, and then pour the feed in the feeding plate 48 into the storage chamber 73 through the discharge port 74 and the discharge table 75, after arriving at the destination, open the door panel motor 39, thereby drive the motor shaft 37 to rotate, and then drive the threaded pipe 36 to descend, thereby drive the upper side 33 to ascend at the right side, thereby rise the door panel 30 through the lower side hinged plate 32, thereby facilitating the catching of sardine.

The invention has the beneficial effects that: according to the invention, the survival rate of the sardines is improved by simulating the mode of adding the catfishes in the process of transporting the sardines, the real catfishes are replaced by the bionic catfishes, so that the effect of recycling can be achieved, the damage of the catfishes to the sardines in the process of transporting can be reduced, and the sardines can be fed by the feeding device in the process of driving by stopping the vehicle midway in consideration of the requirement of feeding the sardines for feeding in the traditional long-distance transport vehicle, so that the transportation time and the transportation cost are reduced, and the function can not be started in the process of short-distance transportation, so that the popularization is worthy.

The above description is only an embodiment of the invention, but the scope of the invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the invention. Therefore, the protection scope of the invention should be subject to the protection scope defined by the claims.

Claims (1)

1. The utility model provides an improve bionical transport case of sardine survival rate, includes bionical case, its characterized in that: two storage cavities are symmetrically arranged in the bionic box from left to right, an inner cavity is arranged between the two storage cavities, water-proof cavities are symmetrically arranged on the left side wall and the right side wall of the inner cavity, a transmission cavity is arranged on the lower side of the storage cavity, and a bionic device is arranged between the transmission cavity and the storage cavity; the bionic device comprises a transmission motor fixedly installed on the bottom wall of the transmission cavity, a transmission shaft which is rotatably connected with the top wall of the transmission cavity is in power connection with the upper side of the transmission motor, the transmission shaft extends upwards to penetrate through the top wall of the transmission cavity to enter the inner cavity and is rotatably connected with the bottom wall of the inner cavity, a triangular block is fixedly arranged on the upper side of the transmission shaft, an annular cavity is formed in the triangular block, thin rods are connected in the annular cavity in a sliding mode in a bilateral symmetry mode, the other side of each thin rod is fixedly provided with the bionic catfish, one side, far away from the inner cavity, of each storage cavity is provided with a fan cavity, a feeding cavity is arranged on the lower side of each fan cavity, and a discharge port is communicated between each feeding cavity and the; an oxygen supply device is arranged between the fan cavity and the transmission cavity, a bottom wall cavity is arranged on the bottom wall of each feeding cavity, a feeding device is arranged between the bottom wall cavity and the feeding cavity, a hydraulic cavity is arranged on one side, close to the storage cavity, of each bottom wall cavity, a communication cavity is communicated between the two hydraulic cavities, a hydraulic device is arranged between the communication cavity and the hydraulic cavity, a top block is fixedly arranged on the upper side of the bionic box, a motor cavity is arranged in the top block, rotating cavities are symmetrically arranged on the left side wall and the right side wall of the motor cavity, and a sealing device is arranged between the rotating cavities and the motor cavity; the oxygen supply device comprises auxiliary shafts which are bilaterally and symmetrically rotationally connected with the upper side wall and the lower side wall of the transmission cavity, each auxiliary shaft upwards extends to penetrate through the top wall of the transmission cavity to enter the bottom wall cavity and is rotationally connected with the bottom wall of the bottom wall cavity, each auxiliary shaft upwards extends to penetrate through the top wall of the material supply cavity to enter the fan cavity and is rotationally connected between the bottom wall of the fan cavity and the top wall of the material supply cavity, double-row belt wheels are fixedly arranged on the transmission shaft, single-row belt wheels corresponding to the double-row belt wheels are fixedly arranged on each auxiliary shaft, a belt is connected between the single-row belt wheels and the double-row belt wheels, universal wheels fixedly connected with the front side wall and the rear side wall of the fan cavity are rotationally connected on the upper sides of the auxiliary shafts, a fan shaft is rotationally connected in the direction of each universal wheel close to one side face, a one-way valve is fixedly arranged at the communication part of each fan cavity and the storage cavity, and an air guide pipe is fixedly arranged in the storage cavity of each one-way valve; the feeding device comprises a feeding plate which is connected with the inner wall of the feeding cavity in a sliding manner and is rotationally connected with auxiliary shafts, each auxiliary shaft is fixedly provided with a worm wheel in the bottom wall cavity, each bottom wall cavity is connected with a slide block in a sliding manner, each water-stop cavity is connected with water-stop plates which are butted with the upper side wall and the lower side wall of the thin rod in a vertically symmetrical and sliding manner, a compression spring is connected between one side surface of each water-stop plate and one side wall of each water-stop cavity, each slide block is internally provided with a worm cavity, the front side wall and the rear side wall of each worm cavity are rotationally connected with a worm shaft, the front side of each worm shaft is fixedly provided with a worm which can be meshed with the worm wheel, the rear side of each worm shaft is fixedly provided with a meshing gear, one side of each meshing gear, which is far away from the worm wheel, is meshed with a lifting plate which is, one side of each discharge port is fixedly provided with a discharge table; the hydraulic device comprises a hydraulic motor fixedly installed in the communicating cavity, the hydraulic motor is in bilateral symmetry and is in power connection with threaded shafts, each threaded shaft is in threaded connection with a sliding pipe in sliding connection with the inner wall of the communicating cavity, a hydraulic plate is in sliding connection with each hydraulic cavity, one side face of each hydraulic plate is fixedly provided with a pushing plate in sliding connection between one side wall of the bottom wall cavity and one side wall of the hydraulic cavity, and each pushing plate is fixedly connected with the corresponding sliding block; the closing means includes that bilateral symmetry articulates be used for sealing on the top piece store the door plant in chamber, motor chamber diapire has set firmly the door plant motor, door plant motor upside power is connected with the motor shaft, threaded connection has the screwed pipe on the motor shaft, the lateral wall rotates around rotating the chamber and is connected with the axis of rotation, screwed pipe bilateral symmetry set firmly with the axis of rotation rotates the upside articulated slab of being connected, every upside articulated slab one side articulate have with door plant articulated downside articulated slab.

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