CN108353844B - Aquaculture is with trading oxygen equipment - Google Patents

Abstract

The invention discloses oxygen exchange equipment for aquaculture, which structurally comprises: the device comprises moving wheels, an intelligent oxygen supply adjusting device, a device shell, a controller, a fixed handle, a power line, an output pipe and a radiator, wherein every two moving wheels are mutually parallel and vertically arranged with four corners of the lower surface of the device shell, the lower end of the intelligent oxygen supply adjusting device embedded into the device shell is simultaneously connected with the lower end of the intelligent oxygen supply adjusting device in an integrated structure in a welding mode, the controller and the intelligent oxygen supply adjusting device are mutually parallel and simultaneously electrically connected with the intelligent oxygen supply adjusting device embedded into the device shell, the fixed handle is positioned in the center of the upper surface of the device shell and is simultaneously fixedly connected with the device shell, can ensure that the device can continuously carry out oxygen production when the oxygen changing equipment works, and simultaneously can filter impurities in advance, and can store and collect oxygen and release when needing to reach the purpose that makes the device can be more perfect and intelligent.

Description

Aquaculture is with trading oxygen equipment

Technical Field

The invention relates to oxygen exchange equipment for aquaculture, belonging to the field of aquaculture.

Background

Aquaculture is the production activity of breeding, cultivating and harvesting aquatic animals and plants under artificial control. Generally comprises the whole process of cultivating aquatic products from seedlings under artificial feeding management. In a broad sense, this may also include the proliferation of aquatic resources.

Aquaculture has modes of rough culture, intensive culture, high-density intensive culture and the like. The rough culture is to put seedlings in medium and small natural waters and to culture aquatic products such as fish in lakes and reservoirs, shellfish in shallow seas and the like by completely relying on natural baits. Intensive culture is to culture aquatic products such as pond fish culture, net cage fish culture, fence culture and the like in a small water body by using bait casting and fertilizing methods. The high-density intensive culture adopts methods of flowing water, controlling temperature, increasing oxygen, feeding high-quality baits and the like to carry out high-density culture in a small water body so as to obtain high yield, such as flowing water high-density fish culture, shrimp culture and the like.

The world aquaculture production has increased rapidly since the 70's of the 20 th century and the proportion in aquaculture is increasing. The history of aquiculture Chinese freshwater aquaculture dates back to 11 th century before the Gongyuan. The "fish culture" was published 5 th century before the Yuan. The freshwater aquaculture mainly comprises two types, namely, intensive culturing of cyprinid fishes in a pond, high yield by feeding and fertilizing, and mixed culturing of various fishes with different feeding habits to give full play to the productivity of water bodies. The other type is to breed seedlings in large and medium-sized water areas such as lakes, reservoirs, ditches, rice fields and the like, and aquatic products are obtained mainly by means of natural baits. In 1986, the freshwater aquaculture area in China is about 4600 ten thousand mu (about 61 percent of the available aquaculture area), wherein the pond accounts for 35 percent and is concentrated in the middle and lower reaches of Yangtze river and the Yangtze delta; lakes account for 17% and are mainly in the middle and lower reaches of the Yangtze river and in northeast and inner Mongolia areas; the reservoirs account for 37 percent and are distributed nationally; the river channel accounts for 9 percent and is mainly located in water network areas of Jiangsu and Zhejiang. The total output of fresh water culture is the first world for years, the total output is increased at a speed of about 22 percent, and the output is 295 ten thousand tons in 1986, which accounts for 36 percent of the total output of aquatic products in China. Wherein the pond accounts for 74 percent, the reservoir accounts for 8 percent, and the balance is the output of lakes, rivers and ditches and paddy fields.

But prior art's equipment of changing oxygen can't make the device can be incessant carry out the system oxygen work when carrying out the work, can't filter impurity in advance simultaneously to can't store and collect oxygen and release when needs, thereby can't make perfect and intelligent that the device can be more.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide oxygen exchange equipment for aquaculture to solve the problems that the oxygen exchange equipment cannot enable a device to continuously perform oxygen generation work during working, impurities cannot be filtered in advance, and stored and collected oxygen cannot be released when needed, so that the device cannot be more perfect and intelligent.

In order to achieve the purpose, the invention is realized by the following technical scheme: an oxygen exchange device for aquaculture, which structurally comprises: a movable wheel, an intelligent oxygen supply adjusting device, a device shell, a controller, a fixed handle, a power line, an output pipe and a radiator, the two moving wheels are parallel to each other and are vertically arranged at four corners of the lower surface of the device shell, the lower end of the intelligent oxygen supply adjusting device embedded in the device shell is connected with the device shell into an integrated structure in a welding mode, the controller is parallel to the intelligent oxygen supply adjusting device, meanwhile, the controller is electrically connected with an intelligent oxygen supply adjusting device embedded in the device shell, the fixed handle is positioned in the center of the upper surface of the device shell and is fixedly connected with the device shell, the power line is embedded into the device shell and is electrically connected with the intelligent oxygen supply regulating device, the output pipe is mutually communicated with the right side surface of the device shell and is mechanically connected with the device shell, the radiator is fixedly arranged below the output pipe and is fixedly connected with the device shell;

the intelligent oxygen supply adjusting device is provided with a power adjusting device, a power conveying device, a pressurizing air inlet device, a sealing jacking device, a filtering oxygen generating device and an oxygen receiving sealing device;

receive oxygen sealing device and be located the inside right side surface of equipment and link together through the welded mode simultaneously with equipment, the inboard surface that oxygen sealing device was received in the embedding in the power adjusting device and adopt clearance fit with receiving oxygen sealing device, power conveyor is located both meshing of power adjusting device's left side surface and links together, close filtration oxygenerator locates power adjusting device's left side surface and through the hub connection together, sealed top moves device and filters oxygenerator and be parallel to each other and adopt clearance fit to link together through the area body with power adjusting device, pressurization air inlet unit is located sealed top moves device's left side surface and welds into integral structure rather than the same simultaneously.

Furthermore, the power adjusting device is provided with a limiting block, a telescopic rod, an electromagnet, a shell frame, a spring, a gear, a wheel shaft, a sliding frame, a sealing support, a matching wheel, a middle rotating wheel, a transmission wheel and a transmission belt.

Furthermore, the upper surface of the telescopic rod is provided with a gear which is vertical to the gear, the limiting block is fixedly arranged on the outer side surface of the telescopic rod and is connected together in a welding mode, the spring wraps the outer side surface of the telescopic rod and is connected together in a clearance fit mode, the shell frame is vertical to the lower surface of the telescopic rod and is movably connected with the telescopic rod, the electromagnet is arranged in the shell frame and is movably connected with the shell frame, the wheel shaft is positioned on the right side surface of the gear and is vertically meshed together, the middle rotating wheel and the wheel shaft are parallel to each other and are connected together in a clearance fit mode through a transmission belt, the matching wheel is arranged on the right side surface of the middle rotating wheel and is meshed together, the sealing support is arranged on the front surface of the matching wheel in a hinge connection mode, the inner side surface of the sliding frame is, the transmission wheel is perpendicular to the transfer wheel and forms an integrated structure through the transmission band.

Furthermore, the power transmission device is provided with a dust collecting chamber, a blade shaft, a gear set, a blade frame, an installation cabin, a transmission shaft, a driving shaft, a double-end motor and an auxiliary shaft, the driving shaft and the auxiliary shaft are parallel to each other and are respectively vertically embedded into the left side surface and the right side surface of the double-head motor, the driving shaft, the auxiliary shaft and the double-head motor are connected together in a clearance fit manner, the transmission shaft is vertically meshed with the upper surface of the auxiliary shaft to form an integrated structure, the gear group is arranged on the upper side surface of the transmission shaft and connected together in a welding mode, the blade shaft is arranged on the left side surface and the right side surface of the gear group and movably connected with the gear group, the blade shaft is embedded into the mounting cabin and movably connected with the inside of the mounting cabin, the blade shaft is positioned on the left side surface of the blade frame and is connected with the left side surface of the blade frame in a welding mode, and the dust collecting chamber is parallel to the mounting cabin from left to right and is fixedly connected with the mounting cabin.

Further, pressurization air inlet unit is equipped with pneumatic tube, first fixing base, mounting bracket, intake pipe, time venturi tube, negative-pressure air fan, joint frame, the joint frame is located the left surface of pneumatic tube and is in the same place with the pneumatic tube welding simultaneously, time venturi tube locates the left surface of joint frame and is in the same place with joint frame fixed connection, the intake pipe link up each other with the left surface of time venturi tube, the mounting bracket is installed perpendicularly and is linked together rather than through the welded mode simultaneously in the upper surface of first fixing base, negative-pressure air fan fixed mounting is embedded the inside of time of time venturi tube at the upper surface of mounting bracket.

Further, sealed top-moving device is equipped with fixed block, carriage, fluted disc, fixed plate, rack, spacing frame, rotation post, alignment jig, spout, the upper surface at the rotation post is welded perpendicularly to the alignment jig, both swing joint are in the same place in the outside surface of rotation post are located to the spout, both swing joint are in the same place in the inside of embedding the spout in the spacing frame, the fluted disc passes through hinged joint's mode and installs the front surface at spacing frame, the rack is parallel to each other with the fixed plate and adopts clearance fit to link together simultaneously, the fixed block is the extension of the vertical axis of rack and welds into integral structure with the rack simultaneously, the inside of fixed block embedding carriage perpendicularly connects into integral structure rather than the clearance fit.

Furthermore, the filtering oxygen-generating device is provided with an electrifying frame, an embedded frame, a protective frame, a sun wheel shaft, a bearing, a tooth socket frame, a planet wheel, a support shaft, a second fixed seat and a zeolite frame, wherein the protective frame is vertically embedded into the embedded frame and movably connected with the embedded frame, the zeolite frame is vertically connected with the inner side surface of the protective frame and the inner side of the protective frame to form an integrated structure, the electrifying frame is positioned on the lower surface of the protective frame and is mutually vertical to the protective frame and forms an integrated structure with the protective frame, the sun wheel shaft is embedded into the bearing and is connected with the bearing in a clearance fit manner, the sun wheel shaft is embedded into the tooth socket frame and is meshed with the tooth socket frame at the same time, the planet wheel is positioned between the sun wheel shaft and the tooth socket frame and is connected with the sun wheel shaft and the tooth socket frame to form an integrated structure, and the support, the second fixing seat is vertically arranged on the upper surface of the protection frame and is fixedly connected with the protection frame into an integrated structure, and the support shaft wraps the outer side surface of the second fixing seat and is movably connected with the second fixing seat.

Furthermore, receive oxygen sealing device and be equipped with support frame, export frame, embedded piece, expansion bracket, steel cable, crossbeam frame, floating pad, collection cabin both are perpendicular to each other and rather than fixed connection together on the upper surface of support frame in the collection cabin, floating pad is located the inside of collection cabin and is adopted clearance fit to link together with the collection cabin simultaneously, the crossbeam frame is installed in the front surface of floating pad through hinged joint's mode and is in the same place rather than fixed connection together, the steel cable is parallel from top to bottom with the expansion bracket and is the integral structure simultaneously and passes through the steel cable and install the lower surface at the crossbeam frame, export frame sets up in the right side surface of collection cabin and rather than collection cabin cooperation link together.

Advantageous effects

The invention relates to an oxygen exchange device for aquaculture, which is characterized in that after the device is electrified, an internal negative pressure fan is electrified to rotate, external air is compressed through an air inlet pipe and enters the interior of a return pipe, then enters the interior of an air pressure pipe through the return pipe, an auxiliary shaft and a driving shaft rotate under the electromagnetic induction of a power motor after the power motor is electrified, the auxiliary shaft drives a transmission shaft to carry out meshing rotation, the transmission shaft transmits power upwards, a gear set is driven under the meshing action, so that necessary rotating power can be provided for a blade shaft, a blade frame can also rotate together, the internal cooling and dust cleaning work is achieved, when a zeolite frame needs to be converted, a repulsive force generated after an electromagnet is electrified extends out of a telescopic rod to push a driving gear to relay the power of the driving shaft to a wheel shaft, then the rotating power is transmitted to an upper intermediate rotating wheel through a transmission belt by the wheel shaft, so that the intermediate rotating wheel rotates, and then the power is transmitted by a sun wheel shaft, thereby can drive the displacement of inside planet wheel on the gear groove and rotate, and rotate and can drive the displacement of support shaft, and the fixing base that support shaft parcel was moved can be pressed and make the inside of protective frame decline and embedding in the embedded frame thereby the zeolite frame on the embedded frame can be proposed and changed, utilize the electrified frame to make inside zeolite heating, according to the different adsorptivity replacement oxygen of nitrogen gas and oxygen, thereby accomplish incessant system oxygen and change, and the transmission band can drive the alignment jig and rotate the spout and form different walks in the pivoted process and make spacing frame drive fluted disc push down or pull out the rack simultaneously, can make the fixed block carry out sealed filtration or pull up the cleanness simultaneously, after the oxygen of inside is sufficient, the cooperation wheel can push down the sealed support and then sealed pneumatic tube, and the oxygen of inside is stored in the inside of collecting chamber, after the floating pad rises to certain degree, can pull up the balancing stand to open and collect the cabin and make inside oxygen get into inside the basin, the oxygen work is traded in the deflection, just so can reach and trade oxygen equipment and can make the device can incessant the work of making oxygen when carrying out the work, can filter impurity in advance simultaneously, and can store and collect oxygen and release when needs, thereby reach and make perfect and intelligent purpose that the device can be more.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic structural view of an oxygen exchange device for aquaculture according to the present invention.

Fig. 2 is a schematic structural diagram of the intelligent oxygen supply regulating device of the invention.

Fig. 3 is a detailed schematic diagram of the component structure of the intelligent oxygen supply regulating device.

Fig. 4 is a schematic view showing the use of the intelligent oxygen supply regulating device of the present invention.

Fig. 5 is a schematic diagram of the intelligent oxygen supply regulating device according to the second embodiment of the present invention.

In the figure: a movable wheel-1, an intelligent oxygen supply adjusting device-2, a device shell-3, a controller-4, a fixed handle-5, a power line-6, an output pipe-7, a radiator-8, a power adjusting device-21, a power conveying device-22, a pressurized air inlet device-23, a sealing jacking device-24, a filtering oxygen making device-25, an oxygen receiving sealing device-26, a limit block-211, a telescopic rod-212, an electromagnet-213, a shell frame-214, a spring-215, a gear-216, a wheel shaft-217, a carriage-218, a sealing bracket-219, a matching wheel-2110, a middle rotating wheel-2111, a transmission wheel-2112, a transmission belt-2113, an ash collecting chamber-221, a blade shaft-222, a gear set-223, a gear set-2112, A vane frame-224, a mounting cabin-225, a transmission shaft-226, a driving shaft-227, a double-head motor-228, an auxiliary shaft-229, a pneumatic pipe-231, a first fixed seat-232, a mounting frame-233, an air inlet pipe-234, a loop pipe-235, a negative pressure fan-236, a joint frame-237, a fixed block-241, a sliding frame-242, a fluted disc-243, a fixed plate-244, a rack-245, a limit frame-246, a rotating column-247, an adjusting frame-248, a sliding groove-249, an electrified frame-251, an embedded frame-252, a protective frame-253, a sun gear shaft-254, a bearing-255, a tooth socket frame-256, a planet gear-257, a support shaft-258, a second fixed seat-259, a zeolite frame-2510, a power transmission shaft, Support frame-261, exit frame-262, embedded block-263, expansion bracket-264, steel cable-265, beam frame-266, floating cushion-267 and collection cabin-268.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

Referring to fig. 1-5, the present invention provides a technical solution of an oxygen exchange device for aquaculture: the structure includes: remove wheel 1, intelligent oxygen suppliment adjusting device 2, device casing 3, controller 4, fixed handle 5, power cord 6, output tube 7, radiator 8, remove two liang of mutual parallels of wheel 1 and install perpendicularly in four corners of device casing 3 lower surface, the lower extreme of embedding device casing 3 inside in intelligent oxygen suppliment adjusting device 2 connects into an integrated structure through the welded mode with it simultaneously, controller 4 is parallel to each other with intelligent oxygen suppliment adjusting device 2, simultaneously controller 4 is connected with intelligent oxygen suppliment adjusting device 2 electricity of embedding device casing 3 inside, fixed handle 5 is located the central of device casing 3 upper surface and is in the same place with device casing 3 fixed connection simultaneously, the inside of embedding device casing 3 in power cord 6 is connected with intelligent oxygen suppliment adjusting device 2 electricity, output tube 7 link up mutually with the right side surface of device casing 3 and is in the same place with its mechanical connection simultaneously, the radiator 8 is fixedly arranged below the output pipe 7 and is fixedly connected with the device shell 3;

the intelligent oxygen supply adjusting device 2 is provided with a power adjusting device 21, a power conveying device 22, a pressurized air inlet device 23, a sealing jacking device 24, a filtering oxygen making device 25 and an oxygen receiving sealing device 26;

the right side surface of the oxygen receiving sealing device 26 positioned in the equipment is connected with the equipment in a welding mode, the inner side surface of the oxygen receiving sealing device 26 is embedded in the power adjusting device 21 and is in clearance fit with the oxygen receiving sealing device 26, the power conveying device 22 is positioned on the left side surface of the power adjusting device 21 and is meshed and connected together, the sealing and filtering oxygen generating device 25 is arranged on the left side surface of the power adjusting device 21 and is connected together through a shaft, the sealing and ejecting device 24 is parallel to the filtering and oxygen generating device 25 and is connected together with the power adjusting device 21 in clearance fit through a belt body, the pressurizing and air inlet device 23 is positioned on the left side surface of the sealing and ejecting device 24 and is welded together with the sealing and ejecting device to form an integrated structure, the power adjusting device 21 is provided with a limiting block 211, an expansion rod 212, an electromagnet 213, a shell frame 214, The device comprises a spring 215, a gear 216, a wheel shaft 217, a carriage 218, a sealing support 219, a matching wheel 2110, a middle rotating wheel 2111, a transmission wheel 2112 and a transmission belt 2113, wherein the gear 216 is arranged on the upper surface of the telescopic rod 212 and is perpendicular to the upper surface of the telescopic rod 212, the limiting block 211 is fixedly arranged on the outer side surface of the telescopic rod 212 and is connected together in a welding mode, the spring 215 wraps the outer side surface of the telescopic rod 212 and is connected together in a clearance fit mode, the shell frame 214 is perpendicular to the lower surface of the telescopic rod 212 and is movably connected with the lower surface of the telescopic rod, the electromagnet 213 is arranged in the shell frame 214 and is movably connected with the shell frame 214, the wheel shaft 217 is positioned on the right side surface of the gear 216 and is vertically meshed together, the middle rotating wheel 2111 and the wheel 217 are parallel to each other and are connected together in a clearance fit mode through the transmission, the sealing bracket 219 is mounted on the front surface of the fitting wheel 2110 by means of hinge connection, the sealing bracket 219 is embedded in the inner side surface of the carriage 218 and is fitted together with the inner side surface of the carriage, the transmission wheel 2112 and the intermediate transmission wheel 2111 are perpendicular to each other and form an integrated structure through the transmission belt 2113, the power transmission device 22 is provided with an ash collecting chamber 221, a blade shaft 222, a gear set 223, a blade frame 224, a mounting cabin 225, a transmission shaft 226, a driving shaft 227, a double-end motor 228 and an auxiliary shaft 229, the driving shaft 227 and the auxiliary shaft 229 are parallel to each other and are respectively and perpendicularly embedded in the left side surface and the right side surface of the double-end motor 228, the driving shaft 227 and the auxiliary shaft 229 are connected together in clearance fit, the transmission shaft 226 is vertically engaged with the upper surface of the auxiliary shaft 229 to form an integrated structure, the gear set 223 is disposed on the, the vane shaft 222 is arranged on the left and right sides of the gear set 223 and movably connected with the gear set 223, the vane shaft 222 is embedded in the installation chamber 225 and movably connected with the same, the vane shaft 222 is arranged on the left side surface of the vane frame 224 and is connected with the same in a welding mode, the dust collection chamber 221 is parallel to the left and right sides of the installation chamber 225 and is fixedly connected with the same, the pressurized air inlet device 23 is provided with an air pressure pipe 231, a first fixed seat 232, an installation frame 233, an air inlet pipe 234, a clip pipe 235, a negative pressure fan 236 and a joint frame 237, the joint frame 237 is arranged on the left side surface of the air pressure pipe 231 and is welded with the air pressure pipe 231, the clip pipe 235 is arranged on the left side surface of the joint frame 237 and is fixedly connected with the joint frame 237, the air inlet pipe 234 is communicated with the left side surface of the clip pipe 235, the installation frame 233 is vertically arranged on the upper surface of the first fixed, the negative-pressure fan 236 is fixedly installed on the upper surface of the mounting frame 233 and is embedded inside the return pipe 235, the sealing jacking device 24 is provided with a fixed block 241, a sliding frame 242, a fluted disc 243, a fixed plate 244, a rack 245, a limiting frame 246, a rotating column 247, an adjusting frame 248 and a sliding groove 249, the adjusting frame 248 is vertically welded on the upper surface of the rotating column 247, the sliding groove 249 is arranged on the outer side surface of the rotating column 247 and is movably connected with the outer side surface of the rotating column 247, the limiting frame 246 is embedded inside the sliding groove 249 and is movably connected with the sliding groove 249, the fluted disc 243 is installed on the front surface of the limiting frame 246 in a hinge connection mode, the rack 245 and the fixed plate 244 are parallel to each other and are connected together in a clearance fit mode, the fixed block 241 is an integrated structure formed by welding the rack 245 while extending the vertical axis of the rack 245, and the fixed block 241 is vertically, the filtering oxygen-making device 25 is provided with an electrifying frame 251, an inner embedded frame 252, a protective frame 253, a sun wheel shaft 254, a bearing 255, a tooth socket frame 256, a planet wheel 257, a support shaft 258, a second fixed seat 259 and a zeolite frame 2510, wherein the protective frame 253 is vertically embedded into the inner embedded frame 252 and movably connected with the inner embedded frame 252, the zeolite frame 2510 is vertically combined with the inner side surface of the protective frame 253 and the inner side of the protective frame 253 to form an integrated structure, the electrifying frame 251 is positioned on the lower surface of the protective frame 253 and is mutually vertical to the protective frame 253 and forms an integrated structure with the protective frame 253, the sun wheel shaft 254 is embedded into the bearing 255 and is connected with the bearing 255 in a clearance fit manner, the inner part of the sun wheel shaft 254 embedded into the tooth socket frame 256 is simultaneously meshed with the tooth socket frame 256, the planet wheel 257 is positioned between the sun wheel shaft 254 and the tooth socket frame 256, the support shaft 258 is installed on the front surface of the planet wheel 257 in a welding mode, the second fixing seat 259 is vertically installed on the upper surface of the protection frame 253 and fixedly connected with the protection frame 253 to form an integrated structure, the support shaft 258 wraps the outer side surface of the second fixing seat 259 and is movably connected with the second fixing seat 259, the oxygen collecting and sealing device 26 is provided with a support frame 261, an outlet frame 262, an embedded block 263, an expansion frame 264, a steel rope 265, a beam frame 266, a floating pad 267 and a collecting chamber 268, the collecting chamber 268 is located on the upper surface of the support frame 261, the two collecting chamber 268 are mutually vertical and fixedly connected with the support frame 261, the floating pad 267 is arranged inside the collecting chamber 268 and is connected with the collecting chamber 268 in a clearance fit mode, the beam frame 266 is installed on the front surface of the floating pad 267 in a hinge connection mode and is fixedly connected with the floating pad 267, the steel rope 265 and the expansion frame 264 are parallel up and down and are installed on 266, said exit frame 262 being disposed on the right side surface of the collection chamber 268 and being cooperatively connected with the collection chamber 268 thereof.

The pressurized gas inlet means 23 of the present invention refers to a switching means for pumping the external gas into the interior of the apparatus.

When the device is used, after the device is powered on, the internal negative pressure fan 236 is powered on to rotate, external air pressure is compressed into the return pipe 235 through the air inlet pipe 234, then the air pressure enters the air pressure pipe 231 through the return pipe 235, the power motor 228 is powered on, the auxiliary shaft 229 and the driving shaft 227 rotate under the electromagnetic induction of the power motor 228, the auxiliary shaft 229 drives the transmission shaft 226 to perform meshing rotation, the transmission shaft 226 transmits power upwards, the gear set 223 is driven under the meshing action, necessary rotating power can be provided for the blade shafts 222, meanwhile, the blade frame 224 can also rotate together, the internal cooling and dust cleaning work is achieved, when the zeolite frame 2510 needs to be converted, the repulsive force generated after the electromagnet 213 is powered on enables the telescopic rod 212 to extend out of the jacking gear 216 to relay the power of the driving shaft 267 to the wheel shaft 217, and then the rotating power is transmitted to the upper transfer wheel 2111 through the transfer belt 2113 by the wheel shaft 217 to enable the runner 2111 to rotate Then the power is transmitted by the sun wheel shaft 254, so as to drive the planet wheel 257 inside to displace and rotate on the gear groove 256, and the rotation drives the support shaft 258 to displace, and the second fixing seat 259 wrapped by the support shaft 258 can be pressed to make the protective frame 253 descend and be embedded into the inner embedded frame 252, so that the zeolite rack 2510 on the inner embedded frame 252 can be replaced, the zeolite inside is heated by the electrifying frame 251, oxygen is replaced according to different adsorptivity of nitrogen and oxygen, thereby completing uninterrupted oxygen generation and replacement, and simultaneously the transmission belt 2113 can drive the adjusting frame 248 to rotate the chute 249 to form different paths in the rotating process so that the limiting frame 246 drives the fluted disc 243 to press down or pull out the rack 245, and simultaneously, the fixed block 241 can be sealed and filtered or pulled up for cleaning, after the oxygen inside is sufficient, the sealing support 219 can be pressed down and sealed by the matching wheel 2110 to seal the pressure pipe 231, the oxygen inside the collection chamber 268 is stored inside the floating pad 267, and the balance bracket 266 can be pulled up after the floating pad 267 rises to a certain degree, so that the collection chamber 268 is opened to allow the oxygen inside to enter the water tank, and the oxygen exchange operation is performed by deflection.

The invention solves the problems that the oxygen generation work of the device can not be continuously carried out by the oxygen exchange equipment when the oxygen exchange equipment works, simultaneously impurities can not be filtered in advance, and the stored and collected oxygen can not be released when the oxygen exchange equipment needs to be released, so that the device can not be more perfect and intelligent.

While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (8)

1. An oxygen exchange device for aquaculture, which structurally comprises: remove wheel (1), intelligent oxygen suppliment adjusting device (2), device casing (3), controller (4), fixed handle (5), power cord (6), output tube (7), radiator (8), its characterized in that:

two liang of being parallel to each other and install perpendicularly in four corners of device casing (3) lower surface in the removal wheel (1), the inside lower extreme of embedding device casing (3) in intelligence oxygen suppliment adjusting device (2) connects into integral structure through the welded mode with it simultaneously, controller (4) and intelligence oxygen suppliment adjusting device (2) are parallel to each other, simultaneously controller (4) are connected with the inside intelligence oxygen suppliment adjusting device (2) electricity of embedding device casing (3) in, fixed handle (5) are located the central authorities of device casing (3) upper surface and are in the same place with device casing (3) fixed connection simultaneously, the inside of embedding device casing (3) in power cord (6) is connected with intelligence oxygen suppliment adjusting device (2) electricity, output tube (7) link up each other with the right side surface of device casing (3) and are in the same place rather than mechanical connection simultaneously, the radiator (8) is fixedly arranged below the output pipe (7) and is fixedly connected with the device shell (3);

the intelligent oxygen supply adjusting device (2) is provided with a power adjusting device (21), a power conveying device (22), a pressurized air inlet device (23), a sealing jacking device (24), a filtering oxygen making device (25) and an oxygen receiving sealing device (26);

the right side surface that receives oxygen sealing device (26) and be located the inside of equipment links together through the welded mode with equipment simultaneously, the inboard surface that receives oxygen sealing device (26) is inlayed in power adjusting device (21) and adopts clearance fit with receiving oxygen sealing device (26), power transmission device (22) are located both meshing of the left side surface of power adjusting device (21) and are linked together, filtration oxygenerator (25) are located the left side surface of power adjusting device (21) and are connected together through the axle, sealed top moving device (24) are parallel to each other and are connected together through the area body and power adjusting device (21) adoption clearance fit with filtering oxygenerator (25), pressurized air inlet unit (23) are located the left side surface that sealed top moving device (24) and weld into integral structure with it simultaneously.

2. An aquaculture oxygen exchange device according to claim 1, characterized in that: the power adjusting device (21) is provided with a limiting block (211), an expansion rod (212), an electromagnet (213), a shell frame (214), a spring (215), a gear (216), a wheel shaft (217), a sliding frame (218), a sealing support (219), a matching wheel (2110), a transfer wheel (2111), a transmission wheel (2112) and a transmission belt (2113).

3. An aquaculture oxygen exchange device according to claim 2, characterized in that: the upper surface of the telescopic rod (212) is provided with a gear (216) and vertical to each other, the limiting block (211) is fixedly installed on the outer side surface of the telescopic rod (212) and connected together in a welding mode, the spring (215) wraps the outer side surface of the telescopic rod (212) and is connected together in a clearance fit mode, the shell frame (214) is vertical to the lower surface of the telescopic rod (212) and is movably connected with the lower surface of the telescopic rod, the electromagnet (213) is arranged in the shell frame (214) and is movably connected with the shell frame (214), the wheel shaft (217) is positioned on the right side surface of the gear (216) and vertically meshed together, the middle rotating wheel (2111) and the wheel shaft (217) are parallel to each other and are connected together in a clearance fit mode through a transmission belt (2113), the matching wheel (2110) is arranged on the right side surface of the middle rotating wheel (2111) and is meshed, the sealing support (219) is installed on the front surface of the matching wheel (2110) in a hinged connection mode, the sealing support (219) is embedded into the inner side surface of the sliding frame (218) and matched with the sliding frame, and the transmission wheel (2112) and the middle rotating wheel (2111) are perpendicular to each other and form an integrated structure through the transmission belt (2113).

4. An aquaculture oxygen exchange device according to claim 1, characterized in that: the power transmission device (22) is provided with an ash collecting chamber (221), a blade shaft (222), a gear set (223), a blade frame (224), an installation cabin (225), a transmission shaft (226), a driving shaft (227), a double-end motor (228) and an auxiliary shaft (229), wherein the driving shaft (227) and the auxiliary shaft (229) are parallel to each other and are respectively and vertically embedded into the left side surface and the right side surface of the double-end motor (228), the driving shaft (227), the auxiliary shaft (229) and the double-end motor (228) are connected together in a clearance fit manner, the transmission shaft (226) is vertically meshed with the upper surface of the auxiliary shaft (229) to form an integrated structure, the gear set (223) is arranged on the upper side surface of the transmission shaft (226) and is connected together in a welding manner, the blade shaft (222) is arranged on the left side surface and the right side surface of the, the blade shaft (222) is embedded into the installation cabin (225) and movably connected with the installation cabin, the blade shaft (222) is positioned on the left side surface of the blade frame (224) and is connected with the left side surface of the blade frame in a welding mode, and the dust collection chamber (221) is parallel to the installation cabin (225) from left to right and is fixedly connected with the installation cabin.

5. An aquaculture oxygen exchange device according to claim 1, characterized in that: pressurization air inlet unit (23) are equipped with pneumatic tube (231), first fixing base (232), mounting bracket (233), intake pipe (234), return shape pipe (235), negative-pressure air fan (236), joint frame (237) are located the left surface of pneumatic tube (231) and are in the same place with pneumatic tube (231) welding simultaneously, return the left surface that shape pipe (235) were located joint frame (237) and with joint frame (237) fixed connection together, intake pipe (234) link up each other with the left surface of returning shape pipe (235), mounting bracket (233) vertical installation is in the upper surface of first fixing base (232) and links together through the welded mode simultaneously, negative-pressure air fan (236) fixed mounting embeds the inside of returning shape pipe (235) simultaneously in the upper surface of mounting bracket (233).

6. An aquaculture oxygen exchange device according to claim 1, characterized in that: the sealing and jacking device (24) is provided with a fixed block (241), a sliding frame (242), a fluted disc (243), a fixed plate (244), a rack (245), a limiting frame (246), a rotating column (247), an adjusting frame (248) and a sliding groove (249), wherein the adjusting frame (248) is vertically welded on the upper surface of the rotating column (247), the sliding groove (249) is arranged on the outer side surface of the rotating column (247) and is movably connected with the outer side surface of the rotating column (247), the limiting frame (246) is embedded into the sliding groove (249) and is movably connected with the sliding groove (249), the fluted disc (243) is arranged on the front surface of the limiting frame (246) in a hinge connection mode, the rack (245) and the fixed plate (244) are parallel to each other and are connected together in a clearance fit mode, the fixed block (241) is an integrated structure formed by welding the rack (245) together when the, the fixed block (241) is vertically embedded into the sliding frame (242) and movably matched with the sliding frame to form an integrated structure.

7. An aquaculture oxygen exchange device according to claim 1, characterized in that: the filtering oxygen-making device (25) is provided with an electrifying frame (251), an embedded frame (252), a protective frame (253), a sun gear shaft (254), a bearing (255), a toothed rack (256), a planet gear (257), a support shaft (258), a second fixed seat (259) and a zeolite rack (2510), wherein the protective frame (253) is vertically embedded into the embedded frame (252) and movably connected with the embedded frame (252), the zeolite rack (2510) is vertically arranged on the inner side surface of the protective frame (253) and forms an integrated structure with the inner side of the protective frame (253), the electrifying frame (251) is arranged on the lower surface of the protective frame (253) and is mutually vertical to the protective frame (253) and forms an integrated structure with the protective frame, the sun gear shaft (254) is embedded into the bearing (255) and is connected with the bearing (255) in a clearance fit manner, the inner part of the sun gear shaft (254) embedded into the toothed rack (256) is simultaneously meshed with the toothed rack (256), the planet gear (257) is located between the sun gear shaft (254) and the gear groove frame (256) and is connected with the sun gear shaft and the gear groove frame through meshing to form an integrated structure, the support shaft (258) is installed on the front surface of the planet gear (257) in a welding mode, the second fixing seat (259) is vertically installed on the upper surface of the protective frame (253) and is fixedly connected with the protective frame (253) to form an integrated structure, and the support shaft (258) wraps the outer side surface of the second fixing seat (259) and is movably connected with the second fixing seat (259).

8. An aquaculture oxygen exchange device according to claim 1, characterized in that: the oxygen-collecting sealing device (26) is provided with a support frame (261), an outlet frame (262), an embedded block (263), an expansion bracket (264), a steel rope (265), a cross beam frame (266), a floating pad (267) and a collecting cabin (268), the collection cabin (268) is positioned on the upper surface of the support frame (261), the collection cabin and the support frame are perpendicular to each other and fixedly connected with each other, the floating cushion (267) is arranged inside the collecting cabin (268) and is connected with the collecting cabin (268) by adopting clearance fit, the cross beam frame (266) is mounted to the front surface of the floating mat (267) by means of a hinge connection while being fixedly coupled thereto, the steel rope (265) is vertically parallel to the telescopic frame (264) and is simultaneously installed on the lower surface of the beam frame (266) through the steel rope (265) in an integrated structure, the outlet frame (262) is arranged on the right side surface of the collecting chamber (268) and is matched and connected with the collecting chamber (268) of the outlet frame.

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