CN111727920B - Pond is bred with floating formula material throwing oxygenation intelligence all-in-one - Google Patents

Abstract

The invention provides a floating type material throwing and oxygen increasing intelligent all-in-one machine for fish pond culture, which comprises two floating support plates, a plurality of transverse support rods, a material throwing and oxygen increasing mechanism and a foam breaking and oxygen increasing mechanism, wherein the two floating support plates are used for supporting equipment to float on the water surface, the transverse support rods are used for connecting the two floating support plates, the material throwing and oxygen increasing mechanism is used for throwing materials and increasing oxygen, the foam breaking and oxygen increasing mechanism is used for breaking oxygen increasing bubbles, the plurality of transverse support rods are fixedly connected to the surfaces of the floating support plates, and the fish pond culture field is related. This pond is bred and throws material oxygenation intelligence all-in-one with floating according to the oxygenation scheduling problem that exists among the current pond feeding process, design special mechanism, mutually support between each mechanism, enlarge in step and throw and feed, oxygenation and the scope of disinfecting to effectual solution generally when throwing something and feeding the shoal of fish, the fish material is comparatively concentrated, aeration equipment is difficult to satisfy the shoal of fish to the needs of oxygen, and then lead to throwing something and feeding equipment and aeration equipment to increase, lead to the energy consumption increase, increase the problem of cost of breeding to a certain extent.

Description

Pond is bred with floating formula material throwing oxygenation intelligence all-in-one

Technical Field

The invention relates to the technical field of culture, in particular to a floating type material throwing and oxygen increasing intelligent integrated machine for fishpond culture.

Background

An automatic aerator and a throwing machine are needed to be used in the fish pond culture process, wherein the throwing machine is a device for throwing fish materials, when the automatic aerator is used, the fish materials are thrown in a fish pond, cultured fish can swim, the automatic aerator is a device for carrying out underwater oxygen aeration, when the fish pond throws the fish materials, fish swarms can be gathered, the demand of the fish swarms on oxygen in water is increased, the fish swarms are fed for a long time, particularly when the fish swarms are large, the fish swarms are limited, the feeding time is long, the fish quantity is large, the oxygen demand is larger, the general automatic aerator is difficult to concentrate the fish materials during oxygen aeration, the concentrated fish swarms are subjected to concentrated oxygen aeration, the throwing range of the throwing equipment is limited, one fish pond needs to be provided with more devices for feeding, and more devices are arranged for aerating the fish swarms, so that the energy consumption of the equipment is increased, generally when throwing something and feeding the shoal of fish, the fish material is comparatively concentrated, and oxygen equipments are difficult to satisfy the shoal of fish to the needs of oxygen, and then lead to throwing something and feeding equipment and oxygen equipments to increase, lead to the energy consumption increase, increase the cost of breeding to a certain extent, so need a pond breed with floating formula throw material oxygenation intelligence all-in-one.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides a floating type material throwing and oxygen increasing intelligent all-in-one machine for fish pond culture, which solves the problems that when fish schools are generally fed, fish materials are concentrated, oxygen increasing equipment cannot meet the requirement of the fish schools for oxygen easily, feeding equipment and the oxygen increasing equipment are increased, energy consumption is increased, and culture cost is increased to a certain extent.

(II) technical scheme

In order to achieve the purpose, the invention is realized by the following technical scheme: the utility model provides a pond is bred with floating material oxygenation intelligence all-in-one of throwing, is used for two showy backup pads that the support equipment floats on the surface of water, a plurality of be used for connecting the transverse strut of two showy backup pads, be used for throwing the material oxygenation mechanism of material and oxygenation and be used for the broken bubble oxygenation mechanism of broken oxygenation bubble, the fixed surface of showy backup pad is connected with a plurality of transverse strut, throw the material oxygenation mechanism and set up on the transverse strut, the setting of broken bubble oxygenation mechanism is in throwing the material oxygenation mechanism.

Preferably, throw material oxygenation mechanism is including throwing workbin, high-pressure immersible pump, ozone generator, synthesizing distributing pipe and total controlling device, throw workbin fixed connection is on the spreader bar, the inside of throwing the workbin is provided with the blanking chamber, throws material chamber and cabin, the cabin sets up in the below of throwing the material chamber, the blanking chamber is located the top of throwing the material chamber, the blanking chamber with throw the material chamber intercommunication, the top fixedly connected with inlet pipe in blanking chamber, the one end of inlet pipe runs through and extends to the outside of throwing the workbin, the inside fixed mounting of cabin has the motor, the output shaft of motor passes through shaft coupling fixedly connected with pivot, the fixed surface of pivot is connected with throws the material blade, the surface of throwing the material blade is the L shape, the inner wall of throwing the material chamber is the V shape, the inner wall contained angle of throwing the material chamber is the degree.

Preferably, the lower fixed surface of spreader bar is connected with extends the bracing piece, the one end fixed mounting that the spreader bar was kept away from to extend the bracing piece has high-pressure immersible pump, ozone generator fixed mounting is on throwing the workbin, the gas-supply pipe has been cup jointed to ozone generator's output, the one end of gas-supply pipe runs through the throwing workbin and extends to the below of throwing the workbin, the surface of gas-supply pipe and the fixed surface of spreader bar are connected, the one end fixedly connected with of throwing the workbin is kept away from to the gas-supply pipe synthesizes the distribution pipe, the gas-supply pipe does not communicate with synthesizing the distribution pipe.

Preferably, the output of high-pressure immersible pump runs through and extends to the inside of synthesizing the distributing pipe, the fixed surface of synthesizing the distributing pipe has cup jointed three spray pipe, each the one end that synthesizes the distributing pipe was kept away from to the spray pipe has all cup jointed the connecting pipe, each the broken oxygenation pipe has all been cup jointed to the one end that the spray pipe was kept away from to the connecting pipe, the surface of gas-supply pipe has cup jointed three and the negative straw of connecting pipe one-to-one, the one end that the gas-supply pipe was kept away from to the negative straw cup joints with the surface of connecting pipe.

Preferably, total controlling means fixed mounting is on throwing the workbin, be provided with the control switch of a plurality of individual control high-pressure submersible pump work on the total controlling means, be provided with the control switch of a plurality of individual control motor on the total controlling means, be provided with the control switch of individual control ozone generator work on the total controlling means, fixed mounting has infrared receiver on the total controlling means, infrared receiver's output and the input signal control of total controlling means are connected, part the output of the control switch on the total controlling means is connected with the input electricity of motor, part the output of the control switch on the total controlling means is connected with the input electricity of high-pressure submersible pump.

Preferably, the bubble breaking and oxygen increasing mechanism is arranged inside the breaking oxygen increasing pipe and comprises a plurality of elastic tennis balls distributed in a staggered manner and a plurality of pressurizing balls corresponding to the elastic tennis balls one by one, each elastic tennis ball distributed in a staggered manner is arranged inside the breaking oxygen increasing pipe, the surface of each elastic tennis ball is in a hollowed-out net shape, each elastic tennis ball is made of spring steel, and three spring wires distributed in a triangular shape are fixedly connected between every two adjacent elastic tennis balls.

Preferably, the inner wall fixedly connected with fixed steel ring of elasticity tennis, annular channel has been seted up on the surface of fixed steel ring, the pressure boost ball sets up the inside at the elasticity tennis, the fixed surface of pressure boost ball is connected with a plurality of shivering bubble flabellum, a plurality of the shivering bubble flabellum is the circumference and distributes on the surface of pressure boost ball, adjacent two the shivering bubble flabellum direction of rotation of the inside of elasticity tennis is different, the top of shivering bubble flabellum all inlays and has the ball, the surface of ball and the inner wall sliding connection of channel, the surface of pressure boost ball inlays and has spacing pearl, spacing pearl is located the both sides of shivering bubble flabellum, the inner wall fixedly connected with arc steel frame of broken oxygenation pipe, fixedly connected with wire net on the arc steel frame, the surface of the elasticity tennis that is closest to the wire net is connected with the surface fixed of wire net.

(III) advantageous effects

(1) According to the fish feeding device, the material throwing and oxygen increasing mechanism is arranged to throw fish materials at a certain angle, and then concentrated oxygen increasing is performed on fish flocks under the fish materials by utilizing water flow jet oxygen increasing, so that the requirements of the fish flocks are met, the oxygen increasing range is overlapped with the feeding range, the output power of the material throwing can be increased by throwing the materials at a certain angle, the material throwing distance is further, the waste caused by throwing the materials in the circumferential direction to the bank side is avoided, and the ozone oxygen increasing can achieve a good sterilizing effect.

(2) According to the invention, by arranging the broken bubble oxygenation mechanism, on one hand, a fine bubble layer is generated below the fish school, the fine bubbles in the bubble layer are more easily dissolved in water to oxygenate the water, and the breaking speed of the broken bubbles is faster when the flow rate of the water is higher, so that the water flow speed can be self-adapted to change, a stable bubble layer can be formed, on the other hand, the fine bubble layer can play a role in floating and supporting the fish materials, the fish material throwing-out force is matched with the buoyancy of the bubbles, so that the fish material range and the oxygenation range can be synchronously diffused, the fish school density is further reduced, the use of equipment is reduced, and the energy consumption is reduced.

(3) According to the invention, special mechanisms are designed according to the problems of oxygenation and the like existing in the existing fishpond feeding process, and the mechanisms are matched with each other to synchronously expand the feeding, oxygenation and sterilization ranges, so that the problems that generally when fish flocks are fed, fish materials are concentrated, oxygenation equipment cannot meet the requirement of the fish flocks on oxygen easily, feeding equipment and the oxygenation equipment are increased, energy consumption is increased, and breeding cost is increased to a certain extent are solved.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a cross-sectional view of the structure of the throwing box of the present invention;

FIG. 3 is a sectional view of the crushing aerator according to the present invention;

FIG. 4 is an enlarged view of the structure of FIG. 3 according to the present invention.

The device comprises a floating support plate 1, a horizontal support rod 2, a material throwing and oxygen increasing mechanism 3, a material throwing box 31, a high-pressure submersible pump 32, an ozone generator 33, a comprehensive distribution pipe 34, a general control device 35, a material dropping cavity 36, a material throwing cavity 37, a cabin 38, a material feeding pipe 39, a motor 310, a rotating shaft 311, a material throwing blade 312, an extension support rod 313, a gas conveying pipe 314, a water spraying pipe 315, a connecting pipe 316, a crushing and oxygen increasing pipe 317, a negative suction pipe 318, an infrared receiver 319, a foam breaking and oxygen increasing mechanism 4, elastic tennis balls 41, pressure increasing balls 42, spring wires 43, fixed steel rings 44, annular channels 45, foam breaking fan blades 46, ball bearings 47, limiting balls 48, an arc steel frame 49 and a steel wire mesh 410.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1-4, an embodiment of the invention provides a floating type intelligent fish pond culturing and throwing oxygen increasing all-in-one machine, which comprises two floating support plates 1 used for supporting equipment to float on the water surface, a plurality of transverse support rods 2 used for connecting the two floating support plates 1, a material throwing oxygen increasing mechanism 3 used for throwing materials and increasing oxygen, and a foam breaking oxygen increasing mechanism 4 used for breaking oxygen increasing bubbles, wherein the surface of each floating support plate 1 is fixedly connected with the plurality of transverse support rods 2, the material throwing oxygen increasing mechanism 3 is arranged on the transverse support rods 2, and the foam breaking oxygen increasing mechanism 4 is arranged on the material throwing oxygen increasing mechanism 3.

The throwing oxygenation mechanism 3 comprises a throwing box 31, a high-pressure submersible pump 32, an ozone generator 33, a comprehensive distribution pipe 34 and a master control device 35, the throwing box 31 is fixedly connected to the transverse strut 2, a blanking cavity 36, a throwing cavity 37 and a cabin 38 are arranged inside the throwing box 31, the cabin 38 is arranged below the throwing cavity 37, the blanking cavity 36 is positioned above the throwing cavity 37, the blanking cavity 36 is communicated with the throwing cavity 37, the top of the blanking cavity 36 is fixedly connected with a feed pipe 39, one end of the feed pipe 39 penetrates through and extends to the outside of the throwing box 31, a motor 310 is fixedly installed inside the cabin 38, an output shaft of the motor 310 is fixedly connected with a rotating shaft 311 through a coupler, the surface of the rotating shaft 311 is fixedly connected with a throwing blade 312, the surface of the throwing blade 312 is L-shaped, the inner wall of the throwing cavity 37 is V-shaped, the included angle of the inner wall of the throwing cavity 37 is 140 degrees, the lower surface of the transverse strut 2 is fixedly connected with an extending support rod 313, a high-pressure submersible pump 32 is fixedly installed at one end of the extension support bar 313 far away from the transverse support bar 2, an ozone generator 33 is fixedly installed on the polishing box 31, an output end of the ozone generator 33 is sleeved with an air pipe 314, one end of the air pipe 314 penetrates through the polishing box 31 and extends to the lower part of the polishing box 31, the surface of the air pipe 314 is fixedly connected with the surface of the transverse support bar 2, one end of the air pipe 314 far away from the polishing box 31 is fixedly connected with a comprehensive distribution pipe 34, the air pipe 314 is not communicated with the comprehensive distribution pipe 34, the output end of the high-pressure submersible pump 32 penetrates through and extends to the inside of the comprehensive distribution pipe 34, three water spray pipes 315 are fixedly sleeved on the surface of the comprehensive distribution pipe 34, one end of each water spray pipe 315 far away from the comprehensive distribution pipe 34 is sleeved with a connection pipe 316, one end of each connection pipe 316 far away from the water spray pipe 315 is sleeved with a crushing oxygenation pipe 317, and the surface of the air pipe 314 is sleeved with three negative suction pipes 318 corresponding to the connection pipe 316 one to one, one end of the negative suction pipe 318, which is far away from the gas pipe 314, is sleeved on the surface of the connecting pipe 316, the master control device 35 is fixedly installed on the polishing box 31, a plurality of control switches for individually controlling the work of the high-pressure submersible pump 32 are arranged on the master control device 35, a plurality of control switches for individually controlling the work of the motor 310 are arranged on the master control device 35, a control switch for individually controlling the work of the ozone generator 33 is arranged on the master control device 35, an infrared receiver 319 is fixedly installed on the master control device 35, the output end of the infrared receiver 319 is in signal control connection with the input end of the master control device 35, the output end of part of the control switches on the master control device 35 is electrically connected with the input end of the motor 310, and the output end of part of the control switches on the master control device 35 is electrically connected with the input end of the high-pressure submersible pump 32.

The bubble breaking oxygen increasing mechanism 4 is arranged inside the breaking oxygen increasing pipe 317, the bubble breaking oxygen increasing mechanism 4 comprises a plurality of elastic tennis balls 41 which are distributed in a staggered manner and a plurality of pressurizing balls 42 which are in one-to-one correspondence with the elastic tennis balls 41, each breaking oxygen increasing pipe 317 is internally provided with a plurality of elastic tennis balls 41 which are distributed in a staggered manner, the surfaces of the elastic tennis balls 41 are in a hollowed-out net shape, the elastic tennis balls 41 are made of spring steel, three spring wires 43 which are distributed in a triangular shape are fixedly connected between every two adjacent elastic tennis balls 41, the inner walls of the elastic tennis balls 41 are fixedly connected with fixed steel rings 44, the surfaces of the fixed steel rings 44 are provided with annular channels 45, the pressurizing balls 42 are arranged inside the elastic tennis balls 41, the surfaces of the pressurizing balls 42 are fixedly connected with a plurality of bubble breaking fan blades 46, the plurality of bubble breaking fan blades 46 are distributed on the surfaces of the pressurizing balls 42 in a circumferential manner, the rotating directions of the bubble breaking fan blades 46 inside the two adjacent elastic tennis balls 41 are different, the top end of the broken bubble fan blade 46 is inlaid with a ball 47, the surface of the ball 47 is in sliding connection with the inner wall of the channel, the surface of the pressurizing ball 42 is inlaid with a limiting ball 48, the limiting ball 48 is located on two sides of the broken bubble fan blade 46, the inner wall of the broken oxygenation pipe 317 is fixedly connected with an arc-shaped steel frame 49, a steel wire mesh 410 is fixedly connected onto the arc-shaped steel frame 49, and the surface of the elastic tennis ball 41 closest to the steel wire mesh 410 is fixedly connected with the surface of the steel wire mesh 410.

When the device is used, a power supply is connected, the master control device 35 is controlled by the remote control device, the high-pressure submersible pump 32 and the ozone generator 33 are controlled by the master control device 35 to work, the ozone generator 33 generates ozone, meanwhile, water sprayed from the output end of the high-pressure submersible pump 32 enters the comprehensive distribution pipe 34 and then enters the connecting pipes 316 through the water spraying pipes 315, the ozone in the air conveying pipe 314 is sucked into the connecting pipes 316 through the negative suction pipes 318 by means of suction force generated by high-speed water flow, the air-liquid mixed flow rate is increased, the ozone is rapidly mixed into liquid, then the air-liquid mixture enters the crushing and oxygen increasing pipes 317, the air-liquid flow inevitably drives the foam crushing blades 46 in the elastic tennis balls 41 to rotate, therefore, the elastic tennis balls 41 distributed in a staggered mode firstly perform primary fine crushing on the bubbles in the air-liquid, and then the rotating foam crushing blades 46 in the elastic tennis balls 41 rotate to further rapidly crush the bubbles from all directions Breaking is carried out to promote the emulsification of the fine bubbles, the fine bubbles are more easily dissolved in water, the closer the elastic tennis balls 41 are to each other when the flow rate of water is higher, the higher the impact force of water flowing through is, the faster the broken bubble fan blades 46 rotate, the pore diameters among the elastic tennis balls 41 can be squeezed and reduced, the higher the bubble emulsification efficiency is, bubbles pass through the convex arc-shaped steel frame 49 and then form a bubble layer below a fish school, the bubble layer rises to enrich oxygen and sterilize, when the motor 310 is started, fish feed is fed through the feed pipe 39, the fish feed enters the interior of the motor 37, the motor 310 drives the material throwing blade 312 to rotate through the rotating shaft 311 to throw the fish feed to an area with the sterilized oxygen enrichment, the fish school is gathered, the bubble layer continuously supplies oxygen to the fish school, meanwhile, the fine bubble layer can play a role of floatage supporting the fish feed, the fish feed throwing force is matched with the buoyancy of the bubbles to realize the synchronous diffusion of the fish feed range and the oxygen enrichment range, thereby reducing the fish population density.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (1)

1. The utility model provides a pond is bred with floating material oxygenation intelligence all-in-one of throwing, is used for throwing material oxygenation mechanism (3) and be used for garrulous bubble oxygenation mechanism (4) of broken oxygenation bubble that is used for supporting equipment to float two blocks of showy backup pads (1), a plurality of are used for connecting two blocks of stubble bars (2) that showy backup pads (1) on the surface of water, are used for throwing material oxygenation mechanism (3) of material and oxygenation, its characterized in that: the surface of the floating support plate (1) is fixedly connected with a plurality of transverse support rods (2), the throwing material oxygenation mechanism (3) is arranged on the transverse support rods (2), and the foam breaking oxygenation mechanism (4) is arranged on the throwing material oxygenation mechanism (3);

the foam breaking oxygenation mechanism (4) is arranged inside the breaking oxygenation pipe (317), the foam breaking oxygenation mechanism (4) comprises a plurality of elastic tennis balls (41) which are distributed in a staggered manner and a plurality of pressure increasing balls (42) which correspond to the elastic tennis balls (41) one by one, a plurality of elastic tennis balls (41) which are distributed in a staggered manner are arranged inside each breaking oxygenation pipe (317), the surface of each elastic tennis ball (41) is in a hollowed-out net shape, the elastic tennis balls (41) are made of spring steel, three spring wires (43) which are distributed in a triangular shape are fixedly connected between every two adjacent elastic tennis balls (41), a fixed steel ring (44) is fixedly connected to the inner wall of each elastic tennis ball (41), an annular channel (45) is formed in the surface of each fixed steel ring (44), and the pressure increasing balls (42) are arranged inside each elastic tennis ball (41), the surface of the pressurizing ball (42) is fixedly connected with a plurality of bubble breaking fan blades (46), the bubble breaking fan blades (46) are circumferentially distributed on the surface of the pressurizing ball (42), the rotating directions of the bubble breaking fan blades (46) in two adjacent elastic tennis balls (41) are different, balls (47) are inlaid at the top ends of the bubble breaking fan blades (46), the surfaces of the balls (47) are slidably connected with the inner wall of the channel, limiting balls (48) are inlaid on the surface of the pressurizing ball (42), the limiting balls (48) are located on two sides of the bubble breaking fan blades (46), the inner wall of the breaking oxygenation pipe (317) is fixedly connected with an arc-shaped steel frame (49), a steel wire mesh (410) is fixedly connected onto the arc-shaped steel frame (49), and the surface of the elastic tennis ball (41) closest to the steel wire mesh (410) is fixedly connected with the surface of the steel wire mesh (410);

the throwing material oxygenation mechanism (3) comprises a throwing material box (31), a high-pressure submersible pump (32), an ozone generator (33), a comprehensive distribution pipe (34) and a master control device (35), the throwing material box (31) is fixedly connected to a cross brace rod (2), a blanking cavity (36), a throwing material cavity (37) and a cabin (38) are arranged inside the throwing material box (31), the cabin (38) is arranged below the throwing material cavity (37), the blanking cavity (36) is positioned above the throwing material cavity (37), the blanking cavity (36) is communicated with the throwing material cavity (37), a feeding pipe (39) is fixedly connected to the top of the blanking cavity (36), one end of the feeding pipe (39) penetrates through and extends to the outside of the throwing material box (31), a motor (310) is fixedly installed inside the cabin (38), an output shaft of the motor (310) is fixedly connected with a rotating shaft (311) through a coupler, the surface of the rotating shaft (311) is fixedly connected with a material throwing blade (312), the surface of the material throwing blade (312) is L-shaped, the inner wall of the material throwing cavity (37) is V-shaped, the included angle of the inner wall of the material throwing cavity (37) is 140 degrees, the lower surface of the transverse supporting rod (2) is fixedly connected with an extension supporting rod (313), one end of the extension supporting rod (313) far away from the transverse supporting rod (2) is fixedly provided with a high-pressure submersible pump (32), an ozone generator (33) is fixedly arranged on the material throwing box (31), the output end of the ozone generator (33) is sleeved with an air pipe (314), one end of the air pipe (314) penetrates through the material throwing box (31) and extends to the lower part of the material throwing box (31), the surface of the air pipe (314) is fixedly connected with the surface of the transverse supporting rod (2), one end of the air pipe (314) far away from the material throwing box (31) is fixedly connected with a comprehensive distribution pipe (34), the gas transmission pipe (314) is not communicated with the comprehensive distribution pipe (34), the output end of the high-pressure submersible pump (32) penetrates through and extends to the inside of the comprehensive distribution pipe (34), three water spray pipes (315) are sleeved on the surface of the comprehensive distribution pipe (34), each water spray pipe (315) is sleeved on one end of the comprehensive distribution pipe (34), each connecting pipe (316) is sleeved on one end, away from the water spray pipes (315), of each connecting pipe (316), a crushing oxygenation pipe (317) is sleeved on one end of each connecting pipe (314), three negative suction pipes (318) in one-to-one correspondence with the connecting pipes (316) are sleeved on the surface of each gas transmission pipe (314), one end, away from the gas transmission pipes (314), of each negative suction pipe (318) is sleeved on the surface of each connecting pipe (316), the master control device (35) is fixedly installed on the material throwing box (31), and a plurality of control switches for independently controlling the high-pressure submersible pump (32) to work are arranged on the master control device (35), the intelligent ozone generator is characterized in that a plurality of control switches for independently controlling the motors (310) are arranged on the master control device (35), a control switch for independently controlling the operation of the ozone generator (33) is arranged on the master control device (35), an infrared receiver (319) is fixedly mounted on the master control device (35), the output end of the infrared receiver (319) is in signal control connection with the input end of the master control device (35), the output ends of some control switches on the master control device (35) are electrically connected with the input ends of the motors (310), and the output ends of some control switches on the master control device (35) are electrically connected with the input end of the high-pressure submersible pump (32);

when in use, the power supply is connected, the master control device (35) is controlled by the remote control device, the high-pressure submersible pump (32) and the ozone generator (33) are controlled by the master control device (35) to work, the ozone generator (33) generates ozone, meanwhile, water sprayed from the output end of the high-pressure submersible pump (32) enters the comprehensive distribution pipe (34) and then enters the inside of each connecting pipe (316) through the water spraying pipe (315), the ozone in the air conveying pipe (314) is sucked into the inside of each connecting pipe (316) through the negative suction pipe (318) by the suction force generated by high-speed water flow, the gas-liquid mixing flow rate is increased, the ozone is rapidly mixed into the liquid, then the gas-liquid mixture enters the inside of each crushing and oxygen increasing pipe (317), and the gas-liquid flowing can inevitably cause the rotation of the foam breaking fan blades (46) in each elastic tennis ball (41), therefore, the elastic tennis balls (41) distributed in a staggered mode firstly carry out primary fine crushing on water bubbles in gas and liquid, then the bubble crushing fan blades (46) rotating inside the elastic tennis balls (41) rotate quickly to further break the water bubbles from all directions to promote bubble fine emulsion, the bubbles are more easily dissolved in water, the closer the elastic tennis balls (41) are to each other when the flow rate of the water is higher, the higher the impact force of water flowing, the faster the bubble crushing fan blades (46) rotate, the pore diameters among the elastic tennis balls (41) can be extruded and reduced, the higher the bubble emulsion efficiency is, bubble layers are formed below fish groups after the bubbles pass through the convex arc-shaped steel frames (49), the bubble layers are increased in oxygen and sterilized, and fish materials are fed through the feed pipes (39) when the motor (310) is started, the fish material enters into the inside of (37), and motor (310) drive throwing material blade (312) through pivot (311) and rotate and shed the fish material to the oxygenation region of being disinfected, and shoal of fish gathers, and the bubble layer continues the oxygen suppliment to shoal of fish, and fine and close bubble layer can play the effect of floating the support fish material simultaneously, and the buoyancy of the dynamics of throwing out of fish material cooperation bubble can realize fish material scope and oxygenation scope synchronous diffusion, and then reduces shoal of fish intensive degree.

Images