CN216796203U - Oxygen supply mechanism for indoor high-density fishpond - Google Patents

Abstract

The utility model relates to the technical field of fishponds, in particular to an oxygen supply mechanism for an indoor high-density fishpond, which solves the problem of uneven oxygen supply in an indoor large fishpond in the prior art. An oxygen supply mechanism for an indoor high-density fishpond, comprising: the high-density oxygen supply pump is arranged at the center of the fishpond; the first air conveying pipe is communicated with the high-density oxygen supply pump. According to the oxygen supply mechanism for the fish pond, the oxygen is controlled to be output upwards through the aeration port on the upper end surface of the first gas pipe, so that the oxygen is conveyed from the bottom of the fish pond to the top of the fish pond, the second gas pipe rotates in an up-and-down arc-shaped limiting mode, oxygen is thrown into water above the fish pond, and therefore the oxygen is filled above the fish pond and below the fish pond to the maximum extent, the oxygen supply mechanism for the fish pond is uniform in oxygen supply, the output oxygen of the high-density oxygen supply pump can be fully utilized, and the uniformity of oxygen obtaining of fish in the fish pond is improved.

Description

Oxygen supply mechanism for indoor high-density fishpond

Technical Field

The utility model relates to the technical field of fishponds, in particular to an oxygen supply mechanism for an indoor high-density fishpond.

Background

All can be provided with the oxygen suppliment mechanism in the pond of breeding fish, the oxygen suppliment mechanism in the pond of breeding fish in current large-scale indoor is high density aeration oxygen-increasing machine.

High density aeration oxygen supply machine generally sets up the middle part at the fishpond when using, oxygen is put in to being on a parallel with the direction of radius to the oxygen supply machine is centrifugal, so, the oxygen content of bottom is higher in the fishpond, also can lead to the condition that the migratory fish gathered together bottom the fishpond, but only the bottom oxygen suppliment blowout in the fishpond, the power of oxygen supply machine can harm the migratory fish too big, so, the oxygen supply volume of fishpond bottom is limited, some migratory fish are at the abundant oxygen suppliment of bottom, other migratory fish are at the oxygen deficiency of top, this just leads to the inside oxygen uneven supply in fishpond, abundant utilization by the migratory fish, so, now provide an indoor oxygen suppliment mechanism for high density fishpond, solve above-mentioned problem.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an oxygen supply mechanism for an indoor high-density fish pond, which solves the problem of uneven oxygen supply in an indoor large fish pond in the prior art.

In order to achieve the purpose, the utility model adopts the following technical scheme:

an oxygen supply mechanism for an indoor high-density fishpond, comprising:

the high-density oxygen supply pump is arranged at the center of the fishpond;

the first gas pipe is communicated with the high-density oxygen supply pump, and a plurality of aeration openings are formed in the upper end surface of the first gas pipe;

the second gas pipe is communicated with the extending end of the first gas pipe, and the extending end of the second gas pipe is provided with an aeration opening;

the drive plate is attached to the inner wall of the fishpond, and the outer walls of the first gas pipe and the second gas pipe are connected with the drive plate;

the movable sleeve is rotatably arranged on the outer side of the top of the fishpond through the bearing sleeve, and is in limited rotation to drive the first gas pipe and the second gas pipe to rotate in an arc shape with the high-density oxygen supply pump as a center and drive the second gas pipe to rotate in a limited manner with the drive plate as a fulcrum arc.

Preferably, still include first annular slide rail and second annular slide rail, first annular slide rail and second annular slide rail set up with the axle center, the bottom of drive plate is spacing to slide in second annular slide rail, the cover is equipped with the stop collar on the first gas-supply pipe, the spacing first annular slide rail in bottom of stop collar slides.

Preferably, the outer side of the top of the driving plate is fixedly connected with a limiting tooth, two clamping plates are installed on the inner side of the movable sleeve, and the limiting tooth is limited between the two clamping plates so as to keep the driving plate vertical in the arc motion state.

Preferably, the first air delivery pipe is connected with the high-density oxygen supply pump through a hose, and the first air delivery pipe is connected with the second air delivery pipe through a telescopic pipe.

Preferably, the sliding sleeve has been cup jointed on the second gas-supply pipe, the fixed cover that is equipped with of extension end of second gas-supply pipe, the cover is equipped with the spring on the second gas-supply pipe, and the both ends of spring are connected with fixed cover and sliding sleeve respectively, be connected with the stay cord on the fixed cover, the extension end of stay cord is connected with the fixed block fixed with the aquarium inner wall.

Preferably, the outside of movable sleeve is provided with the mount, and installs motor and gear on the mount, the output shaft and the gear drive of motor are connected, the outer wall of movable sleeve is annular array and is provided with the latch, through latch meshing transmission between gear and the movable sleeve to the reciprocating type arc of drive movable sleeve rotates.

The utility model has at least the following beneficial effects:

when indoor fishpond oxygen suppliment mechanism starts, the aeration mouth control oxygen of the up end of first gas-supply pipe upwards exports, with from fishpond bottom to fishpond top transport oxygen, and the spacing rotation of arc about the second gas-supply pipe, thereby throw out oxygen to the top water in the fishpond, thereby the top of realizing the fishpond and the below in fishpond all the at utmost be full of oxygen, thereby realized the even oxygen suppliment mechanism for the fishpond of oxygen suppliment, make the output oxygen of high density oxygen suppliment pump can by make full use of, the homogeneity that the migratory fish obtained oxygen in the fishpond has been improved.

The utility model also has the following beneficial effects:

1. only be provided with two power consumptive equipment of high density oxygen supply pump and motor through the oxygen suppliment mechanism, and a motor equipment can drive the spacing rotation of first conveyer pipe arc and carry oxygen in, the upper and lower arc that can also indirect control second conveyer pipe rotates and carries oxygen, has realized the even oxygen suppliment mechanism in large-scale indoor aquarium of a low energy consumption environment-friendly.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

FIG. 1 is a schematic view of an installation structure of an oxygen supply mechanism and a fishpond;

FIG. 2 is a schematic view of the structure of an oxygen supply mechanism;

FIG. 3 is a schematic top view of the fishpond with an oxygen supply mechanism.

In the figure: 1. a motor; 2. a high density oxygen supply pump; 3. a first annular slide rail; 4. a second annular slide rail; 5. a limiting sleeve; 6. a hose; 7. a first gas delivery pipe; 8. a telescopic pipe; 9. a second gas delivery pipe; 10. a sliding sleeve; 11. fixing a sleeve; 12. a fixed block; 13. pulling a rope; 14. a drive plate; 15. a movable sleeve; 16. limiting teeth; 17. a splint; 18. clamping teeth; 19. a gear.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

Referring to fig. 1 to 3, an oxygen supply mechanism for an indoor high-density fishpond includes:

the high-density oxygen supply pump 2 is arranged at the center of the fishpond;

the first gas pipe 7 is communicated with the high-density oxygen supply pump 2, and a plurality of aeration openings are formed in the upper end surface of the first gas pipe 7;

the second air conveying pipe 9 is communicated with the extending end of the first air conveying pipe 7, and an aeration opening is formed in the extending end of the second air conveying pipe 9;

the drive plate 14 is attached to the inner wall of the fishpond, and the outer walls of the first air conveying pipe 7 and the second air conveying pipe 9 are connected with the drive plate 14;

the movable sleeve 15 is rotatably arranged on the outer side of the top of the fishpond through a bearing sleeve, and the movable sleeve 15 rotates in a limiting mode to drive the first gas pipe 7 and the second gas pipe 9 to rotate in an arc mode with the high-density oxygen supply pump 2 as a center and drive the second gas pipe 9 to rotate in an arc mode with the drive plate 14 as a fulcrum;

the scheme has the following working processes: when the oxygen supply mechanism of the indoor fishpond is started, the movable sleeve 15 rotates in an arc limiting manner to control the drive plate 14 to rotate in an arc limiting manner, so that the first gas pipe 7 and the second gas pipe 9 rotate in an arc manner, the aeration port on the upper end surface of the first gas pipe 7 controls oxygen to be output upwards, and the first gas pipe 7 supplies oxygen to water above the first gas pipe when the first gas pipe 7 rotates in an arc manner; meanwhile, the second gas-supply pipe 9 is when 14 arcs of drive plate rotate, the spacing rotation of upper and lower arc, thereby make the extension end of second gas-supply pipe 9 throw out oxygen to pond top water, thereby the top of realizing the pond of breeding fish and the below in pond of breeding fish all the at utmost be full of oxygen, thereby realized the even oxygen suppliment mechanism for the pond of breeding fish of oxygen suppliment, make the output oxygen of high density oxygen suppliment pump 2 can be by make full use of, the homogeneity that the swimming fish obtained oxygen in the pond of breeding fish has been improved.

Further, still include first annular slide rail 3 and second annular slide rail 4, first annular slide rail 3 and second annular slide rail 4 set up with the axle center, drive plate 14's bottom is spacing to slide in second annular slide rail 4, the cover is equipped with stop collar 5 on the first gas-supply pipe 7, slide in the spacing first annular slide rail 3 in bottom of stop collar 5, concretely, the bottom of stop collar 5 and drive plate 14's bottom all inlays and is equipped with the ball, the setting of first annular slide rail 3 and second annular slide rail 4 has guaranteed drive plate 14, the stability of first gas-supply pipe 7 and the annular motion of second gas-supply pipe 9.

Further, the top outside fixedly connected with of drive plate 14 has spacing tooth 16, and two splint 17 are installed to the inboard of movable sleeve 15, and spacing tooth 16 is spacing between two splint 17 to keep vertical when controlling the 14 arc motion states of drive plate, it is concrete, and spacing tooth 16 and two splint 17 are the rectangle structure, and the stable vertical state of drive plate 14 has been guaranteed in splint 17's setting.

Further, first gas-supply pipe 7 is connected with high density oxygen supply pump 2 through hose 6, and first gas-supply pipe 7 is connected with second gas-supply pipe 9 through flexible pipe 8, and is concrete, and the setting of hose 6 guarantees that first gas-supply pipe 7 can be stable around 2 arc rotations of high density oxygen supply pump, and the rotation that second gas-supply pipe 9 can be stable is guaranteed in the setting of flexible pipe 8.

Further, the sliding sleeve 10 has been cup jointed on the second gas-supply pipe 9, the fixed cover that is equipped with of extension end of second gas-supply pipe 9 is fixed and is equipped with fixed cover 11, the cover is equipped with the spring on the second gas-supply pipe 9, and the both ends of spring are connected with fixed cover 11 and sliding sleeve 10 respectively, be connected with stay cord 13 on the fixed cover 11, the extension end of stay cord 13 is connected with fixed block 12 with the aquarium inner wall is fixed, specifically, establish the connection of sliding sleeve 10 on second gas-supply pipe 9 through stay cord 13 and cover, make when drive plate 14 rotates to keeping away from fixed block 12 position department, stay cord 13 is flare-out, thereby pulling sliding sleeve 10 slides on second gas-supply pipe 9, thereby drive second gas-supply pipe 9 takes place the rotation gradually, the spacing rotation of arc of second gas-supply pipe 9 has been realized.

Further, the outside of movable sleeve 15 is provided with the mount, and install motor 1 and gear 19 on the mount, the output shaft and the gear 19 transmission of motor 1 are connected, the outer wall of movable sleeve 15 is annular array and is provided with latch 18, through the meshing transmission of latch 18 between gear 19 and the movable sleeve 15, rotate with the reciprocating type arc of drive movable sleeve 15, it is concrete, drive gear 19 through motor 1 and rotate, and motor 1 is servo drive mode, thereby control movable sleeve 15 and do reciprocating type arc and rotate, and every time the pivoted radian all can not arrive a week.

The foregoing shows and describes the general principles, essential features, and advantages of the utility model. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are merely illustrative of the principles of the utility model, but that various changes and modifications may be made without departing from the spirit and scope of the utility model, which fall within the scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides an indoor high density is oxygen suppliment mechanism for fishpond which characterized in that includes:

the high-density oxygen supply pump (2), the high-density oxygen supply pump (2) is installed at the center of the fishpond;

the first gas pipe (7), the first gas pipe (7) is communicated with the high-density oxygen supply pump (2), and a plurality of aeration openings are formed in the upper end face of the first gas pipe (7);

the second air conveying pipe (9), the second air conveying pipe (9) is communicated with the extending end of the first air conveying pipe (7), and the extending end of the second air conveying pipe (9) is provided with an air exposing port;

the drive plate (14) is attached to the inner wall of the fishpond, and the outer walls of the first air conveying pipe (7) and the second air conveying pipe (9) are connected with the drive plate (14);

the movable sleeve (15), the movable sleeve (15) passes through the bearing housing and rotates the setting in the fishpond top outside, the spacing rotation of movable sleeve (15) to drive first gas-supply pipe (7) and second gas-supply pipe (9) and use high density oxygen supply pump (2) to rotate as central arc, drive second gas-supply pipe (9) simultaneously and use drive plate (14) to rotate as the spacing rotation of fulcrum arc.

2. The oxygen supply mechanism for the indoor high-density fish pond is according to claim 1, characterized by further comprising a first annular slide rail (3) and a second annular slide rail (4), wherein the first annular slide rail (3) and the second annular slide rail (4) are coaxially arranged, the bottom end of the drive plate (14) is limited to slide in the second annular slide rail (4), the first gas pipe (7) is sleeved with a limiting sleeve (5), and the bottom end of the limiting sleeve (5) is limited to slide in the first annular slide rail (3).

3. The oxygen supply mechanism for the indoor high-density fishpond according to claim 1, characterized in that a limit tooth (16) is fixedly connected to the outside of the top of the driving plate (14), two clamping plates (17) are installed on the inside of the movable sleeve (15), and the limit tooth (16) is limited between the two clamping plates (17) to control the driving plate (14) to keep vertical in the arc-shaped motion state.

4. The oxygen supply mechanism for the indoor high-density fish pond is characterized in that the first air delivery pipe (7) is connected with the high-density oxygen supply pump (2) through a hose (6), and the first air delivery pipe (7) is connected with the second air delivery pipe (9) through an extension pipe (8).

5. The oxygen supply mechanism for the indoor high-density fish pond is characterized in that a sliding sleeve (10) is sleeved on the second gas conveying pipe (9), a fixed sleeve (11) is fixedly sleeved on an extending end of the second gas conveying pipe (9), a spring is sleeved on the second gas conveying pipe (9), two ends of the spring are respectively connected with the fixed sleeve (11) and the sliding sleeve (10), a pull rope (13) is connected on the fixed sleeve (11), and the extending end of the pull rope (13) is connected with a fixed block (12) fixed to the inner wall of the fish pond.

6. The oxygen supply mechanism for the indoor high-density fish pond is characterized in that a fixed frame is arranged on the outer side of the movable sleeve (15), a motor (1) and a gear (19) are mounted on the fixed frame, an output shaft of the motor (1) is in transmission connection with the gear (19), clamping teeth (18) are arranged on the outer wall of the movable sleeve (15) in an annular array, and the gear (19) and the movable sleeve (15) are in meshing transmission through the clamping teeth (18) to drive the movable sleeve (15) to rotate in a reciprocating arc mode.

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