CN213908011U - Oxygen supply feeding mechanism for deepwater aquaculture - Google Patents

Abstract

The utility model provides an oxygen suppliment of deep water breed usefulness is fed and is eaten mechanism belongs to fishery equipment technical field. The food box comprises a corrugated pipe, a mounting seat, a floating plate and a food box, wherein the floating plate is fixed on the mounting seat, a one-way valve is arranged on the mounting seat, an inlet of the one-way valve is communicated with the bottom of the food box, a return spring is connected between the upper end and the lower end of the corrugated pipe, and an air vent is formed in the food box; the symmetry is provided with two breather pipes on the food case, the air vent is located the breather pipe, the inner of breather pipe is towards the top of food case, the air vent is the toper that the upper end diameter is less than the lower extreme diameter, the air vent interpolation is equipped with a conical non return pole with the air vent adaptation, the inner of two non return poles is fixed even through the both ends of a reed with a pinion rack respectively, sliding connection has a feed lever in the guide pipe, the fixed screw rod that is provided with in middle part of feed lever, have on the pinion rack with screw rod complex skewed tooth, the fixed floater that is provided with of lower extreme of installation pole. The utility model has the advantages of oxygen supply and food supply.

Description

Oxygen supply feeding mechanism for deepwater aquaculture

Technical Field

The utility model belongs to the technical field of fishery equipment, a mechanism is fed to oxygen suppliment that deep water was bred and is used is related to.

Background

The reservoir is an artificial lake formed by building a barrage at a narrow opening of a mountain ditch or a river. After the reservoir is built, the functions of flood control, water storage irrigation, water supply, power generation, fish culture and the like can be realized. As the government increases the strength of river unobstructed management and pollution prevention and control, a plurality of culture net cages in rivers and lakes, particularly shallow water culture net cages, require dismantling. However, the deep water culture net cage can be adopted in a non-water-taking deep water reservoir.

The existing deepwater aquaculture net cage mainly comprises a frame system, a net bag, a fixing system and supporting facilities, and the cage is lowered to an aquaculture tool with limited depth underwater by utilizing the interaction of a fixing platform and the self characteristics of the cage.

The larger the culture environment is (the larger the space of the net cage is), the higher the cost required by manufacturing and managing the net cage is, so that the conventional culture net cage is generally formed by matching a frame structure floating on the water surface with a net cage sinking into the water, the area corresponding to the net cage is a culture area, the lowest depth of the culture net cage with the structure is smaller (generally about 20 meters), the space below the required depth of culture is smaller, the culture density cannot be too large, the conventional culture net cage is limited by aspects of oxygen supply, feeding and the like, and the culture density is further limited.

SUMMERY OF THE UTILITY MODEL

The utility model aims at the above-mentioned problem that prior art exists, provide an oxygen suppliment of deep water breed usefulness and feed and eat mechanism, the utility model aims to solve the technical problem how realize supplying with when oxygen and fish eat.

The purpose of the utility model can be realized by the following technical proposal: an oxygen supply feeding mechanism for deepwater culture is characterized by comprising a corrugated pipe, a mounting seat, a floating plate and a food box, wherein the floating plate is fixed on the mounting seat, the mounting seat is connected with the upper end of the corrugated pipe, a one-way valve is arranged on the mounting seat, the inlet of the one-way valve is communicated with the bottom of the food box, a return spring is connected between the upper end and the lower end of the corrugated pipe, and the food box is provided with an air vent;

the food box is symmetrically provided with two vent pipes, the vent pipes are positioned in the vent pipes, the inner ends of the vent pipes face the top of the food box, the vent pipes are in a conical shape, the diameter of the upper end of each vent pipe is smaller than that of the lower end of each vent pipe, a conical check rod matched with the vent holes is inserted in each vent hole, the inner ends of the two check rods are fixedly connected with the two ends of a toothed plate through reeds respectively, the toothed plate is transversely and slidably connected onto the inner wall of the food box, the top of the food box is fixedly provided with a guide pipe, a feed rod is slidably connected in the guide pipe, a tension spring is connected between the top of the feed rod and the inner wall of the guide pipe, the middle of the feed rod is fixedly provided with a screw rod, the toothed plate is provided with inclined teeth matched with the screw rod, the lower end of the feed rod is inserted into an inlet of the one-way valve, and the outer ends of the check rods are fixedly connected with an installation rod, and a floating ball is fixedly arranged at the lower end of the mounting rod.

Further, the lower end of the feeding rod is provided with a spiral guide piece.

Furthermore, the corrugated pipe is of a conical structure, and the diameter of the lower end of the corrugated pipe is smaller than that of the upper end of the corrugated pipe.

The oxygen supply feeding mechanism has the following principle:

oxygen supply: because of the existence of the floating plate, the food box is normally positioned above sea level, the height of local water surface can be changed under the push of sea waves, so that the floating plate is sometimes positioned at the connection part of the sea level and sometimes positioned below the sea level, and further the corrugated pipe is in a frequent pulled state, in the process that the lower end of the corrugated pipe is stretched, outside air can enter the food box through the vent hole and enter the corrugated pipe, but cannot enter the bottom of the net box due to higher required pressure, when the corrugated pipe is contracted due to the existence of the reset spring, the air cannot be discharged through the vent hole due to the existence of the one-way valve, and further passes through the hose, the upright post, and then enters the bottom box, enters the bottom of the net box from the air outlet hole in the middle of the bottom box, and oxygen is supplied by blowing at the bottom of the net box;

feeding: powdered or granular fish food of path loads in the food case, can send into some food in the bottom box at the in-process that the air got into the bellows by the air vent to get into in the box with a net by the venthole.

The blocking of the inlet of the one-way valve may be caused by powdery or small-diameter granular fish food, the smooth entering of air into the inlet of the one-way valve may also be affected, if seawater enters the food box due to the overlarge inclination degree of the food box caused by sea waves and other reasons, the serious consequence of the caking of the fish food may be caused, thereby further causing the blocking of the inlet of the one-way valve and the blocking of the hose, in order to realize the ventilation of the food box without water intake, and to stir the fish food in the food box, especially to dredge the inlet of the one-way valve, two check rods are symmetrically arranged in the food box, since the inner end of the vent pipe is upward, outside rainfall and rainfall can not enter the food box, the check rods are moved outwards due to the weight to form an air inlet channel between the outer wall of the check rod and the inner wall of the vent hole, air can enter, if the food box is inclined, the seawater may enter the food box and first contacts the seawater, buoyancy forces the check rod to move up, and the check rod moves to the food box in promptly, makes the inlet channel who forms between check rod and the air vent closed, because the effect of pinion rack and screw rod can cause the longitudinal movement and the rotation of pay-off pole at the in-process that the check rod removed, specifically: when the check rod moves towards the inner side of the food box, the feeding rod moves upwards and rotates, when the check rod moves towards the outer side of the food box, the feeding rod moves downwards and rotates, and the toothed plate is fixedly connected to the two check rods, so that the moving directions of the two check rods are opposite, the check rods moving inwards can be the check rods in the inclined direction of the food box, the air vent on one side of the inclined food box is blocked, and the air vent on the other side is in a smooth state.

And a plurality of groups of check rods can be arranged to be uniformly distributed outside the food box, so that the waterproof effect is improved.

The in-process that the check rod removed in the air vent, pinion rack meeting lateral shifting, the reed offsets the longitudinal movement trend of pinion rack, and the in-process of feed lever longitudinal shifting can reset because of the existence of extension spring, and the removal of feed lever, reed and check rod can make the air admission passageway that the air admission check valve entry be in unobstructed state, and can avoid the condition that the fish food forms "cavity" or food is difficult to get into the bellows at the check valve entry.

The scheme can be realized in water areas with high and low fluctuation on the water surface, such as reservoirs (the water areas with larger areas also have horizontal plane fluctuation caused by wind), sea areas, lakes and the like.

Drawings

Fig. 1 is a schematic structural diagram of the aquaculture net cage.

Fig. 2 is a schematic diagram of the structure of the oxygen feeding mechanism.

Fig. 3 is a cross-sectional view of an oxygen feeding structure.

Fig. 4 is a cross-sectional view of the food box.

In the figure, 1, a box body; 11. a bottom box; 12. a top frame; 13. a column; 21. a bellows; 22. a mounting seat; 23. a hose; 24. a floating plate; 25. a food box; 26. a one-way valve; 27. a return spring; 28. a vent hole; 29. an air outlet; 31. a breather pipe; 32. a check rod; 33. a reed; 34. a toothed plate; 35. a feed bar; 36. a tension spring; 37. a screw; 38. mounting a rod; 39. a floating ball; 4. a material guide sheet; 5. and pulling a rope.

Detailed Description

The following are specific embodiments of the present invention and the accompanying drawings are used to further describe the technical solution of the present invention, but the present invention is not limited to these embodiments.

As shown in fig. 1 and 2, the oxygen feeding device comprises a box body 1 and a plurality of oxygen feeding mechanisms, wherein the box body 1 comprises a bottom box 11, a top frame 12 and a plurality of upright posts 13 connected with the bottom box 11 and the top frame 12, the side surface and the top surface of the box body 1 are wrapped by latticed separation nets, each oxygen feeding mechanism comprises a corrugated pipe 21, a mounting seat 22, a hose 23, a floating plate 24 and an edible box 25, the lower end of the corrugated pipe 21 is connected with the upper end of the hose 23, the lower end of the hose 23 is communicated with the bottom of the box body 1, the floating plate 24 is fixed on the mounting seat 22, the mounting seat 22 is connected with the upper end of the corrugated pipe 21, a one-way valve 26 is arranged on the mounting seat 22, the inlet of the one-way valve 26 is communicated with the bottom of the edible box 25, a return spring 27 is connected between the upper end and the lower end of the corrugated pipe 21, the edible box 25 is provided with a vent hole 28, and the floating plates 24 of each oxygen feeding mechanism are connected through a pull rope 5.

The bottom box 11 is internally provided with a cavity, the middle part of the upper surface of the bottom box 11 is provided with a plurality of air outlet holes 29, the air outlet holes 29 are communicated with the cavity, and the lower end of the hose 23 is communicated with the cavity.

As shown in fig. 2, 3 and 4, two vent pipes 31 are symmetrically arranged on the food box 25, the vent holes 28 are located in the vent pipes 31, the inner ends of the vent pipes 31 face the top of the food box 25, the vent holes 28 are conical with the upper end diameter smaller than the lower end diameter, a conical check rod 32 matched with the vent holes 28 is inserted into the vent holes 28, the inner ends of the two check rods 32 are fixedly connected with both ends of a toothed plate 34 through a reed 33 respectively, the toothed plate 34 is transversely and slidably connected on the inner wall of the food box 25, a guide pipe is fixedly arranged at the top of the food box 25, a feed rod 35 is slidably connected in the guide pipe, a tension spring 36 is connected between the top of the feed rod 35 and the inner wall of the guide pipe, a screw 37 is fixedly arranged at the middle part of the feed rod 35, inclined teeth matched with the screw 37 are arranged on the toothed plate 34, the lower end of the feed rod 35 is inserted in the inlet of the one-way valve 26, an installation rod 38 is fixedly connected at the outer end of the check rod 32, a float 39 is fixedly provided at the lower end of the mounting rod 38.

The lower end of the feeding rod 35 is provided with a spiral material guiding sheet 4.

The upright column 13 is of a hollow structure, the lower end of the hose 23 is communicated with the upper end of the upright column 13, and the lower end of the upright column 13 is communicated with the cavity.

The bellows 21 is of a conical configuration with a lower end diameter smaller than an upper end diameter.

Each floating plate 24 floats on the sea surface, the bottom box 11 is anchored on the sea bottom or fixed at a certain depth below the sea level in other modes, the floating plates 24 and the box body 1 are enabled to pass through the hose 23, the sinking depth of the net box can be further increased in this mode, and the top of the net box is also located at a certain position below the sea level, so that the requirement of the living environment of the fish cultured in the deep sea can be met, on the other hand, the fish can be prevented from crossing the horizontal to escape from the net box, and the net box can be completely located in a 'deep sea area', and the culture space in the net box is all the environment required by the fish cultured in the deep sea.

Because the top of the net cage is not connected with the sea surface, oxygen required by high-density cultivation is insufficient to a certain extent, the feeding difficulty of food is greatly increased, and an oxygen supply feeding mechanism is arranged.

The oxygen supply feeding mechanism has the following principle:

oxygen supply: because of the existence of the floating plate 24, the food box 25 is normally positioned above sea level, the local water level height can be changed under the push of sea waves, so that the floating plate 24 is sometimes positioned at the connection position of the sea level and sometimes positioned below the sea level, and further the corrugated pipe 21 is in a frequent pulled state, in the process that the lower end of the corrugated pipe 21 is stretched, outside air can enter the food box 25 through the vent hole 28 and enter the corrugated pipe 21, but cannot enter the bottom of the net box due to higher required pressure, and when the corrugated pipe 21 is contracted due to the existence of the return spring 27, the air cannot be discharged through the vent hole 28 due to the existence of the one-way valve, further passes through the hose 23 and the upright post 13, then enters the bottom box 11, enters the bottom of the net box from the air outlet hole 29 in the middle of the bottom box 11, and oxygen is supplied by blowing at the bottom of the net box;

feeding: powdered or small-diameter granular fish food is loaded in the food box 25, and part of the food can be fed into the bottom box 11 in the process that air enters the corrugated pipe 21 through the vent hole 28, so that the food enters the net box through the vent hole 29.

Because powdery or small-diameter granular fish food can cause the blockage of the inlet of the one-way valve and can also influence the smooth entering of air into the inlet of the one-way valve, if seawater enters the food box 25 due to the overlarge inclination degree of the food box 25 caused by sea waves and other reasons, the serious consequence of the caking of the fish food can be caused, thereby further causing the blockage of the inlet of the one-way valve and the blockage of the hose 23, in order to realize the ventilation of the food box 25 without water entering, and can stir the fish food in the food box 25, in particular to dredge the inlet of the one-way valve, two check rods 32 are symmetrically arranged in the food box 25, because the inner end of the vent pipe 31 is upward, outside water and rainfall can not enter the food box 25, the check rods 32 are weighted and move outwards to form an air inlet channel between the outer walls of the check rods 32 and the inner walls of the vent holes 28, air can enter, if the food box 25 is inclined, the seawater can enter the food box 25, the floating ball 39 first contacts the sea water, the buoyancy drives the check rod 32 to move upwards, i.e. the check rod 32 moves towards the food box 25, so that the air inlet channel formed between the check rod 32 and the vent hole 28 is closed, and due to the action of the toothed plate 34 and the screw 37, the longitudinal movement and rotation of the feeding rod 35 are caused during the movement of the check rod 32, specifically: when the check rod 32 moves towards the inner side of the food box 25, the feeding rod 35 moves upwards and rotates, when the check rod 32 moves towards the outer side of the food box 25, the feeding rod 35 moves downwards and rotates, and because the toothed plate 34 is fixedly connected to the two check rods 32, the moving directions of the two check rods 32 are opposite, the check rods 32 moving inwards can be the check rods 32 in the inclined direction of the food box 25, so that the vent holes 28 on the inclined side of the food box 25 are blocked, and the vent holes 28 on the other side are in a smooth state.

A plurality of sets of check rods 32 can also be arranged to be evenly distributed outside the food box 25, thereby improving the waterproof effect.

In the process that check rod 32 moves in vent hole 28, toothed plate 34 can lateral shifting, and the longitudinal movement trend of toothed plate 34 is offset by reed 33, and the in-process of feed rod 35 longitudinal movement can reset because of the existence of extension spring 36, and the removal of feed rod 35, reed 33 and check rod 32 can make the air inlet channel that air got into the inlet of check valve 26 be in unobstructed state, and can avoid the condition that the fish food forms "cavity" or food is difficult to get into bellows 21 at the inlet of check valve 26.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein may be made by those skilled in the art without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims (3)

1. An oxygen supply feeding mechanism for deepwater culture is characterized by comprising a corrugated pipe (21), a mounting seat (22), a floating plate (24) and a food box (25), wherein the floating plate (24) is fixed on the mounting seat (22), the mounting seat (22) is connected with the upper end of the corrugated pipe (21), a one-way valve (26) is arranged on the mounting seat (22), an inlet of the one-way valve (26) is communicated with the bottom of the food box (25), a return spring (27) is connected between the upper end and the lower end of the corrugated pipe (21), and a vent hole (28) is formed in the food box (25);

the food box is characterized in that two vent pipes (31) are symmetrically arranged on the food box (25), the vent holes (28) are positioned in the vent pipes (31), the inner ends of the vent pipes (31) face the top of the food box (25), the vent holes (28) are conical, the upper end diameter of each vent pipe is smaller than the lower end diameter of each vent pipe, a conical check rod (32) matched with the vent holes (28) is inserted into each vent hole (28), the inner ends of the two check rods (32) are fixedly connected with the two ends of a toothed plate (34) through a reed (33), the toothed plate (34) is transversely and slidably connected onto the inner wall of the food box (25), a guide pipe is fixedly arranged at the top of the food box (25), a feed rod (35) is slidably connected into the guide pipe, a tension spring (36) is connected between the top of the feed rod (35) and the inner wall of the guide pipe, a screw rod (37) is fixedly arranged in the middle of the feed rod (35), the toothed plate (34) is provided with inclined teeth matched with the screw rod (37), the lower end of the feeding rod (35) is inserted into an inlet of the one-way valve (26), the outer end of the check rod (32) is fixedly connected with an installation rod (38), and the lower end of the installation rod (38) is fixedly provided with a floating ball (39).

2. The oxygen supply feeding mechanism for deep water aquaculture as claimed in claim 1, wherein the lower end of the feeding rod (35) is provided with a helical guide piece (4).

3. The oxygen supply and feeding mechanism for deep water aquaculture of claim 1 wherein said bellows (21) is of a conical configuration with a smaller diameter at the lower end than at the upper end.

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