CN212877073U - Small-size portable scientific research breeding hybridization canopy - Google Patents

Abstract

The utility model discloses a small-size portable scientific research breeding hybridization canopy relates to the hybridization canopy and uses technical field, to the problem of scientific research breeding in-process hybridization canopy to the wasting of resources, now proposes following scheme, including first casing, the inside of first casing is equipped with two risers, two sliding connection has the cultivation board on the riser, the below of cultivation board is equipped with the sieve that is located on the riser, the right side the welding has the second casing on the right side conch wall of riser, install the suction pump on the back outer wall of second casing. The utility model discloses a combination of various structures makes this device not only can carry out even water source or nutrient solution that sprays to the breeding to improve the effect of scientific research, and this device can plant unable absorptive water source or nutrient solution and carry out recycle after screening after spraying, thereby avoid the waste of resource, and this device can move through the universal wheel, makes this device not restricted by time and place, and it is nimble convenient to use.

Description

Small-size portable scientific research breeding hybridization canopy

Technical Field

The utility model relates to a technical field is used to the hybridization canopy, especially relates to a small-size portable scientific research breeding hybridization canopy.

Background

Generally, a series of activities such as investigation, experiment, trial production and the like are carried out by utilizing scientific research means and equipment in order to know the intrinsic nature and the motion rule of objective things, a theoretical basis is provided for creating new products and new technologies, the basic task of scientific research is exploration and unknown understanding, and with the development of science, the experiment for crossbreeding of agricultural products is increasingly expanded.

The hybridization canopy that current scientific research breeding used is the big-arch shelter building of building in the experiment field basically, and the construction cost is great, can't remove and be unfavorable for the scientific research personnel to carry out the laboratory and observe, and miniature hybridization canopy adopts direct emission to the resource that cultivates agricultural product and use basically to the extravagant resource.

SUMMERY OF THE UTILITY MODEL

The utility model provides a small-size portable scientific research breeding hybridization canopy has solved the problem of hybridization canopy to the wasting of resources among the scientific research breeding process.

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

a small-sized movable scientific research and breeding hybridization shed comprises a first shell, wherein two vertical plates are arranged inside the first shell, a cultivation plate is connected to the two vertical plates in a sliding manner, a sieve plate positioned on the vertical plates is arranged below the cultivation plate, a second shell is welded on the wall of the right side of the vertical plate on the right side, a water suction pump is installed on the outer wall of the back side of the second shell, a motor is fixedly connected to the outer wall of the back side of the first shell, a rotating shaft is installed at the output end of the motor, a transmission wheel is connected to the rotating shaft through a bolt, a transmission wheel is also arranged below the transmission wheel, a transmission shaft is connected to the transmission wheel below the transmission wheel through a bolt, a worm wheel is installed on the front side of the transmission shaft, a worm is arranged below the worm wheel, a support rod is movably connected to the, and the half gear and the rack are in meshing transmission.

Preferably, a support plate is welded on the outer wall of the back of the first shell, a motor is connected to the top of the support plate through a bolt, a first slot hole is formed in the wall of the back of the first shell, one end, far away from the motor, of the rotating shaft penetrates through the first slot hole, and one end of the back of the transmission shaft is rotatably connected to the inner wall of the back of the first shell.

Preferably, a belt is connected between the two transmission wheels, the left end of the worm is rotatably connected to the inner wall of the left side of the first shell, a second slotted hole is formed in the vertical plate, the right end of the worm penetrates through the second slotted hole, and an elliptic disc is installed at the right end of the worm.

Preferably, a first sliding groove located on the vertical plate on the left side is arranged above the second slotted hole, a first sliding block is connected to the inside of the first sliding groove in a sliding mode, the right side of the first sliding block is hinged to the screen plate, the right end of the screen plate is hinged to the vertical plate on the right side, a third slotted hole is formed in the wall, close to the vertical plate, of the second shell, inclined plates are arranged on the side, close to the two vertical plates, the right end of each inclined plate is located in the corresponding third slotted hole, and the third slotted hole is in an inclined state.

Preferably, a transverse plate is arranged inside the first shell, a second sliding groove is formed in the middle shell wall of the transverse plate, a second sliding block is connected inside the second sliding groove in a sliding mode, a fixing plate is welded at the bottom of the second sliding block, a guide pipe is installed at the bottom of the fixing plate, thirteen spray holes are formed in the bottom of the guide pipe at equal intervals, and a hose is connected between the guide pipe and the water suction pump.

Preferably, the bottom welding of diaphragm has the dead lever, the bearing is installed to the bottom of dead lever, pass through bolted connection between bearing and the pivot, be equipped with the movable groove on the outer lane of pivot, swing joint has branch in the movable groove, it is connected with the rotation axis to rotate on the half-gear, the top of rotation axis is rotated and is connected on the diaphragm, the rack is kept away from one side of half-gear and is welded on the fixed plate.

Preferably, a fourth slotted hole is formed in the wall of the top of the first shell, a transparent shed is installed in the fourth slotted hole, four supporting columns are welded at the bottom of the first shell, universal wheels are installed at the bottoms of the supporting columns, a feeding pipe is installed on the wall of the right side of the second shell, and the right end of the discharging pipe penetrates through the wall of the right side of the first shell.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model discloses an installation first casing, riser, cultivation board, sieve, swash plate, second casing, suction pump, diaphragm, pipe, motor, pivot, worm wheel, worm, branch, semi-gear and the combination of rack make this device not only can retrieve the water source or the nutrient solution after spraying and recycle, resources are saved, and this device can carry out even water source or nutrient solution of spraying to cultivating the kind to do benefit to scientific research, and this device makes things convenient for the motion through the universal wheel.

To sum up, the utility model discloses a combination of various structures makes this device not only can carry out even water source or the nutrient solution that sprays to the breeding to improve the effect of scientific research, and this device can carry out recycle after screening to planting unabsorbable water source or nutrient solution after spraying, thereby avoid the waste of resource, and this device can move through the universal wheel, makes this device not restricted by time and place, and it is nimble convenient to use.

Drawings

FIG. 1 is a schematic view of a cross-sectional structure of a small mobile scientific research and breeding hybridization shed;

FIG. 2 is a schematic diagram of a side view structure of a small mobile scientific research and breeding hybridization shed;

fig. 3 is the utility model provides a structure sketch map is overlooked to pivot and branch of small-size portable scientific research breeding hybridization canopy.

In the figure: the device comprises a first shell 1, a vertical plate 2, a culture plate 3, a sieve plate 4, an inclined plate 5, a second shell 6, a water suction pump 7, a transverse plate 8, a guide pipe 9, a motor 10, a rotating shaft 11, a worm wheel 12, a worm 13, a support rod 14, a half gear 15 and a rack 16.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-3, a small movable scientific research and breeding hybridization shed comprises a first shell 1, two vertical plates 2 are arranged inside the first shell 1, a cultivation plate 3 is connected on the two vertical plates 2 in a sliding manner, a sieve plate 4 positioned on the vertical plates 2 is arranged below the cultivation plate 3, a second shell 6 is welded on the right side wall of the right vertical plate 2, a water suction pump 7 is arranged on the back outer wall of the second shell 6, a motor 10 is fixedly connected on the back outer wall of the first shell 1, a rotating shaft 11 is arranged at the output end of the motor 10, a driving wheel is connected on the rotating shaft through a bolt, a driving wheel is also arranged below the driving wheel, a transmission shaft is connected on the lower driving wheel through a bolt, a worm wheel 12 is arranged on the front surface of the transmission shaft, a worm 13 is arranged below the worm wheel 12, a support rod 14 is movably connected on the rotating shaft 11, and the half gear 15 and the rack 16 are in meshed transmission.

The back outer wall of the first shell 1 is welded with a support plate, the top of the support plate is connected with a motor 10 through a bolt, a first slotted hole is formed in the back shell wall of the first shell 1, one end of a rotating shaft 11, far away from the motor 10, penetrates through the first slotted hole, one end of the back of the driving shaft is rotatably connected with the back inner wall of the first shell 1, a belt is connected between two driving wheels, the left end of a worm 13 is rotatably connected with the left inner wall of the first shell 1, a second slotted hole is formed in a left vertical plate 2, the right end of the worm 13 penetrates through the second slotted hole, an elliptic disc is arranged at the right end of the worm 13, a first sliding groove positioned on the left vertical plate 2 is arranged above the second slotted hole, a first sliding block is slidably connected inside the first sliding groove, the right side of the first sliding block is hinged on a sieve plate 4, the right end of the sieve plate 4 is hinged, an inclined plate 5 is arranged on one side, close to each other, of each of the two vertical plates 2, the right end of each inclined plate 5 is located in a third groove hole, the third groove hole is in an inclined state, a transverse plate 8 is arranged inside the first shell 1, a second sliding groove is formed in the middle shell wall of each transverse plate 8, a second sliding block is connected inside the second sliding groove in a sliding mode, a fixing plate is welded at the bottom of each second sliding block, a conduit 9 is installed at the bottom of each fixing plate, thirteen spray holes are formed in the bottom of each conduit 9 at equal intervals, a hose is connected between each conduit 9 and the suction pump 7, a fixing rod is welded at the bottom of each transverse plate 8, a bearing is installed at the bottom end of each fixing rod, each bearing is connected with the rotating shaft 11 through a bolt, a movable groove is formed in the outer ring of the rotating shaft 11, a support rod 14 is, a fourth slotted hole is formed in the wall of the top of the first shell 1, a transparent shed is installed in the fourth slotted hole, four supporting columns are welded at the bottom of the first shell 1, universal wheels are installed at the bottoms of the supporting columns, a feeding pipe is installed on the wall of the right side of the second shell 6, and the right end of the discharging pipe penetrates through the wall of the right side of the first shell 1.

In this embodiment, first, when breeding needs photosynthesis, the first housing 1 is pushed to be under the sun, photosynthesis of the breeding is realized through the effect of the transparent shed, when the breeding needs to be sprayed, the motor 10 is started to drive the rotating shaft 11 to rotate, the supporting rod 14 and the driving wheels are driven to move, the two driving wheels are driven to rotate through the belt, the driving shaft is driven to rotate, the worm wheel 12 and the worm 13 are in meshing transmission, the elliptical disc is driven to move, the sieve plate 4 is driven to vibrate, the supporting rod 14 moves along with the rotation of the rotating shaft 11, the half gear 15 is driven to move, the half gear 15 and the rack 16 are in meshing transmission, the conduit 9 is driven to move back and forth, the water pump 7 is started to be conveyed to the conduit 9 through the hose, and then the water source in the second housing 6 is sprayed, the water source and the culture medium piece that leak down on the motion of sieve 4 to cultivate board 3 filter the screening, get into second casing 6 through swash plate 5 and third slot, avoid the waste of resource, two openings openly seted up through first casing 1 to not only can take out cultivate board 3 and can place the instrument between swash plate 5 bottom inner wall in first casing 1, be convenient for cultivate the breeding, make the device can conveniently move through the universal wheel.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (7)

1. A small-size portable scientific research breeding hybridization canopy, includes first casing (1), its characterized in that, the inside of first casing (1) is equipped with two risers (2), two have cultivation board (3) on riser (2), the below of cultivation board (3) is equipped with sieve (4) that are located riser (2), the right side the welding has second casing (6) on the right side conch wall of riser (2), install suction pump (7) on the back outer wall of second casing (6), fixedly connected with motor (10) on the back outer wall of first casing (1), pivot (11) are installed to the output of motor (10), there is the drive wheel through bolted connection in the pivot, the below of drive wheel also is equipped with the drive wheel, the below have the transmission shaft through bolted connection in the drive wheel, worm wheel (12) are installed in the front of transmission shaft, the worm gear (12) is provided with a worm (13) below, the rotating shaft (11) is movably connected with a supporting rod (14), the right end of the supporting rod (14) is welded with a half gear (15), the right side of the half gear (15) is provided with a rack (16), and the half gear (15) and the rack (16) are meshed for transmission.

2. The small-sized movable scientific research and breeding hybridization shed according to claim 1, wherein a support plate is welded on the outer wall of the back of the first shell (1), the top of the support plate is connected with a motor (10) through a bolt, a first slot is formed in the wall of the back of the first shell (1), one end of the rotating shaft (11) far away from the motor (10) penetrates through the first slot, and one end of the back of the driving shaft is rotatably connected to the inner wall of the back of the first shell (1).

3. The small-sized movable scientific research and breeding hybridization shed according to claim 1, wherein a belt is connected between the two driving wheels, the left end of the worm (13) is rotatably connected to the inner wall of the left side of the first shell (1), the vertical plate (2) on the left side is provided with a second slotted hole, the right end of the worm (13) passes through the second slotted hole, and the right end of the worm (13) is provided with an elliptical disk.

4. The small-sized movable scientific research and breeding hybridization shed according to claim 3, wherein a first sliding groove is formed in the left vertical plate (2) above the second groove hole, a first sliding block is connected to the inside of the first sliding groove in a sliding manner, the right side of the first sliding block is hinged to the sieve plate (4), the right end of the sieve plate (4) is hinged to the right vertical plate (2), a third groove hole is formed in the wall of the second shell (6) close to the right vertical plate (2), an inclined plate (5) is arranged on the wall of one side of the two vertical plates (2) close to the right vertical plate, the right end of the inclined plate (5) is located in the third groove hole, and the third groove hole is in an inclined state.

5. The small-sized movable scientific research and breeding hybridization shed according to claim 1, wherein a transverse plate (8) is arranged inside the first housing (1), a second sliding groove is formed in the middle shell wall of the transverse plate (8), a second sliding block is connected inside the second sliding groove in a sliding manner, a fixed plate is welded at the bottom of the second sliding block, a guide pipe (9) is installed at the bottom of the fixed plate, thirteen spray holes are formed in the bottom of the guide pipe (9) at equal intervals, and a hose is connected between the guide pipe (9) and the water pump (7).

6. The small movable scientific research and breeding hybridization shed according to claim 5, wherein fixing rods are welded at the bottoms of the transverse plates (8), bearings are installed at the bottom ends of the fixing rods, the bearings are connected with the rotating shafts (11) through bolts, movable grooves are formed in the outer rings of the rotating shafts (11), supporting rods (14) are movably connected in the movable grooves, rotating shafts are connected to the half gears (15) in a rotating mode, the top ends of the rotating shafts are connected to the transverse plates (8) in a rotating mode, and one sides, away from the half gears (15), of the racks (16) are welded to the fixing plates.

7. The small-sized movable scientific research and breeding hybridization shed according to claim 1, wherein a fourth slot is formed in the top wall of the first shell (1), a transparent shed is installed in the fourth slot, four pillars are welded to the bottom of the first shell (1), universal wheels are installed at the bottoms of the pillars, a feeding pipe is installed on the right side wall of the second shell (6), and the right end of the discharging pipe penetrates through the right side wall of the first shell (1).

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