CN108633553B - Machine-transplanted rice soft disk seedling raising device - Google Patents
Machine-transplanted rice soft disk seedling raising device Download PDFInfo
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- CN108633553B CN108633553B CN201810349022.7A CN201810349022A CN108633553B CN 108633553 B CN108633553 B CN 108633553B CN 201810349022 A CN201810349022 A CN 201810349022A CN 108633553 B CN108633553 B CN 108633553B
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- A—HUMAN NECESSITIES
- A01—AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
- A01G—HORTICULTURE; CULTIVATION OF VEGETABLES, FLOWERS, RICE, FRUIT, VINES, HOPS OR SEAWEED; FORESTRY; WATERING
- A01G9/00—Cultivation in receptacles, forcing-frames or greenhouses; Edging for beds, lawn or the like
- A01G9/02—Receptacles, e.g. flower-pots or boxes; Glasses for cultivating flowers
- A01G9/029—Receptacles for seedlings
- A01G9/0295—Units comprising two or more connected receptacles
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- A—HUMAN NECESSITIES
- A01—AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
- A01G—HORTICULTURE; CULTIVATION OF VEGETABLES, FLOWERS, RICE, FRUIT, VINES, HOPS OR SEAWEED; FORESTRY; WATERING
- A01G27/00—Self-acting watering devices, e.g. for flower-pots
- A01G27/005—Reservoirs connected to flower-pots through conduits
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- Life Sciences & Earth Sciences (AREA)
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- Engineering & Computer Science (AREA)
- Water Supply & Treatment (AREA)
- Cultivation Receptacles Or Flower-Pots, Or Pots For Seedlings (AREA)
Abstract
The invention relates to the technical field of agriculture, in particular to a novel machine-transplanted rice soft disk seedling raising device which mainly comprises a matrix-shaped seedling raising disk formed by horizontally and longitudinally arranging a plurality of seedling holes. The seedling hole is in the shape of an inverted cone, a connecting plate which extends into a square shape from four to four in the horizontal direction is arranged at the edge of the opening of the cylinder, and the thickness of the connecting plate is larger than that of the side wall and the bottom of the seedling hole. Seedling cave lateral wall and lower bottom are equipped with a plurality of hydrophobic holes that link up, and each hydrophobic hole all is equipped with one section breach that extends to all around. The inner wall surface of the seedling hole is provided with a root fixing pile extending towards the central axis direction. The invention aims to separately cultivate each rice seedling through the independent seedling hole, and the rice seedling can not be pulled and broken in the mechanical transplanting process, thereby ensuring the smooth growth of the seedling.
Description
Technical Field
The invention relates to the technical field of agriculture, in particular to a flexible disk seedling raising device for machine-transplanted rice.
Background
Current rice seedling dish all cultivates a plurality of rice seedlings jointly, and the seedling root system after cultivating interweaves together easily, and this makes the root must of the easy damage seedling of subsequent machine transplanting operation, consequently causes the influence for the development of seedling, and this seedling survival rate and the output of rice field cause little influence.
Disclosure of Invention
The invention aims to provide a machine-transplanted rice soft disk seedling raising device, which separately cultivates each rice seedling through an independent seedling hole, and the rice seedling cannot be pulled and broken in the machine transplanting process, so that the smooth growth of the seedling is ensured.
In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a machine transplanting rice floppy disk sprout cultivation device, its mainly includes the sprout cultivation dish that the rectangle set up to the surface of arbitrary one side of sprout cultivation dish evenly is provided with vertically and horizontally staggered's a plurality of V-arrangement grooves, and the V-arrangement groove is divided into a plurality of sizes and equals the same shape with the sprout cultivation dish, and marginal position interconnect's connecting plate. The central part of each connecting plate is provided with a seedling hole which is sunken towards the opening direction of the V-shaped groove. The seedling cave is the inverted cone cylindric to seedling cave lateral wall and lower bottom are equipped with a plurality of hydrophobic holes that link up, and each hydrophobic hole all is equipped with one section breach that extends to all around. The inner wall surface of the seedling hole is provided with a root fixing pile extending towards the central axis direction.
Preferably, the whole seedling raising tray is designed to have biodegradability, and the materials for manufacturing the seedling raising tray are mainly natural materials, such as: bioplastics made from corn starch, and biodegradable plastics produced from traditional petrochemicals designed for their rate of decomposition.
Preferably, the connecting plate of seedling cave is located one side of seedling cave, is close to the connecting plate outer edge and is equipped with the annular circumference and sets up the stiffening rib. Stamp holes which are longitudinally arranged in a penetrating way are arranged between the adjacent connecting plates.
Preferably, a pull cord is included that connects the reinforcing ribs of each seedling well. The two opposite sides of the reinforcing rib are connected with fixing blocks. The stay cord is including the first connecting wire between two fixed blocks of connecting same connecting plate, and arbitrary one side that first connecting wire hugs closely the seedling cave outer wall of telling is walked around to be connected fixedly with the fixed block. The rice transplanting machine also comprises a second connecting line connected between the fixed blocks on the two adjacent connecting plates, the length of the second connecting line is equal to the seedling distance in the actual rice transplanting process, and two ends of the second connecting line are fixedly connected with the fixed blocks on the adjacent connecting plates.
Preferably, the rice seedling planting machine comprises a seeding plate covered on a seedling raising disc, wherein the seeding plate is provided with a pit corresponding to the central part of each seedling hole, and the capacity of the pit is slightly higher than that of a single rice seed volume and is less than two to three rice seed volumes. The bottom of the pit is provided with a cross opening.
Preferably, the gravity culture shelf used for bearing the seedling raising tray of any one of claims 1 to 5 is characterized in that: the gravity cultivation frame comprises a cylindrical rolling cage, a first hollow shaft head and a second hollow shaft head are arranged at two ends of the rolling cage respectively, and the first hollow shaft head and the second hollow shaft head are set coaxially with the rolling cage. The rolling cage is characterized by further comprising supports arranged at two ends of the rolling cage, the bottoms of the supports are fixed with the ground, and bearings matched with the first hollow shaft head and the second hollow shaft head are respectively arranged at the tops of the supports. The rolling cage is characterized by further comprising a plurality of transverse shafts circumferentially arranged on the side of the ring rolling cage, and the transverse shafts are all set in parallel with the rolling cage. The tray for holding the seedling raising tray is hung on the cross shaft, the two ends of the tray are fixedly provided with the suspension arms, and the tops of the suspension arms are matched with the cross shaft through shaft holes.
Preferably, the upward side of the tray is provided with fixing clamps at the peripheral edge, one end of a fixed arm of each fixing clamp is vertically connected and fixed with the tray, and the middle position of a movable arm of each fixing clamp is hinged with the top of the fixed arm through a hinge shaft. The two ends of the return spring are respectively connected and fixed with the movable arm and the fixed arm.
Preferably, the spray pipe is nested in the second hollow shaft head, and penetrates into the rolling cage from the outside of the rolling cage through the second hollow shaft head. The shower is located the inside one end of roll cage and is equipped with the location axle, and the location axle penetrates inside the first hollow shaft to with the cooperation of the hollow position shaft hole of first hollow spindle nose. The pipe wall of the spray pipe in the inner range of the rolling cage is densely provided with through water spray holes. One end of the spray pipe positioned outside the rolling cage is connected with the water outlet end of the water feeding pump through a water pipe.
Preferably, the device comprises a driving mechanism for driving the rolling cage to rotate, a first bevel gear is coaxially connected to one end, away from the roller, of the first hollow shaft head, a transmission shaft perpendicular to the ground is arranged on one side, away from the rolling cage, of the support corresponding to the first hollow shaft head, and a second bevel gear meshed with the first bevel gear is connected to the top of the transmission shaft. One end of the transmission shaft, which is far away from the second bevel gear, is provided with a driven gear. The driving mechanism comprises a double-output-shaft motor arranged at the bottom of the transmission shaft, and a first shaft and a second shaft are respectively arranged at two ends of the double-output-shaft motor. The first shaft of the double-output shaft motor is connected with a driving gear in meshing transmission with the driven gear.
Preferably, including wind-force actuating mechanism, wind-force actuating mechanism includes that the top is equipped with the windmill tower of large-scale rotor, and the windmill tower bottom is equipped with the output shaft. The output shaft rotates synchronously with the large rotor wing through a transmission mechanism. The output shaft is of a hollow structure, and a one-way bearing is coaxially arranged inside the output shaft. The second shaft of the double-output-shaft motor is coaxially embedded into the one-way bearing. The output shaft transmits torque to the second shaft through the one-way bearing.
The invention has the beneficial effects that: each seedling grows in the respective seedling hole, so that the seedling has an independent growth space, and the root hairs cannot be intertwined with other adjacent seedlings.
The seeds can be uniformly put into the seedling holes of the seedling raising tray by only one spreading and scraping of the seeding plate. The seedlings can obtain sufficient nutrients in the independent growth space, and the growth and development of the seedlings are facilitated.
In the process of cultivating the rice seedlings, the rice seedling raising tray is placed into the tray of the gravity cultivation frame and fixed through the fixing clamp, the cultivation frame rotates at a certain speed under the driving of the driving mechanism, at the moment, under the action of centrifugal force, the rice seedlings obtain more gravity than that obtained in the process of cultivation on the normal ground, therefore, the rice seedlings can thrive, the external force resistance of the rice seedlings cultivated in a high-gravity environment can be improved, and the rice seedlings are not easy to damage in the later-stage transportation and rice transplanting process. Meanwhile, the gravity culture rack is provided with an axis spraying system, so that the problem of irrigation in motion is completely solved.
The seedling tray is provided with a seedling separating pull rope, so that the mechanical structure of the rice transplanter can be simplified, and the seedling separating work can be completed only by fixing a fixing head at one end of the rice field and moving the seedling tray. Therefore, in the transplanting operation, the seedlings do not need to be taken out from the seedling raising tray, but the seedling holes with the seedlings are directly inserted into the ground together, so that the roots of the seedlings do not have mechanical stress, and the roots of the seedlings are not damaged.
The fertilizer can be automatically degraded after being planted into underground seedling holes along with seedlings, and can be converted into seedling fertilizer, so that the purpose of environmental protection is achieved, and the growth and development of the seedlings are facilitated.
In order to better tear the seedling holes from the seedling raising tray, the ultraviolet aging lamp on the base of the seedling raising tray can weaken the connection part between the seedling holes before the seedling is transplanted, and the mechanical strength is reduced, so that the running resistance of the seedling transplanter is reduced in the seedling transplanting process.
Drawings
FIG. 1 is a partial schematic view of the invention from an oblique top perspective;
FIG. 2 is a bottom schematic view of the present invention;
FIG. 3 is a schematic view of a loading ledge of the present invention;
Detailed Description
The following detailed description will be made in conjunction with the accompanying drawings in an embodiment of the present invention.
Referring to fig. 1, 2 and 3, a soft-disk seedling raising device for mechanically-transplanted rice mainly comprises a rectangular seedling raising disk, wherein a plurality of criss-cross V-shaped grooves are uniformly formed in the surface of any one side of the seedling raising disk, and divide the seedling raising disk into a plurality of connecting plates 3 which are equal in size, identical in shape and connected at edge positions; the central part of each connecting plate 3 is provided with a seedling hole 2 which is sunken towards the opening direction of the V-shaped groove; the seedling hole 2 is in an inverted cone cylinder shape, a plurality of through hydrophobic holes 4 are formed in the side wall and the lower bottom of the seedling hole 2, and each hydrophobic hole 4 is provided with a section of split extending towards the periphery; the inner wall surface of the seedling cavity 2 is provided with a root fixing pile extending towards the central axis direction. The whole seedling tray is designed to have biodegradability, and the materials for manufacturing the seedling tray are mainly natural materials, such as: bioplastics made from corn starch, and biodegradable plastics produced from traditional petrochemicals designed for their rate of decomposition. The connecting plate 3 of the seedling hole 2 is positioned at one side of the seedling hole 2, and a ring is arranged at the outer edge close to the connecting plate 3 and is circumferentially provided with a reinforcing rib 7. Stamp holes 8 which are longitudinally arranged in a penetrating way are arranged between the adjacent connecting plates 3. Comprising a pull rope connecting the reinforcing ribs 7 of each seedling pit 2. Fixing blocks 11 are connected to two opposite sides of the reinforcing ribs 7. The connecting wire is including connecting the first connecting wire 9 between two fixed blocks 11 of same connecting plate 3, and arbitrary one side of the seedling cave 2 outer wall of telling is hugged closely to first connecting wire 9 and is walked around to be connected fixedly with fixed block 11. The rice transplanting machine further comprises a second connecting line 10 connected between the fixing blocks 11 on the two adjacent connecting plates 3, the length of the second connecting line 10 is equal to the seedling distance in the actual rice transplanting process, and two ends of the second connecting line 10 are fixedly connected with the fixing blocks 11 on the adjacent connecting plates 3.
Seedlings independently grow and develop in the respective seedling holes 2, root hairs can be wound on the fixing piles on the inner walls of the seedling holes 2, so that the seedlings are firmly fixed in the seedling holes 2 and cannot break away from the seedling holes 2 no matter being inverted or bumpy, and when the root hairs grow to a certain degree, the root hairs can grow outwards from the drainage holes 4.
The seedlings are grown in the seedling holes 2 of the seedling raising tray, so that the seedlings and the seedling raising tray are of an inseparable structure, and in the later seedling transplanting process, the seedling raising tray can be split into independent individuals along the shape of the stamp hole 8 under the pulling action of the first connecting line 9 and the second connecting line 10 and are connected with each other through the second connecting line 10. The purpose of this kind of design lies in can simplifying transplanter mechanism, only needs to be located the second connecting wire 10 of seedling cave 2 of sprout cultivation dish one end and fixes the head in the paddy field, then pulls whole sprout cultivation dish to the paddy field afterbody, in the in-process of pulling, by the second connecting wire 10 and the first connecting wire 9 under the traction effect, seedling cave 2 is pulled from sprout cultivation dish one by one together with connecting plate 3 to through placing the angle, submerge in the paddy field. Wherein the first connecting lines 9 are used for ensuring that the seedling holes 2 and the connecting plates 3 cannot be pulled to be broken, and the second connecting lines 10 are used for limiting the seedling transplanting distance. The seedling raising tray consisting of the connecting plate 3 and the seedling holes 2 can be automatically degraded in the rice field, the obstruction and pollution to the later-stage seedling development and land utilization can not be caused, and the degraded seedling raising tray can be absorbed by the seedlings in the form of fertilizer.
In order to solve the problem of seeding each seedling hole 2 in the seedling raising tray, the seedling raising tray comprises a movable seeding plate 12 covering the seedling raising tray, a pit 13 is arranged at the central part of the seeding plate 12 corresponding to each seedling hole 2, and the capacity of the pit 13 is slightly higher than that of a single rice seed volume and is less than two to three rice seed volumes. The bottom of the pit 13 is provided with a cross-shaped opening 14. When sowing, the seeds are scattered on the sowing plate 12 at will, the redundant seeds are scraped off by the surface of the sowing plate 12 which is attached by the scraper, 2 to 3 seeds are left in the pits 13, the sowing plate 12 is pressed by the flexible rolling shaft or the pressing plate made of elastic materials, and the seeds are squeezed open the cross-shaped opening 14 under the action of external force and fall into the seedling holes 2 of the seedling raising plate.
According to the influence of gravity on seedling development, still include a gravity culture frame that is used for bearing weight of sprout cultivation dish, wherein gravity culture frame includes columniform roll cage 15, rolls the both ends of cage 15 and is equipped with first hollow spindle nose 16 and the hollow spindle nose 17 of second respectively, and first hollow spindle nose 16 and the hollow spindle nose 17 of second all set for with roll cage 15 is coaxial. The rolling cage further comprises supports 18 arranged at two ends of the rolling cage 15, the bottoms of the supports 18 are fixed with the ground, and bearings matched with the first hollow shaft head 16 and the second hollow shaft head 17 are respectively arranged at the tops of the supports 18. The rolling cage further comprises a plurality of transverse shafts 19 which are circumferentially arranged at the side part of the ring rolling cage 15, and the transverse shafts 19 are all parallel to the rolling cage 15. A tray 20 for containing seedling raising trays is hung on the transverse shaft 19, two ends of the tray 20 are fixedly provided with suspension arms 21, and the tops of the suspension arms 21 are matched with the transverse shaft 19 through shaft holes. The upward side of the tray 20 is provided with a fixing clamp 22 at the edge of the periphery, one end of a fixed arm of the fixing clamp 22 is vertically connected and fixed with the tray 20, and the middle position of a movable arm of the fixing clamp 22 is hinged with the top of the fixed arm through a hinge shaft. The two ends of the return spring are respectively connected and fixed with the movable arm and the fixed arm. The spray pipe 27 is nested in the second hollow shaft head 17, and the spray pipe 27 penetrates into the rolling cage 15 from the outside of the rolling cage 15 through the second hollow shaft head 17. The spray pipe 27 is provided with a positioning shaft 28 at one end inside the rolling cage 15, and the positioning shaft 28 penetrates into the first hollow shaft and is matched with the shaft hole at the hollow part of the first hollow shaft head 16. The spray pipe 27 is densely provided with through water spray holes at the pipe wall in the inner range of the rolling cage 15. One end of the spray pipe 27 positioned outside the rolling cage 15 is connected with the water outlet end of the water feeding pump through a water pipe. The device comprises a driving mechanism for driving the rolling cage 15 to rotate, a first bevel gear 32 is coaxially connected to one end, away from the roller, of the first hollow shaft head 16, a transmission shaft 36 perpendicular to the ground is arranged on one side, away from the rolling cage 15, of the support 18 corresponding to the first hollow shaft head 16, and a second bevel gear 33 meshed with the first bevel gear 32 is connected to the top of the transmission shaft 36. The end of the drive shaft 36 remote from the second bevel gear 33 is provided with a driven gear 35. The driving mechanism comprises a double-output-shaft motor 37 arranged at the bottom of the transmission shaft 36, and a first shaft and a second shaft are respectively arranged at two ends of the double-output-shaft motor 37. The first shaft of the double output shaft motor 37 is connected with a driving gear 34 meshed with the driven gear 35 for transmission. The wind power generation device comprises a wind power driving mechanism, wherein the wind power driving mechanism comprises a wind turbine tower 41 with a large rotor wing arranged at the top, and an output shaft 42 is arranged at the bottom of the wind turbine tower 41. The output shaft 42 is rotated synchronously with the large rotor via a transmission mechanism. The output shaft 42 is of a hollow structure, and a one-way bearing 43 is coaxially arranged inside the output shaft. The second shaft of the double-output-shaft motor 37 is coaxially embedded inside the one-way bearing 43. The output shaft 42 transmits torque to the second shaft through a one-way bearing 43.
The working principle of the culture shelf is as follows: a plurality of cultivation trays are set on the corresponding tray 20 with the circumference of the roller in a gravity-balanced state. The double-output-shaft motor 37 is started to rotate at a high speed through the inner cores of the gears and the transmission action of the transmission shaft 36, when the roller rotates to a certain rotating speed, each tray 20 is thrown up to the outside of the rolling cage 15 under the action of centrifugal force and the constraint force of the transverse shaft 19, the seedlings fixed in the trays 20 by the fixing clamps 22 obtain centrifugal force larger than the normal gravity at this moment, when the seedlings grow and develop under the annular shape, in order to overcome the centrifugal force, the development is stronger, so that the nutrient conveyor can better develop, and meanwhile, the root system of the seedlings can tend to grow downwards under the action of the centrifugal force, so that the roots of the seedlings are deeper to be pricked, and the later-stage seedling transplanting work is simpler and more convenient. In order to ensure that the seedlings have enough water supply, water is pumped into the spraying pipes 27 through the water feeding pump by the water feeding pump and is sprayed out from the water spraying holes, and the rice seedlings in each tray 20 can obtain the same amount of water because the rolling cage 15 is in a rotating state, so that the guarantee is provided for the consistent growth of the rice seedlings.
Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.
Claims (7)
1. The utility model provides a machine transplanting rice floppy disk sprout cultivation device which characterized in that: the seedling raising tray is rectangular, a plurality of criss-cross V-shaped grooves are uniformly formed in the surface of any one side of the seedling raising tray, and the seedling raising tray is divided into a plurality of connecting plates (3) which are equal in size, identical in shape and mutually connected in edge positions by the V-shaped grooves; seedling holes (2) which are sunken towards the opening direction of the V-shaped groove are formed in the central part of each connecting plate (3); the seedling hole (2) is in an inverted cone shape, a plurality of through hydrophobic holes (4) are formed in the side wall and the bottom of the seedling hole (2), and each hydrophobic hole (4) is provided with a section of split extending to the periphery; the inner wall surface of the seedling hole (2) is provided with a root fixing pile extending towards the central axis direction,
the connecting plate (3) of the seedling hole (2) is positioned at one side of the seedling hole (2), and a ring circumferential reinforcing rib (7) is arranged at the outer edge close to the connecting plate (3); stamp holes (8) which are longitudinally arranged in a penetrating way are arranged between the adjacent connecting plates (3),
the pull rope comprises the reinforcing ribs (7) connected with the seedling holes (2); two opposite sides of the reinforcing rib (7) are connected with fixing blocks (11); the pull rope comprises a first connecting line (9) connected between two fixing blocks (11) of the same connecting plate (3), and the first connecting line (9) is tightly attached to any one side of the outer wall of the seedling hole (2) to be wound and is fixedly connected with the fixing blocks (11); the pull rope further comprises second connecting lines (10) connected between the fixing blocks (11) on the two adjacent connecting plates (3), the length of each second connecting line (10) is equal to the seedling distance in the actual rice transplanting process, and the two ends of each second connecting line (10) are fixedly connected with the fixing blocks (11) on the adjacent connecting plates (3).
2. The machine-transplanted rice soft disk seedling raising device as claimed in claim 1, wherein: the rice seedling raising tray comprises a seeding plate (12) covered on the seedling raising tray, wherein a pit (13) is arranged in the central part of the seeding plate (12) corresponding to each seedling hole (2), and the capacity of the pit (13) is slightly higher than that of a single rice seed volume and is smaller than two to three rice seed volumes; the bottom of the pit (13) is provided with a cross opening (14).
3. The machine-transplanted rice soft disk seedling raising device as claimed in claim 1, further comprising a gravity culture rack for bearing the seedling raising disk, wherein the gravity culture rack is characterized in that: the gravity culture rack comprises a cylindrical rolling cage (15), a first hollow shaft head (16) and a second hollow shaft head (17) are respectively arranged at two ends of the rolling cage (15), and the first hollow shaft head (16) and the second hollow shaft head (17) are coaxially set with the rolling cage (15); the device is characterized by further comprising supports (18) arranged at two ends of the rolling cage (15), the bottoms of the supports (18) are fixed with the ground, and bearings matched with the first hollow shaft head (16) and the second hollow shaft head (17) are respectively arranged at the tops of the supports (18); the rolling cage is characterized by further comprising a plurality of transverse shafts (19) which are circumferentially arranged around the side part of the rolling cage (15), wherein the transverse shafts (19) are all parallel to the rolling cage (15); the tray (20) for containing the seedling raising tray is hung on the transverse shaft (19), the two ends of the tray (20) are fixedly provided with suspension arms (21), and the tops of the suspension arms (21) are matched with the transverse shaft (19) through shaft holes.
4. The machine-transplanted rice soft disk seedling raising device as claimed in claim 3, wherein: fixing clamps (22) are distributed on the edge of the periphery of the upward surface of the tray (20), one end of a fixed arm of each fixing clamp (22) is vertically connected and fixed with the tray (20), and the middle position of a movable arm of each fixing clamp (22) is hinged to the top of the fixed arm through a hinge shaft; the movable arm and the fixed arm are fixedly connected with the hinge shaft, and the movable arm and the fixed arm are fixedly connected with the hinge shaft.
5. The machine-transplanted rice soft disk seedling raising device as claimed in claim 3, wherein: a spray pipe (27) is nested in the second hollow shaft head (17), and the spray pipe (27) penetrates into the rolling cage (15) from the outside of the rolling cage (15) through the second hollow shaft head (17); one end of the spray pipe (27) positioned in the rolling cage (15) is provided with a positioning shaft (28), and the positioning shaft (28) penetrates into the first hollow shaft and is matched with a shaft hole at the hollow part of the first hollow shaft head (16); the spray pipe (27) is densely provided with through water spray holes at the pipe wall in the inner range of the rolling cage (15); and one end of the spray pipe (27) positioned outside the rolling cage (15) is connected with the water outlet end of the water feeding pump through a water pipe.
6. The machine-transplanted rice soft disk seedling raising device as claimed in claim 5, wherein: the device comprises a driving mechanism for driving the rolling cage (15) to rotate, wherein one end, far away from the rolling cage (15), of the first hollow shaft head (16) is coaxially connected with a first bevel gear (32), one side, far away from the rolling cage (15), of the support (18) corresponding to the first hollow shaft head (16) is provided with a transmission shaft (36) vertical to the ground, and the top of the transmission shaft (36) is connected with a second bevel gear (33) meshed with the first bevel gear (32); a driven gear (35) is arranged at one end, far away from the second bevel gear (33), of the transmission shaft (36); the driving mechanism comprises a double-output-shaft motor (37) arranged at the bottom of the transmission shaft (36), and a first shaft and a second shaft are respectively arranged at two ends of the double-output-shaft motor (37); the first shaft of the double-output-shaft motor (37) is connected with a driving gear (34) which is in meshing transmission with the driven gear (35).
7. The machine-transplanted rice soft disk seedling raising device as claimed in claim 6, wherein: the wind power generation device comprises a wind power driving mechanism, wherein the wind power driving mechanism comprises a windmill tower (41) with a large rotor wing arranged at the top, and an output shaft (42) is arranged at the bottom of the windmill tower (41); the output shaft (42) rotates synchronously with the large rotor wing through a transmission mechanism; the output shaft (42) is of a hollow structure, and a one-way bearing (43) is coaxially arranged inside the output shaft; the second shaft of the double output shaft motor (37) is coaxially embedded into the one-way bearing (43); the output shaft (42) transmits torque to the second shaft through the one-way bearing (43).
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CN110859099B (en) * | 2019-12-03 | 2021-08-06 | 河南青源天仁生物技术有限公司 | Degradable seedling raising tray and preparation method thereof |
CN115281016A (en) * | 2022-07-18 | 2022-11-04 | 句容润东生态园林有限公司 | Landscape tree seedling breeds case |
CN118266344B (en) * | 2024-05-31 | 2024-07-23 | 黑龙江省农业机械工程科学研究院 | Rice seedling raising device |
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CN1133670A (en) * | 1995-01-31 | 1996-10-23 | 日本甜菜制糖株式会社 | Continuously assembled pots for raising and transplanting seedlings |
CN1138940A (en) * | 1995-06-24 | 1997-01-01 | 洪宗隆 | Seedlings nursing plate |
CN2285048Y (en) * | 1996-04-18 | 1998-07-01 | 邹金亮 | Seeder for raise rice seedling |
KR100852088B1 (en) * | 2007-06-11 | 2008-08-13 | 전제락 | A raising seeding device |
CN203353283U (en) * | 2013-07-25 | 2013-12-25 | 张家港芳香生物科技有限公司 | Disposable degradable seeding-raising tray |
CN206196479U (en) * | 2016-11-10 | 2017-05-31 | 兰巍 | Can jointing type seedling-cultivation plate |
CN106718287A (en) * | 2017-01-05 | 2017-05-31 | 江苏大学 | A kind of seedling-cultivation plate for realizing equidistantly sending seedling |
CN107409795A (en) * | 2017-08-25 | 2017-12-01 | 佛山市田森温室科技有限公司 | A kind of rotary growing device |
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