CN211531783U - Matrix covering type corn interplanting no-tillage seeder - Google Patents
Matrix covering type corn interplanting no-tillage seeder Download PDFInfo
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- CN211531783U CN211531783U CN202020079550.8U CN202020079550U CN211531783U CN 211531783 U CN211531783 U CN 211531783U CN 202020079550 U CN202020079550 U CN 202020079550U CN 211531783 U CN211531783 U CN 211531783U
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Abstract
A matrix covering type corn interplanting no-tillage seeder belongs to the technical field of agricultural production seeding. The utility model provides a current no-tillage seeder seeding quality poor, the big problem of work energy consumption to and current interplanting technique consumes the problem that labour and seeding quality can't be guaranteed. The corn seeder assembly comprises a corn seed box, a corn seeding unit fixedly arranged below the corn seed box and a corn seed guide pipe fixedly arranged below the corn seeding unit, the corn seeding unit is controlled to act through a speed reduction motor, the matrix drill seeder assembly comprises a first matrix box and a drill pipe communicated and arranged below the first matrix box, one end of the corn seed guide pipe is inserted into the lower part of the drill pipe and communicated with the drill pipe, and the grass seed seeder assembly comprises a grass seed box and a seed sowing plate arranged below the grass seed box; the substrate spreader assembly includes a second substrate box and a second substrate spreading tray disposed below the second substrate box.
Description
Technical Field
The utility model relates to a matrix overlay type corn interplanting no-tillage planter belongs to agricultural production seeding technical field.
Background
No-tillage seeding is a protective tillage planting method for seeding in a manner of little tillage or no tillage on the farmland soil covered by straws. The no-tillage seeding technology has the advantages of high seeding efficiency, less work flow, labor force saving and production cost saving; the soil erosion can be effectively prevented, the water is stored, the moisture is preserved, the water evaporation is reduced, and the water and soil loss is avoided; the soil structure is protected, the soil fertility is fertilized, the cultivated land conditions are optimized, and the like, so that the method is accepted by broad farmers, and the no-tillage planter is widely applied. However, the field environment is more complicated than the traditional sowing mode during the operation of the no-tillage sowing machine, and is easily influenced by the straws, the stubbles and the soil, so that the problems that the ditching depth of the ditcher is inconsistent, the seeder is easily blocked and the like are caused, the sowing quality is reduced, and the working energy consumption of the sowing machine is increased.
The interplanting is to plant different crops in the same farmland according to the agronomic requirements of the different crops. Practice proves that interplanting can fully utilize space and natural resources such as light, heat, gas and the like, and the crop yield per unit area is improved. However, the current agricultural machines and tools for interplanting mainly include manual dibbler and simple self-propelled seeder, still need to consume a large amount of labor force in the working process, and the seeding quality can not be guaranteed, so that the corn and forage grass seeder with high mechanization degree and good seeding quality needs to be researched urgently.
SUMMERY OF THE UTILITY MODEL
The utility model relates to a solve the problem that current no-tillage seeder seeding quality is poor, work energy consumption is big to and current interplanting technique consumes the problem that labour and seeding quality can't be guaranteed, and then provide a matrix covering formula corn interplanting no-tillage seeder.
The utility model discloses a solve the technical scheme that above-mentioned technical problem adopted and be:
a matrix covering type corn interplanting no-tillage seeder comprises a frame, a matrix drill assembly, a corn seeder assembly, a grass seed spreader assembly and a matrix spreader assembly which are sequentially and fixedly arranged on the frame, wherein a driving wheel assembly is arranged below the frame, the corn seeder assembly comprises a corn seed box, a corn seeding single body fixedly arranged below the corn seed box and a corn seed guide pipe communicated with the lower part of the corn seeding single body, the corn seeding single body is controlled to act through a speed reducing motor,
the substrate drill assembly comprises a first substrate box and a drill pipe communicated and arranged below the first substrate box, one end of the corn seed guide pipe is inserted at the lower part of the drill pipe and communicated with the drill pipe,
the grass seed spreader assembly comprises a grass seed box and a seed spreading plate arranged below the grass seed box, and grass seeds in the grass seed box are spread to the ground surface through the seed spreading plate;
the substrate spreader assembly comprises a second substrate box and a second substrate spreading disc arranged below the second substrate box, and the substrates in the second substrate box are spread above the grass seeds on the ground surface through the second substrate spreading disc.
Further, matrix drill final assembly still includes installs first matrix broadcast dish, first broadcast housing and be two splitter boxes that the V-arrangement was arranged in the frame below, and the quantity of maize seed case, the free quantity of maize seeding and the quantity of maize seed pipe are two and correspond and arrange side by side in the frame, and the quantity of drill pipe is two, and corresponds between the top of two drill pipes and the first broadcast housing lateral wall through two splitter boxes intercommunication, first matrix broadcast dish level is installed in first broadcast housing, and realizes its circumferential direction in first broadcast housing through first horizontal motor, and first matrix case is adorned admittedly in the frame top, and the bottom opening of first matrix case sets up and communicates with the first broadcast housing below the frame.
Furthermore, a partition plate is vertically arranged at the communication position of the two shunting grooves which are arranged in a V shape, and one end of the partition plate, which is far away from the first substrate sowing plate, is rotatably arranged at the connecting position of the side walls of the two shunting grooves.
Furthermore, an inverted V-shaped splitter plate and two bus plates are fixedly arranged in each drilling guide pipe, wherein the splitter plate is positioned at the lower part of the drilling guide pipe, matrix splitter channels are respectively formed between the two sides of the splitter plate and the inner wall of the drilling guide pipe, the two bus plates are correspondingly and fixedly arranged on the inner walls of the two sides of the drilling guide pipe in an inverted splayed shape, the matrix bus channels are formed between the two bus plates, and one end of the corn seed guide pipe is inserted between the splitter plate and the two bus plates and is arranged close to the splitter plate.
Further, the grass seed broadcaster assembly still includes grass seed pipe and the horizontal motor of third, the grass seed case is adorned admittedly in the frame top, the seed case is installed in the frame below, and the grass seed case passes through the grass seed pipe and communicates with the seed case, and its circumferential direction is realized through the horizontal motor of third to the seed case.
Further, the seed sowing cover is covered outside the seed sowing plate, the seed sowing cover is of a semi-closed structure, and the open end of the seed sowing cover faces to one side away from the drilling conduit.
Further, matrix broadcaster assembly still includes installs second broadcast housing and the horizontal motor of second in the frame below, second matrix case is adorned admittedly in the frame top, and the bottom opening setting of second matrix case just broadcasts the housing intercommunication with the second, and second matrix broadcast dish realizes its circumferential direction through the horizontal motor of second, the second broadcast housing is semi-enclosed structure, and its opening direction is the same with the opening direction of broadcast housing.
Further, still be provided with monitoring system in the frame, monitoring system includes host computer and the probe through line transmission, the probe is installed between the seed metering mouth of seeding monomer and maize seed guide pipe.
Furthermore, a battery pack is also arranged on the frame, and each motor is connected with the battery pack through an electric wire.
Compared with the prior art, the utility model has the following effect:
through the seeder of this application can realize the no-tillage seeding operation of maize and the interplant operation of maize and forage grass. The adoption is directly sowed on the soil surface to cover the matrix of straw decomposition preparation above the seed of scattering, compared with prior art, the seeding effect is better, and the seeding quality is higher, effectively reduces the disturbance of agricultural machine to soil, and then makes the work consume energy littleer, and green is pollution-free, can effectively improve the work efficiency of maize interline interplanting forage grass, greatly reduced working strength.
Drawings
FIG. 1 is a schematic perspective view of the present application;
FIG. 2 is a schematic side view of the present application;
FIG. 3 is a schematic diagram of a simulation of the working process of the present application;
FIG. 4 is a schematic view of the assembly seeding of the substrate drill;
fig. 5 is a sowing schematic diagram of a sowing operation using the sowing machine of the present application;
FIG. 6 is a schematic longitudinal cross-sectional view of the seed tube of FIG. 4;
FIG. 7 is a schematic view of the three-dimensional structure of the assembly of the corn seeder;
FIG. 8 is a schematic view of the connection of a corn seed guide tube to the assembly of a substrate drill;
FIG. 9 is a schematic view of the attachment of the distribution chute to the first substrate spreading plate;
FIG. 10 is a schematic perspective view of the assembly of the grass seed spreader;
fig. 11 is a schematic perspective view of the substrate spreader assembly.
Detailed Description
The first embodiment is as follows: the embodiment is described by combining figures 1-11, a matrix covering type corn interplanting no-tillage planter comprises a frame 1, a matrix drill assembly 2, a corn seeder assembly 3, a grass seed broadcaster assembly 4 and a matrix broadcaster assembly 5 which are sequentially and fixedly arranged on the frame 1, a driving wheel assembly 6 is arranged below the frame 1, wherein the corn seeder assembly 3 comprises a corn seed box 3-1, a corn seeding monomer 3-2 fixedly arranged below the corn seed box 3-1 and a corn seed guide pipe 3-3 communicated and fixedly arranged below the corn seeding monomer 3-2, the corn seeding monomer 3-2 is controlled to act by a speed reducing motor 3-4,
the substrate drill assembly 2 comprises a first substrate box 2-1 and a drill guide pipe 2-2 communicated and arranged below the first substrate box 2-1, one end of a corn guide pipe 3-3 is inserted at the lower part of the drill guide pipe 2-2 and communicated with the drill guide pipe 2-2,
the grass seed spreader assembly 4 comprises a grass seed box 4-1 and a seed spreading plate 4-2 arranged below the grass seed box 4-1, and grass seeds in the grass seed box 4-1 are spread to the ground surface through the seed spreading plate 4-2;
the substrate spreader assembly 5 comprises a second substrate box 5-1 and a second substrate spreading disc 5-2 arranged below the second substrate box 5-1, and the substrate in the second substrate box 5-1 is spread above the grass seeds on the ground surface through the second substrate spreading disc 5-2.
The travelling wheel assembly 6 comprises two groups of travelling wheels and is used for meeting the requirement that the seeder travels and moves in the field. Frame 1 includes the main body frame who is enclosed by the channel-section steel and at main body frame upper surface welded steel sheet for bear each working member of seeder, like corn disseminator assembly 3 etc.. The matrix drill assembly 2, the corn seeder assembly 3, the grass seed broadcaster assembly 4 and the matrix broadcaster assembly 5 are respectively and fixedly arranged on the frame 1 through bolts. The seeder can realize bidirectional operation, does not need to turn around in the working process, can realize seeding and matrix covering circulation reciprocating operation, and obviously improves the working efficiency.
The corn seeding unit 3-2 is prior art and is not described in detail here. The output shaft of the corn seeding unit 3-2 is connected with the speed reducing motor 3-4 to provide power required by seed discharging of the seeding unit, and the speed reducing motor 3-4 is also provided with a motor speed regulator for realizing the speed regulation of the speed reducing motor 3-4 and further controlling the seed discharging speed of the corn. When the corn sowing monomer 3-2 starts to work, the corn seeds 102 are uniformly sown into the corn seed guiding pipe 3-3 at equal intervals through the corn sowing monomer 3-2.
The corn seeds 102 enter the drill pipe 2-2 filled with the matrix through the corn seed guide pipe 3-3, the matrix in the first matrix box 2-1 coats the corn seeds 102 through the drill pipe 2-2 and falls on the ground in a strip shape, and the operations of seeding the corn seeds 102 and covering the matrix are completed.
The first substrate box 2-1 and the second substrate box 5-1 have the same substrate, and the substrate falling on the ground surface through the substrate drill assembly 2 is in a strip shape and is used for covering the corn seeds 102 falling to the ground; the substrate dropped on the ground surface through the substrate spreader assembly 5 is in a scattering shape and is used for covering the grass seeds scattered on the ground surface.
In the reciprocating movement process of the seeder in the field, the corn can be sown firstly, the forage grass can be sown in a return stroke, and the corn can also be sown in the return stroke.
Through the seeder of this application can realize the seeding of no-tillage entirely, at pre-buried filtration irrigation pipe 101 in underground before the seeding, filtration irrigation pipe 101 leads to water after the seeding, and the moisture content of upper soil 100 is guaranteed to the moisture that oozes, satisfies the water supply demand that the seed is grown.
The power that the seeder went in the field derives from the traction force that the solar energy intelligence at ridge both ends pulls mobile platform 103 provides, and matrix covering formula corn interplanting no-tillage seeder realizes the field removal under the effect of traction force, the work of sowing and matrix seeding. When the seeder needs to move transversely in the field, the seeder is firstly pulled to the movable platform 103 under the action of traction force, the movable platform 103 drives the seeder to move transversely, and after the seeder moves to a proper position, the seeder is moved out of the movable platform 103 through the traction force to perform subsequent seeding and interplanting operations. The solar intelligent traction mobile platform 103 is a mobile winch structure, and the movement and the guidance are realized by drawing the seeder through a steel wire rope.
The substrate adopted by the application is prepared by decomposing the straws, so that the resource utilization of the straws is realized, the nutrients of the soil 100 are improved, the physical and chemical properties of the soil 100 are improved, and the substrate has important significance for realizing agricultural green production.
Through the seeder of this application can realize the no-tillage seeding operation of maize and the interplant operation of maize and forage grass. The direct seeding is carried out on the surface of the soil 100, and the substrate prepared by decomposing straw is covered above the sowed seeds, so that compared with the prior art, the sowing effect is better, the sowing quality is higher, the disturbance of agricultural machinery to the soil 100 is effectively reduced, the working energy consumption is smaller, the environment-friendly effect is realized, the pollution is avoided, the working efficiency of interplanting pasture between corn rows can be effectively improved, and the working intensity is greatly reduced.
The substrate drill assembly 2 further comprises a first substrate sowing disc 2-3, a first sowing housing 2-4 and two shunting grooves 2-5 which are arranged in a V shape and are arranged below the rack 1, the number of the corn seed boxes 3-1, the number of the corn sowing monomers 3-2 and the number of the corn seed guiding pipes 3-3 are two and are correspondingly arranged on the rack 1 side by side, the number of the drill guiding pipes 2-2 is two, the top ends of the two drill guiding pipes 2-2 are correspondingly communicated with the side wall of the first sowing housing 2-4 through the two shunting grooves 2-5, the first substrate sowing disc 2-3 is horizontally arranged in the first sowing housing 2-4, the circumferential rotation of the first drill sowing housing 2-4 is realized through a first horizontal motor 2-6, a first substrate box 2-1 is fixedly arranged above the rack 1, the bottom end of the first substrate box 2-1 is provided with an opening and is communicated with a first sowing cover 2-4 below the frame 1.
The number of the corn seed boxes 3-1, the number of the corn sowing monomers 3-2, the number of the corn seed guide pipes 3-3 and the number of the drill sowing guide pipes 2-2 are two and are correspondingly arranged on the rack 1 side by side, so that two rows of sowing are realized. The first spreading cover 2-4 is of a circumferential semi-closed structure and is fixed by a first support frame hung below the rack 1, the rotating power of the first substrate spreading disc 2-3 is provided by a first horizontal motor 2-6, and the rotating speed of the first horizontal motor 2-6 can be adjusted by arranging a motor speed regulator. The two diversion grooves 2-5 are used for averagely diverting the matrixes thrown out of the first matrix spreading plate 2-3 into two groups, and the two groups of matrixes respectively fall on the ground surface through the two drilling conduits 2-2, so that the covering thickness of the matrixes falling from the two drilling conduits 2-2 is basically the same.
The communicated part of the two shunting grooves 2-5 which are arranged in a V shape is vertically provided with a clapboard 2-7, and one end of the clapboard 2-7 which is far away from the first substrate broadcasting disc 2-3 is rotatably arranged at the connecting part of the side walls of the two shunting grooves 2-5. By the design, one end of the partition plate 2-7 is hinged and fixed at the joint of the two branch runners 2-5, the size of the inlet of the two branch runners 2-5 can be adjusted by changing the rotating angle of the partition plate 2-7 relative to the joint of the side walls of the two branch runners 2-5, the quantity of the substrate entering the two drilling guide pipes 2-2 is further adjusted, and finally the covering quantity of the two rows of seeding substrates is adjusted.
An inverted V-shaped splitter plate 2-8 and two bus plates 2-9 are fixedly mounted inside each drilling guide pipe 2-2, wherein the splitter plates 2-8 are located at the lower portion of the drilling guide pipe 2-2, substrate splitter channels are respectively formed between the two sides of the splitter plates 2-8 and the inner wall of the drilling guide pipe 2-2, the two bus plates 2-9 are correspondingly and fixedly mounted on the inner walls of the two sides of the drilling guide pipe 2-2 in an inverted splayed shape, a substrate bus channel is formed between the two bus plates 2-9, and one end of the corn seed guide pipe 3-3 is inserted between the splitter plates 2-8 and the two bus plates 2-9 and is arranged close to the splitter plates 2-8. By the design, the corn seeds 102 discharged by the corn seed guide pipe 3-3 and the matrix falling from the drill pipe 2-2 fall to the ground surface together, and the processes of seeding and matrix covering of the corn seeds 102 are completed. One end of the corn seed guide pipe 3-3 is inserted below the V-shaped flow distribution plate 2-8, so that the interference of the matrix falling in the drill seed guide pipe 2-2 to the corn seed sowing is avoided. The two confluence plates 2-9 are used for converging the dispersed matrixes, promoting the centralized blanking of the matrixes and ensuring that the matrixes are centralized and covered above the corn seeds 102.
The assembly 4 of the grass seed spreader further comprises a grass seed guide pipe 4-3 and a third horizontal motor 4-4, the grass seed box 4-1 is fixedly arranged above the rack 1, the seed spreading plate 4-2 is arranged below the rack 1, the grass seed box 4-1 is communicated with the seed spreading plate 4-2 through the grass seed guide pipe 4-3, and the seed spreading plate 4-2 circumferentially rotates through the third horizontal motor 4-4. The rotating speed of the third horizontal motor 4-4 can be adjusted by setting a motor speed regulator, so as to control the seed sowing quantity. When the seed sowing device starts to work, a seed falling opening at the bottom end of the grass seed box 4-1 is opened, grass seeds fall onto the rotating seed sowing plate 4-2 through the grass seed guiding pipe 4-3 under the action of gravity, and the grass seeds are thrown out of the seed sowing plate 4-2 under the action of centrifugal force and fall onto the ground surface.
The seed sowing cover 4-2 is covered with a seed sowing cover 4-5, the seed sowing cover 4-5 is of a semi-closed structure, and the open end of the seed sowing cover is arranged towards the side away from the drill pipe 2-2. The third horizontal motor 4-4 is fixedly arranged on the seed spreading housing 4-5. The direction and the range of grass seed throwing are limited by arranging the seed throwing cover 4-5.
The substrate broadcaster assembly 5 further comprises a second broadcasting housing 5-3 and a second horizontal motor 5-4 which are arranged below the rack 1, the second substrate box 5-1 is fixedly arranged above the rack 1, an opening at the bottom end of the second substrate box 5-1 is communicated with the second broadcasting housing 5-3, the second substrate broadcasting disc 5-2 realizes circumferential rotation through the second horizontal motor 5-4, the second broadcasting housing 5-3 is of a semi-closed structure, and the opening direction of the second broadcasting housing is the same as that of the second broadcasting housing 4-5. The rotating speed of the second horizontal motor 5-4 can be adjusted by arranging a motor speed regulator, so that the throwing amount of the matrix is adjusted. The second substrate sowing plate 5-2 is correspondingly and fixedly arranged below the frame 1 through a second supporting frame. When the substrate spreader assembly 5 starts to work, the blanking port of the second substrate box 5-1 is opened, the substrate falls above the second substrate spreading disc 5-2 from the blanking port under the action of gravity, the second substrate spreading disc 5-2 is driven by the second horizontal motor 5-4 to rotate at high speed, and the falling substrate is uniformly thrown out by the generated centrifugal force and covers the grass seeds which are spread in advance.
The machine frame 1 is also provided with a monitoring system, the monitoring system comprises a host 7 and a probe 8 which are transmitted through a line, and the probe 8 is arranged between a seed discharging port of a seeding monomer and the corn seed guide pipe 3-3. The design is used for detecting the seeding effect and quality. Host computer 7 is installed in frame 1, and probe 8 transmits the seeding signal who detects for host computer 7, and host computer 7 judges whether seeding has the problem according to the detection index, and when seeding goes wrong, host computer 7 can send out the police dispatch newspaper.
The frame 1 is also provided with a battery pack 9, and each motor is connected with the battery pack 9 through an electric wire. With the design, the battery pack 9 and a plurality of wires form a power supply system to supply electric energy to each motor.
Claims (9)
1. The utility model provides a matrix coverage formula maize interplanting no-tillage seeder which characterized in that: the corn seeder comprises a rack (1), a matrix drill assembly (2), a corn seeder assembly (3), a grass seed spreader assembly (4) and a matrix spreader assembly (5) which are sequentially and fixedly arranged on the rack (1), wherein a running wheel assembly (6) is arranged below the rack (1), the corn seeder assembly (3) comprises a corn seed box (3-1), a corn seeding monomer (3-2) fixedly arranged below the corn seed box (3-1) and a corn seed guide pipe (3-3) communicated with and fixedly arranged below the corn seeding monomer (3-2), the corn seeding monomer (3-2) is controlled to act through a speed reducing motor (3-4),
the substrate drill assembly (2) comprises a first substrate box (2-1) and a drill guide pipe (2-2) communicated and arranged below the first substrate box (2-1), one end of a corn seed guide pipe (3-3) is inserted at the lower part of the drill guide pipe (2-2) and is communicated with the drill guide pipe (2-2),
the grass seed spreader assembly (4) comprises a grass seed box (4-1) and a seed spreading plate (4-2) arranged below the grass seed box (4-1), and grass seeds in the grass seed box (4-1) are spread to the ground surface through the seed spreading plate (4-2);
the substrate spreader assembly (5) comprises a second substrate box (5-1) and a second substrate spreading disc (5-2) arranged below the second substrate box (5-1), and the substrates in the second substrate box (5-1) are spread above the grass seeds on the ground surface through the second substrate spreading disc (5-2).
2. The matrix covering type corn interplanting no-tillage planter as claimed in claim 1, wherein: the matrix drill assembly (2) further comprises a first matrix sowing disc (2-3), a first sowing cover shell (2-4) and two shunting grooves (2-5) which are arranged in a V shape, the number of the corn seed boxes (3-1), the number of the corn sowing monomers (3-2) and the number of the corn seed guiding pipes (3-3) are two and are correspondingly arranged on the rack (1) side by side, the number of the drill guiding pipes (2-2) is two, the top ends of the two drill guiding pipes (2-2) are correspondingly communicated with the side wall of the first sowing cover shell (2-4) through the two shunting grooves (2-5), the first matrix sowing disc (2-3) is horizontally arranged in the first sowing cover shell (2-4), and the circumferential rotation of the drill sowing disc in the first sowing cover shell (2-4) is realized through a first horizontal motor (2-6), the first substrate box (2-1) is fixedly arranged above the rack (1), and the bottom end opening of the first substrate box (2-1) is arranged and communicated with the first broadcast sowing encloser (2-4) below the rack (1).
3. The matrix-covered corn interplanting no-tillage planter as claimed in claim 2, wherein: the communicated part of the two shunting grooves (2-5) which are arranged in a V shape is vertically provided with a clapboard (2-7), and one end of the clapboard (2-7) far away from the first substrate sowing disc (2-3) is rotatably arranged at the connecting part of the side walls of the two shunting grooves (2-5).
4. The substrate-covered corn interplanting no-tillage planter as claimed in claim 3, wherein: an inverted V-shaped splitter plate (2-8) and two bus plates (2-9) are fixedly mounted inside each drilling guide pipe (2-2), wherein the splitter plates (2-8) are located at the lower portion of the drilling guide pipe (2-2), matrix splitter channels are respectively formed between the two sides of the splitter plates (2-8) and the inner wall of the drilling guide pipe (2-2), the two bus plates (2-9) are correspondingly and fixedly mounted on the inner walls of the two sides of the drilling guide pipe (2-2) in an inverted splayed shape, a matrix bus channel is formed between the two bus plates (2-9), and one end of the corn seed guide pipe (3-3) is inserted between the splitter plates (2-8) and the two bus plates (2-9) and is arranged close to the splitter plates (2-8).
5. The substrate-covered corn interplanting no-tillage planter as claimed in claim 1, 2, 3 or 4, wherein: the grass seed broadcaster assembly (4) further comprises a grass seed guide pipe (4-3) and a third horizontal motor (4-4), the grass seed box (4-1) is fixedly mounted above the rack (1), the seed sowing plate (4-2) is mounted below the rack (1), the grass seed box (4-1) is communicated with the seed sowing plate (4-2) through the grass seed guide pipe (4-3), and the seed sowing plate (4-2) realizes circumferential rotation through the third horizontal motor (4-4).
6. The substrate-covered corn interplanting no-tillage planter as claimed in claim 5, wherein: the seed sowing cover (4-5) is covered outside the seed sowing plate (4-2), the seed sowing cover (4-5) is of a semi-closed structure, and the open end of the seed sowing cover is arranged towards one side away from the drilling conduit (2-2).
7. The substrate-covered corn interplanting no-tillage planter as claimed in claim 1, 2, 3, 4 or 6, wherein: the substrate broadcaster assembly (5) further comprises a second broadcasting housing (5-3) and a second horizontal motor (5-4) which are arranged below the rack (1), the second substrate box (5-1) is fixedly arranged above the rack (1), a bottom opening of the second substrate box (5-1) is arranged and communicated with the second broadcasting housing (5-3), the second substrate broadcasting disc (5-2) realizes circumferential rotation through the second horizontal motor (5-4), the second broadcasting housing (5-3) is of a semi-closed structure, and the opening direction of the second broadcasting housing is the same as that of the second broadcasting housing (4-5).
8. The substrate-covered corn interplanting no-tillage planter as claimed in claim 7, wherein: still be provided with monitoring system on frame (1), monitoring system includes host computer (7) and probe (8) through line transmission, probe (8) are installed between the seed metering mouth of seeding monomer and maize seed guide pipe (3-3).
9. The substrate-covered corn interplanting no-tillage planter as claimed in claim 8, wherein: the frame (1) is also provided with a battery pack (9), and each motor is connected with the battery pack (9) through an electric wire.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN202020079550.8U CN211531783U (en) | 2020-01-14 | 2020-01-14 | Matrix covering type corn interplanting no-tillage seeder |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN202020079550.8U CN211531783U (en) | 2020-01-14 | 2020-01-14 | Matrix covering type corn interplanting no-tillage seeder |
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CN111052914A (en) * | 2020-01-14 | 2020-04-24 | 中国热带农业科学院南亚热带作物研究所 | Matrix covering type corn interplanting no-tillage seeder |
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CN111052914A (en) * | 2020-01-14 | 2020-04-24 | 中国热带农业科学院南亚热带作物研究所 | Matrix covering type corn interplanting no-tillage seeder |
CN111052914B (en) * | 2020-01-14 | 2024-05-07 | 中国热带农业科学院南亚热带作物研究所 | Matrix covered corn interplanting no-tillage planter |
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Granted publication date: 20200922 |