DE202017104254U1 - Working unit of the potato planter - Google Patents

Abstract

The working unit (1) of the potato planter comprising the frame (2) and the assembly group of working tools attached to the frame (2) for the treatment of the shape of the dam, characterized in that the assembly group of working tools for the simultaneous treatment of at least two dams (3 , 3 ') and includes a dam blade (4), an upper left mold (6), an upper right mold (6'), a left side mold (8) and a right hand mold (8 ') where the Dyke share (4) has the trapezium average in the plane perpendicular to the direction of movement with the baseline above to form a trackless furrow (5) between two dams (3, 3 '), the upper molds (6, 6') are arranged horizontally and connect symmetrically from the two sides of the dam share (4) to form the upper parts of the dams (3, 3 '), with their labor rights in an arc (bowl-shaped form) or in the Shape of a V to form the infiltration troughs (7) are formed with the depth of 10 to 50 mm, and their inner edges, which rest against the perch family (4) are lower than their outer edges, which are turned away from the perch family (4), and the lateral forming tools (8, 8 ') for forming the sidewalls of the dams (3, 3') adjoin upper molds (6, 6 ') and thus form the shape of an isosceles trapezium.

Description

Field of engineering

The technical solution relates to the field of agriculture, specifically the working unit of the potato planter with the assembly group of tools for the shaping of dams and furrows and for the application of fertilizers in dams in the planting of potatoes.

Previous state of the art

The potato planters are used to plant the tubers in beds, to cover them and to form a dam. For the overlapping of the tubers and for the shaping of the dams, the working units are used, which consist of a frame that carries the working tools, especially the group of shaped sheets, and which form a dam above the tubers, whose shape depends on the shape and depends on the setting of the mold sheets and the properties of the soil. In most cases, double-row or four-row laying machines are used, which form the track and trackless furrows between the individual dams. The main disadvantage of the known working units is that their construction is not suitable for improving the retention of the precipitation water in the dam and for limiting the surface run-off of the water which runs from the raised center of the dams on the sides of the dams into the furrow. Precipitation water trailing the slopes of the dams accumulates in the furrows and in the case of dependent land it is the cause of surface runoff, erosion and related loss of soil and nutrients. The main object of the technical solution, therefore, is to form such a working unit and assembling group of molds which would form the dam with an improved shape and which would secure the limitation of the surface runoff and the improvement of the retention of the precipitation water as a result of the design of the dam itself.

To increase the infiltration of precipitation water into the dam, plant potting and dike construction have been used to date as the most common anti-erosion measure, reducing the risk of erosion by up to 85% compared to classical technology of cultivation. Plant potting and dike-building are most commonly carried out in the middle, undifferentiated furrow, where the fixed blades or the fixed dike share on the top of the dam alternately form the holes and dykes. In the technology of potato-growing with the stoning with respect to the attachment of the stones and tubers in the track furrow it comes after the passage of the technique usually to form a compact paved layer, if it is very difficult in with the holes and dykes Help to make the blades. With the help of a special adapter to the potato planter, the holes on the surface of the dams and furrows can be expressed in the soil profile. However, the soil and walls of the dams thus formed are often fastened with worse infiltration capabilities for the water from the precipitation than holes with the small dikes formed by the wheel with shovels and the more intense precipitation then leads to their faster blockage through the washed-up earth mass. A further object of the technical solution is therefore the formation of an improved construction of the perforated paddle wheel and vanes which would overcome the above deficiencies.

Other implements worn on the frame of the potato planter are applicators of mineral fertilizers for local application when planted on the sides of the tubers. The subterranean local application has many advantages compared to the surface application, such as: the application of fertilizers only in dams and not in furrows, the minimization of nitrogen losses by the volatilization of ammonia, the lower content of nitrates in the soil and their losses Flooding, the higher utilization of nutrients by the plants u. Ä. are. In recent years, the fertilizers are often applied by means of small application flocks, which are placed in front of the set of plants, in the bands in the two sides of the tuber usually at a distance of 10-12 cm at the level of the lower part of the tuber or below applied the tuber. The deeper the fertilizer is applied, the greater the draft resistance of the small flocks, it can cause the wet soil to fall and worsen its patency between the small flocks, what the remnants after harvesting or the roots of weeds (eg ) deteriorate. To eliminate these problems, a larger distance of the application shares (25 cm and more) is selected. In the more shallow application to the level of tubers, the fertilizers are painted by the set of people in the pages. The fertilizer can then be applied to the lower humidity and smaller rooting locations, as reflected by the lower utilization of nutrients by the plants, especially over more dry years. The largest use of nutrients from the applied fertilizers in potato cultivation without irrigation at the distance of the fertilizer is up to 10 cm from the center of the tuber. The final task in the construction of the new The working unit of the potato planter is therefore the improvement of the uniformity of the application of fertilizers and its variable distribution in different places in the dam with the more stable water regime for better utilization of nutrients by the plants.

Principle of the technical solution

The shortcomings of the known working units described above are eliminated by the working unit of the potato planter according to the presented technical solution, which includes a frame and an assembly group of the working tools.

The principle of the technical solution is that the assembly group of working tools adapted for the simultaneous adaptation of two dams, possibly for the adaptation of more pairs dams and that they a dam merge, an upper left mold, an upper right mold, a left side mold and includes a right side molding tool. The perch has the trapezoidal cross section with a broad baseline at the top to form a trackless furrow between two dams. Upper molds are arranged horizontally and symmetrically connect from the two sides to the percussion to form the upper parts of the dams, with their working parts formed into an arc or into the V-shape to form the cup-shaped infiltration channels having the depth of 10 to 50 mm are. The inner edges of the upper molds, which rest against the percussion, are lower than their outer edges, which are turned away from the perch. The side molds, which connect to upper molds to form the side walls of the dams, close to the upper molds and thus form the shape of an isosceles trapezium. The dams, which are formed by this Zusammenleggruppe the molds are by the formation of the bowl-shaped infiltration channels on the upper parts of the dams, by the all extension of the upper parts of the dams and by their embankment toward the center, by a moderate bevel their side walls and characteristic of the reduction of the depth of the middle trackless furrow. This shaping allows the retention of precipitation water from a larger area.

In the advantageous embodiment of the technical solution, the advantage of achieving an even higher effect of retaining the precipitation water, the working time further includes a rotatable Pflanzlochrad, which is mounted behind the percussion and the circumference with the blades for the formation of the holes and the dyke is provided in the middle trackless furrow. The blades of the rotatable Pflanzlochrads are angularly adjustable in the direction of the percussion and locked in the selected position. The rotatable Pflanzlochrad serves to form the holes and the dikes in the middle trackless furrow. By turning the blades, it is possible to adapt the planting hole and the dike construction to the width of the furrow or the character and the dependence of the property and thus to form a broken trackless furrow with the larger surface and with the better anti-erosion properties.

Furthermore, it is advantageous if on the lower part of the blades at least one loosening tooth is formed, which serves to achieve the optimal loosening and the coarse structure on the bottom of the holes formed.

In a further advantageous embodiment of the technical solution, the working unit further includes at least one dike share, which is attached to the upper mold to form the elongated holes and dikes in the bowl-shaped infiltration channel on the upper part of the dams, the dike share with the drive to the oscillating Movement of the dike group in the vertical direction is connected. The dike group forms a broken bowl-shaped infiltration channel and further improves the infiltration and anti-erosion properties of the dams.

In the advantageous embodiment of the technical solution, the work unit includes two dyke shares, the left dike share is mounted behind the upper left mold and the right dike share is mounted behind the upper right mold. The drive of the dyke shares is advantageously formed by a crank mechanism which is connected to the rotatable Pflanzlochrad. From the point of view of the optimum properties of the holes and dykes formed, it is advantageous if the width of the dyke share is in the range of 0.03 to 0.2 m and if the height of the stroke of the dyke shares in the range of 0.02 to 0.08 m lies.

In another advantageous embodiment of the technical solution, the working unit further includes at least two applicators of the mineral fertilizer for each dam, which are arranged in different locations of the area demarcated by the working tools for the local application of the fertilizer, with the advantage then closing four applicators of the Mineral fertilizer for each dam located around the central area of the dam intended for laying potato tubers.

Application of fertilizers in places with greater moisture-proofness, eg near the tuber or directly to the tuber, in the zone with the better water regime in the adapted form of the dam, or in the vicinity of the middle trackless flattened furrow, the adapted by the rotatable Pflanzlochrad increases the utilization of nutrients from the applied fertilizers of the plants and the stability of the yields of the tubers and their quality. Application of smaller doses of fertilizer to multiple sites in the dam improves rooting, speeds up the absorption of nutrients and reduces the risk of leaching losses.

In order to make it possible to optimize the dosage and the application of the fertilizer in different locations in the dam, it is advantageous if the applicators are connected to the Diffuseuren that connected by a blower for pneumatic transport of mineral fertilizer from the connected to the reservoir of mineral fertilizer Dosing system are driven, and individual applicators or connected pairs of applicators are connected to the diffuser via distributor / mixer. The dose and the type of fertilizer shall be optimized according to the specific precipitation and soil conditions of each site, after the risk of erosion and the elutriation of nutrients, with the binding to the innovated form of the dam, through the assembly group of the molds, through the rotatable Pflanzlochrad and is formed by the dyke shares of the working unit according to the technical solution.

Overall, the advantages of the potato planter working unit according to the technical solution are that it forms an innovated form of the dam, which improves the retention of the precipitation water and restricts its surface runoff. It further eliminates the strengthening or scraping of the bottom of the hole at the planting hole, and conversely, it forms the loosened holes with the improved infiltration of the precipitation water. Last but not least, it allows variable application of the fertilizer in different doses in different places in the dam, depending on the water regime and other conditions.

Explanation of the drawings

The technical solution is explained in more detail by means of the drawings, where the

1 Perspective view of the work unit,

2 Perspective view of the assembly group of work tools,

3 Perspective view of the assembly group of working tools for forming two dams,

4 Cross section through two dams, which are loud through the assembly group of work tools 3 be treated,

5 Cross section through two dams, which are loud through the assembly group of work tools 3 treated with the continuous bowl-shaped infiltration channels,

6 Perspective view of the assembly group of the working tools 3 supplemented with the rotary planter wheel, with the broken middle trackless furrow and with the broken bowl-shaped gutters,

7 Cross section through the assembly group of work tools aloud 6 treated with the schematic diagram of the small dyke shares, which are attached to the two sides of the Pflanzlochrads,

8th Cross section through two dams, loud by the working tools 6 and 7 be treated,

9 Longitudinal section through the interrupted mean trackless furrow treated by the rotary planting hole wheel,

10 Longitudinal section through the broken bowl-shaped infiltration channel, which is treated by a small dike group,

11 Circuit diagram of the applicators in the system for dosing the mineral fertilizer,

12 Section through the working unit, which is provided with two applicators of mineral fertilizer for each dam,

13 Section through the working unit, which is provided with three applicators of mineral fertilizer for a dam and with two applicators for the second dam,

14 Section through the work unit, which is provided with four applicators of mineral fertilizer for each dam,

15 View on the rotatable Pflanzlochrad with the loosening teeth.

Examples of the realization of the technical solution

It is understood that the concrete incidents described below and illustrated realization of the technical solution for illustration, rather than restriction of the technical solution for the given examples are presented. Those skilled in the art will or may be able to ascertain, using routine experimentation, a greater or lesser number of equivalents to the specific implementations of the technical solution described herein. These equivalents are also included within the scope of the following claims.

The work unit 1 The potato planter, not shown, has a welded frame 2 made of steel profiles on which the working tools to treat the shape of two dams 3 . 3 ' at the same time and for the application of mineral fertilizers in the dams thus formed 3 . 3 ' around the potato tuber 15 to be carried around.

On 2 to 5 is the assembly group of the basic working tools for shaping the new form of dams 3 . 3 ' displayed. It is the dam merge 4 , the upper left mold 6 , the upper right mold 6' , the lateral left mold 8th and the right side mold 8th ,

On 2 . 3 . 4 This assembly group is illustrated independently to illustrate, in reality, it is attached to the dam body, which is part of the frame 2 so make out how 1 is apparent. The assembly group of the press plates 4 . 6 . 6' . 8th . 8th has the optimized form for making an innovative form of dams 3 . 3 ' , The dambands 4 has the trapezoid average with the wider baseline above. It ensures the formation of a narrowed and flattened middle trackless furrow 5 Starting from the water from the upper parts of the dams 3 . 3 ' back hold. They are through the upper molds 6 . 6' shaped, which are designed horizontally and from the two sides to the perch 4 symmetrically connect the lower, ie the working surfaces of the upper mold, 6 . 6' are formed in the shape of an asymmetrical open letter "V" as out 4 is apparent. They can also be formed into a bow or other convex shape. The consequence of the action of the upper molds 6 . 6' is the formation of the bowl-shaped infiltration channels 7 on the upper parts of the dams 3 . 3 ' , which serve to retain the rainwater. The infiltration channels 7 in the middle of the depth can be in the range of 10-50 mm, optimally around 20 mm.

Another important feature of the upper molds 6 . 6' is the uneven height of their edges. The inner edges, which are connected to the top of the dam 4 abut, lie lower than their outer edges, that of the Causeway 4 are averted. This design limits the running down of precipitation water on the outsides of the dams 3 . 3 ' and conversely, it ensures that most of the rainwater in the bowl-shaped infiltration channel 7 on the upper part of the dams 3 . 3 ' , or in the trackless furrow with holes and small dams is collected. The upper parts of the dams 3 . 3 ' are also extended in comparison with the previous form, they have the width of 250-350 mm. The outside walls of the dams 3 . 3 ' are through the lateral molding tools 8th . 8th molded to the upper molds 6 . 6' they form an isosceles trapezoidal shape and are arranged obliquely against each other at an angle of 40 to 50 °, which compares with the previous forms of dams 3 . 3 ' a more moderate draft and also contributes to slowing down the discharge of rainwater.

To further improve the retention of the water from precipitation and to limit erosion serve other tools, namely the rotatable Pflanzlochrad 9 for plant potting and dike-building the middle trackless furrow 5 , and the dyke shares 12 . 12' for potting and dike-building the bowl-shaped infiltration channels 7 on the upper parts 3 . 3 ' , These tools and their effects are on 6 to 10 displayed. The rotatable Pflanzlochrad 9 is with the blades 10 provided in the furrow 5 the holes alternately with small dams form, as above all 9 visible, and so they form a broken furrow 5 that have even better retention capabilities than the uninterrupted rut 5 has that up 3 is shown. The shovels 10 are in the direction of Moundhide 4 angularly adjustable and lockable in the selected position, because they are attached to the rotatable pin with the thread with the lock by a nut, as shown 9 is apparent. Turning the blades 10 can be the width of the furrow 5 or the requirements for judging and the size of the dams can be adjusted according to the dependence of the property. The edges of the blades 10 can either be smooth as it is on 9 is pictured, or they can with one to three loosening teeth 11 Be provided as it is 15 is apparent. The loosening teeth 11 are used for optimal loosening and to achieve the coarse soil structure on the bottom of the holes, in the middle trackless furrow 5 are formed.

On 7 . 10 and 12 are the dyke shares 12 . 12' pictured at the top Molds 6 . 6' are attached and used to form the holes and dams in the bowl-shaped infiltration channels 7 on the upper parts of the dams 3 . 3 ' serve. It is possible that the planting hole and the dike construction are minimal at one of the gutters 7 However, it is the treatment of the two gutters 7 at the same time advantageous. The dyke shares 12 . 12' are alternately lifted and lowered during the movement of the potato planter, so they form in the gutter 7 Holes alternately with the dykes, like out 10 is apparent. The width of the dike group 12 . 12' is 0.03 to 0.2 m depending on the set depth of the dike and the depth of 0.02 to 0.08 m with the possibility of adjusting the length of the dike from 0.05 to 0.8 m, after the character and the dependence of the terrain. The vertical swinging movement of the dyke shares 12 . 12' is from the crank mechanism 13 in connection with the rotatable Pflanzlochrad 9 hedged, like out 1 and 12 is apparent.

The work unit 1 As further working tools can also applicators 14 of mineral fertilizer 18 Include that while moving the potato planter into the dams 3 . 3 is introduced. For every dam 3 . 3 ' are in the area, by the dam flock 4 and through the molds 6 . 6' . 8th . 8th is delimited, two to four applicators 14 arranged, in different areas of the average of the dams 3 . 3 ' , The positions of the applicators 14 in the range of the average of the dams 3 . 3 ' are made 12 to 14 can be seen where these positions with the positions of the reference numerals 18 containing the doses of the applied mineral fertilizer 18 from the applicators 14 denote, cover. The cheapest option is the use of four applicators 14 , in principle, around the central area of the dams 3 . 3 ' in which the potato tuber 15 as it is laid out 14 is apparent. The application of smaller doses of fertilizer in several places in the dam 3 . 3 ' improves the rooting of the dam 3 . 3 ' It accelerates the intake of nutrients and reduces the risk of nutrient loss through flushing. The application of the fertilizer 18 under the tuber 15 allows better utilization of nutrients in more dry years. The application of the fertilizer 18 under the bottom of the infiltration channel 7 allows fertilization in the form of fertilizer potting after precipitation. The application of the fertilizer 18 next to the tuber 15 towards the middle trackless furrow 5 allows the use of the zone with better humidity conditions and greater moisture safety. Cans and type of mineral fertilizer 18 and its attachment in the dam 3 . 3 ' can be optimized according to the specific precipitation and soil conditions of each site, the risk of erosion and the elutriation of nutrients in the lower stratum, and it is possible to increase the dosage of fertilizers 18 into the zones with the greater moisture safety for better utilization of the nutrients from the applied granulated fertilizers 18 to adapt variably through the plants.

For dosage of fertilizers 18 the conventional gravitational dosing, or the combination of gravitational and pneumatic dosing can be exploited. However, as the cheapest and most effective, the pneumatic metering scheme shows up 11 is shown. In this case of execution are the applicators 14 with the diffusers 16 that by the blower 17 are connected via the in the applicators 14 the mineral fertilizer 18 from the reservoir 20 , which is arranged on the potato planter supplied. For the basic dosage of the fertilizer 18 serve the dosing 18 at the outlet from the reservoir 20 attached, but the control of the distribution of fertilizer 18 in individual applicators 14 is from the distributors / mixers 21 secured, the first behind the Diffuseuren 16 are attached. The distribution or mixing of fertilizers into individual applicators 14 can be done manually or automatically. Single applicators 14 in different areas of the average of the dams 3 . 3 ' then ensure the controlled dosage of fertilizers 18 in optimal zones, as described above.

Industrial Applicability

The working unit according to the technical solution can be used as a working part of potato planters in agriculture.

LIST OF REFERENCE NUMBERS

1

 work unit

2

 frame

3

 dam

3 '

 dam

4

 Damm crowd

5

 mean trackless furrow

6

 upper left mold

6'

 upper right mold

7

 bowl-shaped infiltration channel

8th

 lateral left mold

8th

 lateral right mold

9

 rotatable Pflanzlochrad

10

 shovel

11

 loosening teeth

12

 left dike crowd

12'

 right dike crowd

13

 crank mechanism

14

 Applicator of the mineral fertilizer

15

 potato tuber

16

 diffuseur

17

 fan

18

 mineral fertilizers

19

 dosing

20

 reservoir

21

 Distributor / mixer

Claims (10)

The work unit ( 1 ) of the potato planter, the frame ( 2 ) and the assembly group of the frames ( 2 ) attached working tools for the treatment of the shape of the dam, characterized in that the assembly of the working tools for the simultaneous treatment of at least two dams ( 3 . 3 ' ) and a group of dams ( 4 ), an upper left mold ( 6 ), an upper right-hand mold ( 6' ), a lateral left mold ( 8th ) and a right side mold ( 8th ), where the dike group ( 4 ) has the trapezium average in the plane leading to the direction of movement with the baseline at the top to form a trackless furrow ( 5 ) between two dams ( 3 . 3 ' ) is vertical, the upper molds ( 6 . 6' ) are arranged horizontally and close from the two sides to the perch ( 4 ) to form the upper parts of the dams ( 3 . 3 ' ) in a bow (bowl-shaped shape) or in the shape of a V to form the infiltration troughs ( 7 ) are formed with the depth of 10 to 50 mm, and their inner edges, which are connected to the perch ( 4 ) are lower than their outer edges, that of the Mammal ( 4 ) and the lateral forming tools ( 8th . 8th ) to form the sidewalls of the dams ( 3 . 3 ' ) connect to upper molds ( 6 . 6' ) and thus form the shape of an isosceles trapezium. The work unit according to claim 1, characterized in that it further comprises a rotatable Pflanzlochrad ( 9 ), which is behind the causeway ( 4 ) and that on the circumference with the blades ( 10 ) for the formation of holes and dykes in the middle trackless furrow ( 5 ), the blades ( 10 ) in the direction to the dike group ( 4 ) are angularly adjustable and can be locked in the selected position. The working unit according to claim 2, characterized in that on the lower part of the blades ( 10 ) at least one loosening tooth ( 11 ) is formed. The work unit according to one of claims 1 to 3, characterized in that it further comprises at least one dyke share ( 12 . 12' ) attached to the upper mold ( 6 . 6' ) to form the holes and dykes at the upper part of the dams ( 3 . 3 ' ) is arranged, the dike crowd ( 12 . 12' ) with the drive for the oscillating movement of the dyke share ( 12 . 12' ) is connected in the vertical direction. The work unit according to claim 4, characterized in that it comprises two dyke shares ( 12 . 12' ), whereby the left dike group ( 12 ) behind the upper left mold ( 6 ) is arranged and the right dike crowd ( 12' ) behind the upper right mold ( 6' ) is arranged. The working unit according to claims 2 and 5, characterized in that the drive of the dyke shares ( 12 . 12' ) by the crank mechanism ( 13 ), which with the rotatable Pflanzlochrad ( 9 ) is formed. The working unit according to claim 6, characterized in that the width of each dike group ( 12 . 12' ) in the range of 0.03 to 0.2 m and the height of the stroke of the dyke shares ( 12 . 12' ) is in the range of 0.02 to 0.08 m. The work unit according to one of claims 1 to 7, characterized in that it further comprises at least two applicators ( 14 ) of the mineral fertilizer ( 18 ) for each dam ( 3 . 3 ' ) located in various locations in the area covered by the crest ( 4 ) and the molding tools ( 6 . 6' . 8th . 8th ) for the local application of the fertilizer ( 18 ) is delimited. The working unit according to claim 8, characterized in that it comprises four applicators ( 14 ) of the mineral fertilizer ( 18 ) for each dam ( 3 . 3 ' ) surrounding the central area of the dam ( 3 . 3 ' ) for the laying of potato tubers ( 15 ) is determined. The working unit according to claim 8 or 9, characterized in that the applicators ( 14 ) with the diffusers ( 16 ) connected by the blower ( 17 ) for the pneumatic transport of mineral fertilizer ( 18 ) from the dosing system ( 19 ) connected to the reservoir ( 20 ) of the mineral fertilizer ( 18 ), driven, and individual applicators ( 14 ) or connected pairs of applicators ( 14 ) to the diffusers ( 16 ) via distributor / mixer ( 21 ) are connected.

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