DE3511539A1 - Seed-grain separating device - Google Patents

Abstract

A seed-grain separating device with circular cells (9) in a cellular wheel (3) has scooping extensions (10) which lead to the cells (9) and which are as wide over their entire length as the cells (9). The bottom of the scooping extensions (10) is plane. The diameter of the cells is smaller than the width of the cell track (16), on which the seed grains (17, 19, 20, 21, 22) roll for the purpose of filling the cells (9). <IMAGE>

Description

3511533

Law office

Ruppert & SchJagwein

Bahnhofsatlee 11
D-6350 Bad Nauheim
Telephone: 060 32/23 37

A.J. Tröster GmbH & Co. KG P.O. Box 240

6308 Butzbach

Seed separationqsv / orrichtunq

The invention relates to a seed separating device, consisting of a stationary housing and a rotating cell wheel which cells distributed over its circumference on a cell web in the form of radial passages with a circular cross section has on the outer surface of the cell wheel, apart from the area of a seed outlet, are covered by the housing, and in the case of a cell web above a receiving area inside the housing covering, the seeds from falling back from the cells in the cell wheel preventing cover provided and in which the individual cells each have a straight scoop attachment pointing in the direction of rotation to have. Such a seed separating device is described in DE-OS 33 11 994, for example.

In the receiving area of the cellular wheel, a seed should get into each cell passing through it. To this one To favor the filling process are known Seed singling device in the direction of rotation pointing scoop approaches provided. These run tangentially into the outer surface of the bucket wheel, have an arcuate shape in the axial direction of the bucket wheel curved bottom and taper at the end remote from the respective cell. Form the scoop thus expanding in width towards the cells,

Conducting the individual seeds towards the center of the cell Barges.

When designing the scoop and the cells is make sure that, if possible, only one seed can get into each cell. Is committed additional seed in an already occupied cell, then this must be stripped off before passing the cover will. Especially when this stripping is done by running against the leading edge of the cover, it can occur at higher circulation speeds lead to semen breakage.

To facilitate stripping, it is known from DE-GM 1 904 282, the aforementioned scoop approaches in to arrange their shape corresponding approaches opposite to the direction of rotation and completely on the scoop approaches to renounce. If there is a double occupancy with such a seed distribution device, then The second seed that protrudes from the inside of the cell can be relative due to the backward-facing approach easily stripped off, so that the risk of semen breakage is reduced. With the seed singling device According to this utility model, however, it is to be expected, especially at high driving speeds, that that not all cells are filled, because scoops

missing and there is a risk that seeds as a result of j

of the approaches leave the cell immediately before they

got deep enough into the cell. It then comes at '

the seed deposit to defects, which reduces the yield.

DE-AS 28 02 926 describes a seed association ^:

treatment device in which the problem of damage of seeds is attempted to solve that the i

individual cells from a closed cover ring.

are constantly covered and the charging of the cells i

from the side over provided in the inner circumferential surface of the cell wheel, bent towards the cells

Slots takes place. These slots are not designed as scoop approaches that gradually penetrate into the jacket surface formed, but already break through the jacket surface completely at their end pointing in the direction of rotation. As a result, several seeds are always lined up one behind the other in the slots. The problem of unoccupied In such a seed separating device, cells are not created by the fact that the seeds are not in get the slots, but by the fact that they can get jammed in the slots, and then no seeds more can get out of the slits into the cells. Such jamming leads to the fact that the respective slot the loading activity completely stops, while it is always only with the devices described above to occasional voids as a result of "not catching" of a seed can come.

The invention is based on the object of a seed separating device of the type mentioned in such a way that even at high storage speeds a reliable filling of all cells with only one seed each is possible and with the seed breakage does not occur.

This object is achieved according to the invention in that each scoop attachment has a straight bottom in the axial direction of the cellular wheel over its entire length and likewise over its entire length about as broad as the cylindrical cells.

What physically designed by such according to the invention Creation approaches happen, is difficult to understand. Extensive experiments showed, however, that just by this formation of the scoop approaches it neither to one Significant breakage of the seeds still resulting in defects unoccupied cells comes. It is assumed that due to the constant width of the scoop

put the individual seeds in the scoop earlier than in the case of pointed scoop approaches and rolling to the side next to the scoop approaches "Tip" seeds into the scoop from the side can. Since the bottom of the scoop in If the axial direction of the cell wheel is straight, the seeds are not centered on the middle of the cell. At a A further seed that is supplied via the scoop does not necessarily lie in the cell that is already occupied the middle against the embedded seed but to the side of it. There it can be stripped off more easily, as a seed lying in the middle, because the scoop does not encompass it from two sides and because it has to rise less high when rolling over the embedded seed.

Practice has shown that the trapping of seeds and the stripping of seeds from already occupied cells takes place particularly well if, according to an advantageous embodiment of the invention, each scoop attachment has lateral boundary surfaces directed perpendicularly into the inner circumferential surface of the cellular wheel.

The bottom of each scoop could be of constant depth to have. However, the desired effect is particularly evident when the bottom of each scoop towards the cell increasing distance from the cellular wheel axis has.

A further optimization of the form of the scoop approaches in terms of function can be achieved by the Bottom of each scoop also in the direction of rotation of the Cell wheel runs straight and tangential into the lateral surface to> r cell.

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It is also beneficial if the individual cells are smaller in diameter than the width of the cell web. Man then has the option of arranging two rows of cells next to each other or can be used for different Seed types in otherwise unchanged cellular wheels Cells with diameters adapted to the seed type drill.

The invention allows numerous embodiments. To the further clarification of its basic principle is one of which shown in the drawing and is explained below described in more detail. In the drawing they show

Fig. 1 is a cross section through an inventive designed seed singulation

direction ,

Fig. 2 is a section on an enlarged scale along the line II-II in Figure 1 in Area of a creative approach

FIG. 3 shows a plan view of the area of the seed separating device shown in FIG. 2 ,

Flg. FIG. 4 shows a cross section through a partial area of the seed separating device which is closer than that of FIG.

FIG. 1 shows a hollow cylindrical housing 1 with an outer jacket surface 2. Inside the housing 1 is a cellular wheel 3 is arranged, which turns clockwise when the seed separating device is in operation a horizontal axis 4 rotates. This direction of rotation was indicated by an arrow. The bucket wheel 3 has an inner jacket surface 5 which is partially covered by an annular cover 6. This cover 6

begins in the upper left quadrant, about 30 ° above the horizontal and ends at the vertical coordinate running through axis 4. The cover 6 covers the cellular wheel also in a lower area in which there is a seed outlet 7 in the form of an opening is located in the outer surface of the housing.

Seed can through a seed inlet 8 in the end face of the housing 1 get into the housing 1.

The individual seeds then move along the inner circumferential surface 5 of the bucket wheel 3 and are able to do so to get into individual cells 9 in the outer surface of the cellular wheel. These cells 9 are through inclined holes generated. Each cell 9 has one in each case in the direction of movement of the cellular wheel 3 Scoop attachment 10. The more precise design of the scoop attachments 10 is important for the present invention and will be explained in more detail later.

The cover 6 has an inlet edge 11 which is formed in the shape of a cutting edge by a bevel 12. A scraper can be arranged spatially in front of the inlet edge 11, the seeds from double-coated cells 9 stripped off before reaching the inlet edge 11.

FIG. 2 shows in section the lower area of the housing 1 and the star feeder 3. It can be seen that the Cell wheel 3 consists of a conical side area 14 and a cylindrical area 15, the inside has a cell track 16 on which the seeds roll. In the figure 2, a seed 17 is shown which is located in the scoop 10. It can be seen that this scoop attachment 10 is one in the axial direction of the Cell wheel 3 has a flat bottom 18. Furthermore, the scoop 10 has lateral boundary surfaces 24, 25, the Lead vertically or undercut into the cell web 16.

The top view in Figure 3 also shows that the
Scoop 10 is so wide over its entire length
like the cell 9. The cell 9, and thus also the scoop attachment 10, are much narrower than that
Width of the cell web 16. Several seeds 17, 19, 20, 21, 22 shown in FIG. 3 show how these get into the scoop attachment 10.

From Figure 4 it can be seen that the bottom 18 of the
Schöpfansätzes 10 leads tangentially into the cell path 9 and runs in a straight line in the direction of movement of the cellular wheel 3. It is indicated how a seed 17
over a seed 19 already located in the cell 9 can be stripped away.

List of references used

1 housing

2 outer surface

3 star feeder

4 axis

5 inner surface

6 coverage

7 seed outlet

8 seed inlet

9 cell

Scoop

11th Inlet edge 12th bevel 13th Scraper 14th Side area 15th cylindrical area 16 Cell track 17th Seed grain 18th floor 19 - 22nd Seed grain 24 Boundary area 25th Boundary surface.

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Claims (5)

Claims 1. Seed singling device, consisting of a stationary housing and a rotating cell wheel which is distributed over its circumference on a cell path has cells in the form of circular, radial passages in cross section, which on the outer jacket surface of the cell wheel, apart from the area of a seed outlet, through the Enclosures are covered, and the seeds is provided from the cells in the cellular hindrance cover from falling back in the inside of the housing a, the cells path above a receiving region covering and in which in each case facing the individual cells of a in the circumferential direction, have rectilinear pumping approach, characterized characterized in that each scoop (10) has a straight bottom (18) over its entire length in the axial direction of the cellular wheel (3) and is also approximately as wide as the cylindrical cells (9) over its entire length. 2. A seed separating device according to claim 1, characterized in that each scoop attachment (10) has side boundary surfaces (24, 25) directed perpendicularly or dovetail into the inner circumferential surface (5) of the cellular wheel (3). 3. Seed separating device according to claims 1 or 2, characterized in that the bottom (18) of each scoop attachment (10) to the cell (9) has increasing distance from the cellular wheel axis (4). 4. Seed singling device according to one or more of the preceding claims, characterized in that the bottom (18) of each scoop attachment (10) also in the direction of rotation of the cellular wheel (3) in a straight line and tangentially into the inner lateral surface (5) - ver Cell (3) runs. 5. Seed singling device according to one or more of the preceding claims, characterized in that the individual cells (9) are smaller in diameter than the width of the cell web (16).