NL1011957C2 - Tractor-drawn planting machine with sloping plates to feed bulbs onto vibrating plate with direction of motion opposite to that imparted by vibrating plate to assist separation - Google Patents

Abstract

Two adjustable sloping plates (10,11) feed bulbs (5) from the hopper (4) onto the vibrating plate (6). The lower plate (10) imparts a motion opposite to that imparted by the vibrating plate (T). Bulbs are deposited on the upward sloping section (12) of the profiled band (7) before entering the tube (2), around which a net (3) is bunched (8). Band speed is adjustable in relation to forward speed (V).

Description

Mobile device for planting bulbs

The invention relates to a mobile device for planting bulbs, with means for placing a tubular net in a trench to be formed in the ground and supply means for supplying the bulbs to be planted in this net, to which supply means a a stock holder for the spheres provided with an outflow opening, a vibrating plate extending below the outflow opening, determining a direction of transport, and guiding members connecting to the vibrating plate and ending in the net.

With the aid of devices of this type, a slot is formed in the bottom, in which a tube-like net is deposited in which spheres are supplied. These devices are generally coupled behind a tractor. In order to obtain a regular crop distribution, it is important that the bulbs are fed regularly into the net. In the known devices of the present type, however, it is very difficult to effect such a regular supply of bulbs.

In a known mobile device of the type to which the invention relates, the spheres flow via the outflow opening at the bottom of the storage container substantially onto the vibrating plate in the transport direction thereof. In order to properly dose the spheres on the vibrating plate 25 and the adjoining guide members, it is generally required that the distance between the top of the vibrating plate and the bottom of the outflow opening (i.e. the bottom point of the storage container) is approximately one and a half times the average diameter of the 30 bulbs in question. In practice, however, it appears that blockages can occur between the vibrating plate and the underside of the storage container. These blockages are due in part to the fact that the spheres are not regularly formed, ie deviate from the ideal round shape, and the fact that irregularities such as <\ Λ 4 · - 2 clumps often occur on and between the spheres. or the like. In order to prevent the occurrence of these blockages, it is then frequently proceeded to set the distance between the top of the vibrating plate and the outflow opening and the bottom side of the storage container larger than the aforementioned optimum value. Although blockages can hereby largely be prevented, the dosing of the bulbs is then irregular, because sometimes piled up bulbs leave the vibrating plate and get into the net 10 as accumulations.

The object of the invention is to provide a mobile device for planting bulbs according to the type mentioned in the preamble, with which the above-mentioned drawbacks can be removed in a simple, yet effective manner.

For this purpose, the mobile device for planting bulbs according to the invention is characterized in that the outflow opening of the storage container is formed such that a direction of movement 20 is provided to the outflowing bulbs with a component opposite to the direction of transport of the vibrating plate.

It has been found in an extremely surprising manner that when the outflowing spheres are provided with an initial direction of movement with a component opposite to the transport direction of the vibrating plate, an extremely regular distribution of the spheres is obtained on this vibrating plate without the tendency of congestion between the vibrating plate and the outflow opening or the underside of the storage container.

Structurally, there are various possibilities for forming the outflow opening of the storage container in such a way that the desired initial direction of movement is provided to the outflowing spheres. Here, an embodiment is preferred, in which the outflow opening is determined between two plates extending transversely to the direction of transport of the vibrating plate and mutually enclosing an angle, a bottom plate of which extends obliquely against the said transport direction and in some distance ends above the vibration plate, while an upper plate slopes downwards in said transport direction and ends some distance above the lower plate.

In principle, the bottom plate which runs obliquely downwards against the said transport direction provides the desired direction of movement of the outflowing spheres. In principle, the distance between the bottom plate and the bottom end of the top plate determines the outflow velocity of the outflowing spheres from the storage container.

The optimum position and the optimum mutual position of the two plates and their position relative to the vibrating plate is preferably determined in practice. In this context it is then advantageous if the bottom plate is adjustable in its own plane. By adjusting the bottom plate in its own plane, the distance between the bottom end of this bottom plate and the vibrating plate can be adjusted, for example to one and a half times the average spherical diameter. In addition, it can also be advantageous to make the top plate adjustable in its own plane, which provides an option for controlling the outflow speed of the spheres from the storage container.

Of course it is also conceivable for the plates to be adjustable in other ways, for instance to have an adjustable angle of inclination.

If the plate or plates are indeed adjustable, adjustment mechanisms known per se can be used for this purpose, which will be immediately clear to a skilled person and therefore need no further explanation. The described measures provide a regular distribution of the outflowing amount of spheres on the vibrating plate. It is important to ensure that this regular distribution is maintained until the bulbs have been fed into the net. One possibility to accomplish this is that the guide members include a conveyor belt connecting to the vibrating plate. With such a conveyor belt the flow of spheres can be fed into the network without disturbances.

Various additional measures are possible with regard to such a conveyor belt, in order to further optimize the operation of the device according to the invention. For example, a special embodiment is mentioned, in which the conveyor belt has a first, upwardly extending section immediately connecting to the vibrating plate. When the device has been temporarily brought to a standstill, the upwardly-extending section prevents the spheres located on the vibrating bottom from being fed into the then still stationary net and an impermissible accumulation of spheres taking place there. In this embodiment it is even conceivable that the vibrating plate is still moving, while the conveyor belt is stationary. Also in such a case, the upward-sloping section of the conveyor belt then prevents the supply of spheres into the net.

The engagement of the conveyor belt on the spheres can be optimized when this conveyor belt is provided with carrying members, profiles or the like formed on its surface. In this way, it is also prevented that, for instance when the conveyor belt is stationary, spheres roll down along the conveyor belt.

In order to obtain an optimum supply of spheres in the net 25, it is further preferred that the speed of the conveyor belt is coupled to the speed of travel of the mobile device. It is of course possible that the ratio between the speed of the conveyor belt and the speed of movement of the mobile device is adjustable. Due to such adjustability of the said ratio, the density of the spheres in the net can be varied.

The possibility is also mentioned that the position of the conveyor belt (including the angle of inclination thereof) is adjustable. This also provides a means to control the supply of the bulbs into the net.

1 0 M 9 5 7 5

Finally, the possibility can also be mentioned that the vibrating plate is adjustable with regard to its vibration frequency and / or position.

The invention will be explained in more detail below with reference to the only figure, which schematically shows in side view a number of parts belonging to a mobile device according to the invention in their mutual relationship.

Before proceeding to a description of the essential parts of the device according to the invention, it is noted that the figure shows only those parts which are required for a direct understanding of the inventive idea. For example, structural parts such as the frame, in which the various parts are suspended, the chassis with wheels and drive members, have been omitted for the sake of clarity.

The mobile device for planting bulbs includes, inter alia: plow-shaped means 1 for forming a trench in the ground; a tube part 2 for receiving and controlled delivery of a tubular net 3; A storage container 4 for bulbs 5 to be planted; a vibrating plate 6 extending under the storage container 4 with a direction of transport indicated by arrow T, and a conveyor belt 7 extending from the vibrating plate 6 into the tubular part 2.

The mobile device is generally moved by a tractor (not shown) in the direction of travel indicated by arrow V. In accordance with the speed of advancement, the net 3 located at storage location 8 on the tubular part 2 is laid backwards in the bottom slot formed by the plow-shaped means 1. In this case, the conveyor belt 7, which acts as a supply means for supplying bulbs to be planted in the net 3, delivers bulbs 5 in the net 3 in a regular manner.

It is essential for good crop distribution that the supply of the bulbs 5 in the net 3 takes place in a regular manner. For this purpose, a regular outflow of the 1 o 1 1 9 5 7 6 quantity of bulbs 5 from the storage container 4 is important. This outflow takes place via an outflow opening 9 located on the underside of the storage container 4. According to the invention, this outflow opening 9 is determined between two extending transversely to the transport direction T of the vibrating plate 6 (i.e. perpendicular to the plane of the drawing) and plates 10 and 11 enclosing each other at an angle. A lower plate 10 slopes obliquely against the said transport direction T of the vibration plate 6 and ends at some distance above this vibration plate 6. An upper plate 11 slopes downwards in the said transport direction T and ends at some distance above the lower plate 10. In the embodiment shown, both plates are adjustable in their own plane, for instance slidable along the respective parts of the storage container 4.

Due to the described configuration of the outflow opening 9 with bottom plate 10 and top plate 11, the spheres 5, as seen in the figure, flow obliquely downwards to the right. As a result, the outflowing amount of spheres 5 initially has a movement component opposite to the direction of transport T of the vibrating plate 6. It now appears that this results in an extremely regular distribution of the spheres 5 on the vibrating plate 6, which results in a regular supply of the spheres to the conveyor belt 7 and the halves in the net 3. It also appears that this greatly prevents the occurrence of blockages, in particular between the vibrating plate 6 and the lower end of the lower plate 10.

The speed of the conveyor belt 7 is generally coupled to the speed of travel of the device. This also means that, when the device is stationary, the conveyor belt 7 is also stationary. In such a case, in order to prevent spheres 5 from getting into the net 3, in the embodiment shown, the conveyor belt 7 is provided with a first, upwardly extending section 12, which connects directly to the vibrating plate 6. prevents that, when the conveyor belt 7 is stationary and the vibrating plate 6 is still driven, spheres 5 can enter the net 3. After all, the upwardly extending section 12 prevents further movement of the spheres 5. In order to also prevent the spheres 5 from rolling downwards along the section 13 running at an angle into the net 3, the conveyor belt 7 in the shown embodiment is provided with entrainers, profiles or the like formed on its surface 14.

As noted, generally, the speed of the conveyor belt is coupled to the speed of travel of the mobile device. In such a case, however, the relationship between the speed of the conveyor belt 7 and the forward speed of the mobile device can be adjustable. This also applies to the position of the conveyor belt 7 (inter alia the angle of inclination thereof) and the vibration frequency and / or position of the vibration plate 6. As a result of all these measures, the speed at which the spheres are fed into the net 3, and therefore the density of the spheres 5 in the net 3 are controlled.

The device according to the invention is characterized by an extremely regular, trouble-free supply of bulbs 5 from the storage container 4 via the vibrating plate 6 and the conveyor belt 7 to the net 3, without the device being temporarily brought to a standstill thereby disrupting has.

The invention is not limited to the embodiment described above, which can be varied widely within the scope of the invention as defined by the claims.

1 µM 957

Claims (11)

1. Mobile device for planting bulbs, with means for laying a tubular net in a trench to be formed in the ground and supply means for supplying the bulbs to be planted in this net, up to which feed means are provided on its underside of an outflow opening provided for the spheres, a vibrating plate extending below the outflow opening, determining a transport direction and connecting and connecting to the vibrating plate and guiding members in the net belong, characterized in that the outflow opening of the stock container is formed that a direction of movement is provided to the outflowing spheres with a component opposite to the direction of transport of the vibrating plate. 2. Device as claimed in claim 1, characterized in that the outflow opening is determined between two plates extending transversely of the transport direction of the vibrating plate and mutually enclosing an angle, a bottom plate of which runs obliquely downwards against said transport direction and on some distance ends above the vibrating plate, while an upper plate runs obliquely downward in said transport direction and ends some distance above the lower plate. Device according to claim 2, characterized in that the bottom plate is adjustable in its own plane. Device according to claim 2 or 3, characterized in that the top plate is adjustable in its own plane. 5. Device according to any one of the preceding claims, characterized in that one of the guiding members is a conveyor belt connecting to the vibrating plate. 6. Device as claimed in claim 5, characterized in that the conveyor belt has a first, upwardly extending section immediately connecting to the vibrating plate. : I 9 s 7 Device as claimed in claim 5 or 6, characterized in that the conveyor belt is provided with carrying members, profiles or the like formed on its surface. 8. Device as claimed in any of the claims 5-7, characterized in that the speed of the conveyor belt is coupled to the speed of movement of the mobile device. 9. Device according to claim 8, characterized in that the ratio between the speed of the conveyor belt and the speed of movement of the mobile device is adjustable. 10. Device as claimed in any of the claims 5-9, characterized in that the position of the conveyor belt is adjustable. 11. Device according to any one of the preceding claims, characterized in that the vibrating plate is adjustable with regard to its vibration frequency and / or position. -, -: 1957