NL9001785A - Granular material dispensing mechanism - comprises non-circular horizontal shaft rotating to=and=fro above hopper outlet - Google Patents

Abstract

Granular material such as salt is dispensed in metered amounts from a hopper with a bottom outlet. Above the outlet a horizontal metering shaft rotates to and fro, and is of non-round cross-section. The hopper can taper towards the outlet, while the distance between the latter and the shaft is adjustable. The angle through which the shaft turns can also be adjustable, and it can have a lever actuated by a ram.

Description

Device for dosed dispensing of a granular material

The invention relates to a device for dosed dispensing of a granular material, such as salt or the like, with a reservoir containing the material and at least one material outlet opening arranged in the bottom of the reservoir.

Such a device is used, inter alia, for applying layers of salt between successive layers of fish in crates and the like. The salt generally has a coarse granular structure and is very hygroscopic. As a result, the salt tends to crumble to form salt bridges and the like in the reservoir. This makes it considerably more difficult to release the salt from the reservoir via the material outflow opening in a controlled manner.

The object of the invention is to provide a device of the type mentioned in the preamble, wherein this drawback is eliminated in a simple, yet effective manner.

To this end, the device according to the invention is characterized by a dosing shaft with non-round cross section which extends substantially horizontally and extends above the outflow opening.

The reciprocating movement of the dosing shaft, due to its non-round cross-section, leads to a periodic force exerted on the material present in the reservoir, so that this material will crumble less quickly, material bridges formed if necessary and it will escape through the material outlet opening. flow of material is promoted.

In a preferred embodiment of the device according to the invention, it holds that the reservoir tapers narrowly towards the outflow opening and the distance between the outflow opening and the metering shaft is adjustable.

Due to the tapering shape of the reservoir tapering towards the outflow opening, all material is forced to flow along the metering shaft before reaching the outflow opening. This makes full use of the favorable effect of the dosing shaft. In addition, the combination of the adjustability of the distance between the outflow opening and the metering shaft and the tapered shape of the reservoir means that an adjustment can be made of the amount of material delivered through the outflow opening. It is also now possible to optimize the position of the metering shaft in view of the nature of the material present in the reservoir.

A further possibility to be able to control the amount of material dispensed is provided by an embodiment of the device according to the invention, wherein the rotation angle of the dosing shaft is adjustable. This adjustability can be advantageously realized if the metering shaft carries a lever on which a cylinder-piston assembly engages, the distance between the point of engagement and the axis of rotation of the metering shaft being adjustable. At a large distance between the point of engagement of the cylinder-piston assembly on the lever and the axis of rotation of the metering shaft, a rotation of the metering shaft takes place at a given angle of the cylinder-piston assembly. When the said distance is reduced, the rotation angle of the dosing shaft will increase.

It is also favorable if the metering shaft is mounted eccentrically. In this way, shock loads are exerted on the reservoir, which counteract the formation of material bridges and loosen the granular material.

The metering shaft can take many different forms.

It is thus possible for the metering shaft to have a polygonal, for example square, cross section. Another possibility is a metering shaft, which consists of a cylindrical core provided with protrusions.

Preferably, it applies that the outflow opening is in the form of an elongated slot. In this way, the granular material is released over a wide area through the outflow opening. This also reduces the chance of blockages at the location of the outflow opening.

It is also preferable that the reservoir can be moved to and fro transversely to the outflow opening.

In particular when the device according to the invention is used for applying layers of salt to successive layers of fish in crates, such a reciprocating movement of the reservoir offers special advantages. The metering shaft produces a uniform material flow from the material outflow opening, the reciprocating movement of the reservoir effecting an even distribution of this outflowing material quantity over the fish.

Finally, an embodiment is convenient, in which the reservoir has two outflow openings, which are spaced at some distance from each other. The amount of material contained in the reservoir is supplied partly to one outflow opening and partly to the other outflow opening. The capacity of the device can be effectively increased in this way.

The invention is explained in more detail below with reference to the drawing, in which an embodiment of the device according to the invention is shown.

Figure 1 shows a schematic side view of an embodiment of the device according to the invention;

Figure 2 shows on a larger scale the part of the device according to the invention indicated by II in Figure 1, and

Figure 3 shows a section along the line III-III in Figure 2.

In the side view of the device according to the invention according to figure 1, a part of a frame 1 is visible, which is provided with a support rail 2. On this support rail 2, with the aid of running wheels 3, there is a reservoir 4 for a granular material, for example salt 5 , hung up.

The reservoir 4 is provided with a driving device 6, which is only schematically indicated, such as a gear driven by a motor (not shown) which cooperates with a stationary rack 7. With the aid of the driving device 6, the reservoir 4 can move back and forth over the carrier rail 2. are moved between the position shown in solid lines and the position shown partly in dotted lines.

Above the device is a supply provision 8, such as a conveyor belt, for arranging the granular material in the reservoir 4. The position of the supply facility is such that the granular material supplied by it falls into this reservoir in any position occupied by the reservoir 4.

The reservoir 4 has in its bottom two material outflow openings 9 and 10. In the reservoir 4, a converted wall part 11 is arranged such that the material-receiving part of the reservoir 4 extends from top to bottom in the direction of the material outflow openings 9 and 10 tapers narrow.

Above each material outflow opening 9 and 10 there is a substantially horizontally extending dosing shaft 12, 13. These dosing shafts 12 and 13 are rotatable to and fro by means of cylinder-piston assemblies in a manner to be explained in more detail below with reference to Figure 2. 14 and 15.

Two crates 16, in which fish are stored, are placed under the reservoir 4. Salt, which flows out of the reservoir 4 through the material outflow openings 9 and 10, is now evenly spread over the fish present in the crates 16 by the reciprocation of the reservoir 4 over the carrier rail 2. It is hereby possible that when the salt is applied on one side of the crate at the location of the other side of the crate, a new layer of fish is placed in the crate. In this way, alternating layers of salt and fish can be placed in the crate.

The manner in which the salt flows through the material outflow openings 9 and 10 is explained in more detail with reference to Figure 2, which shows the part indicated by II in Figure 1 on a larger scale. A part of the reservoir 4 with wall part 11 is again visible. The dosing shaft 13 is located some distance above the material outflow opening 10, each end 17 of which extends through an elongated recess 18 in the respective side wall 19 of the reservoir 4 and is mounted in a bearing plate 20 slidable and lockable relative to the side wall 19, each of which closes the recess 18. The manner in which the bearing plate 20 can be slid and fixed relative to the side wall 19 is only of minor importance here and is therefore not explained in more detail.

A lever 21 is mounted on one end 17 of the dosing shaft 13 (the end shown in figure 3), on which the piston rod 22 of the cylinder-piston assembly 15 engages. The connection between the piston rod 22 and the lever 21 is herein adjustable by means of a slot 23 such that the distance between the point of engagement 24 of the piston rod 22 on the lever 21 and the axis of rotation 25 of the dosing shaft 13 is adjustable.

It is furthermore visible in figure 2 that the dosing shaft 13 has a square cross-section.

It is noted that the construction at the location of the material outflow opening 9 and the dosing shaft 12 is completely identical to the construction described above with reference to Figures 2 and 3. For a description of the operation of the device, therefore, only the operation of the dosing shaft 13 is discussed below.

During operation, the cylinder-piston assembly 15 is actuated intermittently such that the piston rod 22 thereof is continuously retracted and extended. As a result, the dosing shaft 13 will rotate back and forth about its rotation axis 25. As a result of the non-round, square, cross-section of the dosing shaft 13, a shock-like engagement of the salt contained in the narrowing part of the reservoir 4 takes place. As a result, this salt is effectively moved down through the material outflow opening 10, minimizing the risk of salt bridges being formed.

When material with a different consistency is present in the reservoir 4, it may be necessary to change the position of the dosing shaft 13 relative to the material outflow opening 10. This can easily be done by arranging the bearing plate 20 in a different position relative to the side wall 19 of the reservoir 4. As a result, the axis of rotation 25 of the dosing shaft 13 will be displaced relative to the material outflow opening 10. The angle at which the metering shaft 13 rotates back and forth can also be varied, depending on the desired effect to be achieved and / or the material present in the reservoir 4. To this end, with constant movement of the piston rod 22, the point of engagement 24 can be arranged at a greater or smaller distance from the axis of rotation 25 by moving the end of the piston rod 22 via the slot 23 relative to the lever 21.

A downward displacement of the engagement point 24 results in a greater angular rotation of the metering shaft 13, while conversely an upward displacement results in a smaller angular rotation.

The invention is not limited to the embodiment described above, which can be varied in many ways within the scope of the invention. Depending on the material present in the reservoir 4, it is thus possible to use dosing shafts 12 and 13, the cross-section of which has a different shape than the square shape shown. Metering shafts with a polygonal cross section or metering shafts, which consist of a cylindrical core provided with protrusions, are mentioned as an example.

Claims (10)

Device for dosed dispensing of a granular material, such as salt or the like, with a reservoir containing the material and at least one material outflow opening arranged in the bottom of the reservoir, characterized by a substantially horizontally extending above the outflow opening, rotatable dosing shaft with non-round cross section. Device according to claim 1, characterized in that the reservoir tapers narrowly towards the outflow opening and the distance between the outflow opening and the metering shaft is adjustable. Device according to claim 1 or 2, characterized in that the angle of rotation of the metering shaft is adjustable. Device according to claim 3, characterized in that the metering shaft carries a lever on which a cylinder-piston assembly engages, the distance between the point of engagement and the axis of rotation of the metering shaft being adjustable. Device according to any one of claims 1-4, characterized in that the metering shaft is mounted eccentrically. Device according to any one of claims 1 to 5, characterized in that the metering shaft has a polygonal, for example square, cross section. Device as claimed in any of the claims 1-7, characterized in that the dosing shaft consists of a cylindrical core provided with protrusions. 8. Device as claimed in any of the claims 1-7, characterized in that the outflow opening has the form of an elongated slot. Device as claimed in claim 8, characterized in that the reservoir is movable to and fro transverse to the outflow opening. 10. Device as claimed in any of the claims 1-9, characterized in that the reservoir has two outflow openings, which are spaced at some distance from each other.