RO120255B1 - Conveyor for granular material - Google Patents

Abstract

The invention relates to a conveyor for conveying granular material from a location near the ground to an elevated position. According to the invention, the conveyor has an intake hooper (17) having a front end (21) secured to an input end of a tube and an endless belt (7) for conveying the material from the intake hooper (17), at least two augers (25 and 27) being mounted to the discharge end of the tube, within the hopper (17), said two augers being positioned above the endless belt (7) and externally to the input end of the tube, said belt (7) and the augers (25 and 27) being driven by some appropriate drive means, the augers (25 and 27), which are actuated in a rotary motion, convey the granular material from the hooper (17) towards the input end of the tube, so as to ensure a complete feed of the input end of the tube, the granular material being then carried to the discharge end of the tube by the belt (7).

Description

The invention relates to a conveyor used for the transport of granular material.

Known helical conveyors (snail conveyors) and belt conveyors are known for transporting granular material from a place near the ground to a position at a height.

Helical conveyors typically include a snail mounted inside a tube. The snail is usually slightly smaller in diameter than the inner diameter of the tube or channel. Rotating the screw drives the granular material in the direction of the tube or groove, to be unloaded at the top end. Typically, helical conveyors have high flows because the material is effectively transported along the entire cross-section of the tube. However, some granular materials, such as mineral fertilizers and sensitive seeds (for example, peas, lentils, beans and canola), are likely to be damaged when transported in a helical conveyor. Such deterioration results in poor quality of the granular material and / or reduced germination power of the seeds.

Belt conveyors typically include an endless belt mounted in an elongated transport body. The tape is rotated to carry the material up the body. Conveyor-type conveyors cause significantly less damage to granular material than helical conveyors. However, the flow rate of this type of conveyor is comparatively lower than that of the helical type conveyors.

The use of helical conveyors, mounted in tubes, is also known. It is also known the use of snails mounted above such belts, inside feed bins of helical conveyors, to help introduce the material to be transported, up to the tube transport portion of such helical conveyors. Such a helical conveyor model includes a tapered snail, which extends into said tube, above the belt. However, the extension in the tube of the helical element may limit the flow of the conveyor, because a portion of the cross section of the tube at the inlet end is occupied by said screw. Further, the use of a single snail in a feed hopper is problematic, because the snail tends to load the tape on one side, which can lead to a deviation from the parallelism of the band and its deterioration. In addition, the relatively large size, required for a single snail, increases the height of the feed hopper, making it unsuitable for unloading certain dumpers at the bottom in the feed hopper. In addition, mounting the snail so that it extends into said tube limits the ability to adjust the position of the snail in the feed hopper and does not provide the flexibility required to fully empty the hopper. It also limits the ability to vary the size of the snail and, depending on the material to be transported, the respective snail may damage that material. Finally, using a single snail in the feed hopper tends to load the tape (and feed hopper) on one side.

It is an object of the present invention to provide an improved carrier which eliminates the mentioned disadvantages.

According to the invention, the granular material carrier comprises an elongated tube having an inlet end and a discharge end;

- a feed hopper at the inlet end of the tube; an endless belt, which passes through the feed hopper and through the elongated tube and returns to the feed hopper outside the tube, said band being adapted to rotate, to transport material from the feed hopper to the discharge end of the tube; at least two snails mounted in the feed hopper positioned above the endless belt; and actuating means for driving the endless belt and rotating said snails, wherein the rotation of said snails carries granular material from the feed hopper to the inlet end of the tube.

In an embodiment of the invention, the placement of the snails in said hopper 1 is made so that it can be adjusted and facilitate the removal and easy replacement of the respective snails. In addition, the speed at which the snails must be rotated is adjustable. The above 3 ensure a high flexibility in relation to the different applications for which the carrier will be used. In another embodiment of the invention, the snails are mounted in a fixed position, above 5 bands.

The invention also provides a conveyor having a low profile feed hopper. It facilitates the use of the respective conveyor with bottom unloaders, etc., which have small space for placing underneath the feed hopper. 9 Where a high volume but low profile bunker is needed, a wide bunker may be used in connection with additional snails, located to the rear of the bunker 11 and adapted to move material from the sides of the bunker to the center, where it will be transported by the said belt and the snails to the front end of the hopper 13 and the inlet end of the tube.

In general, the invention seeks to provide a high-flow conveyor, providing an intensive supply of the conveyor, to the point where the tape enters said tube. The conveyor according to the present invention is also adjustable, in that the orientation, size 17 and material of the snails and the speed at which they are actuated, can be modified according to the application for which the conveyor is used. 19

Preferred embodiments of the invention will now be described, by way of example, with reference to the accompanying drawings, in which:

FIG. 1 is a perspective view of the feed hopper of a carrier, according to an embodiment of the invention;

FIG. 2 is a horizontal plan view of the feed hopper of a carrier, according to an embodiment of the invention;

FIG. 3 is a side view of the feed hopper of a conveyor, according to an embodiment of the invention;

FIG. 4 is a perspective view of the rear end of the feed hopper of a carrier, according to an embodiment of the invention; şi29

FIG. 5 is a perspective view of the feed hopper of a carrier, according to an embodiment of the invention.

Fig. 1 to 4 show a conveyor according to an embodiment of the invention, which includes a part 1 of the feed hopper, a part of unloading (not shown) and a 33 elongated transport tube (not shown) extending between them. An endless belt 7 is mounted on a set of rollers, including rollers 3, 5 (see fig. 3), so that the tape has a 35 branch (stroke) of transport passing through the part 1 of the feed hopper, where it is directed into the transport tube and thence through the transport tube to the unloading part (not shown). A return stroke of the strip 7 passes out of the tube, from the unloading side, back to the part 1 of the feed hopper, passing between the rollers 3 and 5 and through the 39 slot 9 (see figs. 1 and 4) and here again through the feed hopper and back into said tube. 41

Part 1 of the feed hopper comprises a hopper 17, having a rear wall 19, a front end 21 and side walls 23. At the beginning of the transport race, the strip 7 43 passes through the rear wall 19 and extends to the front end 21 of the hopper where it enters the said tube, (not shown). Preferably, the side walls 23 of the hopper 17 45 are arranged such that when the strip 7 moves to the front end 21 of the hopper, said walls progressively force the strip into a hemispherical configuration. This fact 47 helps the tape 7 to take the shape of the tube and to enter the tube, while reducing wear on the tape 7 and the hopper 17 as a result of the entry of the tape into said tube. 49

RO 120255 Β1

The inlet end of the tube (not shown) forms a closed connection with the front end 21 of the hopper 17. The connection between the feed part 1 of the hopper and the respective tube can be made by conventional methods, which include flanges together with screws, on said tube and hopper, welding, etc.

Two helical elements 25 and 27 are mounted in the hopper 17, being positioned above the band 7. Each of the helical elements 25 and 27 has a screw-fixed end on the corresponding drive motors 41 and 43. Said motors and snails are retained on the rear wall 19 of the bunker, by mountings comprising slots and screws between the plates 45.47 and the rear wall 19. As is best seen from FIG. 1, the plates include slots 49, generally oriented vertically, which allow the vertical adjustment of the height of the snail relative to the hopper, towards the rear of the hopper 1 of the feed. The vertical slots 49 are aligned with horizontal slots 51 (see fig. 4) on the rear wall 19. The horizontal slots 51 allow the horizontal orientation of the snails 23, 25 in the hopper 17 to be adjusted.

The other end of each of the aforementioned snails is mounted to the front of the hopper, by means of mountings which include bearings 53 which are bolted to some bearings 55. The bearings 55, in turn, are connected to the console 57, as shown clearly in FIG. 1 and 2. It will be noted that the bearings 55 bearings include slots 59, generally oriented vertically, which facilitates the vertical adjustment of the snail portions. It will also be noted that the respective console 57 generally includes horizontal slots 60 which allow the horizontal adjustment of the orientation of the snails 25 and 27 relative to the front end of the hopper 17.

Due to the way the snails are mounted in the hopper, it is easy to remove, replace or replace the snails. Further, depending on the applications that the user gives to the carrier, it may be advantageous to use snails having turns made of different materials or snails of different sizes. More specifically, regarding the material of the coils, it is mentioned that any kind of material can be used, including steel, plastic or a brush material. In general, it is advantageous to use coils made of plastic or in the form of brushes, because, compared to steel, these types less damage the material being transported. However, due to the arrangement of two snails, as discussed below, it is preferable to have turns on both the right and the left. In trade, there are spiral snails oriented both to the left and to the right. As for brushes made of plastic and in the form of a brush, a special order may be required, for such orientation to the left or right of the turns 9. In addition, the steel turns can be used slower than those of the material. plastic or brush. As a result, steel can be more cost-effective.

Regarding the size of the spiral screw, it is mentioned that it can be optimally different sizes, depending on the type of material being transported. In general, the smaller the coil, the smaller the damage caused to the particle material, because there will be less contact with the coil material having a smaller diameter. In addition, it is advantageous to use a smaller diameter of the coil, as this will allow a lower profile of the feed hopper 17, thus facilitating loading from a trough located relatively closer to the ground. This can be especially important, where, for example, the conveyor will be used to transport material that is stored in a container that is unloaded at the bottom. In general, the proper diameter of the coil will depend on the size of the bunker as well as the particulate material to be transported.

RO 120255 Β1

As mentioned, it is preferable to use turns of 1 snail oriented both left and right in the hopper. This is desirable, in order to minimize leakage, because if properly disposed, the opposite turns will tend to move the particulate material to the central part of the feed hopper 17 when the material is transported to the front of the bunker.

Considering the snail's adjusting capacity relative to the bunker and the ability of 7 separately adjusting the opposite ends of each snail, it is necessary to provide for the snail's oscillation around the snail's connections on the respective bunker. In the illustrated embodiment, the necessary freedom of movement is achieved, allowing a certain set of screws in the respective slots. However, any other suitable means that allow 11 freedom of movement can be used.

Fig. 5 illustrates an alternative of the embodiment, according to the invention, with two 13 helical elements 25 and 27 mounted in the hopper 17, in a fixed position, above the strip 7. The hopper 17 has a wall 61 posteriorly connected to each side wall 23. Each of the 15 helical elements 25 and 27 have a screwed end on the corresponding drive motors 41 and 43. The actuating motors 41 and 43 and the helical elements 25 and 27 are retained in the rear wall 61, in a fixed position, above the belt 7.

The other end of each of the aforementioned snails is mounted to the front part 19 of the hopper 17, by means of supports which include bearings 53 which are screwed to the bearings 63. The respective bearings 63 bearings are connected, in turn, to 21 console 65. Thus mounted, the snails 25 and 27 are held in a fixed position, above the band 7.

As can be seen from the above, in the examples shown in the respective figures, 23 for the operation of the snails, an actuation system with two motors is used. Preferably, the drive motors will be of the variable speed type. In the operating process, the optimum operating speed of the snails may vary depending on the application, including the angle under which the conveyor must operate and the type of material to be transported. 27 However, in general, each of the snails mentioned will be operated at the same speed. Accordingly, a single drive motor with appropriate chain drives may be used. In an even more general way, any drive system can be used to drive snails, a system that does not impair the orientation ability of snails 25 and 27 in the feed hopper 31 17.

Generally, in the process of operation, the helical elements 25 and 27 are rotated so that the particulate material, deposited inside the bunker 17, is taken by one of the helical elements which helps to drive the material towards the center 35 of the front end 21 of the bunker. In the embodiments shown in the appended figures, the helical element 25 has a left turn and is rotated clockwise, while 37 the helical element 27 has a right turn and is rotated counterclockwise. The reference to the direction of rotation of each of the coincidental elements 25 and 27 takes into account the sense seen from the rear wall 19 or 61 towards the front end 21 of the hopper 17. 41

When material is introduced into the bunker 17, it is transported to the front end 21, by the web 7 and / or the snails 25 and 27. As the material moves to the front end 43, the web 7 is bent by the converging portions of the side walls 23 , having a hemispherical shape, for insertion into the inlet end of the tube. The rotating 45 of the helical elements 25 and 27 combined with the displacement of the strip 7 ensures a continuous flow of granular material to the front of the hopper 17. When high flows are required, 47

EN 120255 Β1 the snails may operate so that the action of the helical elements 25 and 27 ensures a continuous, complete flow of the material being transported to the front end of the hopper 17 and the inlet portion of the tube. As a result, the conveyor with tape and tube ensures a complete supply, which provides flow rates for the respective conveyor, as a whole.

While the figures do not present alternative configurations, those skilled in the art will understand that various combinations of elements can be used, which are within the scope of the inventive concept of the present invention. For example, in addition to the tape and the two snails that are used to transport particulate matter to the tube portion of the conveyor, additional snails may be added, in a larger bunker, in order to transport material to the respective snail. tape, for moving under the action of the belt and the two snails 25 and 27 feed.

In general, it should be understood that those skilled in the art can make numerous alternatives, modifications and variants, without exceeding the essential elements of the invention, as set forth in the appended claims.

Claims (12)

claims 1. Granular material conveyor, comprising: a) an elongated tube, having an inlet end and a discharge end; b) a feed hopper (17) mounted at the inlet end of the tube; c) an endless belt (7) which passes through the feed hopper and the elongated tube and returns to the feed hopper (17) outside the tube, said belt being adapted to be rotated, in order to carry material from the hopper power supply to the discharge end of the tube; d) at least two snails (25, 27) mounted in the feed hopper (17), positioned above the endless belt (7); and e) actuating means (41, 43) for driving the endless belt (7) and rotating the snails (25,27), in which the rotation of the snails (25,27) causes the granular material from the feed hopper (17) to be transported to the end. tube inlet. 2. The conveyor according to claim 1, characterized in that the snails (25, 27) include a left-facing and a right-hand spiral, each extending from the rear of the feed hopper (17) to the front end of and in which the rotation of the respective snails tends to transport the material they catch, towards the inlet end of the tube. 3. Conveyor according to claim 2, characterized in that the left and right snails (25, 27) have opposite turns and are rotated in the opposite direction, so that each snail tends to carry the material it catches towards the middle of the inlet end. of the tube. 4. The conveyor according to claim 2, characterized in that at least one snail is mounted using adjustable supports, adapted to adjust the position and orientation of said snail with respect to the feed hopper (17) and the belt (7). 5. Transporter according to claim 4, characterized in that a first end of each snail is mounted by means of a bearing (53), on a bearing support (55) which, in turn, is mounted on consoles (57) towards the front end of the feed hopper (17) and in which the connection between the bearing support (55) and the consoles (57) ensures adjustment of the bearing location (53) relative to the feed hopper (17). RO 120255 Β1 6. The conveyor according to claim 5, characterized in that a second end 1 of each snail is connected to a means for driving said snail, and wherein said second end is mounted on the feed hopper (17) such that the location of this 3 the second end of each snail can be adjusted relative to the feed hopper. 7. The conveyor according to claim 6, characterized in that the actuator means includes separate motors, connected to each screw, and wherein the location of each motor is adjusted when adjusting the location of the second end of said screw. 7 8. The conveyor according to claim 1, characterized in that the actuating means for rotating the at least two snails are adjustable so as to provide drive 9 with variable speed of said snails. 9. The conveyor according to claim 1, characterized in that the snails (25, 27) are 11 removably disposed inside the feed hopper (17), to facilitate their removal and replacement. 13 10. Transporter according to claim 1, characterized in that the depth of the feed bin (17) is chosen so as to minimize the profile of the respective feed hopper, while facilitating the fitting of snails of suitable size in the feed hopper. (17). 17 11. The conveyor according to claim 1, further comprising at least one feed snail mounted in the feed hopper, for bringing material from the sides of the hopper to said belt and snails. A conveyor according to claim 2, characterized in that at least one snail 21 is mounted at a fixed angle with respect to the belt (7).