The invention relates to bin blenders for mixing particulate solid materials.
The bin blender, or tote blender as it is also called, is one of a family of devices for batch mixing particulate solids, in which mixing is promoted by rotating a vessel containing the solids about a fixed axis. Bin blenders usually have a square cross-section, constant in the upper part of the bin, and reducing uniformly to a discharge point at the lower end. The axis of rotation is fixed at an angle of typically about 15 degrees to a diagonal drawn between opposite corners of a cross-section through the bin. Bin blenders are an attractive option for many processes, because the blending vessel can also be used for storing and transporting the particles, while keeping them in a controlled environment.
The purpose of a blender is to produce a uniform mixture of two or more different components, which are placed in the blender in fixed proportions to each other, so that, after the blender has been operated, samples taken from the mixture contain the different components in proportions the same as or similar to the proportions of the components placed in the blender. In many industrial applications, the mixture made in the blender is removed from the blender, and then divided into batches. If the components in the blender are not intimately and uniformly mixed, then the proportions of the components in the different batches can differ from batch to batch. Also, the proportions of the components in a batch can differ from the proportions of the components placed in the blender. For most mixing operations, if the proportions of the components in samples taken from the mixture are sufficiently close to the proportions of the components placed in the blender, then the mixing operation is thought of as satisfactory. The extent to which the proportions of the components must be similar to the proportions of the components placed in the blender, or the limits of the composition of the mixture are often given in specifications relating to the particular mixture and mixing operation.
In broad terms in one aspect the invention comprises a bin blender for mixing particulate solid materials comprising a closable bin for containing the materials and having a non-circular cross-sectional shape, the bin being rotatably mounted for rotation of the bin about an axis extending across the interior of the bin, and an internal baffle within the bin having a height dimension, and a depth dimension of the baffle across the interior of the bin and generally towards or through a center region of the bin.
Preferably the axis of rotation of the bin extends across the interior of the bin at an angle of less than about 45° to a diagonal across the bin between two opposite corners of the bin. Preferably the axis of rotation of the bin extends across the interior of the bin at an acute angle of less than about 30° to the diagonal across the bin.
Preferably the baffle member extends at an angle of less than about 45° to the axis of rotation of the bin. Preferably the baffle member extends at an angle of less than about 30° to the axis of rotation of the bin. Preferably the baffle extends at an acute angle to the axis of rotation of the bin.
Preferably the baffle extends in a depth dimension of the baffle from at or near one corner or side of the bin part way across the interior of the bin towards another corner or side of the bin. Preferably the depth dimension of the baffle member across the interior of the bin is between about one third and two thirds of the dimension across the interior of the bin in the plane of the baffle member. Preferably the height dimension of the baffle member is less than the full height of the interior of the bin but is at least half of the full height of a substantially constant cross-section part of the interior of the bin.
It has been found that it can be difficult to operate a bin blender in a way that produces a satisfactory mixture. More particularly, it can be necessary to rotate a bin blender a very large number of times to achieve good mixing. This can cause breakage of the materials being blended, and is also time consuming. With the blender of the invention the number of times that a bin blender must be rotated so that the proportions of the components in samples taken from the mixture, are sufficiently close to the proportions of the components placed in the blender, that the composition of the mixture is within specification and the mixing operation is considered to be satisfactory, is reduced.
The invention is further described with reference to the accompanying drawings, by way of example and without intending to be limiting. In the drawings:
Referring to
In use dry particulate solids are loaded into the interior of the bin through door 3, and the bin is then closed and rotated through 360 degrees a number of times about an axis extending asymmetrically (or symmetrically) across the interior of the bin, such as asymmetric axis R—R indicated in
Referring to
In the form of
In the preferred form shown in the drawings, the bin has a square transverse cross-section as shown, and the axis of rotation R′—R′ shown in
In the form of
In the form of
It is not essential that the baffle extend from a corner of the bin and
Experimental work has shown that in a bin blender incorporating a baffle of the invention, the degree of mixing or blending achieved with a set number of rotations of the bin is very substantially and surprisingly improved, or that to achieve a desired degree of blending or mixing the number of rotations required may be reduced substantially, giving a commercially significant reduction in blending time required. Experiments measuring the extent of mixing were carried out with a white powder. Some of the particles in the powder were stained with a black dye. The stained particles, which were black, could easily be seen against a background of white particles. White powder was placed in the blender so that about 70% of the volume of the blender was filled with particles, and a small quantity of the stained particles was placed in a narrow region 7 of the blender as shown in
This was first of all done with the blender without an internal baffle. The blender was then rotated 20 times, at a rate of 50 revolutions per minute. The number of rotations and the speed of rotation were chosen for the purposes of this experiment, and are for example only. The powder was then removed from the blender by using a suction device to suck the powder out. The powder was sucked out a small amount at a time, and in a way that the surface of the powder exposed in the blender was flat and could easily be inspected. It could be seen that there were black particles outside the narrow region 7 where they had been placed before the blender was rotated. Photographs were taken of the surface of the powder in the blender with a digital camera, and
In a second experiment, the blender was fitted with a baffle as shown in
The black particles move from the narrow region, 7, because of the effects of the mixing processes in the blender, and in a mixture that is well mixed it is to be expected that the black particles will be spread out in the mixture in a uniform manner. Referring to
The foregoing describes the invention including a preferred form thereof. Alterations and modifications as will be obvious to those skilled in the art are intended to be incorporated within the scope hereof as defined in the accompanying claims.
Number | Date | Country | Kind |
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502032 | Apr 2000 | NZ | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/NZ01/00066 | 4/20/2001 | WO | 00 | 3/13/2003 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO01/80984 | 11/1/2001 | WO | A |
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Number | Date | Country | |
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20030161213 A1 | Aug 2003 | US |