WO2017175089A1 - Apparatus for gravitational stratification of minerals and/or precious metals - Google Patents

Abstract

The present invention belongs to the field of prospecting for granular minerals and/or precious metals, and is preferably directed to gold and/or diamond mining, in alluvial mineral prospecting and deep sea mining. The object of the present invention is a gravitational stratification apparatus that comprises at least one tubular stratification chamber (1) and rotary means, the stratification chamber (1) being hinged to the rotary means such that it can pivot about a perpendicular axis that intersects a longitudinally central position. Also described by the present invention is a system that includes said apparatus, the method for operating the apparatus and the use thereof. In one of its embodiments, the apparatus contains physical semi-axles (7) for rotating the stratification chamber (1) and a cover (2) arranged at one end of the stratification chamber (1) and provided with an opening/closing mechanism (3) having an opening pivot (4) parallel to the perpendicular rotation axis.

Description

 DESCRIPTION

APPARATUS FOR GRAVIC STRATIFICATION IN PROSPECTION OF MINERALS AND / OR

 GRANULAR PRECIOUS METALS AND THEIR METHOD OF OPERATION

FIELD OF INVENTION

The present invention is in the area of prospecting for minerals and / or granular precious metals, preferably for gold and / or diamond mining, alluvial mineral prospecting and deep sea mining.

BACKGROUND OF THE INVENTION The present invention finds a closer background in the mineral / metal selection and capture rails (sluice boxes), a millenary instrument, still broad to intensively used, in both small and very large mineralogical installations. These gutters can operate over water in a mobile floating structure called a dredger that captures or sucks the sands along with water from the bottom of the river or sea, usually near the mouth of rivers that have gold or diamond sands.

The rails comprise channels and channels through which water with material to be selected passes, being the channels suitable for fixing the desired materials. There has been some improvement in gutter performance due to new channel shapes and the use of rugs under the channels. However, the hydraulic principles used in its operation are still the same, namely the creation of a water stream strong enough to drag stones, pebbles, gravel and the sands from the gutter principle to the end. This strong stream of water will also have to allow stones, pebbles, sand and sand to overtake the various channels, creating a hydraulic suction or low pressure downstream of each channel. It is this suction that captivates the small gold particles and fixes them behind the channels. The largest particles, the nuggets, being much heavier, are retained in front of the channels, that is upstream.

The gutters concentrate the gold along with the black sands which are very small grains of hematite and magnetite and some quartz grains calling this "concentrates" set that have to be processed by other yard or laboratory equipment. These include vibrating tables, spiral wheels, pulsating jigs, and many others. These gold separators or instruments work only concentrates, they do not work alluvial soils directly because they are extremely slow. An example of this is the technical solution disclosed in the patent application.

AU649512.

This type of equipment not only consists of a complex construction structure, but works only on the surface, requiring previous transport steps to the surface of the entire mineral mass, and typically the selected minerals or metals are collected from these still black sand structures, requiring additional steps to remove them.

US2011174697 discloses another distinct but more complex type of solution based on the hydrocyclone principle applied to mining prospecting. It is an apparatus that applies a centrifugal force to a fluid such that it is vortexed in that fluid such that particles are separated according to their density. Some definitions of this technical area relevant to the present invention are presented.

Slipping: smooth sliding of the entire mineral mass without changing the internal stratification or relative position of the minerals within the mineral mass according to their density.

Riding: layers of minerals sliding over other stationary layers, changing their relative positions.

Gravitational fall stratification: change of the previous relative position of minerals within the mineral mass due to their higher density and consequent higher terminal velocity during a low turbulent laminar gravity fall in a fluid. In this process the volume of the particles is also relevant.

SUMMARY OF THE INVENTION

The object of the present invention is an apparatus for gravity stratification in prospecting of granular minerals and / or precious metals comprising at least one tubular stratification chamber (1) and rotating means, said stratification chamber (1) being hinged with the means. of rotation such that it can rotate about an axis perpendicular to itself, said rotation perpendicular axis intersecting a longitudinally central position of said stratification chamber (1).

It is unknown an apparatus for the present purpose which is based on the same principle as the present device, which enables the separation of minerals or granular precious metals by slip without straddling the strata by the rotatable capability of a tubular stratification chamber (1). around a central, imaginary axis. This equipment is of less construction complexity. than those known in the prior art and can operate both surface and submerged at any depth, eliminating the need to transport the material to be selected to the surface. The rotation capacity is also linked to the reduction of the longitudinal length of said chamber (1), replacing a longer length with the gravity drop repeatability.

In an advantageous embodiment of the apparatus of the present invention, combinable with the above, the rotating means consists of at least one physical axis coupled to the outer surface of a longitudinally central section of said chamber (1) said physical axis coinciding with said axis. perpendicular rotation.

This structure suitable for rotation of the stratification chamber (1) enables the total weight of said chamber (1), the material to be selected and the water inside the chamber (1) to be concentrated on the shaft, enabling a low energy consumption spent on the rotation / stratification activity.

In another advantageous embodiment of the apparatus of the present invention, combined with any of the foregoing, the physical axis comprises at least two physical half shafts (7), each coupled to the outer surface of a layering chamber (1).

This is the most general configuration in which two physical axes (7) coupled to the physical axis provide that the stratification chamber (s) (1) rotate about the transverse axis. Since the interior of the layering chamber (1) must be clear, the physical half shafts (7) cannot pass through said laying chamber (1), otherwise they would prevent the layering process.

In another advantageous mode of the apparatus of the present invention, combined with any of the foregoing, it comprises a plurality of stratification chambers (1), all said chambers (1) being coupled together such that (i) their rotational movement is mutually supportive and (ii) they are in the same plane. This advantageous series configuration allows for greater layering capability of the apparatus without directly proportional increase in energy expenditure. The arrangement of the different stratification chambers (1) jointly and aligned with each other in the same plane allows a movement applied to either of them to be repeated in the others, allowing the same stratification process in each of them.

In yet another advantageous mode of the apparatus of the present invention, combined with any of the foregoing, the inner surface of the tubular layering chamber (1) is smooth. This is a considerable difference from state-of-the-art solutions, which rely on protruding structures or grooves, thus irregularities, to capture the desired materials.

In the present apparatus, this feature is advantageous in that it allows in a sliding rotation by the inner surface of the stratification chamber (1) to occur no stratification of the mineral strata.

In another advantageous mode of the apparatus of the present invention, combined with any of the foregoing, the stratification chamber (1) has a cylindrical, frusto-conical, prismatic or frusto-pyramidal shape and is preferably cylindrical since it is the turbulence inside is most reduced, being even stronger and consuming less material in the construction. However, any of the above forms is suitable for implementation of the present apparatus.

Also part of the present invention is a gravity stratification system for prospecting minerals and / or granular precious metals comprising the apparatus described above, in any of its configurations, and a sieve suitable for sieving mineral soil, the mesh of said sieve being preferably at least 7 times less than the distance between edges or diameter of the section formed by the end of the stratification chamber ( 1) tubular, even more preferably at least 10 times lower. In the present apparatus, a mesh is used to screen the minerals to be processed which additionally defines not only the maximum but also the minimum size achieved of the mineral sought. As an example for gold: if the screen has a mesh of 1 cm it is possible to capture gold particles with a diameter of 0.5 mm, which is 20 times smaller. In order to achieve a gravitational concentration of even smaller particles then the screen size of the chosen screen would also have to be smaller.

This system allows the pre-selection of material to be selected through the screen, and the indicated ratio allows the mitigation of turbulence that would exist inside the stratification chamber (1) during the fall of the larger minerals / metals when compared to the section of said chamber (1).

It is further part of the present invention a method of operating the apparatus described above, in any of its configurations, comprising the following steps:

 a) introducing at least one liquid, preferably water, and material to be stratified into each stratification chamber (1) of said apparatus;

 (b) stratification of the material to be stratified, including for each stratification chamber (1):

 (i) sliding rotation of the material to be stratified without riding;

ii) gravity drop positioning of the material to be stratified. This is the method of operation of the apparatus described above, including step a) of preparing the apparatus with the material to be selected and a liquid consisting preferably of water, and step b), which contains the stratifying steps. whereby through step b) the denser minerals will be close to the inner face of the lid (2) after sub-step ii). Other examples of suitable liquids are oily liquids.

It is also the object of the present invention to use the apparatus described above for prospecting for minerals and / or granular precious metals, preferably for gold and / or diamond mining.

DESCRIPTION OF THE FIGURES

Figure 1 is a representation of an apparatus according to the present invention in a specific embodiment containing a single cylindrical shaped stratification chamber (1). The fixed axis is visible, which includes two physical half shafts (7), one on each side of the laminating chamber (1), as well as at its ends, one closed and the other with a lid (2) suitable for opening and closing. . The appliance is represented with material and water inside, already stratified in this case. Thus, the next step of the method would be to collect the material with opening of the lower lid (2). Also shown is the watertight base (5) positioned at the opposite end of the lid (2). Also depicted in the figure are stratified material, specifically gold particles (9), diamonds (10), quartz crystals (11), black sands (12), coarse sand (13), fine sand (14) and very fine sand. (15).

Figure 2 is a detail view of an apparatus according to the present invention in a specific embodiment in which a spring opening and closing mechanism is represented, the opening rotation axis (4) being also visible. In this case, the perpendicular axis of rotation is perpendicular to the image plane, being parallel to said aperture rotation axis (4). It is equally the stratified material, specifically gold particles (9), diamonds (10), quartz crystals (11), black sands (12), coarse sand (13), fine sand (14) and very fine sand (15) ). Figure 3 is a representation of a specific embodiment of the apparatus of the present invention with a plurality, specifically 8, stratification chambers (1). In this embodiment, the apparatus contains two physical half shafts (7) and a center plate (6) with means for coupling all stratification chambers (1). Additionally, the chambers (1) contain lids (2) with a single set of opening and closing support means (8), which aggregates all the stratification chambers (1), and improves their joint movement.

Figure 4 - representation of a stratification chamber (1) and its perpendicular axis of rotation, in the longitudinally central position, indicating the direction of rotation around that axis.

DETAILED DESCRIPTION OF THE INVENTION

More general and advantageous embodiments of the present invention are described in the Summary of the invention. These configurations are detailed below in accordance with other advantageous and / or preferred embodiments of the present invention.

In a preferred embodiment of the apparatus of the present invention, said physical axis consists of:

• (i) n + 1 physical half shafts (7), each physical half shaft (7) being coupled to two of said layering chambers (1) and being in the number of layering chambers (1), or (Ii) at least one center plate (6) with means for coupling several of said stratification chambers (1) and two physical half shafts (7)

 - coupled to the layering chambers (1) positioned at ends of said plurality of layering chambers (1) or

 - coupled to ends of said center plate, in turn coupled to stratification chambers (1) positioned at ends of said plurality of stratification chambers (1), or

 (Iii) a plurality of physical half shafts (7), with at least part of said stratification chambers (1) directly coupled together, for example by welding;

wherein said physical half shafts (7) preferably contain bearings.

Alternative (ii) enables two different configurations, wherein said physical half shafts (7) may be placed in each stratification chamber (1) or only in the stratification chambers (1) of the ends of the series, or between some of the stratification (1). Preferably, the physical half shafts (7) contain bearings.

In another preferred embodiment of the apparatus of the present invention, combined with any of the foregoing, the stratifying chamber (1) comprises at least one opening at least one of its two longitudinal ends, suitable for entering and / or exiting stratifying material. each opening containing a lid (2) suitable for opening and closing and for providing tightness when closed, said lid (2) having one with an opening / closing mechanism (3) with an opening rotation axis (4), and being said opening rotation axis (4) positioned such that it is parallel to the perpendicular axis of rotation, and preferably the opening / closing mechanism (3) being a spring mechanism. Each stratification chamber (1) contains at least one opening so that a liquid and the material to be stratified and selected can be introduced and removed. The opening will be positioned at a specifically longitudinal end and preferably contain a sealing cap (2) so that there is no loss of the liquid and the material itself. Each opening contains a lid (2), which lid (2) is such that it contains an opening / closing mechanism (3) with an opening rotation axis (4) which is parallel to the perpendicular axis of rotation, to provide that when from the lid opening (2) the desired materials - which are stratified for immediate removal from the stratification chamber (1) - will not be lost because the lid (2) is opened without opening control. With the opening rotation axis (4) in said position, the opening section of the lid (2) is more controllable, because the end region of the widest opening layer (1) is that diametrically opposed to said opening axis. opening rotation (4). In a preferred mode of the apparatus of the present invention, it contains a watertight base (5) positioned at the opposite end of the laminating chamber (1) to that of the lid (2).

In a preferred embodiment of that immediately described above, the apparatus further comprises opening and closing support means positioned substantially close to the lid (2), preferably consisting of at least one clamp (8), most preferably each clamp (8) coupling two or more. more stratification chambers (1) of the apparatus. This clamp (8) has as its primary function the connection of the lid (2) to the end of the layering chamber (1). However, having different configurations, it will be possible to enclose and hold all the stratification chambers (1) of a plurality of chambers - a series -, configuring a specific mode of implementation of the solidarity movement of the different stratification chambers (1). In addition to the configuration in which the plurality of stratification chambers (1) are centrally aggregated, this solution allows for better joint movement of the chambers (1), especially in cases where the longitudinal length of the stratification chambers (1) is high.

In another preferred embodiment of the apparatus of the present invention, combined with any of the foregoing, the layering chamber (1) is pivotable with the pivoting means such that it can rotate 360 °.

In yet another preferred embodiment of the apparatus of the present invention, combined with any of the foregoing, it further comprises support means for said physical axis, preferably consisting of a support with support arms, suitable for positioning on the ground or on a structure. As mentioned, the weight of the present apparatus is supported by the physical axis, one of its configurations consisting of the mentioned physical axles (7). The physical axis will be supported by a support structure consisting of said support means and which in turn may consist of support arms which directly support the physical axis.

In another preferred embodiment of the apparatus of the present invention, combined with any of the foregoing, the longitudinal length of said stratifying chamber (1) is at least 10 times greater than the distance between opposite vertices or diameter of the section formed by the end of said stripping chamber. stratification (1).

In an advantageous embodiment of the method of the present invention, comprising repeating step b) 4 to 15 times, preferably 5 to 10 times, as gold or minerals slightly denser than quartz such as diamonds or other crystals. For gold it takes 5 to 6 repetitions, but for lower density minerals like diamond it may take up to 10 repetitions. Each cycle has two phases, the first one starting with a slow rotation causing the mineral extracts to slowly slide down the inner wall of the stratification chambers (1) towards the base, but without riding, until the rotation reaches the pre-riding limit angle of minerals, usually between 130-135 ° according to soil type, followed by the gravitational fall phase ( (b) under laminar flow with very little water turbulence within the stratification chambers (1), at this stage the stratification chambers (1) stand vertically with the caps (2) facing downwards by rapid reverse rotation of 130-135 °, repeating these two phases 5 to 10 times of slow gliding without riding and of gravitational fall. In order to be able to repeat the layering operation, the slip phase was designed by placing the mineral mass - the material to lay down - at the other end of the layering chamber (1) with a slow sliding through the inner walls of the layering chamber (1). conserving the relative position of the minerals achieved in the previous stratification.

It is this partial stratification, followed by a reverse sliding, which permits a new partial and always cumulative stratification to the previous ones, followed by a new sliding, repeating this partial stratification several times until the denser minerals reach the end of the path. it is next to the lid (2). Thus, with slipping, the required length of the stratification chamber (1) is reduced making the apparatus relatively short, practical, more energy efficient, possible for use in large industry and in the field. Generally for gold mining, due to its density (19.28 g / cm3) 4 or 5 cycles of partial stratification and slippage are required and twice as many cycles for diamonds as their density is only 3,516 to 3,525g. / cm3, relatively closer to the density of quartz crystals in the sands, which ranges from 2.6 to 2.65g / cm3. Another advantage concerns the so-called black sands which are always collected by the gutters along with the gold.

In the case of gold extracted by the apparatus of the present invention, it is already separated from the black sands, and comes together with quartz grains of the largest size allowed by the sieving mesh, which place them next to the denser metals and crystals. But because they are bigger it makes cleaning gold or removing it much easier and faster. The black sands (hematite and magnetite) are separated from the heavy minerals harvested in this device because although hematite and magnetite have a higher density than diamonds, their tiny size prevents them from being near larger crystals near the lid (2) in the discharge. The explanation for this is found in Stokes's law which explains that in the gravitational fall into a fluid the terminal velocity of mineral particles or a crystal depends mainly on its density but also on its radius squared (if spherical in shape). And since the tiny hematite and magnetite particles cannot stay close to the discharge cap (2) where the larger rounded quartz and diamond crystals are. As noted, in a preferred embodiment of the method of the present invention the unmounted rotation of step i) has as a limiting angle 130-135 ° from the previous position consisting of a vertical position.

In another specific embodiment of the method of the present invention, combined with any of the above, it comprises a step of collecting selected materials, carried out subsequent to step b), including:

c) positioning each stratification chamber (1) in a position substantially perpendicular to the gravity vector with the dipping aperture of the stratification chamber (1) in a container with a liquid identical to that contained within the stratification chamber (1); d) collection of selected materials.

Step c) allows the shaft of the lid opening mechanism (2) to be turned upwards, and the lids (2) to be immersed in water having under each stratification chamber (1) a container with water for collecting minerals. wanted. The water in the container covering the lid (2) is necessary to prevent air from entering the stratification chamber (1), i.e. not to lose the water inside it, which is used for subsequent exploration. Step d) is performed with a slight lid opening (2). In another preferred embodiment of the method of the present invention, combined with any of the above, the amount of liquid is such that it is at a level of at least 70% of the longitudinal length of the stratification chamber (1) when it is in a perpendicular position to the ground, preferably 75%, and the volume of material to stratify preferably less than or equal to 25% of the internal volume of the stratification chamber (1). By filling at least 70%, it is intended to prevent the material to be selected from scratching the interior of the layering chamber (1). The quantity of material to be selected, such as river or sea sandy soil, is such that its volume does not exceed 25% of the internal volume in each stratification chamber (1). This filling operation may be carried out with the support of a tapered instrument whose tip penetrates each stratification chamber (1) and has an outlet hole with a diameter of less than half the diameter of the lid opening section (2) if the section is circular, or less than half the distance between opposite vertices of the polygon of the stratification chamber section (1) next to the lid (2), if the chamber section (1) is polygonal in shape, followed by full filling with closing the chambers with the lids (2), the stratification chambers (1) being upright to avoid air bubbles inside, which would cause unnecessary and harmful turbulence, and finally the rapid 180 ° rotation to start a new first time of the stratifying repetitive cycles. MODES OF CARRYING OUT

In different embodiments of the apparatus object of the present invention, the layering chamber (1) is of a plastic, metallic or composite material.

In a preferred embodiment of the apparatus object of the present invention, the laminating chamber (1) and the lid (2) are transparent. This implementation is particularly useful for configurations where the apparatus contains a single laminate chamber (1), therefore for a smaller use where the user easily visualizes the degree of laminate of the materials to be selected. It is however also suitable for cases where a plurality of stratification chambers (1) exist in a more industrial use. In this case, the solution of stratification chambers (1) with stronger and therefore opaque materials, such as metallic materials, will be preferred.

In the following, different possibilities for implementing the apparatus and method of the present invention are described, which may configure different embodiments.

The apparatus of the present invention may be operated manually or mechanically and / or motorized, operating in a single series or in several, and thus processing hundreds of tons / hour of gold or diamond alluvial on site or on ships, requiring for Your job is a fraction of the energy spent to process the same amounts of mineral by traditional machines.

As mentioned, another important advantage of this apparatus is that it can operate while fully or partially submerged in water in any depth, in particular by dredging, or by vessels, maintaining the same operation as in the open air.

In this case the outer shape of the stratification chambers (1) will be hydrodynamic, the stratification chambers (1) of each series being further apart than when operating out of water, although in any case connected and always in the same plane.

This is a great advantage of this device which is not present in traditional large or small mineral extraction machines, allowing to use in great depth when the minerals sought are in riverbed or deep seabed, very significantly reducing the energy costs that would be required to bring to the surface all the minerals to be worked out of water.

Another important advantage of this apparatus is that it works using water, recovering much of the water that is inside the stratification chamber (1) when emptying minerals, and when laying new sandy soil to be worked on.

As noted, initial screening is useful for several reasons: determining the minimum diameter of the stratification chambers (1), facilitating stratification, deciding on the size of the largest and smallest minerals to be collected and increasing the speed of operation.

The following describes in detail an embodiment of the apparatus of the present invention, with details of its method of operation.

The apparatus of the present invention is a mining machine sorting and extraction unit for operating in particular in Auriferous or diamond alluvial soils, having a specific and exclusive functioning, and the invention, in its configuration, characterized by having several mechanical elements related to each other in specific proportions with the following constitution: several stratification chambers (1) connected in the same plane , forming a series that operates simultaneously, each stratification chamber (1) having a preferably cylindrical interior shape, as being the most efficient, causing less turbulence, being the most resistant shape and consuming less material in its construction, but they may optionally have other similar shapes, the inner surface of each stratification chamber (1) being smooth or slippery.

An apparatus may be extraordinarily composed of a single stratification chamber (1), but to increase profitability the apparatus generally operates in series and the machines may have several series of stratification chambers (1).

The stratification chambers (1) may optionally have other cylindrical-like shapes such as the conical, prismatic and pyramidal trunk, the inner surface of each stratification chamber (1) being always smooth or slippery, which is a useful condition to allow the slipping phase on the inner surface of the apparatus without the mineral extracts being mounted.

Each laminating chamber (1) has a watertight lid (2), a quick open / close mechanism (3) of the lid (2) which is controlled, each lid (2) being connected to the laminating chambers (1) via an opening rotation axis (4) of each lid (2), which are connected to a multiple opening and closing support bracket (8) which surrounds and holds all the stratification chambers (1) of this series in the same plane, has a watertight base (5) in each laminating chamber (1) disposed at the end of each laminating chamber (1) opposite that of the lid (2), a central plate (6) surrounding the central portion of the laminating chambers (1), in which they are inserted at the middle of the chamber of the (1) two diametrically opposed physical half shafts (7), fixed perpendicular to the length of the stratification chambers (1) and parallel to the opening rotation axis (4) of the lid (2), thereby allowing the lid to open ( 2) For extraction of minerals the lid (2) opens upwards leaving the bottom where a container full of water to collect the sought minerals is placed.

The amount of sand or alluvial soil to be introduced into each stratification chamber (1) is previously and automatically determined.

The measurement of the inner diameter of each laminating chamber (1) near the lid (2), if the section of the laminating chamber (1) near the lid (2) is circular, or the internal distance between opposite edges in the case of The section next to the lid (2) is polygonal, is at least 7 times larger than the mesh size of the screen chosen for pre-screening of the mineral soils to be worked by the apparatus. Usually it is almost always 10 times or more.

This measure has to do with the great turbulence that would exist within the stratification chamber (1) during the fall of the largest minerals into smaller diameter stratification chambers (1). The ideal measurement depends on many variables but is greater than 7 times the mesh size of the screen used, 7 being the minimum indicated.

The length of each laminating chamber (1) is preferably at least 10 times larger than the diameter of the laminating chamber section (1) next to the lid (2) in case the laminating chamber section (1) is circular. or be at least 10 times the distance between opposite vertices of the polygon of the laminating chamber section (1) next to the lid (2), if the laminating chamber section (1) is polygonal in shape. This number was found to be the most profitable. The total weight of the apparatus is supported by said physical half shafts (7) which may be placed either in each stratification chamber (1), or in the stratification chambers (1) at the end of the series or between some of the stratification chambers (1). ) having such physical half shafts (7) bearings and supported on a support with support arms or similar structures fixed to each other by the base of that structure.

The support structure of the physical half shafts (7) must be positioned to allow the introduction of a container with water to receive the rejected minerals by each stratification chamber (1) after extraction of the wanted ones. The presence of water in the mineral extraction containers and mineral waste disposal containers is required if the operator wants the appliance - in the stratification chamber (1) - to remain filled with water for the next operation. The following describes an embodiment of the method of operation of the apparatus embodiment of the present invention described above. The operation method of this device is divided into 4 different times; filling, the stratification chambers (1) being upright, the stratifying repetitive cycles, when the denser minerals end up close to the inner face of the lid (2), the collection of the minerals sought by the controlled opening of the lid ( 2), the stratification chamber (1) being just before the horizontal position at about 80 ° and finally the emptying of unselected minerals with the apparatus with the stratification chambers (1) being upright with the lid (2) face down.

The first step of filling the stratification chambers (1) comprises the following stages; filling the stratification chambers (1) with water at a level greater than 3/4 of their height to prevent minerals from scratching the interior of the sidewall, followed by filling with the river or sea sandy soil without minerals in excess of 25% of the internal volume in each chamber (1) having the support of a tapered instrument the tip of which penetrates each stratification chamber (1) and has an outlet hole of less than half the diameter of the section of the stratification chamber (1) near the lid ( 2) if the section of the laminate chamber (1) is circular, or less than half the distance between opposite vertices of the polygon of the section of the laminate chamber (1) near the lid (2), in the case of the section of the laminate chamber (1) have a polygonal shape, followed by full filling with water and finally the closure of the layering chambers (1) with the lid (2), the layering chambers (1) being upright to avoid bubbles. air into the stratification chamber (1), which would cause unnecessary and harmful turbulence, and finally the rapid 180 ° rotation to begin a new first time of the stratifying repetitive cycles.

The second time, the stratifying cycles, is made up of 5 to 10 repetitions, depending on gold mining or minerals slightly denser than quartz such as diamonds or other crystals. For gold it usually takes 5 to 6 repetitions, depending on the type of soil, the range of sieves chosen and the particle size to be recovered, but for lower density minerals such as diamond, up to 10 repetitions may be required. Each cycle has two phases, the first starting with a slow rotation causing the mineral extracts to slowly slide down the inner wall of the stratification chambers (1) towards the base, but without riding, until the rotation reaches the pre-limiting angle. minerals, generally between 130 ° and 135 ° according to the type of soil, followed by the gravitational fall phase under laminar regime with very little turbulence of the minerals placed in the water inside the stratification chamber (1). vertical stratification chambers (1) with the caps (2) facing downwards by a rapid reverse rotation of 130 ^ to 135 ^, these two stages repeating 5 to 10 times of slow sliding without riding and falling gravity, with inversion of the direction of rotation in the next movement. The third time, the collection of the sought minerals, is the 80 ° rotation since the last gravity drop, the stratification chamber (1) being almost horizontal with the lid opening mechanism axis (2) facing upwards. , and the lids (2) immersed in water having under each stratification chamber (1) a container with water for collecting the sought minerals. The water in the container covering the lid (2) is necessary to prevent air from entering the stratification chamber (1), ie not to lose water from the interior if it is required for further exploration.

The operator may vary slightly the angle chosen according to his experience and the type of minerals to be harvested and the soil in which he is operating.

The fourth time, the emptying of the unselected minerals, is performed with the stratification chambers (1) again vertically by 80 ° reverse rotation and the full opening of the lids (2) having a container underneath with water for no air enters the layering chamber (1), and a final 180Â ° rotation with the lid (2) closed to start a new first filling time with the layering chamber (1) already filled with water.

The opening and closing of the covers (2) as well as the rotations of the stratification chambers (1) can be movements adjusted and performed manually, or mechanically, or automatically according to the size of the apparatus. The apparatus may operate with a single stratification chamber (1) alone, or several stratification chambers (1) may be used joined together in a plane forming a series as shown in Figure 3, or may work several series performing all specific movements. simultaneously in each series. In another embodiment of the apparatus of the present invention, it contains a single, small-sized laminating chamber (1) with laminating chamber (1) and transparent material lid (2), which is intended to help determine the number of stratifying cycles required for the mineral sought and the riding angle in different unknown soils or in different new regions or at great depths. It can also be used for field prospecting.

Alternatively the specific operation of the apparatus may be carried out by having the stratification chambers (1) of the apparatus wholly or partially submerged in water at any depth, as part of dredgers or ships, and in any event maintaining the identical operation of air. free, with the obvious differences from the presence of water.

In this case, the outer shape of the layering chambers (1) is hydrodynamic and the layering chambers (1) although connected to one another are further apart, also for hydrodynamic reasons.

As will be apparent to one of ordinary skill in the art, the present invention should not be limited to the embodiments described herein, and various changes which remain within the scope of the present invention are possible.

Of course, the preferred modes set forth above are combinable in different possible forms, avoiding the repetition of all such combinations here.

Claims

1. Apparatus for gravity stratification for prospecting for granular minerals and / or precious metals, comprising at least one tubular stratification chamber (1) and rotating means, said stratification chamber (1) being hinged with the rotating means. such that it can rotate about an axis perpendicular to itself, said rotating perpendicular axis intersecting a longitudinally central position of said stratification chamber (1).

Apparatus according to the preceding claim, characterized in that the rotating means consists of at least one physical axis coupled to the outer surface of a longitudinally central section of said stratification chamber (1), said physical axis coinciding with said perpendicular axis. of rotation.

Apparatus according to the preceding claim, characterized in that the physical axis comprises at least two physical half shafts (7), each coupled to the outer surface of a stratification chamber (1).

Apparatus according to any one of the preceding claims, characterized in that it comprises a plurality of stratification chambers (1), all stratification chambers (1) being coupled together such that (i) their rotational movement is integral with one another. and (ii) are on the same plane.

Apparatus according to the preceding claim, characterized in that said physical axis consists of:

(i) n + 1 physical half shafts (7), each physical half shaft (7) being coupled to two of said layering chambers (1) and being in the number of layering chambers (1), or (ii) at least one central plate (6) with means for coupling several of said stratification chambers (1) and two physical half shafts (7)

 - coupled to the layering chambers (1) positioned at ends of said plurality of layering chambers (1) or

 - coupled to ends of said central plate, in turn coupled to stratification chambers (1) positioned at ends of said plurality of stratification chambers (1),

 or

 (iii) a plurality of physical half shafts (7), with at least part of said stratification chambers (1) directly coupled together, for example via welding;

wherein said physical half shafts (7) preferably contain bearings.

Apparatus according to any one of the preceding claims, characterized in that each stratification chamber (1) comprises at least one opening at least one of its two longitudinal ends, suitable for entering and / or exiting stratifying material, each opening containing a lid (2) suitable for opening and closing and for providing tightness when closed, said lid (2) having an opening / closing mechanism (3) with an opening rotation axis (4), and said rotation axis opening (4) positioned such that it is parallel to the perpendicular axis of rotation, and preferably the opening / closing mechanism (3) is a spring mechanism.

Apparatus according to the preceding claim, further comprising opening and closing support means positioned substantially close to the lid (2), preferably consisting of at least one clamp (8), most preferably each clamp (8) coupling two or more. more stratification chambers (1) of the apparatus.

Apparatus according to any one of the preceding claims, characterized in that the inner surface of each stratification chamber (1) is smooth.

Apparatus according to any one of the preceding claims, characterized in that the tubular stratification chamber (1) is cylindrical, frusto-conical, prismatic or frusto-pyramidal in shape and is preferably cylindrical.

Apparatus according to any one of the preceding claims, characterized in that the laminating chamber (1) is pivoted with the rotating means in such a way that it rotates 360 °.

Apparatus according to any one of claims 2-10, further comprising support means for said physical axis, preferably consisting of a support with support arms, suitable for positioning on the ground or on a structure.

Apparatus according to any one of the preceding claims, characterized in that the laminating chamber (1) and the lid (2) are transparent.

Gravity stratification system for prospecting granular precious minerals and / or metals comprising the apparatus of any preceding claim and a suitable sieve for sieving mineral soil, the mesh of said sieve being preferably at least 7 times smaller than edge distance or diameter of the section formed by the end of the tubular stratification chamber (1), most preferably at least 10 times smaller.

Method of operating the apparatus of any one of claims 1-12 comprising the following steps:

 a) introducing at least one liquid, preferably water, and material to be stratified into each stratification chamber (1) of said apparatus;

 (b) stratification of the material to be stratified, including for each stratification chamber (1):

 (i) sliding rotation of the material to be stratified without riding;

 ii) gravity drop positioning of the material to be stratified.

A method according to the preceding claim comprising repeating step b) 4 to 15 times, preferably 5 to 10 times.

Method according to any one of claims 14-15, characterized in that the unstrapped rotation of step i) has as a limiting angle 130-135 ° from the previous position which consists of a vertical position.

A method according to any one of claims 14-16 comprising a step of collecting selected materials carried out subsequent to step b), including:

 c) positioning each laminating chamber (1) in a position substantially perpendicular to the gravity vector by dipping the opening of the laminating chamber (1) into a container with a liquid identical to that contained within the laminating chamber (1); d) collection of selected materials.

Method according to any one of claims 14-17, characterized in that the amount of liquid is such that it is at a level of at least 70% of the longitudinal length of the stratification chamber (1) when it is in a perpendicular position. to the ground, preferably 75%, and being the volume of material to be stratified is preferably less than or equal to 25% of the internal volume of the stratification chamber (1).

Use of the apparatus of any one of claims 1-12 for prospecting for minerals and / or granular precious metals, preferably for gold and / or diamond mining.