Method of construction for density screening outer transport walls

Abstract

A method for combining three different means of constructing the concentric layers of the outer collecting wall for industrial size centrifuges, whereby treating the inward-facing elements of easily cast or stamped materials using processes such as Physical Vapor Deposition, Chemical Vapor Deposition or metal plating, transforms them into an innermost member with superior hardness and durability, and whereby said wear surface member or deposited layer is physically supported by a middle composition layer made up of one or more investment castings designed to optimally transfer centrifugally-induced compression loads from the innermost wear surface toward the outer surface of the composite wall, such castings being of ceramic, metals or other materials, and whereby the outer surface of said composite wall is comprised of a filament-wound hoop strength reinforcement layer, using aramid, graphic, carbon or such fibers mixed and embedded in resin, such that all highly desirable characteristics for a centrifuge outer, heavies-collecting wall are provided, including interior hardness and wear abrasion, incompressibility and intrinsic dynamic balance, and substantially higher hoop or bursting strength, than can be attained through any metal-crafted centrifuge outer wall, and, model for model, for substantially lower design and fabrication costs.

Description

LIST OF REFERENCE NUMERALS

Part 1 Pyramidal or conical shaped outer wall Collecting Void

Part 2 Hardened Wear Surface, as separately inserted tiles (shown in FIG. 1) or as a chemically deposited or metal-plated integral coating layer on the interior facing portions of the compression load-transfer casting (Part 4), (shown in FIG. 2)

Part 3 Collecting Void Orifice at apex of each pyramidal or conical collecting void

Part 4 Compression load transfer casting

Part 5 Filament winding outer reinforcement layer

Part 6 Hardened exit nozzles to insert into and through Parts 2, 4 and 5

Part 7 Compression load transfer casting, Monolithic or One-Piece version

Part 9 Cast vertical holes to accept longitudinal bolts for connecting entire wall assembly

Part 9 Cast slots to accept vanes on solid type centrifuge cores using said vanes to create vertical fluid working columns or sectors

Part 10 Compression load transfer casting, Horizontally Cast Slice version

Part 11 Area for installation of centrifuge core

Part 12 Containment zone for ejected heavy materials

Part 13 Non-rotating Outer Heavies Catchment Shell

Part 14 Compression load transfer casting, Vertical version

Part 15 Entry End Cap

Part 16 Recessed top receptacles for longitudinal assembly bolts

Part 17 Outlet End Cap

Part 18 Main Fluid Entry

Part 19 Path of Longitudinal Assembly Bolt(s)

Part 20 Fluid Entry Shaft

Part 21 Clarified Fluid Outlet and Transmission Shaft

Part 22 Solid Center Centrifuge Core and Anti-Vorticity, Vertical Segment Vanes

Part 23 Anti-Vorticity Vanes (producing vertical fluid working columns or sectors)

Part 24 Disk Stack Centrifuge Core Assembly

DESCRIPTION OF THE INVENTION

First Embodiment--Monolithic Casting

As a significant part of the work done to develop the Density Screening outer wall transport method, the inventors have extensively reviewed late 20^th century material science from manufacturing areas entirely outside of centrifugal devices. This review of so-called new materials has led to another key feature of the Density Screening method, which is to combine in a hybrid or sandwich construction manner, three different material technologies, each ideally suited to solving selected challenges in centrifuge design and performance. FIGS. 1 and 2 illustrate the deceptively simple appearing outcome of this re-thinking.

Reading FIGS. 1 and 2 from left to right, the sequence of materials in the optimum hybrid or sandwich construction of one cut-away, pyramidal void section of a Density Screening outer wall is presented as each would be sequentially encountered by a heavy particle being thrown via centrifugal force, outwards from the spinning column of fluid, in any centrifugal device core.

Ignoring for a moment the detail of nozzles (far left, Part 6), the heavy particles being thrown outward encounter the first layer of a Density Screen outer wall, a layer known as a wear surface (Part 2). Such a surface can be a thin-stamped or cast piece of metal, ceramic or other material, or it can be achieved via a chemical transformation or metal plating of the surface of the middle (casting) layer (Part 4), such that the "wear surface" and the "compression transfer casting" are one physical piece, comprising two elements.

One surprisingly economical possibility for this innermost layer as a separate applied tile, is thin-stamped aluminum, whose facing surface is transformed prior to wall assembly into an ultra-hard coating of sapphire via Physical Vapor Deposition (PVD) or into other extremely hard surfaces via Chemical Vapor Deposition (CVD). Conversely and for a given outer wall design, the compression load-transfer (middle) layer members may be easily-cast aluminum, the inner faces of which are similarly given ultra-hardness through such surface treatments.

This innermost layer or member of the Density Screening materials hybrid or sandwich is therefore quite flexibly configurable to economically achieve extreme wear and abrasion resistance.

Regarding nozzles (extreme left, Part 6, in FIGS. 1 and 2), there are numerous ultra-hard, off-the-shelf nozzle technologies to chose from, to fit into the apex opening of each pyramidal or conical void. Such nozzles are readily available in ruby, sapphire and diamond, with many thread and other attachment variations and are offered in a broad variety of orifice sizes.

Moving outwards past the wear surface layer of the Density Screening hybrid or sandwich, next is seen the compression transfer layer or component (Part 4). Bearing in mind the extreme weight and centrifugal thrust of the heavy particles continuously bombarding the outer wall of a centrifuge, a practical means must be devised to support the thin wear surface layer by transferring the compressive loads of such bombardment along to the outer parts of the Density Screen outer wall.

FIGS. 1 and 2 thus next shown an incompressible load transferring casting (Part 4), which can be fabricated to extremely accurate size, weight and density tolerances via investment casting. Investment casting of ceramic, aluminum or other materials produces parts of high precision and intricacy, whose uniform size, stiffness and density makes them intrinsically dynamically balanced, and thus ideal for centrifuge outer wall use as the compression transfer element of the sandwich. The inventors have developed several multiple void casting schemes, including fabricating multiple voids as monolithic or one-piece castings (FIGS. 8 and 9), as horizontal castings to be stacked atop one another (FIG. 12), and as vertical castings (FIGS. 15 and 16).

The primary embodiment of this method of construction is presented as the one-piece or Monolithic casting scheme. When employing Density Screening outer transport walls for very high rotational speed devices, it is anticipated that the monolithic or one-piece approach, fabricated of various materials via investment casting, will yield the greatest stiffness and torsional twist resistance. Casting the compression load-transfer casting layer in one piece, particularly for a relatively tall centrifuge core, requiring six, eight, 10 or more stacked annular bands of collecting voids, does make for the most intricate casting in the one-piece scheme, and will therefore be the most expensive to set up.

As with all the casting variations presented in this application, hardened wear surface inserts may be placed so as to protect all heavy material bombardment areas of the compression load-transfer casting. FIG. 11 shows the insertion of such surfaces on a Monolithic type of such casting. Again, the interior walls of the casting itself, may, conversely, be chemically or otherwise transformed to integrally provide the desired hardened interior surfaces.

It is expected that these tall, relatively intricate castings will pay for themselves in certain higher stress applications, due to their torsional rigidity.

Moving outward (in FIGS. 1 and 2, from left to right), in the Monolithic casting embodiment of the Density Screening outer centrifuge wall, we and move on to the final and outer layer of the wall or shell, which is constructed via a late 20^th century technology means called filament winding (Part 5). Originally performed using steel wire and fiberglass, filament winding is a means for converting the tensile strength of certain wire or fibers into hoop strength by repetitively winding a vessel such as our composite centrifuge outer wall, in known patterns which produce maximum burst resistance for that vessel.

Certain recently perfected fibers, notably arymid (also called Kevlar), carbon and graphite, exhibit some of the highest tensile strengths known to science. Carbon fiber, for example, can provide a tensile strength seven to ten times higher than that of titanium, and with many more times than that afforded by any steel alloys. Numerous applications using such fibers in various ultra-high-strength applications are well documented, all outside of the centrifuge industry. Coating such fibers with various resin-binder chemicals, and then continuously winding them around the outer surface of a vessel translates these materials' very high tensile strength into extremely high bursting strength for such a container.

Thus, the outermost layer of the construction method for Density Screening is achieved through filament winding (farthest right in FIGS. 1 and 2, part 5). This part of the construction is done by applying resin-impregnated carbon, Kevlar and/or mixtures of these and other high-strength filaments as the outer wrapping, directly over the compression load-transferring casting layer.

Beyond the dramatic increase in achievable bursting strength for any given size spinning centrifugal device offered by filament winding technology, is a second major and well-documented feature of this technology, torsional stiffness. Currently, filament winding is a mature technology used to create helicopter transmission shafts, spinning jet engine components and other extremely high-stress spinning elements which must transfer rotational energies without twisting and thus resisting the development of harmonics from twist or flexion. Applying filament winding as the outer hybrid component of Density Screening outer transport walls brings not only previously unknown bursting strength but also the ability to resist and contain torsional twisting and related harmonics, an ability very much required for centrifugal devices planned to achieve the rotational speeds required to produce 5,000, 8,000 or more multiples of gravity.

As stated previously, the inventors have explored and devised multiple physical means of construction for Density Screening outer transport walls, by combining in hybrid fashion multiple material and manufacturing technologies developed across several fields of material science developed since the 1970's. To the inventors' best knowledge, none of these new, but nonetheless prior art, materials and fabrication methods, either singly or in the novel hybrid combinations to be documented in subsequent device patents, appear at all in prior centrifuge art, which relies almost exclusively on cast and carved steel, steel alloys or titanium metals for nearly all centrifuge components.

The documented tensile strength of carbon and Kevlar filaments and combinations can approach ten times that of metals conventionally used for centrifuge outer walls. Wrapping the outer surface of any Density Screening transport wall assembly with such filament yields centrifuges which will exhibit as much as ten times more burst strength than any tubal, decanter or disk centrifuges on the market, or, which could be theoretically rotated ten times faster than conventional centrifuges of equal diameter without bursting. This has the import of providing the unprecedented design flexibility, offering desirable combinations of "much larger" times "much faster" centrifugal devices in every category.

When the strength and low fabrication cost of this application are combined with outer collecting wall void geometry advantages as detailed in pending U.S. patent application Ser. No. 09/115,527 made available by this composite means of construction, it is clear that the Density Screening offers an original and substantially improved new method of heavy material transport for the entire family of spinning centrifugal devices.

Second Embodiment--Assembly of Sub-Castings

The inventors have thoroughly developed a second technique for fabricating the all-important compression load-transferring layer for Density Screening outer transport walls. This technique is to produce multiple castings and then assemble them around the centrifuge core. As with the monolithic castings, wear surface inserts protect the leading, or bombardment side of each void casting area.

Two different schemes have been developed for assembling multiple compression load-transfer castings into completed outer walls, horizontal, and vertical. Horizontal castings (FIGS. 11 and 12) offer much of the torsional rigidity of the monolithic casting means, but each of the horizontal castings is simpler to lay out, having fewer multiple intricate elements, and thus may be less expensive.

A second advantage of stacking multiple horizontal castings is the option this means affords for incorporating different slope angles and other void geometry variations from horizontal layer to horizontal layer. In other words, if for a given centrifugal separation, it were desirable to have different void slope angles in each annular horizontal layer of collecting voids, thus stacking horizontally cast layers, each of which was manufactured having different void geometries, will permit the creation of standard, interchangeable, and variable-slope parts.

This means that as a fluid moved longitudinally down a centrifuge, heavy materials being sequentially thrown from the device's center core, changing in characteristic, would meet optimized slope angles in the voids of the outer wall, which void slopes were different in each horizontal layer of the wall. Thus an end-user of such a centrifuge could maintain an inventory of horizontal castings, each with different, pre-determined void slope characteristics, and field-swap or vary the configuration of the outer collecting wall of his centrifuge at will. While such configure-in-the-field flexibility could also be obtained by purchasing and inventorying hand several monolithic type outer walls, each having pre-set, different slope combinations in various layers, this would be a far more expensive approach.

The other multiple, compression load-transfer layer casting method is Vertical (see FIGS. 15 and 16). The inventors' studies indicate that this probably is the least expensive casting scheme for initial setup, layout and molding, since each casting is simpler, i.e., contains fewer complex internal voids, as compared to the radiating hollow core design of both the horizontal and monolithic approaches. As with combination-assembly horizontal castings, vertical castings also lend themselves to easy, field-changeable and field-replaceable outer wall configurations.

Operation of the Invention

Preferred Embodiment--Monolithic Casting

The invention is a method of construction for the Density Screening multi-collecting void outer shell or wall, to enclose different types of prior art centrifuge cores. This method combines several different materials and corresponding means of fabrication to produce a three-or-four-layered outer wall whose composite or hybrid construction combines all the strengths of each of the means into the final assembly. Therefore this section, "Operation of the Invention" describes the method of fabrication or construction, which combines these several means.

All forms of this method of construction, for combining several different fabrication means in hybrid fashion to create the outer walls for centrifuges, begin with a thin stamped, castor chemically applied wear surface (shown in all Figures as Part 2), which forms the innermost of the concentric hybrid wall layers.

Moving outwards from the center to the outside, the second concentric layer of the hybrid shell, in the preferred embodiment of the invention, is the metal or ceramic-cast compression-load transfer or backing layer. Generically in FIGS. 1 and 2, this is shown in the form of arbitrarily cut-aways of a single outer wall void, as Part 4. Two versions of the preferred embodiment, Monolithic casting for the compression load transfer layer are shown as FIG. 8 and FIG. 9. These figures happen to show six circular arrays of voids stacked, one atop the other; any number of such stacked horizontal bands of voids may be cast and used, however.

Parts 1 in FIG. 8 are the pyramidal or conical voids in the interior wall of the casting, while Parts 2 are the wear surface inserts or coatings that protect the interior faces of the casting. FIG. 10 shows such a monolithic casting and indicates how tile-type wear surface inserts are placed. (The interior wear surfaces can also be a layer added via chemical deposition or plating techniques). This version of such a casting also includes vertically cast slots (Parts 9), to receive the outer edges of vertical, anti-vorticity vanes attached to the center member of a solid-core type centrifuge (Part 23, in FIG. 25, illustrates such a core variant).

FIG. 9 shows a very similar Monolithic casting of the compression load transfer layer, only without such vertically cast slots, not needed when such an outer centrifuge wall is used to enclosed other types of centrifuge cores (i.e., not having vanes). FIG. 13 shows a top view of FIG. 8, a Monolithic casting with vane insert slots. FIG. 24 shows a Monolithic compression wall transfer casting, protected by wear surface inserts or coatings on all its voids (not shown), ready for assembly with two matching diameter end caps (at the entry and outlet ends, parts 15 and 17 respectively. Note that in both end caps there are cast bolt end receptacles (Parts 8), through which longitudinal bolts are passed to secure together the end caps and the casting. (See FIGS. 8, 9 and 13 for the locations of Parts 8, the cast holes in the castings through which these longitudinal assembly bolts pass).

FIGS. 13 and 14 also show the outermost zone and element of the assembled outer wall, which is the heavies catchment zone (Part 12) and the non-rotating outer catchment cylinder or sleeve (Part 13).

FIG. 25 shows an exploded view of the overall assembly for one variant of this method's centrifuge outer wall construction, including the wear surface (Parts 2), which is one monolithic casting (Part 8). Such a casting by itself achieves the planned length for a given devise. This Figure also shows the longitudinal assembly bolt holes (Parts 8) included into such monolithic castings, as well the orifices (Parts 3) at the apex of each void, which orifices penetrate the castings and outer Filament Winding layer, the inlet and outlet End Caps (Parts 15 and 17), containing the end holding receptacles (Parts 16) for longitudinal assembly bolts (not shown), and a solid center centrifuge core (Part 22), which in this iteration includes vertical zone-producing anti-vorticity vanes (Parts 23). The outer, filament-winding layer which wraps the entire assembly is not shown in FIG. 24.

Alternate Embodiments--Assmebling Multiple Castings

As with the primary embodiment of this method of construction invention, the inner most file or layer of the alternate embodiments begins with the insertable or chemically deposited or plated, hardened wear surface elements. The variability of the alternate embodiments occurs in the next outermost layer, and involves the casting methods used to produce the compression load-transfer casting element for the hybrid outer wall. Two such casting element methods are claimed.

Assembly of Horizontal Castings

First, is the casting of horizontal layers of circularly arrayed collecting voids. FIG. 11 shows one such casting (Part 10), revealing the collecting voids (Parts 1), the wear surface inserts (Parts 2), and also the void apex exit orifices and nozzles (Parts 3 and 6). The horizontal casting shown in FIG. 11 includes slots (Parts 9) to receive vertical, anti-vorticity vanes from a solid-center centrifuge core.

FIG. 12 shows the stacking of multiple such castings to achieve an outer wall of any practical length. FIGS. 13 and 14 show top views of an outer wall made up of several stacked horizontal castings (FIG. 13 shows the castings with slots to receive solid core vanes, while FIG. 14 shows the castings without such slots, Parts 7 or 10). Again, the outer heavies catchment zone (Part 12) and non-rotating outer catchment sleeve (Part 13) are also shown.

Assembly of Vertical Castings

The second multiple casting technique is vertical. These are placed in a circular array, such that their vertical stacks of collecting voids become annual rings of such voids. FIG. 15 shows six such castings (Parts 14), revealing the collecting voids (Parts 1), the wear surface inserts or coatings (Parts 2), and also the void apex exit voids. (Parts 3). The castings shown in this figure include the cast-in vertical slots (Parts 9) to accommodate vertical, anti-vorticity vanes attached to a solid center type centrifuge core; FIG. 19 shows a top view of these six vertical castings combined to make up an outer centrifuge wall, including the cast vane slots (again, Parts 9).

FIG. 16 shows six very similar vertical castings (Parts 14), only without cast slots for vanes; such vertical castings are used to surround centrifuge cores which do not require vertical, anti-vorticity vanes. Note in both FIGS. 15 and 16 the cast vertical bolt holes (Parts 8), through which the overall wall's longitudinal assembly bolts pass. FIG. 20 shows a top view of an array of this type of vaneless, vertical casting, with six of them assembled into the outer void collecting wall for a centrifuge.

FIGS. 17 and 18 shows the insertion of thin stamped or cast, separate tile-type wear surfaces (Parts 2), cast or stamped with multiple connected voids to match its vertical casting member, into vane-type compression load-transfer vertical castings (Parts 14). Note the additionally insertable hard material (ruby, sapphire, diamond), off-the-shelf orifice nozzles (Parts 6). As in all embodiments, the wear surface member may also be chemically deposited or metal-plated directly on the compression transfer castings, as an alternative to the separate insertable tiles.

Examples of Completed Density Screen Assemblies

Once the wear surface inserts are attached to the Monolithic, or to the Horizontally cast or Vertically cast compression load transfer castings, and the castings are properly assembled and secured, the final filament-winding layer can be added. FIGS. 13 and 19 show top views of the wear surface plus compression load-transfer casting assemblies, in variants with slots for centrifuge core radiating vanes. FIGS. 14 and 20 show top views of wear surface plus compression load-transfer assemblies, in variations with no such slots. All four of these figures show the inner most layer of the hybrid shell wall, the wear surface layer, as a separate member (Parts 2), although this surface may be integral to the casting layer. The cylindrical outer surface of the Monolithic or of the assembled Horizontal or Vertical castings serves as the winding mold or Mandrill, around which aramid, carbon, graphite or mixtures of such ultra-strong fibers are filament wound, to impart extremely high bursting strength to the entire composite assembly.

Such fibers are wound using one of several types of specialty binding resins, which resins when cured, lock together the fibers with all other hybrid layers of the outer wall assembly. FIG. 21 shows how any of the variously configured wear surface plus casting assemblies are combined with end caps (Parts 15 and 17) prior to filament windings. FIGS. 22 and 23 show, in sparse, representational style, the filament winding layer encasing the compression load-transfer castings, which in turn carry the wear surface inserts on the interior of each collecting void facing the fluid work area.

FIGS. 24, 25 and 26 show exploded views of the overall assembly of three different centrifuge outer walls, surrounding different types of centrifuge cores. These figures all include the wear surfaces (Parts 2), the compression load-transfer castings (Monolithic in FIG. 23, Horizontal castings stacked in FIG. 24, and Vertical castings joined in FIG. 25). All these figures also show the longitudinal assembly bolt holes (Parts 8) included into each horizontal casting, the orifice (Parts 3) at the apex of each void, which orifice penetrates both the castings and the filament winding outer layer, the inlet and outlet End Caps (Parts 15 and 17), containing the end cap, bolt-holding receptacles (Parts 16) for the longitudinal assembly bolts (not shown), and centrifuge core (FIGS. 24 and 26 show a Disk Stack core [Part 24]), while FIG. 25 shows a solid center core (Part 22) in an iteration that includes anti-vorticity vanes (Parts 23) used to create vertical fluid working sectors).

Conclusions, Ramifications and Scope of Invention

Centrifuges for separating materials from fluids in comparatively high volumes, i.e., over 10 gallons per minute, have traditionally been metal crafted. Such centrifuge types notably are Disk Centrifuges and Decanter Centrifuges. The present invention, a method of combining several radically different material and construction means in several layers of a hybrid or composite outer centrifuge wall, replaces the use of cast and machined metal for such walls. This replacement leads to new centrifuge geometries, to much less expensive outer wall design and fabrication, to the production of centrifuges which can routinely contain the physical stresses of operation at up to 8,000 gravities of centrifugal force, and which can do so in volumes which the resulting composite wall can contain up to 300 to 500 gallons per minute.

Centrifuges are still used in municipal wastewater treatment, in the production of many industrial products, and extensively in the petrochemical industry. However, for high-volume, very high speed centrifuges to be of economic use in wastewater, and for them to be applied at all for large volume point-of-supply water treatment, breakthroughs in strength, geometry, cost and mechanical elegance (which translates into low maintenance) are required. The method of construction hereby claimed goes to this exact industrial target, the separation of large volumes of fluid, and the extraction of very small, light particles from such volumes. Together with the inventors' geometry claims, this application for method of construction supplies a significant new answer to the evolution of centrifuges for environmental use.

Claims

1. A method for constructing a outer collecting wall of a centrifuge in concentric layers by combining three different means of fabrication, comprising the steps of:

a) designing and fabricating the innermost layer, which is that portion of the centrifuge's outer collecting wall that is in direct communication with a fluid working area of the centrifuge using thin cast or stamped tile members which have been wears-surface-treated to create a wears surface, the wears surface being the surface which is in direct communication with fluid from the fluid working area;

b) designing and fabricating the middle layer of the centrifuge's outer collecting wall, which is that portion of the centrifuge wall which supports the innermost layer to transfer outwards compression loads created by centrifugal force and relatively heavy materials striking said wear surface, the middle layer being made of relatively lightweight but incompressible metal, ceramic or other incompressible material castings;

c) designing and fabricating the outermost layer of the centrifuge's outer collecting wall for achieving relatively high hoop strength, by filament winding the centrifuge's entire outer collecting wall with fibers from the group consisting of; graphite fibers, carbon fibers, aramid fibers, any other fibers having a tensile strength greater than or equal to titanium, or combinations of any or all of these fibers; and

whereby unique structural virtues of the three means of construction of the centrifuge's outer collecting wall are selected to best satisfy differing structural needs of each layer and then are combined so that the centrifuge's outer collecting wall achieves relatively high wear resistance for the innermost layer, optimum compression-transfer, shape holding, dynamic balance and dimensional uniformity for the middle layer, and relatively high hoop strength for the outermost layer which creates a relatively high hoop strength for the centrifuge's entire outer collecting wall.

2. A method for constructing a outer collecting wall of a centrifuge in concentric layers by combining three different means of fabrication, comprising the steps of:

a) designing and fabricating the innermost layer, which is that portion of the centrifuge's outer collecting wall that is in direct communication with a fluid working area of the centrifuge by chemical disposition or metal plating directly on to a middle layer to create an integral, hardened innermost layer wear surface directly on the middle layer;

b) designing and fabricating the middle layer to transfer outwards compression loads created by centrifugal force and relatively heavy materials striking said innermost layer wear surface, the middle layer being made of relatively lightweight but incompressible metal, ceramic or other incompressible material castings;

c) designing and fabricating the outermost layer of the centrifuge's outer collecting wall for achieving relatively high hoop strength, by filament winding the centrifuge's entire outer collecting wall with fibers from the group consisting of graphite fibers, carbon fibers, aramid fibers, any other fibers having a tensile strength greater than or equal to titanium, or combinations of any or all of these fibers; and

whereby unique structural virtues of the three means of construction of the centrifuge's outer collecting wall are selected to best satisfy differing structural needs of each layer and then are combined so that the centrifuge's outer collecting wall achieves relatively high wear resistance for the innermost layer, optimum compression-transfer, shape holding, dynamic balance and dimensional uniformity for the middle layer, and relatively high hoop strength for the outermost layer which creates a relatively high hoop strength for the centrifuge's entire outer collecting wall.

3. A centrifuge having an outer collecting wall, comprising:

a centrifuge core disposed within the outer collecting wall;

the outer collecting wall disposed within a non-rotating sleeve with a containment zone for heavy materials disposed therebetween;

the outer collecting wall including a wear layer, a middle layer and an outer reinforcement layer;

at least one exit nozzle having a generally apex configuration extending through the wear layer, the middle layer and the outer reinforcing layer;

the wear layer operable to contact a fluid media, the wear layer including the at least one exit nozzle to transport the heavy materials through the outer collecting wall;

the middle layer operable to provide structural support to the wear layer, the middle layer including a respective structural shape for each exit nozzle to transport heavy materials through the outer collecting wall; and

the outer reinforcement layer operable to provide high pressure and torsional support for the outer collecting wall.

4. The centrifuge of claim 3, wherein the wear layer comprises a plurality of inserts selected from the group consisting of hardened wear surfaces, thin-stamped pieces of metal, cast pieces of metal, cast surfaces, and ceramic.

5. The centrifuge of claim 3, wherein the wear layer comprises a coating applied to the middle layer, the coating applied by a technique selected from the group consisting of physical vapor deposition, chemical vapor deposition, plating, and chemical transformation.

6. The centrifuge of claim 3, wherein the middle layer comprises a casting formed from a relatively lightweight, incompressible metal, ceramic or other incompressible material.

7. The centrifuge of claim 3, wherein the middle layer comprises multiple cast sections arranged as a generally horizontal cast or vertical cast or both.

8. The centrifuge of claim 3, wherein the respective structural shape includes a multi-walled body void.

9. The centrifuge of claim 3, wherein the outer reinforcing layer comprises a filament winding, the filament winding comprises a material selected from the group consisting of steel wire, fiberglass, aramid fibers, carbon and graphite, titanium, steel alloys, other fibers having a tensile strength greater than or equal to titanium, and any combinations of these fibers.

10. The centrifuge of claim 3, further comprising the wear layer and the middle layer joined with each other.

11. A centrifuge for removing heavy density particles from a fluid medium, comprising:

a fluid entry shaft attached to an entry cap, the fluid entry shaft operable to allow a fluid medium to enter the centrifuge;

a hybrid outer wall section operable to separate heavy density particles from the fluid medium by centrifugal force and to transport the heavy density particles to a non-rotating outer heavies catchment shell, the hybrid outer wall section including:

at least one hardened exit nozzle extending through a wear layer, a compression-load transfer casting and an outer reinforcement layer, the nozzle formed in the hybrid outer wall section operable to transport the heavy density particles to the non-rotating outer heavies catchment shell;

the wear layer forming a hardened wear surface over the compression-load transfer casting;

the compression-load transfer casting operable to provide a respective geometry to aid in separation of the heavy density particles and provide balance to the hybrid outer wall section; and

the outer reinforcement layer operable to increase burst strength and torsional rigidity of the hybrid outer wall section;

the non-rotating outer heavies catchment shell operable to contain the heavy density particles separated from the fluid medium which exits the centrifuge through a clarified fluid outlet;

a transmission shaft operable to cause rotation of the hybrid outer wall section along a symmetrical axis to produce centrifugal force within the centrifuge; and

an end cap coupled to the hybrid outer wall section opposite the entry cap.

12. The centrifuge of claim 11, further comprising the wear layer and compression-load transfer casting joined with each other.

13. The centrifuge of claim 11, wherein the compression-load transfer casting includes a variety of geometric shapes and an orifice, the orifice operable to provide an opening for the hardened exit nozzle.

14. The centrifuge of claim 11, wherein the compression load transfer casting includes a cast slot, the cast slot operable to attach a center member to the centrifuge.

15. The centrifuge of claim 11, wherein the center member includes anti-vorticity vanes.

16. The method of manufacturing a centrifuge having an outer collecting wall, comprising:

providing a centrifuge having a centrifuge core disposed within an outer collecting wall, the outer collecting wall including a wear layer, a middle layer and an outer reinforcement layer;

placing the wear layer on the middle layer, the wear layer being in direct communication with a fluid medium and including a wear resistant surface and an hardened nozzle for removing heavy density particles from the fluid medium under centrifugal force;

arranging the middle layer in a symmetrical pattern around an axis of rotation within the outer collecting wall, the middle layer operable to maintain structural support for the wear layer and shaped to aid in density separation of the fluid medium under centrifugal force;

forming the outer reinforcement layer concentric to the middle layer, the outer wall formed from a filament winding, wherein the filament winding operable to increase burst strength and torsional rigidity of the centrifuge; and

aligning the outer collecting wall to rotate around the axis of rotation, the outer collecting wall disposed within a non-rotating sleeve operable to form a containment zone for heavy materials disposed therein.

17. The method of claim 16, further comprises disposing a centrifuge core symmetrically around the axis of rotation, the centrifuge core including an anti-vorticity vane.

18. The method of claim 16, further comprises designing and fabricating the centrifuge to operate at pressures ranging from 5,000 to 8,000 gravities.

19. The method of claim 16, further comprises designing and fabricating the centrifuge to operate within a flow range of 300 to 500 gallons per minute.

20. The method of claim 16, further comprises designing and fabricating the centrifuge to remove density particles as small as 0.5 microns in size.

21. The method of claim 16, forming the wear layer with thin cast or stamped tile members.

22. The method of claim 16, forming the wear layer directly on the middle layer to create a wear resistant surface by a technique selected from the group consisting of physical vapor deposition, chemical vapor deposition, plating, and chemical transformation.

23. The method of claim 16, further comprising forming the middle layer selected from the group consisting of a monolithic cast section, a horizontal casting, a vertical casting, a stamped member and any combination thereof.

24. A centrifuge having an outer collecting wall, comprising:

a centrifuge core disposed within an outer collecting wall;

the outer collecting wall disposed within a non-rotating sleeve with a containment zone for heavy materials disposed therebetween;

the outer collecting wall including a wear layer, a middle layer and an outer reinforcement layer;

at least one hardened material nozzle having a generally apex configuration extending through the wear layer, the middle layer and the outer reinforcing layer;

the wear layer operable to contact a fluid media formed from a coating on the inner surfaces by a technique selected from the group consisting of physical vapor deposition, chemical vapor deposition, plating, and chemical transformation, the wear layer including the at least one apex opening to transport the heavy materials through the outer collecting wall;

the middle layer operable to provide structural support to the wear layer, the middle layer including a respective structural shape for each apex opening to transport heavy materials through the outer collecting wall;

the respective structural shape including a void area forming the interior wall;

the void area having a multi-walled shaped including conical and pyramidal shapes with the apex opening operable to direct heavy material into the apex opening to transport the heavy materials through the outer collecting wall; and

the outer reinforcement layer formed by a filament winding process operable to provide high pressure and torsional support for the outer collecting wall.

25. A centrifuge having an outer collecting wall, comprising:

a centrifuge core disposed within an outer collecting wall;

the outer collecting wall disposed within a non-rotating sleeve with a containment zone for heavy materials disposed therebetween;

the outer collecting wall including a wear layer, a middle layer and an outer reinforcement layer;

at least one opening having a generally apex configuration extending through the wear layer, the middle layer and the outer reinforcing layer;

the wear layer operable to contact a fluid media formed from tile wear surface inserts, the wear layer including the at least one apex opening to transport the heavy materials through the outer collecting wall;

the middle layer operable to provide structural support to the wear layer, the middle layer including a respective structural shape for each apex opening to transport heavy materials through the outer collecting wall;

the respective structural shape including a void area forming the interior wall;

the void area having a pyramidal shape with the apex opening operable to direct heavy material into the apex opening to transport the heavy materials through the outer collecting wall; and

the outer reinforcement layer formed by a filament winding process operable to provide high pressure and torsional support for the outer collecting wall.

26. The centrifuge of claim 25, further comprising the middle layer and the outer reinforcement layer joined with each other.