Patent Grant
8051724
The present invention relates to methods of cooling and controlling the flow of a hot, reactive medium containing gas or vapor phase particles.
Gas or vapor phase particle production is an important technique for producing engineered materials, especially nanomaterials. Specific characteristics of particles produced in gas or vapor phase synthesis reactions depend not only on the energy delivered to the reactive medium, but also on the conditioning of the reactive medium once the medium has left the reactor.
In a particle production reactor, basic product species are formed within extremely short time spans as the reactive medium cools following ejection from the energy delivery zone. During the time following ejection, further formation mechanisms determine the ultimate characteristics of the final product.
Chemical reactions such as nucleation and surface growth occur within precursor materials largely during energy delivery. However, these formation mechanisms continue to be active in the first short moments following ejection. More prevalent in the post-ejection time period are bulk formation mechanisms, such as coagulation and coalescence, which operate on already formed particles. Proper conditioning of the reactive medium following ejection from the energy delivery zone accounts for these and other formation mechanisms to control formation of a final product having desired characteristics.
In addition to particle formation, proper conditioning must account for post-formation processing of the product. Although particles, once formed, cool rapidly through radiative heat loss, the residual gas in which they are entrained after formation cools much more slowly, and especially so when confined. Confinement is necessary to some degree in any controlled-environment processing system, and economic concerns usually dictate relatively confining controlled environments because large environments cost more to build and maintain. Because supply systems require product sufficiently cool for handling, such systems must provide efficient mechanisms for cooling of the entire gas-particle product, yet also provide for efficient transport of the product to collection points within the system. They must also prevent agglomeration of the particles beyond a certain point or time period to ensure proper grain size in the final product.
Transport of particles within a gas stream relies on entrainment of the particle, which is largely a function of particle properties, including mass, temperature, density, and interparticle reactivity, as well as gas properties, including density, velocity, temperature, viscosity, and composite properties, such as particle-gas reactivity. Cooling of a gas by definition affects gas temperature, but also may easily lead to changes in other properties listed above, exclusive of mass. In view of this, balancing efficient cooling and transport of gas-particle product requires careful optimization of process parameters, which the present invention seeks to achieve.
According to the present invention, a conduit system for transporting particle and gas mixtures is presented. The conduit system is primarily intended to condition and conduct gas particle product emitted from gas phase particle production reactors, such as flame reactors, plasma reactors, hot wall reactors and laser reactors. Conditioning performed within the system includes cooling of gas-vapor mixtures and maintaining entrainment of particles therein for sampling and collection. The conditioning performed within the present invention accounts for particle interaction mechanisms within the gas particle mixture.
The conduit system comprises a conduit defining a flow direction from a first end to a second end and including a plurality of fluid delivery features. The fluid delivery features each include a port in the interior surface of the conduit, and are spaced along the conduit. The ports allow communication between the exterior and the interior of the conduit.
The conduit system works to cool, deliver and further condition a reactive gas-particle mixture produced by a gas phase particle production reactor. In operation, a hot gas-particle mixture tends to expand as it flows through the conduit. Expansion of the gas-particle mixture against the inner surfaces of the conduit can lead to adhesion thereto by particles and subsequently to the deposit of residues within the conduit. This pollution of the conduit can affect fluid flow within the conduit and can contaminate subsequent gas-particle mixtures flowing in the conduit.
The occurrence of significant deposits would make regular cleaning of the conduit necessary to ensure proper operation. Cleaning can require deactivation of the equipment and reduce the efficiency of the process, thereby resulting in increased expense and decreased productivity.
However, occurrence of residue is minimized by the present invention, in which conditioning fluid flows into the conduit through the plurality fluid delivery features, providing a sheath of conditioning fluid between the gas-particle mixture and the inner surfaces of the conduit. Preferably, the conditioning fluid flows symmetrically through one or more ports into the conduit. Symmetric inflow of conditioning fluid constricts the flow of the gas-particle mixture and reinforces the conditioning fluid sheath in the region of each fluid delivery feature. Preferably, fluid delivery features provide conditioning fluid regularly enough so that complete intermixture of the gas-particle mixture with the conditioning fluid sheath never occurs. The conditioning fluid is preferably provided at a cooler temperature than the gas-particle mixture and substantially prevents the gas-particle mixture from encountering the inner surfaces of the conduit. In a further aspect, the temperature of the region of the conduit surrounding each fluid delivery feature can be controlled to aid in conditioning the gas-particle mixture and to prevent deposition of particles thereon.
A specific conditioning fluid is selected for its intrinsic properties. Desired intrinsic properties depend to an extent on the specific mixture being conducted through the conduit. For example, typically inert gasses, such as argon, neon, and helium, are preferred for their near-non existent reactivity. Among inert gasses, argon is more preferred than helium or neon because it provides a more effective sheath. Furthermore, extrinsic properties, such as temperature and density, correlate to the ability of the conditioning fluid to cool and condition the gas-particle mixture and are controlled to provide desired levels of cooling and conditioning to the gas-particle mixture.
Although the specific mixture under consideration partially determines the conditioning fluid used and the selection of the extrinsic fluid properties, the location of fluid introduction also must be considered. In one embodiment, the conditioning fluid introduced through the features closer to the particle source is different than the fluid introduced through the features farther from the particle source. For example, a first gas can be introduced through the features closer to the injection end of the conduit, while a second gas can be introduced through the features farther away from the injection end. In alternative embodiments, the same type of conditioning fluid is introduced through each fluid delivery feature, but extrinsic properties of the fluid, such as temperature, are varied according to the delivery location. The conditioning fluid introduced through each feature in the set of fluid introduction features is preferably chosen to balance the competing concerns of economic efficiency and high product quality. Preferably, the conditioning fluid is supplied passively, as described more fully below, through a neutral pressure environment formed around fluid delivery ports within the conduit. Furthermore, the conduit is configured so that the conditioning fluid flows at a rate sufficient to maintain entrainment of the particles within the gas flow.
Therefore, the present invention provides a flowing sheath of conditioning gas along the inner walls of a conduit through which a gas-particle mixture flows. As the conditioning gas and the gas-particle mixture flow through the conduit, the introduction of fresh conditioning gas maintains entrainment of the particles and cools the gas-particle mixture.
In one aspect of the present invention, a conduit system is provided. The conduit is formed by a surface extending from a first end to a second end. The conduit is configured to channel a mixture stream from the first end to the second end. A plurality of fluid delivery features are disposed along the conduit between the first end and the second end. Each fluid delivery feature is configured to deliver a conditioning fluid into the conduit in an annular formation in a direction angled towards the second end in the same direction as the flow of the mixture stream, thereby providing a sheath of conditioning fluid between the conduit surface and the mixture stream.
In another aspect of the present invention, a method of conditioning a mixture stream is provided. The method comprises providing a conduit formed by a surface extending from a first end to a second end. A plurality of fluid delivery features are disposed along the conduit between the first end and the second end. The mixture stream flows through the conduit from the first end to the second end. A conditioning fluid is delivered into the conduit while the mixture stream flows through the conduit. The conditioning fluid is delivered through a plurality of delivery features disposed along the conduit between the first end and the second end. Each fluid delivery feature delivers the conditioning fluid into the conduit in an annular formation in a direction angled towards the second end in the same direction as the flow of the mixture stream, thereby providing a sheath of conditioning fluid between the conduit surface and the mixture stream.
In preferred embodiments, each fluid delivery feature comprises a ports structure and an annular housing. The port structure is fluidly coupled to the interior of the conduit and is configured to deliver the conditioning fluid into the conduit in an annular formation in a direction angled towards the second end in the same direction as the flow of the mixture stream. The annular housing is disposed around the conduit and covers the port structure. The annular housing comprises a fluid supply port configured to supply the conditioning fluid to the port structure for delivery into the conduit.
The description below concerns several embodiments of the invention. The discussion references the illustrated preferred embodiment. However, the scope of the present invention is not limited to either the illustrated embodiment, nor is it limited to those discussed. To the contrary, the scope should be interpreted as broadly as possible based on the language of the Claims section of this document.
In the following description, numerous details and alternatives are set forth for purpose of explanation. However, one of ordinary skill in the art will realize that the invention can be practiced without the use of these specific details. In other instances, well-known structures and devices are shown in block diagram form in order not to obscure the description of the invention with unnecessary detail.
This disclosure refers to both particles and powders. These two terms are equivalent, except for the caveat that a singular “powder” refers to a collection of particles. The present invention may apply to a wide variety of powders and particles. Powders that fall within the scope of the present invention may include, but are not limited to, any of the following: (a) nano-structured powders(nano-powders), having an average grain size less than 250 nanometers and an aspect ratio between one and one million; (b) submicron powders, having an average grain size less than 1 micron and an aspect ratio between one and one million; (c) ultra-fine powders, having an average grain size less than 100 microns and an aspect ratio between one and one million; and (d) fine powders, having an average grain size less than 500 microns and an aspect ratio between one and one million.
The present invention will be readily understood by the following detailed description in conjunction with the accompanying drawings. To facilitate this description, like reference numerals designate like elements.
The present invention includes a plurality of fluid delivery features. Each fluid delivery feature preferably includes one or more ports configured to deliver a symmetrical sheath of conditioning fluid. Although the specific details of the fluid delivery features are determined within each embodiment, largely with reference to the types of fluids and particles the embodiment is designed to deal with, the generally preferred configuration of the ports is discussed in the following paragraphs. Furthermore, the operation of the fluid delivery features and the effect of fluid and particle parameters on their design are also discussed.
The ports allow communication between the exterior and the interior of the conduit. Preferably, each port is configured to deliver conditioning fluid evenly and along the inner surface of the conduit substantially in the direction of flow within the conduit. Two structural features are preferably present in each fluid delivery feature: the ports are angled along the flow direction of the conduit, and each port delivers fluid along the entirety of an inner cross-sectional boundary of the conduit. Fluid can be delivered evenly or unevenly along the entirety of the inner cross-sectional boundary. In one embodiment, uneven fluid delivery is used to counteract the influence of gravity on the entrained particles.
The first structural feature results in an angled path of fluid flow into the conduit through the ports. Introducing conditioning fluid along an angled path results in less significant disturbances to the gas-particle mixture flowing through the interior ‘core’ of the conduit, resulting in little additional turbulence therein. As discussed below, less significant perturbation of the gas-particle mixture results in less efficient cooling, but succeeds in minimizing particle deposition within the conduit. Although a less-angled path of fluid flow more parallel to the direction of flow within the conduit may be preferred in some applications, the present invention prefers an angular path of delivery to allow for constriction of the gas-particle mixture flow.
The second preferred structural feature, each port delivering fluid along the entirety or substantial entirety of an inner cross-sectional boundary of the conduit, seeks to maximize effectiveness of the conditioning gas as a sheath between the gas-particle mixture and the inner surface of the conduit. The present invention contemplates myriad ways of accomplishing this goal. In one aspect, each port is formed from a plurality of sub-ports, each shaped to provide fluid flow along a small portion of the inner surface. The sub-ports are tapered, offset or otherwise situated so that sufficient material remains within the conduit to provide structural stability around the port. In a further aspect, one continuous port is provided within the inner surface of the conduit and an external housing is coupled to the conduit to provide structural support in the region of the port. In this aspect, the housing may also provide a fluid reservoir where conditioning fluid is held and allowed to flow into the port.
Furthermore, each port is preferably in fluid communication with a reservoir containing conditioning fluid. In the preferred embodiment of the present invention, the reservoir is integrated into a housing surrounding a port of a fluid delivery feature in the conduit. In this aspect, the housing provides structural support to the conduit. In alternative embodiments, the reservoir is simply a manifold for conditioning fluid delivery and does not provide structural support to the conduit. In a further alternative embodiment, the reservoir is a chamber sealed with the conduit and surrounding a structural housing including a fluid supply port. In each aspect, the reservoir is sealed to the conduit. Exemplary seals include high temperature o-ring seals, pressure fitted seals, and integral constructions.
Conditioning fluid is preferably supplied to the reservoir through a supply port exposed to the reservoir. The reservoir preferably has the smallest possible volume while still maintaining sufficient space therein to allow uninterrupted flow of conditioning fluid into the conduit, so long as conditioning fluid is maintained at appropriate pressure, as will be discussed more fully below. In alternative embodiments, conditioning fluid is supplied directly from a fluid manifold to the port, or to each sub-port where the port comprises more than one sub-port with no intervening reservoir.
The present invention contemplates a variety of constructions for the conduit system, including fully modular constructions, fully integrated constructions, and combinations thereof. In an exemplary modular construction, the conduit system is pieced together from a plurality of components, each belonging to one of two component types: conduit pieces, and couplers.
The conduit pieces contemplated are simply lengths of conduit having substantially constant cross sectional dimensions. Preferably these conduit pieces have lengths substantially greater than their cross-sectional dimensions. Furthermore, these conduit pieces are preferably actively cooled by a heat exchanger.
Couplers join multiple conduit pieces together. Preferably, two adjacent conduit pieces are joined by one coupler. The couplers include the fluid delivery features mandated in the present invention. Specifically, a modular conduit coupler comprises a first and a second end each configured to couple with a conduit piece. Between the first and second ends, one or more ports are formed to deliver fluid into the coupler. Furthermore, a fluid reservoir is preferably coupled with the one or more ports formed in the coupler. In an additional aspect, the one or more ports can have a variable total surface area.
In one particular embodiment, a coupler comprises two cylindrical pieces with substantially similar outer cross-sectional dimensions and each having one chamfered edge configured so that the chamfered edges are mateable and positioned a gap distance from one another to form a gap therebetween. The coupler also comprises a third cylindrical piece configured to mate with the exterior surfaces of the two cylindrical pieces to effectively couple the two pieces with one another such that the third cylindrical piece covers the gap, the third piece has a passageway therein for supplying fluid to the gap. Furthermore, the third piece can be slidably configured to adjust the total surface area of the gap, and thus adjust the flow volume of conditioning fluid into the conduit.
Preferably, the conduit has the following general dimensional characteristics. The spacing between the fluid delivery features is substantially larger than the cross-sectional dimension of the conduit, and the outer cross-sectional dimension of the conduit is substantially constant over its length. Furthermore, the fluid delivery features are preferably spaced evenly along the conduit. However, the present invention contemplates other spacings.
In a preferred embodiment, the ratio between the cross-sectional dimension and the fluid delivery spacing is approximately 1 to 36. More specifically, the conduit preferably has a cross-sectional dimension of approximately 2 inches, and the preferable spacing between fluid delivery features is approximately 6 feet.
As described above, a purpose of regularly introducing conditioning gas is to maintain entrainment of particles within the gas-particle mixture and to prevent deposition of particles on the surfaces of the conduit. The likelihood of particle deposition within the conduit increases as intermixture of the gas-particle mixture with the sheath of conditioning gas occurs. Ideally, the gas-particle mixture is confined to the inner ‘core’ of the conduit. Preferably, the sheath of conditioning gas surrounds the gas-particle mixture ‘core’ and insulates the conduit surfaces from interaction with particles. Without regular introduction of conditioning gas, particle deposits within the conduit may occur. The specific regularity of introduction necessary is largely determined by the particular gas-particle mixture. Conduit systems in accordance with the present invention differ in the spacing of their fluid delivery features according to the gas-particle mixture for which they are designed, and in other aspects as well. Furthermore, the extrinsic properties, e.g., temperature and pressure, of the conditioning gas are controlled to maintain entrainment of the particles within the gas-particle mixture.
In the present invention, the spacing between fluid delivery features is determined with a goal of preventing full intermixture between the conditioning gas sheath and the gas-particle mixture at any point in the conduit. Intermixture between the gas-particle mixture and the conditioning gas depends on many factors including temperature, particle properties, density, velocity, viscosity, both of the mixture and of the conditioning gas.
Another aspect of conduit system design directed to maintaining particle entrainment is the spacing of the fluid delivery features. Regular introduction of fresh conditioning gas is preferred to maintain integrity of the sheath of conditioning gas. As the gas-particle mixture and surrounding sheath of conditioning gas travel away from a fluid delivery feature, they tend to intermix: increasing intermixture of the sheath gas and the core of gas-particle mixture leads to undesired interactions between the particles and the surfaces of the conduit.
Although, as described above, regular introduction of conditioning fluid is preferred within the present invention, the inclusion of multiple different spacings is also contemplated. As described earlier, the conditioning fluid sheath loses integrity and stops functioning due to intermixture of the gas-particle mixture and the sheath. When the temperature difference between the conditioning gas sheath and the gas-particle mixture is greater, the two fluids mix more rapidly, e.g., within a shorter distance of conduit, following introduction of the conditioning fluid. Therefore, because the particle-gas mixture cools as it flows through the conduit, the frequency of introduction for some systems can be lessened farther along the conduit in the direction of flow. In other words, the spacing of the fluid delivery features can increase along the conduit in the direction of flow.
The flow of the conditioning gas into the fluid delivery features is preferably caused by formation of a negative pressure differential along the conduit, which also aids in maintaining flow of the mixture within the conduit. This negative pressure differential is preferably formed by coupling a vacuum formation system with the end of the conduit. Alternatively, the negative pressure differential is formed by drawing fluid from a distal end of the conduit. In further alternative embodiments, active injection of conditioning fluid is contemplated.
Furthermore, the conduit is preferably engineered so that any deposition of particles within the conduit will be relatively permanent with respect to the gas-particle stream. In other words, no significant variation in stream flow rate or strength occurs whereby an earlier-deposited particle might be re-entrained into the stream. Substantially constant fluid flow rates also promote more ‘permanent’ deposition. Accordingly, operation of the vacuum system or other flow control system must be carefully controlled.
Referring now to
Some embodiments of the present invention revolve around the use of a nano-powder production reactor. In general, vapor phase nano-powder production means are preferred. The mixture production system 110 can use elements of nano-powder production systems similar to those disclosed in U.S. patent application Ser. No. 11/110,341, filed on Apr. 19, 2005 and entitled, “HIGH THROUGHPUT DISCOVERY OF MATERIALS THROUGH VAPOR PHASE SYNTHESIS”, which is currently published as U.S. Publication No. 2005-0233380-A. In such a nano-powder production system, working gas is supplied from a gas source to a plasma reactor. Within the plasma reactor, energy is delivered to the working gas, thereby creating a plasma. A variety of different means can be employed to deliver this energy, including, but not limited to, DC coupling, capacitive coupling, inductive coupling, and resonant coupling. One or more material dispensing devices introduce at least one material, preferably in powder form, into the plasma reactor. The combination within the plasma reactor of the plasma and the material(s) introduced by the material dispensing device(s) forms a highly reactive and energetic mixture, wherein the powder can be vaporized. This mixture of vaporized powder moves through the plasma reactor in the flow direction of the working gas.
Referring back to
The conduit system 120 conducts and processes the gas-particle mixture, maintaining entrainment of particles within the mixture by both physically processing the mixture and by surrounding the mixture with a conditioning fluid sheath. Aspects of the physical processing performed by the conduit system 120 are discussed in more detail later in this paper. To form a sheath around the gas-particle mixture, the conditioning fluid is provided through a plurality of port structures 141, 143, and 145 formed within the conduit 140. In a preferred embodiment, a conditioning fluid reservoir system 130 delivers conditioning fluid through the fluid delivery lines 132, 134, and 136 to the respective conditioning fluid delivery chambers 142, 144, and 146 of the conduit structure 120. The conditioning fluid delivery chambers 142, 144, and 146 respectively surround the port structures 141, 143, and 145. In one embodiment of the present invention, the fluid reservoir system 130 comprises a single fluid reservoir containing a single type of conditioning fluid which flows through each of the fluid delivery lines 132, 134, and 136. In alternative embodiments, the fluid delivery structure comprises multiple reservoirs, each containing possibly different types of conditioning fluid that are delivered through the conditioning fluid lines 132, 134, and 136 to the conditioning fluid delivery chambers 142, 144, and 146 respectively. As described earlier, in some instances the present invention contemplates varying both the type, and the physical properties of the conditioning gas based on the location of the fluid delivery port under consideration. The various embodiments of the conditioning fluid delivery system 130 are configured based on the type of variation desired.
In one embodiment, the fluid delivery chambers 142, 144, and 146 are disposed within housings that provide structural support to the conduit 140. In alternative embodiments, the fluid delivery chambers 142, 144, and 146 are sealed reservoirs that do not provide structural support to the conduit 140, but instead, the port structures 141, 143, and 145 comprise structural elements. In either case, the fluid delivery chambers 142, 144, and 146 are preferably sealed with the conduit 140 via bonding, pressure fitting, integral formation, or construction using a high temperature o-ring seal.
The repeated introduction of conditioning gas, combined with the length of travel from the production system 110 and the physical processing discussed more thoroughly elsewhere, combine to cool and conduct the gas to the sampling zone 150, while maintaining entrainment and minimizing deposition of the particles within the conduit system 120. The sampling zone 150 includes the sampling device 155 coupled with the conduit system 120 to separate a portion of a gas-particle mixture flowing therein. In aspects of the present invention, the sampling device 155 has an optimal operating temperature range for the sampled gas-particle mixture. Preferably, the conduit system 120 and the sampling zone 150 are configured to cool the gas-particle mixture to within the optimal operating temperature range of input for the sampling device 155. Configuration parameters for the conduit system 120 include overall distance from the production system 110 to the sampling zone 150, the number and frequency of ports, and the type of conditioning gas introduced into the ports.
It is contemplated that the sampling device 155 can be configured in a variety of ways. In one embodiment, the sampling device 155 comprises a sampling structure, at least one filled aperture formed in the sampling structure, and at least one unfilled aperture formed in the sampling structure. Each filled aperture is configured to collect particles from the mixture stream, such as by using a filter. The sampling structure is configured to be adjusted between a pass-through configuration and a collection configuration. The pass-through configuration comprises an unfilled aperture being fluidly aligned with a conduit, such as conduit 140, thereby allowing the unfilled aperture to receive the mixture stream from the conduit and the mixture stream to flow through the sampling structure without substantially altering the particle content of the mixture stream. The collection configuration comprises a filled aperture being fluidly aligned with the conduit, thereby allowing the filled aperture to receive the mixture stream and collect particles while the mixture stream is being flown through the filled aperture.
It is contemplated that the sampling structure can be adjusted between the pass-through configuration and the collection configuration in a variety of ways. In one embodiment, the sampling structure is a disk-shaped structure including an annular array of apertures, wherein the annular array comprises a plurality of the filled apertures and a plurality of the unfilled apertures. The sampling structure is rotatably mounted to a base, wherein rotational movement of the sampling structure results in the adjustment of the sampling structure between the pass-through configuration and the collection configuration. In another embodiment, the sampling structure is a rectangular-shaped structure including a linear array of apertures, wherein the linear array comprises a plurality of the filled apertures and a plurality of the unfilled apertures. The sampling structure is slideably mounted to a base, wherein sliding of the sampling structure results in the adjustment of the sampling structure between the pass-through configuration and the collection configuration.
As shown in
Referring now to
Each fluid delivery feature 210, 220, 230 preferably includes a port structure 214, 224, 234 with which a fluid reservoir is coupled to introduce conditioning fluid into the conditioning fluid stream 260 within the conduit structure 200 as described above. The introduction of conditioning fluid in a symmetric distribution from the port structures 214, 224, 234 around the gas-particle mixture stream 270 causes constriction of the gas-particle mixture stream 270 at the constriction points 216, 226, 236. After the constriction of the gas particle mixture stream 270, the mixture stream 270 will begin to mix with the conditioning fluid stream 260 and expand toward the interior wall of the conduit 242 after a period of time. Preferably, the next port structure will constrict the gas-particle mixture stream 270 before it expands to completely fill the conduit 242. Both the conditioning fluid stream 260 and the gas-particle mixture stream 270 flow in the direction of the arrow 250. The motive force determining this flow direction is preferably an external low pressure source, such as a vacuum as discussed elsewhere. However, it is contemplated that the motive force can be provided in other ways as well.
As the gas-particle mixture 270 flows through the fluid delivery features 210, 220, 230, the conditioning fluid delivery promotes entrainment of particles within the flowing mixture 270 and prevents contamination of conduit system 200. By providing an insulating layer between the gas-particle mixture and the inner surfaces of the conduit system 200, delivery of conditioning fluid substantially prevents deposition thereon of particles and subsequent contamination.
As mentioned earlier, if deposition does occur, the configuration of fluid delivery features 210, 220, 230, combined with substantially constant fluid flow, substantially prevents deposited content from re-entraining into the flow of fluid within the conduit system 200. Thus, under desired operating conditions, particles do not reenter the stream once deposited.
Although the fluid delivery features 210, 220, and 230 appear substantially identical as illustrated, the present invention contemplates modifying the shapes and configurations thereof according to their relative spacing along the flow direction of the conduit system 200.
Referring now to
The annular housing subsection 330 can include a relieved portion 334 configured to form a fluid supply chamber 340 when the annular housing subsection 330 mates with the conduit subsections 310 and 320. Preferably, the mating between the conduit subsections 310, 320 and the annular housing subsection 330 is accomplished by a press fit, a friction fit or other similar means. The fluid supply chamber 340 is preferably arranged circumferentially around the conduit subsections 310, 320 and configured to communicate fluidly with the channel 360. Furthermore, the annular housing subsection 330 preferably includes the fluid supply port 332 for supplying conditioning fluid therethrough to the fluid supply chamber 340. Preferably, a conditioning fluid reservoir (not shown) supplies conditioning fluid to the fluid supply port 332 and therethrough to the fluid supply chamber 340, wherefrom the conditioning fluid is drawn into the fluid delivery channels 360 and through the conduit structure containing the conduit coupler 300.
As can be seen in
The arrows 322 illustrate the flow of the gas-particle mixture through the conduit coupler 300. As shown, the flow is constricted near the fluid delivery channels 360 by the symmetric delivery of conditioning fluid into the coupler 300.
At step 410, a mixture production system, such as the gas-particle mixture production system discussed above, produces a mixture stream. It is contemplated that the mixture stream can be produced in a variety of ways. However, in a preferred embodiment, energy is delivered to a working gas, thereby forming a plasma stream. The plasma stream is then applied to a precursor materia, such as powder particles. The powder is preferably vaporized and the mixture stream is formed, preferably comprising vaporized particles entrained therein.
At step 420, the mixture stream flows to and through a conduit system. The conduit system preferably comprises a conduit formed by a surface extending from a first end to a second end. A plurality of fluid delivery features are preferably disposed along the conduit between the first end and the second end. The mixture stream flows through the conduit from the first end to the second end. It is contemplated that the mixture stream can be partially cooled and that vaporized particles may have already been partially or completely condensed prior to introduction into the conduit.
At step 430, a conditioning fluid is delivered into the conduit while the mixture stream flows through the conduit. The conditioning fluid is delivered through the plurality of delivery features. Each fluid delivery feature delivers the conditioning fluid into the conduit in an annular formation in a direction angled towards the second end in the same direction as the flow of the mixture stream, preferably providing a sheath of conditioning fluid between the conduit surface and the mixture stream.
At step 440, the mixture stream flows from the conduit to a collection device. In a preferred embodiment, the mixture stream at this point has been sufficiently cooled so that the particles have condensed.
At step 450, the mixture stream flows through the collection device and the collection device separates condensed particles from the mixture stream. As previously discussed, this separation can be achieved in a variety of ways.
The present invention has been described in terms of specific embodiments incorporating details to facilitate the understanding of the principles of construction and operation of the invention. As such, references herein to specific embodiments and details thereof are not intended to limit the scope of the claims appended hereto. It will be apparent to those skilled in the art that modifications can be made to the embodiments chosen for illustration without departing from the spirit and scope of the invention.
The present application claims to co-pending U.S. Provisional Application Ser. No. 60/928,946, filed May 11, 2007, entitled “MATERIAL PRODUCTION SYSTEM AND METHOD,” which is hereby incorporated by reference as if set forth herein. The co-pending U.S. patent application Ser. No. 11/110,341, filed on Apr. 10, 2005, entitled, “HIGH THROUGHPUT DISCOVERY OF MATERIALS THROUGH VAPOR PHASE SYNTHESIS” is incorporated by reference.
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