This disclosure relates generally to converters, including thermal oxidizers, and, more particularly, to block channel geometries and arrangements.
Thermal oxidizers have blocks (e.g., refractory elements) with a refractory material to exchange heat between the blocks and a gaseous or liquid flow. Typically, thermal efficiency and plug resistance are issues with the blocks.
To clarify multiple layers and regions, the thickness of the layers are enlarged in the drawings. Wherever possible, the same reference numbers will be used throughout the drawing(s) and accompanying written description to refer to the same or like parts.
Apparatus and methods to improve plug resistance and/or thermal efficiency for blocks of thermal oxidizers are described herein. Although thermal oxidizers are described, the described methods and apparatus may apply to other converter blocks including selective catalytic reducers (“SCRs”), etc. One described example apparatus includes a block of a converter having a plurality of channels defining interior walls, which define a cellular pattern in a cross-sectional view of the block. The pattern comprises regular sub-patterns consisting of at least one central channel, which is proximate an interior of the block, and a plurality of surrounding channels.
Another example apparatus includes a block of a converter having a plurality of channels defining interior walls, which define a cellular pattern in a cross-sectional view of said block. The pattern comprises regular sub-patterns consisting of at least one central channel on an interior of the block and a plurality of surrounding channels proximate an interior of the block. Each central channel is surrounded by five or more of the surrounding channels, and the interior walls have a varying thickness along a perimeter of each central channel.
Another example apparatus includes a block of a converter and a plurality of channels defining interior walls and extending through a depth of the block to allow fluid to flow therethrough. Each of the central channels, which is proximate an interior of the block, is surrounded by five to twelve surrounding channels and each central channel has a profile with a shape having greater than four sides. Each surrounding channel is substantially equidistant to a center of its respective central channel.
Another described example apparatus includes a block of a converter and a plurality of channels extending through the block to allow fluid to flow therethrough. Each channel is in fluid communication with an opening of a heating chamber and each central channel in an interior of the block is surrounded by five to twelve surrounding channels. Each surrounding channel is substantially equidistant to a center of its respective central channel and each channel exchanges heat between the fluid and the block.
Another described apparatus includes a plurality of channels extending through a block of a converter to allow a fluid to flow therethrough. Each central channel in an interior of the block has a shape having greater than four sides and is surrounded by five or more surrounding channels. Each surrounding channel being substantially equidistant to a center of its respective central channel and a ratio of a hydraulic diameter of the central channels over interior wall thicknesses between the channels is to be approximately equal to a value in a range from 0.58 to 6.53.
One described method includes determining relevant equations to increase plug resistance of channels in a converter, calculating, using a processor, particle formations utilizing theoretical particle formations, calculating a time to plug using a general form for the time of coalescence, calculating a kappa factor reiteratively, calculating secondary factors to determine plug resistance results of the channels, and outputting the plug resistance results and secondary results.
Another described example method includes determining relevant equations to increase thermal efficiency of channels in a converter, calculating transient effects of the system using a transient thermal convective equation, calculating, using a processor, a convectional coefficient using channel morphology factors, calculating wetted and occupied areas for the channels, calculating a secondary parameter to determine thermal efficiency results of the channels, and outputting the thermal efficiency results and secondary results.
Some of the examples described relate to blocks containing refractory materials or other similar materials found within thermal oxidizing systems. Refractory material retains its shape and structure at high temperatures and may comprise ceramics, clay materials, silica, zirconia, alumina, and/or oxides such as lime and magnesia. The main classifications of refractory material may include clay-based, alumina-based, magnesia, dolomite, carbonates, silica, zircon, etc. Precious metals and iron-based refractory materials also exist.
A thermal oxidation block exchanges heat between the block and a gaseous or liquid flow of a stream passing through the block. The stream is heated in a chamber, in which the fluid is chemically converted in an exothermic reaction (e.g., exothermally oxidizes). The examples disclosed relate to cross-sectional designs of the blocks (e.g., refractory elements). The examples disclosed also describe calculating the dimensional characteristics for channels (e.g., cells, passages), or any other relevant critical features. Parameters for defining the gaseous or liquid flow through the block may include a channel hydraulic diameter, an inner wall width and an outer wall width. These parameters are related to fluid properties of the flow and thermal characteristics of the system and also affect the eventual plugging of the block. The hydraulic diameter relates the cross-sectional area to its respective perimeter and is commonly used for calculating a Reynolds number for pipe flow. Plugging may occur as the gas or liquid containing impurities imparts particles onto the channels, which may adhere to surface walls of the channels, and, eventually, these particles may plug (e.g., clog) the channels. Plugging may be reduced by use of an anti-adhesive coating (e.g., a silicon resistance coating) or a catalytic coating. The catalytic coating, which contains a catalyst, may be applied in an SCR process to further neutralize the harmful compounds present.
Thermal oxidizer blocks generally use blocks with square channel designs. The edges of the square channels are usually aligned (i.e., sets of rows are not offset from one another). The equations and ratios described below are related to an improved channel (e.g., cell) design in comparison to known hydraulic diameter and square channel designs. The system performance improvements seen by the examples described may be one or more of a combination of efficiency, streamlining or resistance to plugging (e.g., clogging), thermal convection, flow stagnation, pressure differential and destruction removal efficiency (“DRE”). The DRE is a measure of destruction of harmful gases (e.g., volatile organic compounds (“VOCs”)). Destruction of the VOCs occurs when the VOCs oxidize (e.g., become other compounds) as they are heated. The DRE is calculated by dividing the mass or volume of the VOCs exiting by the mass or volume of the VOCs that enters the oxidizer (e.g., 10 lbs. of VOCs enters while 1 lb. of the VOCs exits results in a corresponding 90% DRE). Critical features of the block may be limited by current production technology, which may include extruding and stamping (e.g., the limitations may include arrangement of the channels, size of the channels, amount of the channels in a defined area, etc.).
The examples described herein improve the system efficiency and/or resistance to plugging (e.g., increase the time until the blocks become clogged or plugged) in conjunction with at least one other system performance factor. One described example block employs a heat transfer regenerative mass and has a plurality of channels for the exchange of heat between the fluid and the block. Geometry of the block channels is designed to increase efficiency and/or resistance to plugging, and manufactured to provide a cross-sectional structure to improve the system performance factors. The interior channel wall thicknesses of the blocks may be defined by multiple factors to enhance the performance of the blocks within known manufacturing limitations. Additionally, the geometry of a boundary of the block itself (e.g., outer wall) may be adjusted to be further improve overall performance of the block.
The design of the geometry of the channels and the spacing between the channels may have significant effects on the overall performance of the block and, therefore, the thermal oxidizer. Additionally, the shape of the channels (e.g., round, hexagonal, octagonal, square, parallelogram, ellipse, oval, etc.) may also significantly affect thermal efficiency, plug resistance and numerous other measures of performance. Utilizing a round profile channel surrounded by at least six other surrounding channels may significantly improve thermal efficiency over other channel arrangements.
Likewise, utilizing a hexagonal or octagonal profile surrounded by six other surrounding channels may significantly improve resistance to plugging. Time to plugging is a variable that is necessary to be accounted for, in conjunction with thermal efficiency. Particle growth models provide an ability to account for particle coalescence and, thus, plugging. The examples described in accordance with the teachings of this disclosure describe channel geometries and arrangements that substantially improve thermal efficiency and/or plug resistance.
Although certain geometries of the channels are described, the geometry of the channels may vary and include shapes such as a shape having greater than four sides which may contain sharp and/or rounded edges. Other channel geometries may include shapes which may contain intersecting tangent angles that are always less than 90 degrees, shapes consisting of straight or spline segments, shapes containing polygons with a combination of splines, and/or any other appropriate shapes to allow fluid to flow through the channels.
Some oxidizer systems may involve switching or reversing between stacks (e.g., towers) of blocks in fluid communication with a combustion chamber. In scenarios in which it is desirable to keep the fluid or gas at relatively elevated temperatures as the fluid or gas is provided to the combustion chamber, the blocks themselves may heat the fluid or gas on a second cycle after the directions are reversed (e.g., the outlet on the previous cycle becomes an inlet the next cycle). In some examples, the blocks may have sharp (e.g., “knife-like”) edges proximate an inlet and/or outlet of the blocks to further improve plug resistance of the blocks.
In operation, fluid flows from the inlet 106 and into the blocks 102. As the fluid moves through the blocks 102, heat is transferred from the blocks 102 to the fluid. After the fluid passes through the blocks 102, the fluid flows into a combustion chamber 110, where the fluid is heated. Although the combustion chamber 110 is shown, any appropriate type of heating chamber may be used. Heating the fluid oxidizes the fluid and allows some impurities (e.g., VOCs) to be taken out (e.g., burned-off). After being heated, the fluid then moves into the blocks 104. As the fluid moves through the blocks 104, heat is transferred from the fluid to the blocks 104. Finally, the fluid flows out of the oxidation system 100 through the outlet 108.
Dh, the hydraulic diameter relating the possible flow to its perimeter, which is found through equation 4, is described below in connection with
A hydraulic flow 806 is shown in an irregular channel 808. The irregular channel 808 may result from edge effects near an outer edge 810. These edge effects/irregularities may result from the manufacturing processes (e.g., extruding or stamping, etc.) or an intended design to maintain a constant wall thickness in the outer edge 810 (i.e., as shown in another irregular channel 812).
As seen by fundamental equation 16, which is described below in connection with
Flowcharts of representative example machine readable instructions for calculating relevant parameter values for both plug resistance and thermal efficiency are shown in
As mentioned above, the example processes of
The silicon mass flow rate is
or contains a chamber concentration of
The resonance time is 1.5 seconds at a temperature of 850° C.
A second step involves calculating particle formation (block 2304). Utilizing theoretical particle formations as defined by aerosol dynamics provides a basis for estimating a time to clog/plug a system. The area of stagnation and the number of stagnation points are critical to determining the time to plug. Equations 8, 9 and 11 may be used to find a channel structure which will perform within predefined system parameters. These calculations demonstrate that substantially thin walls and relatively higher flow areas prevent particle growth. This is mainly due to the thermal dynamic loads which are present within the flow. In some examples, the inner wall thickness may be limited to approximately 0.5 mm. Presuming this value as a limiting factor, the outer wall and hydraulic diameters may be defined with respect to a particular system. Additionally, particle growth is related to temperature. Within the system requirements as set forth above, a 30% reduction in temperature may correspond to a 10% reduction in particle size, which may be sufficient to resist plugging for a system. The hexagonal or circular channel structure may cool a fluid faster, thereby increasing its resistance to plugging. For an improved design block, a 30% reduction in temperature should occur within the first 300 mm of the portions 1108, 1112 (e.g., zones 3 & 4) of
Equation 1 is commonly referred to as system efficiency or effectiveness. Tcomb is a combustion chamber temperature. TInlet is a temperature at an inlet to the oxidizer. TOutlet is a temperature at an outlet of the oxidizer.
Equation 2 is a theoretical initiation of plugging at the state at which a system fails to operate in a nominal state. The flow is considered to be choked when the flow is less than 50-100% of its nominal design flow: Equation 2 has a 50% choke factor. QNominal is a nominal design flow. {dot over (m)} is a mass flow rate. ρ is an average stream density.
For equation 3, UAve is an average stream velocity where NCells is a number of channels.
Equation 4 calculates a hydraulic diameter, Dh. The hydraulic diameter is used often in relation to pipe or duct flow where a Reynolds-Dh, which is the Reynolds number with respect to the hydraulic diameter, is calculated. Its geometric equivalence is based upon flow through a tube or circular cross-section. AreaCross-section is a cross-sectional open area. PerimeterWetted is a periphery of the channel which is exposed to the flow.
Equation 5 represents a basic form of particle diffusivity, where
is an activation energy, P is a pressure [Pa], and
is an activation volume for diffusion. The exponential is dependent on pressure and temperature as seen in this equation.
Equation 6 represents a basic form of coalescence on the atomic scale, where νp is a particle volume, σ is a surface tension, Df is a solid state diffusivity, and νo is a volume of diffusing species.
Equation 7 represents a pressure difference a nanoparticle would experience from the Laplace equations. σ is the surface tension, dp is a particle diameter, Pi is an internal pressure of the particle, and Pa is an ambient pressure of the particle.
Combining equations 5, 6 and 7, a general form for the time of coalescence is obtained. Equation 8 is a basis for particle growth/formation. dp is the particle diameter [m]. ko is an oxygen to saline molar ratio
T is the atmospheric temperature [K]. Do is an area of aerosol diffusivity constant
νo is the volume based on oxygen [cm3]. λ is a volume of the oxygen anion [cm3]. σ is the surface tension
Ea is the activation energy
Va is the molar volume
Pa is the atmospheric pressure. There are various values for λ and ko, depending on the source as well as the activation energies with respect to the reactions that are taking place. From an analysis in this example, the time to coalesce for a particle size of 0.03 nm is 1.5 s, which means that within the system cycle time, a particle may form within the stream with an average diameter of 0.03 nm. This data suggests that a typical oxidizer will have enough resonance time to propagate particle growth. After the particle coalesces, it will grow exponentially. The coalescent points correlate to the points of stagnation seen in
Equation 9 represents an area of stagnation, Astag, which is directly related to a total area, ATotal, occupied by the channel/structure and an area, AHyd, of the flow moving through the channel.
Astag=ATotal−AHyd (9)
Equation 10 represents an average length from the edge of the hydraulic flow to the line of stagnation. This value will vary with different designs. Mathematical arrangement optimization favors an arrangement of a circle touching six sides. This arrangement corresponds to a circular structure which has six points of contact.
A third step involves calculating a time to plug (block 2306). Equation 11 represents one form to estimate the time to plug for a system. k is a system correlation factor for mapping prior data to plugging. Pstag is a value for the points of stagnation. ρair is a density of air. μ is a dynamic viscosity of the air. V is a combustion bed velocity. tr is a residence time. ρSi is a density of the silicon in the chamber. In order for this equation to be valid, Astag must be less than Ahydraulic. The area of stagnation, Astag, is less than the area of flow for a channel.
For an example where k=30 s2, L(square)=0.48 mm, L(hex)=0.34 mm, L(circle)=0.34 mm, Astag(square)=3.15 mm2, Astag (hex)=2.73 mm2, Astag (cir)=2.73 mm2, Dh=2.9 mm, inner wall thickness=0.5 mm, PStag(square)=4, PStag (hex)=6, Pstag (circular scenario 1)=8, PStag (circular scenario 2)=5, the dynamic factor
with Lave for the circle=0.385 mm and Lave for the others=0.5 mm, the time to plugging for the square structure is 5.2 months. The time to plugging for the hexagonal structure, the circular scenario 1, and the circular scenario 2 are 6.0, 6.1 and 5.98 months respectively
The octagonal structure may resist plugging for a longer period of time than the hexagonal structure and may also have increased heat transfer to the stream. Manufacturing costs for the octagonal structure may be greater than the hexagonal block. However, the octagonal block may still be the preferred structure. A factor, referred to as an infinity-clause, may cause the circular structure to fail earlier than the hexagonal structure, as seen in the circular scenario 2. When the side of the polygon is on the order of the inner wall thickness, then the infinity clause will apply if the pollutant concentration is above system tolerable levels. This condition would promote particle growth at an infinite number of points, each with an exponential growth rate.
Equation 11 illustrates that the square structure may plug relatively earlier than the hexagonal or the circular structures. Some circular structures may clog in a relatively shorter time period in comparison to the hexagonal structure because there is an infinite set of unions between a perimeter of the circle and a boundary layer of the flow. If the dynamic loads are sufficient and the infinity clause is out of scope, the circular structure in the scenario 1 will remain free from plugging for the largest amount of time. Blocks 2308, 2310, 2312, 2314 illustrate how the k factor of equation 11 must be solved reiteratively.
A fourth step involves calculating secondary parameters (block 2316). The secondary parameters include thermal convection, flow stagnation, pressure differential and/or destruction removal efficiency (DRE). Should the length or area of stagnation, from equation 10 be too large, some or all of the secondary parameters may have less-favorable values. The closer Lstag is to the initial particle size, the longer the system will perform without being plugged. Reducing the inner wall thickness will decrease the pressure differentials and the area of stagnation. If the process tools and the manufacturing process to make the block are designed correctly, the DRE may also be reduced. The average length of stagnation may be related to the inner wall thickness which, in turn, may be related to the hydraulic diameter. The ratio between the inner wall and the hydraulic diameter affects the pressure losses of the system.
The pressure differentials may be calculated using Bernoulli's equation 12. A balance between the pressure losses and the thermal conductivity may be realized, in part, with equation 24.
Utilizing current production technology, example design parameters will be similar to those displayed in the table 2200 of
Other structural modifications such as, but not limited to, those shown and described in connection with
The factors, ratios and structural designs are dependent on system parameters and/or current production capabilities. One additional factor to consider is the cost of manufacturing. Material and die costs, etc. may benefit one type of structure over another. Taking these factors into account, the hexagonal structure may be the preferred design. Hence, the plurality of channel structures would be hexagonal in appearance. The block structure, in this example, satisfies resistance to plugging, and reduces both the DRE and the pressure drop. Once these factors and the results are determined, it may be determined whether or not to proceed to another analysis with new parameters and/or variables (block 2318).
The dichotomy of the system complexities are exemplified by equation 5. In order to improve the efficiency of the system, the energy out, Eout, must be maximized, while the systems total energy, Ein, is minimized. In either case, the heat transfer from the media to the air stream is crucial. For example, if there was no heat transferred between the media and the airstream, a burner would have to compensate to heat the stream up to the desired temperature. Thus, maximizing the energy that goes in and out of the stream will allow less use of the burner and, therefore, increase system efficiency. Based on these considerations, first the set of equations must be defined (block 2402).
Equation 13 represents the energy contained within the air stream including energy transferred to and from a block.
Equation 14 represents the energy in a block. Note that when the block temperature reaches the air temperature, no energy is transferred. A hot combustion zone around 900° C. will affect the top 750 mm of the block with a nominal thermal conductivity value of approximately
and a cycle time of 60 s. This implies that the heat available to the stream will be relatively consistent with respect to the chamber temperature within the top 600 mm of the block.
{dot over (q)}Block=kBlockL(TAir−TBlock) (14)
Equation 15 represents the heat transfer to or from a block. The average transfer of energy to or from the block is calculated by an average thermal convection coefficient, a surface area of “contact,” a block temperature and a fluid temperature. The surface area of contact, Asurf, is the actual wetted surface area.
Though there are many scenarios in which the energy into the air may be maximized, this example will focus on the mass of the block. This example will consider a cycle time of 60 s, and a Dh of 2.9 mm with walls 0.5 mm in average thickness. For this example, the bed heights will be 1.2 and 1.5 m. The initial conditions may assist in defining the average values for the system operational conditions. The block design may be adjusted depending upon system and/or operational considerations. This example will consider three channel morphologies including the square, the hexagon, and the circle.
Equation 16, the transient thermal convective heat transfer equation, demonstrates that as the cycle time increases, more heat is taken or given to the source, which results in lower system efficiency (block 2404). Due to the difficulties in solving this equation, this example will consider simplistic approximations for optimization.
Next, the steady-state thermal convective coefficient,
The average thermal convection coefficient contains channel morphology factors including ca, cn, cw, N, l, and ρCell. It is also dependent on Nussult's number, Nu, and the thermal conductivity of the fluid and the solid. Solving this equation for the three channel morphologies, demonstrates that the circular structure will have the highest heat transfer. Since the bed height is greater than 0.6 m and the heat transfer is greater, the block will transfer more heat to or from the stream. This transfer of heat reduces the outlet temperature, thereby increasing the overall system efficiency. A well-arranged circular channel structure will also have more mass.
A next step involves calculating wetted and occupied areas for the channels (block 2408). Equations 18, 19 and 20 represent the calculations for determining the wetted area of a channel structure with respect to the hydraulic diameter. The wetted area is the surface area of the channel (i.e., the total open area).
Equations 21, 22 and 23 represent the area the channel structure occupies with respect to the hydraulic diameter (e.g., the occupied area of the channel).
A highly efficient arrangement for circular channel structures is one that touches on six sides, hence, the occupied area of the circular structure is substantially similar to the hexagon structure. Using these equations with optimal arrangements, the circular structure will have 8.1% more mass than the square structure and 24.8% more than the hexagon structure. This does not, however, take into account the differing number of channels for each geometry. In any case, the circular channel structure will have the most mass, the highest thermal convection coefficient and, thus, a well-arranged circular structure may have the largest system efficiency.
Among the several caveats in generating an optimal block design, the spacing between the channels and their orientation are among the most important. The time dependent equations may be step-sized and a comparative analysis may be performed utilizing the ratio between the inner wall thickness and the hydraulic diameter to compare the designs. The orientation of the hexagon and the circle are similar, however, the average wall thicknesses vary. Using these equations with an average inner wall thickness on the hexagonal structure of 0.5 mm, the optimal minimum thickness for the circular structure is 0.385 mm. Therefore, the circular structures should be spaced approximately 0.38-0.39 mm apart to substantially increase their performance. These dimensions, however, may be difficult to implement considering current manufacturing limitations. In any case, the circular channel structures should be arranged relative to one another similar to a hexagon arrangement.
The next step involves determining a secondary factor (block 2412), which includes thermal convection, flow stagnation, pressure differentials and/or DRE. Equation 24 calculates a performance factor, ITP.
Once these factors and the results are determined, it may be determined whether or not to proceed to another analysis with new parameters and/or variables (block 2414).
The kinematic viscosity and other fluid properties are related to the thermal convection and pressure drop. This non-dimensional quantity is useful for optimizing channel densities with respect to fluid properties. With a greater hAve and a smaller Δp, the circular structure may perform the most effectively if the channels are arranged appropriately.
Utilizing the fluid properties of the air and the hydrodynamic properties of the block with equation 12, it may be shown that the pressure drop will be less for a hexagonal or circular structure than with the square structure. Hence, for this example, a well packed circular structure would provide the most benefit to the system. The outer wall thickness may be two to three times greater than the inner wall thickness for manufacturing stability. The preferred outer wall thickness is identical to the inner wall thickness.
One of the preferred structures, as shown in
Each of the example demonstrated ratios and/or variables may be used to optimize a design with respect to a desired effect or a combination of effects. For the examples described herein, system efficiency and/or plugging are very significant considerations for the system. A system analysis performed with equation 16 and
This ratio for thermal efficiency is further preferred to be from 2.58 to 5.53 and especially preferred to be from 3.58 to 4.83.
The preferred design to resist plugging is to have the wall separation as thin as possible and the Dh as high as possible. Reducing the operating temperature would also resist plugging. Systems with high silicon plugging would perform significantly better with a ratio of
This ratio for plug resistance is further preferred to be from 6.47 to 16.48 and especially preferred to be from 9.58 to 13.83. As the pollutant increases in density, the hydraulic diameter also increases. Since the hydraulic diameter is much greater than twall, no stagnation effects are prevalent. If the open area becomes relatively large, the block may have diminished thermal effectiveness. Secondary system requirements may be applied as needed per system requirements. The tolerance range of both ratios results from current manufacturing technology and material selection.
The processor platform 2500 of the illustrated example includes a processor 2512. The processor 2512 of the illustrated example is hardware. For example, the processor 2512 can be implemented by one or more integrated circuits, logic circuits, microprocessors or controllers from any desired family or manufacturer.
The processor 2512 of the illustrated example includes a local memory 2513 (e.g., a cache). The processor 2512 of the illustrated example is in communication with a main memory including a volatile memory 2514 and a non-volatile memory 2516 via a bus 2518. The volatile memory 2514 may be implemented by Synchronous Dynamic Random Access Memory (SDRAM), Dynamic Random Access Memory (DRAM), RAMBUS Dynamic Random Access Memory (RDRAM) and/or any other type of random access memory device. The non-volatile memory 2516 may be implemented by flash memory and/or any other desired type of memory device. Access to the main memory 2514, 2516 is controlled by a memory controller.
The processor platform 2500 of the illustrated example also includes an interface circuit 2520. The interface circuit 2520 may be implemented by any type of interface standard, such as an Ethernet interface, a universal serial bus (USB), and/or a PCI express interface.
In the illustrated example, one or more input devices 2522 are connected to the interface circuit 2520. The input device(s) 2522 permit a user to enter data and commands into the processor 2512. The input device(s) can be implemented by, for example, an audio sensor, a microphone, a camera (still or video), a keyboard, a button, a mouse, a touchscreen, a track-pad, a trackball, isopoint and/or a voice recognition system.
One or more output devices 2524 are also connected to the interface circuit 2520 of the illustrated example. The output devices 2524 can be implemented, for example, by display devices (e.g., a light emitting diode (LED), an organic light emitting diode (OLED), a liquid crystal display, a cathode ray tube display (CRT), a touchscreen, a tactile output device, a light emitting diode (LED), a printer and/or speakers). The interface circuit 2520 of the illustrated example, thus, typically includes a graphics driver card.
The interface circuit 2520 of the illustrated example also includes a communication device such as a transmitter, a receiver, a transceiver, a modem and/or network interface card to facilitate exchange of data with external machines (e.g., computing devices of any kind) via a network 2526 (e.g., an Ethernet connection, a digital subscriber line (DSL), a telephone line, coaxial cable, a cellular telephone system, etc.).
The processor platform 2500 of the illustrated example also includes one or more mass storage devices 2528 for storing software and/or data. Examples of such mass storage devices 2528 include floppy disk drives, hard drive disks, compact disk drives, Blu-ray disk drives, RAID systems, and digital versatile disk (DVD) drives.
The coded instructions 2532 of
Although certain example methods, apparatus and articles of manufacture have been described herein, the scope of coverage of this patent is not limited thereto. On the contrary, this patent covers all methods, apparatus and articles of manufacture fairly falling within the scope of the claims of this patent.
This patent arises as a continuation of U.S. patent application Ser. No. 14/015,544, which was filed on Aug. 30, 2013, and granted as U.S. Pat. No. 9,683,474, and is hereby incorporated herein by reference in its entirety.
Number | Name | Date | Kind |
---|---|---|---|
610292 | Thornton | Aug 1898 | A |
1452742 | Johnston | Apr 1923 | A |
1670127 | Stancliffe | May 1928 | A |
1795055 | Taylor et al. | Mar 1931 | A |
2018223 | Otto | Oct 1935 | A |
2018224 | Otto | Oct 1935 | A |
2432198 | Karlsson et al. | Dec 1947 | A |
2495960 | George | Jan 1950 | A |
2506244 | Stopka | May 1950 | A |
2507862 | Mead | May 1950 | A |
2706109 | Odman | Apr 1955 | A |
2823027 | Coberly | Feb 1958 | A |
2983486 | Rosenberg | May 1961 | A |
3097930 | Holland | Jul 1963 | A |
3251403 | Smith | May 1966 | A |
3384359 | Potocnik | May 1968 | A |
3554273 | Kritzler | Jan 1971 | A |
3870474 | Houston | Mar 1975 | A |
4020896 | Mold et al. | May 1977 | A |
4321961 | Hemsath | Mar 1982 | A |
4343354 | Weber | Aug 1982 | A |
4361182 | Michalak | Nov 1982 | A |
4378045 | Balke et al. | Mar 1983 | A |
4405010 | Schwartz | Sep 1983 | A |
4509584 | Michalak et al. | Apr 1985 | A |
4577678 | Frauenfeld et al. | Mar 1986 | A |
4651811 | Frauenfeld et al. | Mar 1987 | A |
4655802 | Jaumann | Apr 1987 | A |
4789585 | Saito et al. | Dec 1988 | A |
5352115 | Klobucar | Oct 1994 | A |
5516571 | Kawamoto | May 1996 | A |
5590708 | Ulrich | Jan 1997 | A |
5755569 | Berg et al. | May 1998 | A |
5851636 | Lang et al. | Dec 1998 | A |
5893406 | Brophy | Apr 1999 | A |
6019160 | Chen | Feb 2000 | A |
6062297 | Kasai et al. | May 2000 | A |
6264464 | Bria | Jul 2001 | B1 |
6793010 | Manole | Sep 2004 | B1 |
7354879 | Reid | Apr 2008 | B2 |
8361592 | Miyairi et al. | Jan 2013 | B2 |
9683474 | Widhalm | Jun 2017 | B2 |
20040170804 | Niknafs et al. | Sep 2004 | A1 |
20060217262 | Yoshida | Sep 2006 | A1 |
20090176053 | Miyairi | Jul 2009 | A1 |
20100155038 | Greco et al. | Jun 2010 | A1 |
20110042035 | Seebald | Feb 2011 | A1 |
20110127011 | Agostini et al. | Jun 2011 | A1 |
20110240622 | Sanchez et al. | Oct 2011 | A1 |
20120048524 | Murayama et al. | Mar 2012 | A1 |
20150066176 | Widhalm | Mar 2015 | A1 |
Number | Date | Country |
---|---|---|
201093906 | Jul 2008 | CN |
0140601 | Jan 1988 | EP |
1136755 | Sep 2001 | EP |
690515 | Apr 1953 | GB |
2000-258081 | Sep 2000 | JP |
2000258081 | Sep 2000 | JP |
Entry |
---|
International Searching Authority, “International Search Report”, issued in connection with PCT Application No. PCT/US2014/053204, dated Nov. 11, 2014, 5 pages. |
International Searching Authority, “Written Opinion”, issued in connection with PCT Application No. PCT/US2014/053204, dated Nov. 11, 2014, 7 pages. |
International Searching Authority, “International Preliminary Report on Patentability”, issued in connection with PCT Application No. PCT/US2014/053204, dated Mar. 1, 2016, 7 pages. |
The State Intellectual Property Office of China, English version of “First Office Action”, issued in connection with Chinese Patent Application No. 201480008079.0, dated Jul. 25, 2016, 12 pages. |
The State Intellectual Property Office of China, English version of “Second Office Action”, issued in connection with Chinese Patent Application No. 201480008079.0, dated Feb. 4, 2017, 19 pages. |
Gu et al., On the design of two-dimensional cellular metals for combined heat dissipation and structural load capacity, International Journal of Heat and Mass Transfer 44, Jun. 2001, 13 pages. |
Suh et al., Modeling particle formation during low-pressure silane oxidation: Detailed chemical kinetics and aerosol dynamics, J. Vac. Sci. Technol. A. vol. 19, No. 9, May 2001, 12 pages. |
United States Patent and Trademark Office, “Notice of Allowance,” issued in connection with U.S. Appl. No. 14/015,544, dated Feb. 14, 2017, 24 pages. |
United States Patent and Trademark Office, “Non-Final Office Action,” issued in connection with U.S. Appl. No. 14/015,544, dated Aug. 11, 2016, 27 pages. |
United States Patent and Trademark Office, “Election/Restriction,” issued in connection with U.S. Appl. No. 14/015,544, dated Mar. 18, 2016, 10 pages. |
English translation of Chinese Patent Office, “Notice of Decision of Granting Patent Right for Invention,” issued in connection with Chinese application No. 201480008079.0, dated Jul. 31, 2018, 3 pages. |
English Translation of the State Intellectual Property Office of China, “Third Office Action,” issued in connection with Chinese application No. 201480008079.0, dated Aug. 7, 2017, 5 pages. |
English version of the State Intellectual Property Office of China, “Fourth Office Action,” issued in connection with Chinese application No. 201480008079.0, dated Jan. 25, 2018, 22 pages. |
Number | Date | Country | |
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20170248054 A1 | Aug 2017 | US |
Number | Date | Country | |
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Parent | 14015544 | Aug 2013 | US |
Child | 15597777 | US |