The present disclosure relates to high temperature furnaces and retort assemblies for use in high-temperature furnaces.
High-temperature processing of ceramic matrix composite (CMC) parts such as melt infiltration, chemical vapor infiltration, and chemical vapor deposition are often performed using a furnace. In some cases, rather than loading parts directly into a furnace for processing, parts are loaded into a retort before the retort is loaded into a furnace for processing. A retort device may be alternatively called a loading fixture. A retort device supports parts for processing in a furnace and withstands the harsh furnace environment, which may include extreme temperatures, reactant gases, and pressures above or below atmospheric pressure.
In some examples, the disclosure is directed to a multilevel retort assembly comprising: a base defining a base perimeter; a plurality of shells, each shell having a diffuser plate support and a perimeter with a substantially similar shape as the base perimeter, wherein the plurality of shells are stacked on each other, mechanically supported by the base, and surround an inner retort volume, and wherein at least one shell of the plurality of shells defines a removable window; and a plurality of diffuser plates, each diffuser plate supported by a corresponding diffuser plate support of the plurality of diffuser plate supports.
In some examples, the disclosure is directed to a method of processing parts in a furnace comprising: removing a removable window from at least one shell of a multilevel retort assembly, wherein the multilevel retort assembly comprises a base defining a base perimeter, a plurality of shells, each shell having a diffuser plate support and a perimeter with a substantially similar shape as the base perimeter, wherein the plurality of shells are stacked on each other, mechanically supported by the base, and surround an inner retort volume, and wherein at least one shell of the plurality of shells defines a removable window; loading one or more parts into the inner retort volume of the multilevel retort assembly through the removable window such that the one or more parts are supported by one or more plate of a plurality of diffuser plates, wherein each diffuser plate is supported by a corresponding diffuser plate support; and securing the removable window of the multilevel retort assembly to the at least one shell of the plurality of shells.
The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention will be apparent from the description and drawings, and from the claims.
Like symbols in the drawings indicate like elements.
Retort devices are used in the manufacturing of articles, such as ceramic matrix composite (CMC) parts, at high temperatures. Rather than load parts directly into a furnace, a retort device may be loaded with parts for processing in a furnace, and the loaded retort placed in the furnace. In this way, retort devices may improve furnace uptime in industrial operations by allowing for loading and unloading of parts outside of the furnace, thus reducing the time spent waiting for the furnace to cool down for loading and unloading. Further, in some processes, retort devices assist in processing material by containing reactant gases inside the retort device while inert guard gases flow around the outside of the retort device. In some implementations, a retort device can additionally or alternatively act as a pressure vessel within the furnace. In some examples, pressure inside the retort in an inner retort volume is reduced to below atmospheric pressure to operate the furnace as a vacuum furnace.
In some examples, high temperature processing of parts including melt infiltration (MI), chemical vapor infiltration (CVI), chemical vapor deposition (CVD), and/or heat treatment steps, may use a multilevel retort assembly according to the present disclosure. In these and other processes, a retort which is substantially gas tight (gas tight or nearly gas tight) may be used, so that interaction between process gases in the retort device and the parts being processed can be controlled. A substantially gas tight retort is a retort that allows inert gases flowing outside the retort to slowly leak into the retort, while reducing or substantially preventing process gases within the multilevel retort assembly from flowing out of the retort. In some implementations, a multilevel retort assembly according to the present disclosure may provide a substantially gas tight inner retort volume.
Since processing MI, CVI, and/or CVD of parts uses extensive input of raw materials and energy, it may be desirable to process many parts in parallel. For example, a plurality of parts may be loaded in a retort for a single batch process in a furnace, to improve part processing throughput. Some retort assemblies according to the present disclosure may allow for efficient use of available furnace space by including multiple levels to support parts within the retort assembly.
One way to use relatively more of the available volume in a furnace than a single level retort may allow is to include multiple levels that may mechanically support parts within an inner retort volume. Some multilevel retorts include a retort assembly which includes a plurality of shells or rings in a vertical direction. Inside the inner retort volume, and separate from the outer shell structure, a part-supporting scaffold may mechanically support parts on diffuser plates, which rest on standoff rods extending from the diffuser plate below. In multilevel retort assemblies of this type, the retort assembly must be completely disassembled between batches to load or unload parts. The shells or rings require lifting and removal, which may be unsafe or ergonomically problematic due to the size and weight of these structures.
In example multilevel retort assemblies according to the present disclosure, the multilevel retort assembly may be loaded and unloaded without disassembling the shells, which may reduce loading and unloading time and/or provide for safer and more ergonomic loading and unloading of the retort. For instance, multilevel retort assemblies according to the present disclosure include at least one removable window which provides access to at least one level of the multilevel retort assembly, allowing for loading and unloading of parts without disassembly of the multilevel retort assembly. This may allow for time savings over loading or unloading a conventional multilevel retort assembly. For example, a conventional multilevel retort assembly may take approximately 60 to 90 minutes to load and unload. In contrast, a multilevel retort assembly according to the present disclosure may be loaded and unloaded in about 15 minutes. Additionally, or alternatively, multilevel retort assemblies according to the present disclosure provide increased capacity for parts by removing internal support structures, which consume space in the inner retort volume that could otherwise be used for parts.
Referring to
Each shell of plurality of shells 18 may have a perimeter shaped and sized substantially similar to or the same as base perimeter 20. For instance, in the illustrated example, base perimeter 20 defines a substantially circular shape and each shell of plurality of shells 18 defines a substantially cylindrical shape with the same diameter when multilevel retort assembly 10 is assembled. In some examples, a bottom surface of first shell 18a may be base 16, and first shell 18a may define base perimeter 20. In other words, in some examples, first shell 18a may be integral with the base 16. In other examples, first shell 18a is separate from base 16. Shells 18 also may be referred to as rings 18.
In some examples, each individual shell of the plurality of shells 18 may have substantially the same dimensions and be interchangeable with each other shell of plurality of shells 18. For purposes of discussion, a first shell 18a is labelled in
First shell 18a may form a hollow structure with a cross-sectional shape and size substantially the same as the shape and size of base perimeter 20. In the illustrated example, first shell 18a is substantially a hollow cylinder. Plurality of shells 18 may be arranged vertically on base 16 to define inner retort volume 22. Plurality of shells 18 may fit together and be topped with cover 24 to define inner retort volume 22. In some implementations, base 16, plurality of shells 18, and cover 24 form a substantially gas tight multilevel retort assembly 10. While furnace 12 is in operation, guard gases may flow around multilevel retort assembly 10, slowly leaking or diffusing into inner retort volume 22.
Plurality of shells 18 may be stacked on each other and supported by base 16. In some examples, plurality of shells 18 are stacked on each other vertically, meaning plurality of shells 18 fit together and are arranged to support each other in a vertical direction, defining multilevel retort assembly 10. In some examples, plurality of shells 18 may be assembled horizontally, fitting together in a horizontal direction to define multilevel retort assembly 10.
Multilevel retort assembly 10 also includes a plurality of diffuser plates 26. Plurality of diffuser plates 26 function as mechanical support supporting parts 28 within inner retort volume 22. Multilevel retort assembly 10 may include any suitable number of diffuser plates 26 and spacing between adjacent diffuser plates 26 may be selected based on the size (e.g., height) of parts 28. In some examples, multilevel retort assembly 10 may include one diffuser plate for each shell of shells 18.
Although not labelled in
Each individual diffuser plate of plurality of diffuser plates 26 may define a level of multilevel retort assembly 10. Each level of the multilevel retort assembly 10 may mechanically support one or more parts 28 during heat treatment.
Each diffuser plate 26 may define plurality of apertures 30. Plurality of apertures 30 may be gaps, holes, spaces, slots, or the like in diffuser plate 26 which allow gases in inner retort volume 22 to pass from one level to another. In some examples, diffuser plate 26 defines plurality of apertures 30 that are substantially evenly distributed across the diffuser plate 26.
At least one shell of plurality of shells 18 includes a removable window 32a. In the illustrated example of
Removable window 32a may be removed from the remaining portion of shell 18a, as illustrated in
In some examples, removable window 32a may not be completely removed from first shell 18a but rather configured to swing open like a door by inclusion of a hinge or other mechanism.
Cover 24 may define at least one aperture 34 that allows gases to enter inner retort volume 22. Cover 24 may otherwise seal multilevel retort assembly 10 so that multilevel retort assembly is substantially gas tight. At least one aperture 34 may be a circular aperture. At least one aperture 34 may include three separate apertures defined by cover 24.
Multilevel retort assembly 10 includes plurality of diffuser plates 26, two of which are labelled in
Each diffuser plate support of plurality of diffuser plate supports 36 functions to support a diffuser plate of plurality of diffuser plates 26, which function to support a load (e.g., parts 28 shown in
In some examples, removable window 32 (not shown in
In some examples, multilevel retort assembly 10 may include an arrangement in which plurality of shells 18 are stacked on each other by fitting at least one protrusion 38 extending from a surface of a first shell 18a of plurality of shells 18 with a depression 40 in a corresponding surface of a second shell 18b of plurality of shells 18. In some examples, the surface of the first shell 18a may be the top surface, and the corresponding surface of second shell 18b may be a bottom surface. At least one protrusion 38 may extend vertically from any portion of the top surface of first shell 18a, such as a radially outer portion of a top surface of first shell 18a. Similarly, depression 40 may be defined at any corresponding portion of the bottom surface of second shell 18b, such as a radially outer portion of bottom surface of second shell 18b. The radially inner portion of a shell 18 may be defined as a portion that is closer to inner retort volume 22 than it is to the surroundings of multilevel retort assembly 10. Similarly, the radially outer portion of a shell 18 may be defined as a portion that is closer to the surroundings of multilevel retort assembly 10 than it is to inner retort volume 22. This allows protrusion 38 to mate with depression 40 and radially restrain first shell 18a and second shell 18b relative to each other. In other implementations, protrusion 38 may be at a radially outer portion of the top surface of first shell 18a and depression may be at a radially outer portion of the bottom surface of second shell 18b, or protrusion 38 and depression 40 may be at a radially middle portion of the top and bottom surfaces, respectively. Generally, protrusion 38 and depression 40 at any radially corresponding location of the top and bottom surfaces such that their positions are complementary and they engage when first shell 18a and second shell 18b are stacked.
Similarly, in some examples, second shell 18b includes at least one protrusion 42 extending from a top surface of second shell 18b and third shell 18c includes a corresponding depression 44 in a bottom surface of third shell 18c of plurality of shells 18. At least one protrusion 42 extends from a top surface of second shell 18b into corresponding depression 44 in third shell 18c. In some implementations, as each shell 18 is substantially identical, the position of the protrusions and depressions may be similarly substantially identical, such that shells 18 may be stacked on each other in any order.
As mentioned above, shells 18 may include a removable window and a diffuser plate support.
Removable window 32a defines a portion of the perimeter of first shell 18a. In the example shown in
Body portion 54 of first shell 18a has an outer surface 46 facing the surroundings of the retort assembly and an inner surface 48 facing inner retort volume 22, and inner surface 48 and outer surface 46 are separated by an approximately equal distance D at any point on outer surface 46, such that the radial thickness of shell 18a at a given height is substantially constant.
Body portion 54 of first shell 18a may include at least one retaining strap 56 configured to secure removable window 32a to body portion 54 of first shell 18a. In some examples, at least one retaining strap 56 may be a releasable coupling configured to controllable secure and release removable window 32a and body portion 54. In some examples, at least one retaining strap feature 56 may wrap all the way around the outer perimeter of body portion 54. In other examples, as shown in
In some examples, removing removable window 32a from at least one shell 18a of multilevel retort assembly 10 may removing all removable windows 32 all shells 18 of the multilevel retort assembly 10.
The technique of
The technique of
Number | Name | Date | Kind |
---|---|---|---|
1913386 | Hansen | Jun 1933 | A |
2040261 | Klouman | May 1936 | A |
3112919 | Gunow | Dec 1963 | A |
3198503 | Eichelberg | Aug 1965 | A |
4909732 | Wingens | Mar 1990 | A |
5193998 | Hack et al. | Mar 1993 | A |
5267259 | Gillhaus et al. | Nov 1993 | A |
5413132 | Cronan | May 1995 | A |
5478057 | Wilhelmi et al. | Dec 1995 | A |
6369361 | Saito et al. | Apr 2002 | B2 |
6383297 | Schmidt | May 2002 | B1 |
7008210 | Manabe | Mar 2006 | B2 |
7687024 | Bergman | Mar 2010 | B2 |
8137470 | Min et al. | Mar 2012 | B2 |
8388895 | Jung | Mar 2013 | B2 |
10435810 | Loboda et al. | Oct 2019 | B2 |
10945313 | Rathi | Mar 2021 | B2 |
11072032 | Winnicka | Jul 2021 | B2 |
20040035366 | Keum et al. | Feb 2004 | A1 |
20100239878 | Nagata | Sep 2010 | A1 |
20110115138 | Sarres et al. | May 2011 | A1 |
20190337071 | Winnicka | Nov 2019 | A1 |
20210037612 | Kwon | Feb 2021 | A1 |
Number | Date | Country |
---|---|---|
2363208 | May 2002 | CA |
108728800 | Nov 2018 | CN |
112179067 | Jan 2021 | CN |
10157840 | Oct 2002 | DE |
10338431 | Mar 2005 | DE |
202008009980 | Nov 2008 | DE |
0312909 | Apr 1989 | EP |
0460484 | Dec 1991 | EP |
0662519 | Jul 1994 | EP |
2995894 | Mar 2016 | EP |
2509452 | Jan 1983 | FR |
2015230152 | Dec 2015 | JP |
20140100649 | Aug 2014 | KR |
2012144879 | Apr 2014 | RU |
201317374 | May 2013 | TW |
WO-2011117409 | Sep 2011 | WO |
2013005448 | Jan 2013 | WO |