This invention relates generally to apparatus and methods for the design, retrofitting and repair of supports for the multiplicity of radiant tubes that convey organic materials to be heated in industrial fired heaters.
Without limiting the scope of the invention, its background is described in connection with existing radiant tube supports for industrial direct fired heaters or furnaces. Fired heaters are central to the processes required for the operation of oil refineries and the design of such heaters must conform to API 560. Fired heaters are also used in chemical and petrochemical processes to induce chemical reactions within the organic materials and are typically referred to as industrial fired furnaces. A fired heater typically consists of a radiant section, radiant coil, burners and a flue gas stack, and can also incorporate a convection section with coil, forced draft and/or induced draft fans or combustion air preheat. Each individual heater is designed to transfer a defined amount of heat to the coils at a certain rate, based on the volume and rate of organic material running through the coils all at a specified efficiency.
Depending on the chemical process, such heaters operate in the temperature range from 400° C. to over 1000° C. As depicted in
Regardless of the configuration, the severe operating conditions required by the design include high operating temperatures that adversely affect the constituent metals of the entire internal aspects of the heater including by oxidation, creep, stress fracturing and thermal cycling during start up and shut down operations. The radiant tubes are further affected by the chemicals conveyed within them and deposits thereof including corrosion, erosion, metal dusting and coke deposition on the inner walls of the tubes. Coke deposits can result in elevated tube metal temperatures, leading to carburization and metal dusting of steel tubing, affect heat flow through each tube and the entire coil. Internal corrosion in the tube coils results from the combined effects of the chemical composition of the process fluid, process and tube metal temperatures, fluid velocity and tube metallurgy. Fortunately the radiant tubes can be inspected by several non-destructive techniques including by smart pigging, boroscoping, magnetic testing of austenitic tubes, ultrasonic testing, infrared inspection and by eddy current analysis, among others.
In fired heaters the radiant tubes are typically supported by radiant tube coil supports 24 (also termed hangers or hooks) that are generally bolted or clipped to the interior walls and roof of the heater. Due to the weight that they support, the radiant tube supports are generally bolted through the heater casing into structural support columns or beams 26 along the sides or roof, exterior to the heater casing. Insulation is installed throughout the interior of the heater radiant firebox, convection section, and typically the stack. The radiant tube supports hold the radiant coils in position by supporting and guiding the tubes and are designed to minimize sagging, bowing and buckling of the tubes and to keep the coil stable without swaying and within acceptable stress limits while allowing for the free expansion of the tubes of the coil during startup and shutdown of the heater. The coils are generally hung a distance off of the insulation interior surface (hot face) of the heater to reduce shadowing of the back side of the coil tubes, increasing heat transfer to the tube through improved radiation. The radiant tube supports are individually designed such that as a whole a plurality of supports will carry a vertical load that includes the weight of the tube and fitting components of the entire coil, the contents of the coil (fluid or gas), and the horizontal frictional load experienced when the coils expand/contract upon the heater being started/shutdown.
An example of a radiant tube support in use in the industry is shown in
Radiant tube supports are made from heat resistant alloys chosen for high-temperature strength, creep properties, and resistance to corrosion. Typically, radiant tube supports are cast out of high nickel chrome alloy material capable of resisting the elevated temperatures experienced inside the radiant firebox enclosure. Nonetheless, the tube supports are susceptible to high temperature oxidation, high temperature embrittlement, thermal fatigue, stress fracturing and mechanical damage from thermal cycling during operations as well as corrosion from fuel ash and other combustion products. Tube hangers and supports fail for several reasons including elevated stress, long term creep, mechanical damage from vibration or expansion and mechanical impact during cleaning, corrosion, metallurgic changes over time, and poor quality castings.
As is clear from
From the foregoing it is apparent there is a need in the art for improved tube supports that can be inspected and replaced during operation of the heater as well as tube supports that are universally adaptable for different heater designs. The invention described provides novel radiant tube supports that may be tested for integrity and replaced during heater operation and further provides a tube support system that may be retrofitted or replaced on existing heaters of varying designs while they remain in service.
The present invention is directed to novel radiant coil supports that are insertable from outside of the firebox and will fit heaters having different refractory lining thicknesses. Methods of repair and installation of such supports are provided. In one embodiment, a radiant tube coil support system for fired heaters is provided that includes a support mounting frame adapted to be mounted on an external surface of a heater casing and a plurality of tube supports that are mounted to the heater casing from the external surface of the heater casing, wherein each tube support system includes a heater casing internal section termed a tube support that supports the weight of the radiant coil. In certain embodiments the tube support includes one or more voids that are cast into the tube support. In certain embodiments, the voids are ventable to an exterior of the heater casing. The voids reduce the weight of the tube support and allow sampling of gases or pressure from an interior of the support to allow for external monitoring for cracks in the tube supports.
In certain embodiments, the radiant tube coil support system further includes a plurality of tube keepers wherein each keeper that is adapted and dimensioned for placement over an upward surface of at least one individual tube support and the tube keeper together with the tube support surround over one-half of an outer circumference of the radiant tube and control movement of the radiant tube. The keeper may include one or more voids that are ventable to an exterior of the heater casing. Sampling of gases or pressure from an interior of the keeper allows for external monitoring for cracks in the keepers.
Both the tube support and the tube keeper are insertable from the external surface of the heater. In one embodiment, both the tube support and the tube keeper include an external shoulder that remains outside of the heater casing.
In certain embodiments, depth control spacers are utilized to abut the external shoulder and control a depth that the tube support can enter into an interior of the heater casing. In certain embodiments a locking mechanism that is mounted on the support frame controls outward movement of the tube support. In other embodiments, the tube support and tube keeper are held together by close fitting in passage through a hole in a retainer plate and external shoulders of the tube support and tube keeper that do not pass through the hole in the retainer plate are sandwiched between the retainer plate and the base plate, wherein the tube support and tube keeper together with the retainer plate and base plate form a unitary support system that act to sandwich the tube support and tube keeper together as they are installed around a radiant tube.
In other embodiments, the tube supports and tube keepers can be locked together at the base and attached to the support frame through the use of a clamp type fixture consisting of a base plate and retainer plated bolted together. In certain embodiments, the tube supports include an upwardly curved distal end dimensioned to cradle a radiant tube and a tube keeper is utilized that covers at least a portion of an upper aspect of a radiant coil such that the tube support and tube keeper together prevent the radiant coil from bending, falling, or otherwise leaving the support.
For a more complete understanding of the present invention, including features and advantages, reference is now made to the detailed description of the invention along with the accompanying figures:
While the making and using of various embodiments of the present invention are discussed in detail below, it should be appreciated that the present invention provides many applicable inventive concepts which can be employed in a wide variety of specific contexts. The specific embodiment discussed herein are merely illustrative of specific ways to make and use the invention and do not delimit the scope of the invention.
To facilitate the understanding of this invention, a number of terms are defined below. Terms defined herein have meanings as commonly understood by a person of ordinary skill in the areas relevant to the present invention. Terms such as “a”, “an” and “the” are not intended to refer to only a singular entity, but include the general class of which a specific example may be used for illustration. The terminology herein is used to describe specific embodiments of the invention, but their usage does not delimit the invention, except as outlined in the claims.
Provided herein are various embodiments of novel radiant tube coil support designs that are insertable through holes in the casing walls of the heater from the outside of the heater in contrast to existing designs that are bolted to the inside of the heater casing. Due to the combined tapered and smooth outer profile of the tube supports and any included keeper, the interior heater insulation may be better applied by tight fitting to the tube support and any included keeper such that the overall effectiveness of the insulation and long-term performance of the insulation are improved. In certain embodiments, the radiant tube support attachment locations are moved off of the heater structural columns where they are typically attached in prior art designs. This allows a uniform application of the insulation system across the locations of the structural support columns and provides improved protection of the structural columns from exposure to excessive temperatures as a result of premature failure of the insulation system.
Because the supports are inserted from the outside of the heater they can be replaced while the heater remains in service. In one embodiment, the tube support design allows for use in different heater designs that share the same radiant coil tube outside diameter but have different insulation thicknesses and different distances between the radiant coil tube centerline and the hot face of the insulation system. This feature makes it economically feasible to have spare supports on hand as they can be used in multiple heaters.
The radiant tube coil support designs provided herein feature an increased bearing surface for supporting and guiding of the radiant tube coils and together with the keeper described herein, the combined support system provides improved restraint of the radiant tube coil without over stressing or damaging the tube coils.
In certain embodiments, radiant tube supports and keepers are provided that are cast or fabricated to include hollow voids that have vents to the outside of the heater and allow for one or more of: 1) ventilation of the radiant tube coil supports allowing them to run at a cooler temperatures during operation and thus improving their functional lives; 2) accurate temperature measurements of the tube supports during operation; 3) through continuous or intermittent monitoring of products of combustion and/or internal negative pressure (draft) through the support and keeper vents (if a keeper is included), cracks in the tube supports and tube keepers can be identified from outside the heater during operation; and 4) improved distribution of the high alloy metal thus improving the strength to weight ratio. In one embodiment, the radiant tube supports disclosed herein are designed with external depth control spacers to accommodate minimal vertical rotation in its base, providing support/restraint to allow for some tube vertical movement during operation, the flexibility intending to reduce additional stresses in the coil tubes.
The following examples are include for the sake of completeness of disclosure and to illustrate the methods of making the compositions and composites of the present invention as well as to present certain characteristics of the compositions. In no way are these examples intended to limit the scope or teaching of this disclosure.
Radiant Tube Coil Support and Keeper Profile
One embodiment of a radiant tube coil support and tube keeper according to the invention is depicted in
Tube keeper 50 is fabricated, or preferably cast, with one or more internal voids 54. In the depicted embodiment, tube keeper 50 has two interior voids 54 and 54′ separated by vertical internal support wall 52. In the depicted embodiment allowing for a circulation path through the keeper body, support wall 52 does not extend the full length of the keeper body and thus a communication 56 is provided between void 54 and 54′. The void or voids 54 are vented to the outside of the heater casing 32 through one or more keeper vents 58. The entire radiant tube coil support system is held in place by support mounting frame assembly 60, which is welded to the outside of heater casing 32. Support mounting frame consists of a frame that attaches such as via welding to the heater casing from the exterior, and provides for removable access plates 66 that serve to complete the enclosure, creating a seal that minimizes the ingress of ambient air during operation.
In the embodiment shown in
Samples of gases from the interior of keeper 50 or the interior of the support 70 may be obtained through sample ports 68, which are in gaseous communication with tube support vents 78 and keeper vents 58. If keeper 50 or tube support 70 is cracked, combustion gases will be detectable in samples taken from sample port 68. Alternatively or in addition, pressure readings may be taken of the gases within keeper 50 or support 70 with reduced pressures expected in the event of cracks in tube keeper 50 or tube support 70.
Installation specifics. With the frame assembly 60 installed, such as by welding at the desired position on the heater casing, oval openings are cut in the casing and through the insulation. The tube support is then inserted through the opening at an angle, allowing for proper positioning of the hook at the tip of the tube support with the tube. Due to the size of the insertion hole, the tube support is insertable at a downward angle from horizontal angle and can get below the lowest aspect of the radiant tube without disturbing the placement of the tube. After insertion past the deepest aspect of the radiant tube, the support is raised to a more horizontal position. This is followed by insertion of the keeper, which slides into position, filling the oval hole and locking the tube support and tube keeper in position. In certain embodiments, depth control spacers 64 are then installed in position. As shown in the embodiment depicted in
In certain alternative embodiments as generally depicted in
Unitized Tube Support and Keeper System
In
In
For installation oval openings are cut in the heater casing 32 and through insulation 30. Retainer plate 102 is placed in position such that its central hole (104 on
Radiant Tube Coil Integrity Testing Using Tube Supports During Plant Operation
In another embodiment, the tube support is adapted to measure the load of the tube resting on it. During operation the load of the tube is transferred to the tube support and keeper. With the load tube support and keeper being transferred to the heater structure through the depth control spacers, load gauges can be installed between the depth control spacers and the frame assembly to measure the loading of the tube supports by the tubes, capturing any weigh changes during operation attributable to coking of the tubes, tube carburization over time or thermal expansion issues.
All publications, patents and patent applications cited herein are hereby incorporated by reference as if set forth in their entirety herein. While this invention has been described with reference to illustrative embodiments, this description is not intended to be construed in a limiting sense. Various modifications and combinations of illustrative embodiments, as well as other embodiments of the invention, will be apparent to persons skilled in the art upon reference to the description. It is therefore intended that the appended claims encompass such modifications and enhancements.
This application claims priority based on U.S. Provisional Application Ser. No. 62/146,795 filed Apr. 13, 2015, which is incorporated herein by reference in its entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/US2016/027122 | 4/12/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2016/168191 | 10/20/2016 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
1787038 | Geoffray | Dec 1930 | A |
1815750 | Watts | Jul 1931 | A |
1883123 | Trainer | Oct 1932 | A |
2175555 | Brown | Oct 1939 | A |
2355800 | Hensel | Aug 1944 | A |
2834327 | Banker | May 1958 | A |
2852219 | Perkins | Sep 1958 | A |
3554168 | Woebcke | Jan 1971 | A |
3599914 | Stephens | Aug 1971 | A |
3844515 | Knol | Oct 1974 | A |
4706614 | Fournier | Nov 1987 | A |
4986222 | Pickell | Jan 1991 | A |
5799623 | Born | Sep 1998 | A |
6047929 | Kaji | Apr 2000 | A |
6178926 | Worman | Jan 2001 | B1 |
20040124075 | Nogueira, Jr. | Jul 2004 | A1 |
Entry |
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International Search Report and Written Opinion in PCT/US16/27122, dated Jul. 15, 2016. |
International Search Report and Written Opinion issued in counterpart European Application No. 16780563.9 dated Nov. 20, 2018. |
Number | Date | Country | |
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20180127661 A1 | May 2018 | US |
Number | Date | Country | |
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62146795 | Apr 2015 | US |