This invention relates generally to repair of Silica brick heating walls in a refractory furnace, and more specifically, in a non-limiting and exemplary embodiment, to the repair of Silica brick heating walls, roof and/or corbel areas in a coke oven.
Typically, coke is produced in a coke oven battery which includes a plurality of side-by-side coking chambers or ovens which are separated from each other by heating walls, the heating walls extending the full length of the chambers. The ovens are sometimes' referred to as “pushing ovens” because after the coking process, the coke is pushed in the lengthwise direction out of the ovens. A typical coke oven installation might include, for example 30 to more than 100 individual coking chambers or ovens in side-by-side relationship, with each chamber being from 3 to 7 meters high, typically 14 or more meters long, and approximately ½-1 meter wide. Each heating wall is typically built up from a number of horizontally extending courses of silica bricks, the bricks being assembled to define vertically and/or horizontally extending internal flues or vents (and other passages) within the heating walls.
In time, due primarily to the harsh thermal cycling environment, coking coal pressures or operating practices on some or all of the heating walls, roof and/or corbel areas require repair and/or reconstruction.
Currently, heating walls in coke ovens are typically repaired by replacing individual bricks in the damaged area(s). See, for example, U.S. Pat. No. 2,476,305. A more recent patent, U.S. Pat. No. 4,452,749, discloses molding individual replacement bricks from a castable refractory material. These processes, however, are very labor intensive, costly and time consuming.
There remains a need for a simpler and less costly repair process, particularly in those instances where the expected remaining useful life of the installation is between 5-20 years.
In accordance with a non-limiting exemplary embodiment, there is disclosed herein a new process for the repair or replacement (reconstruction) of damaged heating walls (and/or roof and corbel areas) in a coke oven. Specifically, that portion of a heating wall that requires repair/replacement is removed via suitable demolition procedures, with all necessary precautions taken for the safety of the workers involved. For purposes of this invention, it will be assumed that a portion of one heating wall needs reconstruction, but it will be appreciated that the repair/reconstruction process described herein is applicable to situations where entire walls, the roof (or portions thereof) and/or corbel areas need replacement. Accordingly, reference to a “refractory brick wall” is intended to encompass vertical walls as well as horizontal roof and floor (corbel) areas.
After the individual Silica bricks in the wall portion to be repaired are removed, and with suitable bracing installed as necessary, pre-engineered pre-fabricated forms are built and castable refractory material poured into the forms to form new wall sections. In the preferred arrangement, the new wall sections are built up in stages, with outer forms of about two to twelve feet in height installed along the full length of the section to be repaired. Internal, consumable forms are added to define, for example, the vertical flue vents and any other required passages. The refractory, castable material is then poured into the form and allowed to cure. Another forms stage is stacked on the first stage, and the process repeated until the new wall reaches the chamber or oven roof. Finishing procedures at the roof level will be discussed further herein.
Accordingly, in one aspect, the invention relates to a method of repairing a refractory brick wall in a furnace comprising:
(a) identifying a refractory brick wall or portion thereof that requires repair/reconstruction;
(b) demolishing the refractory brick wall or portion thereof;
(c) installing outer reusable forms in situ defining a new wall or wall portion;
(d) installing inner consumable forms defining one or more passageways within the new wall or wall portion; and
(e) pumping castable material into an area bounded by the outer forms, existing Silica brick and steelwork and around the inner forms;
(f) curing the castable material; and
(g) removing said outer forms.
(h) performing a controlled heat up of new refractory
(i) Tensioning the new wall with buckstay springs
(j) developing a schedule with plant operations of returning the oven repaired back into service
In the exemplary embodiment, steps (c) through (f) are carried out to form a first section of the new wall or portion thereof of a height less than a finished height for the new wall or portion thereof; and repeating steps (c) through (e) to form one or more additional sections, stacked one on the other, until the finished height is achieved.
In another aspect, the invention relates to a method of replacing all or a portion of a Silica brick heating wall in a coke oven, the heating wall located between a pair of adjacent ovens and containing at least one flue passage, the method comprising:
(a) demolishing the wall or portion thereof;
(b) installing outer forms defining a new wall or portion thereof in situ, between the adjacent ovens, and inner consumable forms defining at least one new flue passage within the new wall or portion thereof;
(c) pumping a refractory castable material within the outer forms and around the inner forms and allowing the material to cure;
(d) removing the outer forms; and
(e) performing a controlled heat up
(f) tensioning the new wall with buckstay springs
(g) developing a schedule with plant operations of returning the repaired ovens back into service
The exemplary embodiment will now be described in connection with the drawings identified below.
With reference initially to
In
In the plan view of
Initially, the areas to be reconstructed must be sealed off and, to this end, bulkheads 42, 44 are constructed within the adjacent chambers or ovens 16, 18, beyond the area to be repaired. The bulkheads 42, 44 are composed of bricks 46, e.g., 4.5×9×3 inch insulating (to 1800° F. or higher) clay bricks, laid up as best seen in
So-called “headache” racks (not shown) are installed prior to entering the oven chambers to provide protection from falling debris during and after demolition of the damaged wall area. These racks may comprise metal netting or similar, suspended from the roof or by other suitable means.
Optionally, insulation which may take the form of ceramic fibers blankets 48, 50 may be applied to the exposed walls of adjacent heating walls, and across the bulkheads 44, 46 (
Turning to
With this preliminary work completed, demolition can begin, with the damaged (and surrounding, to the extent desired) refractory bricks removed from the top down. At some point in the demolition process, it may be necessary or desirable to shore-up the existing, remaining portion of the heating wall being repaired. More specifically, a vertically oriented “buck stay” (I-Beam) 60 may optionally be installed remote from the existing flue 62 of the repair wall, as best seen in
As demolition continues, additional bracing may be installed as needed. After all of the damaged and surrounding wall bricks have been removed, the area is cleaned and prepared for the new wall construction. These new walls are constructed using a combination of reuseable and consumable forms similar to those used in typical concrete wall constructions.
With particular reference to
Thus, the first stage of the construction involves the placement of external wall forms 74 and 76, in combination with consumable “box” forms 78, 80 and 82 located within the confines of the outer forms to thereby define the discrete internal, vertically-oriented flue (or other) passages. It will be appreciated that within the various internal box forms, additional form work or bracing may be added as necessary to either provide support for the internal forms or to define additional sub-passages within the flues (see, for example, braces 83 in
The refractory material may be a product sold under the name FosKast FS-P available from Fosbel, Inc., of Brook Park, Ohio, USA. This is a fused, silica-based, zero expansion, pumpable, castable designed for severe service applications requiring high mechanical strength and resistance to thermal shock, with a minimum service temperature of 2800° F. (1538° C.). The material is installed in the formwork preferably by pumping into the formwork from above the respective form sections, using an industrial concrete vibrator to ensure uniformity of material while pumping. Thereafter, a second stage form construction substantially identical to that described above (or modified as needed), is stacked on top of the first stage, and the pumping process repeated. Ceramic welds are installed at the tie in joints.
This process of stacking forms and pouring/curing the refractory material is repeated until the new wall reaches substantially the height of the roof 32. This procedure is shown schematically in
In one embodiment, the formwork is brought as close as possible to the roof and then a second phase of pumping takes place to pump the roof section. In another embodiment, a portion of the roof corresponding to the repaired wall area is removed and the framework will then extend through the roof opening, with the adjacent roof sides forming a part of the formwork. In this case, the forms will be sized such that the final pour will be substantially flush with the outer surface of the roof.
The material is then allowed to cure, following the material manufacturer's recommendations. Subsequently, all remaining braces will be removed and the internal forms burned out thru a complex controlled heat up over 60 hours for dry out and curing.
It will be appreciated that there may be several different sized and shaped forms that are required to cast around various oven components.
The repair/reconstruction process described herein has many advantages over the prior practice of replacing the damaged silica bricks on an individual basis. For example, typical long lead time brick delivery delays are eliminated; the reconstruction is far less complex labor intensive; shorter heat up cycle, the process easily accommodates expanded oven walls, and existing roofs can be preserved if desired. In addition, lost production days and hence lost production costs are reduced.
It is understood that this disclosure does not describe even in general terms all of the safety precautions/procedures that may be mandated or otherwise deemed appropriate for carrying out repairs in a coke oven or similar. Such precautions/procedures are well known to those skilled in this art, and therefore need not be described herein.
As already mentioned above, the process disclosed herein is equally applicable to the oven roof (or portions thereof) and to the corbel or floor area (or portions thereof).
While the invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not to be limited to the disclosed embodiment, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.
Number | Date | Country | Kind |
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151/DEL/2008 | Jan 2008 | IN | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GB2008/003686 | 10/29/2008 | WO | 00 | 4/19/2011 |
Number | Date | Country | |
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60996104 | Nov 2007 | US |