The present invention relates generally to a wall box for a retracting sootblower for sealing a cleaning port opening in the wall of a large scale boiler. More particularly, the present invention is directed to a sootblower wall box constructed to provide enhanced sealing of the wall box opening when the sootblower is in a non-operating, retracted position.
To optimize the thermal efficiency of large scale fossil fuel burning heat exchangers or boilers, it is necessary to periodically remove deposits such as soot, slag and fly ash from their interior heat exchanging surfaces. Typically, a number of cleaning device such as those known as sootblowers, are mounted to the exterior of the boiler. One type of sootblower has a lance tube which is inserted periodically into the boiler through a cleaning port located in the boiler wall. Positioned on the forward end of the lance are one or more cleaning nozzles. The nozzle discharges a pressurized cleaning medium, such as air, water steam or other solutions. The high pressure cleaning medium contacts deposits of soot, slag and fly ash and causes them to be dislodged from the internal structures of the boiler.
Conventional wall box assemblies serve a number of purposes. One purpose being to provide a support structure for the previously mentioned cleaning lances. Without a sealing wall box, during cleaning, combustion by-products would escape to the exterior of the boiler or air could enter the boiler through the gap between the cleaning lance and the cleaning port. Controlling leakage through the boiler access ports poses a number of significant design challenges. There is a requirement of sealing the opening to prevent boiler gases from leaking outside the boiler. Conversely, in many applications of negative pressure operating boilers, there is a desire not to admit fresh air in an uncontrolled manner through sootblower wall ports. Oxy-fuel boilers use a mixture of flue gas and oxygen as an oxidant instead of air, and therefore the uncontrolled introduction of air is undesirable. The wall box for a lance port must also provide a good seal against the lance tube during its operation for the reasons mentioned previously.
Some existing wall box assembly designs incorporate two pressurized air flow circuits and include a sealing air chamber and an aspirating air chamber. Both chambers are supplied with pressurized air and provide air to the wall box at a pressure greater than the internal operating pressure of the boiler. When the sootblower lance is inserted through the wall box for cleaning, positive pressure sealing air is provided to the wall box assembly. Once the cleaning lance is fully retracted, aspirating air is directed toward the interior of the heat exchanger through an annular array of ports. The orientation of the aspirating ports, along with the increased pressure of the aspirating air, restricts the outflow of combustion by-products from the cleaning port during normal operation of the boiler. Mechanical closure devices may be used to plug the wall ports between operating cycles of the sootblower.
The requirement of a wall box to have sealing airflow imposes efficiency limitations by requiring a constant source of compressed air. Purge airflow also imposes cost due to the equipment and plumbing required and gives rise to a source of system failure. It is desirable to reduce the reliance on sealing air while meeting acceptable sealing performance requirements for the wall box.
The above design objectives are achieved through providing a sootblower isolation wall box in accordance with the present invention. In the preferred embodiments, the wall box includes a clamping seal assembly having movable sealing elements which are actuated through fluid operated cylinders or other actuation devices to clamp against the lance tube in the manner similar to a drill motor or lathe chuck. In the preferred embodiments, the clamping seal assembly is used in conjunction with another seal assembly such as a labyrinth-type ring seal assembly which may be of conventional design. In operation, during the cleaning cycle, the clamping seal assembly is actuated to disengage from the lance tube which can then be moved into and out of the boiler. During the cleaning cycle, the labyrinth-type seal or other seal assembly is primarily relied upon to provide wall box sealing. Once the lance tube reaches a retracted and parked position, the clamping seal assembly is actuated to clamp against the lance tube to provide enhanced sealing. In preferred embodiments, continuous purge or sealing air flow is not required once the lance tube is in the parked position due to the high level of sealing provided by the clamping seal assembly.
Additional benefits and advantages of the present invention will become apparent to those skilled in the art to which the invention relates from the subsequent description of the preferred embodiment and the appended claims, taken in conjunction with the accompanying drawings.
With particular reference to
As best shown in
Clamping seal assembly 18 includes housing 24 in the form of an annular open-ended cup with the open end enclosed by lead-in funnel plate 26 which includes a tapered surface 27 to aid in guiding lance tube 15. Once the funnel plate 26 is affixed to housing 24, an annular internal cavity 28 is formed which provides an area for sealing airflow, as explained in more detail in the following description. Port 47 is provided to allow an external source of high pressure air to be supplied to annular internal cavity 28.
Referring particularly to
As best shown by
An additional seal assembly is preferably used in conjunction with clamping seal assembly 18, shown here and described as labyrinth seal assembly 20. Labyrinth seal assembly 20 includes an open ended cup shaped annular housing 54. End plate 56 is affixed to the open end of housing 54 to enclose and form internal annular chamber 58. Port 60 provides for a source of sealing airflow to annular chamber 58. Within housing 54 is disposed collar 62 having a number of radial holes or ports 64 for providing purge airflow. A series of stacked seal plates 66 is provided within annular chamber 58 and each has a circular inner bore having a diameter which provides a small radial clearance with the outside diameter surface of lance tube 15. Labyrinth seal assembly 20 is of generally conventional construction. By providing a multiplicity of seal plates 66, the pressure difference (and leakage) between adjacent plates can be reduced to provide for sealing leakage control in the manner of a labyrinth-type seal unit.
Operation of wall box assembly 10 will now be explained with particular reference to
When a sootblower cleaning cycle is to be performed, the fluid pressure applied to cylinders 38 is relieved, allowing the seal shoes 32 to retract to a released position under the influence of actuating cylinder springs 40, thus providing a radial clearance between the outer circumference of the lance tube 15 and seal elements 34. After the cylinder retraction occurs, the sootblower may be operated, causing lance tube 15 to be inserted inside the boiler for cleaning purposes. During the longitudinal motion of lance tube 15, labyrinth seal assembly 20 provides sealing and is supplied with seal gas flow into port 60 during the cleaning step. The seal gas may be air, but in some applications such as oxy-fuel boilers, nitrogen may be preferred. Also, in some applications, no seal gas would be supplied to labyrinth seal assembly 70 and the seal assembly would operate in a passive mode, serving to reduce the amount of flue gas leakage from the boiler. Once the lance tube 15 again reaches its retracted and parked position, withdrawn from the boiler, fluid pressure may again be applied to cylinders 38 to move the shoes 32 to the sealing position to provide the positive sealing engagement with the lance tube.
Labyrinth seal assembly 20 provides an additional benefit when used in conjunction with clamping seal assembly 18. Upon retraction of lance tube 15, seal plates 66 scrape off and clean the outside surface of lance tube 15. This action improves the service life of seal elements 34 and enables them to seal more effectively against a cleaned lance tube. For these reasons, labyrinth seal assembly 20 is best positioned closer to the cleaning port 14 than clamping seal assembly 18.
Clamping assembly housing 74 is formed by two stacked plates 76 and 78 which form annular chamber 80 which communicates with pressure port 82. Housing 74 is mounted rigidly to labyrinth seal assembly 20. Annular jaw plate 84 is trapped within annular chamber 80. Details of jaw plate 84 are best described with reference to
Now again referring to
As mentioned previously, the primary benefit of wall box assembly 70 as compared with the first embodiment, is the ability of clamping seal assembly 72 to adjust its center position to match that of the lance tube which it engages when in the sealing position. Since the labyrinth seal plates 62 form a small clearance with the outside diameter of lance tube 15, they define a center position for lance tube 15. It is desirable to allow the clamping seal assembly 72 to locate to that position rather than placing forces on the lance tube 15 which would tend to move it from its position within labyrinth seal assembly 20. If the clamping seal assembly 18 or 72 when it is clamped, forces lance tube 15 against seal plates 66, excessive wear can occur, which reduces the sealing efficiency and life span of seal assembly 20.
Many times on long travel blowers, the lance tube is intentionally off set from the center line of the wall box (deflection correction). This allows the lance tube 15 to move through a straighter arc into the boiler and is done to compensate for the weight and sagging of the lance tube. The labyrinth seal plates 66 are designed to follow the lance tube 15 and are self centering so excessive wear will not occur. If the wall box assembly 10 did not have the self centering feature, it would require custom placement on each blower to match where the natural center line of the lance tube 15 would be after deflection correction has been set.
In operation, when it is desired to actuate clamping seal assembly 72 to seal against lance tube 15, fluid pressure, preferably air, is applied to pressure port 82. The pressurized fluid flows into annular chamber 80 and surrounds jaw plate 84 in the radial clearance provided between the outside diameter of jaw plate 84 and the inside diameter of annular chamber 80. The fluid pressure enters radial bores 98 and applies fluid pressure to piston heads 96. A pressure differential across actuating pistons 94 occurs because the applied fluid pressure does not act on the radially inward surfaces of the actuating pistons 94 due to the sealing provided by rings 108 and 110. If fluid pressure of a predetermined level is applied, the spring bias forces of coil springs 102 are overcome and the seal assemblies 88 are moved to their radially inward sealing positions, clamping against lance tube 15. Wall box assembly 70 operates like assembly 10 with regard to the periodic clamping and unclamping during actuation of an associated sootblower with the clamping seal assemblies 18 and 72 being actuated to clamp against the lance tube 15 when it is in the retracted and parked position.
In the embodiment shown by
Although both sootblower isolation wall box assemblies 10 and 70 are illustrated and described used with a secondary seal in the form of labyrinth seal assembly 20, it should be understood that other forms of secondary seal assemblies may be used with clamping seal assemblies 18 and 72 and, in some applications, it may be unnecessary to provide a secondary seal assembly, and consequently the clamping seal assemblies 18 and 72 may be used by themselves.
While the above description constitutes the preferred embodiment of the present invention, it will be appreciated that the invention is susceptible to modification, variation and change without departing from the proper scope and fair meaning of the accompanying claims.
Number | Name | Date | Kind |
---|---|---|---|
3972537 | McClelland | Aug 1976 | A |
4924817 | Seelen | May 1990 | A |
5048636 | Roehrs | Sep 1991 | A |
6877712 | Wiedemann | Apr 2005 | B2 |
7814979 | Springett et al. | Oct 2010 | B2 |
20070137866 | Ravensbergen et al. | Jun 2007 | A1 |
Number | Date | Country | |
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20110061611 A1 | Mar 2011 | US |