A sootblower for cleaning a plurality of surfaces within an interior volume of a combustion device is provided. The sootblower includes a combustion assembly configured to generate a pressure wave and a delivery assembly having an outlet for delivering the pressure wave into the interior volume of t
A sootblower for cleaning a plurality of surfaces within an interior volume of a combustion device is provided. The sootblower includes a combustion assembly configured to generate a pressure wave and a delivery assembly having an outlet for delivering the pressure wave into the interior volume of the combustion device.
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The invention claimed is: 1. A sootblower for cleaning a plurality of surfaces within an interior volume of a combustion device, the sootblower comprising: a combustion assembly configured to generate a pressure wave; a delivery assembly defining a pressure wave path extending in a substantially li
The invention claimed is: 1. A sootblower for cleaning a plurality of surfaces within an interior volume of a combustion device, the sootblower comprising: a combustion assembly configured to generate a pressure wave; a delivery assembly defining a pressure wave path extending in a substantially linear direction between the combustion assembly and an outlet portion of the delivery assembly; and a translating assembly configured to translate the delivery assembly in a forward direction, from a resting position to an operational position, along a translation path generally parallel to the pressure wave path to selectively position the outlet portion of the delivery assembly within the interior volume of the combustion device and deliver the pressure wave along the pressure wave path, in the forward direction, into the volume of the combustion device and remove deposits from the surfaces of the combustion device. 2. A sootblower as in claim 1, wherein the outlet portion includes a generally non-linear portion to guide the pressure wave towards the surfaces of the combustion device. 3. A sootblower as in claim 2, wherein the non-linear portion is a divergent section to emit the pressure wave in a direction substantially perpendicular to the pressure wave path. 4. A sootblower as in claim 3, wherein the outlet portion includes a pair of diametrically opposed nozzles. 5. A sootblower as in claim 4, wherein the nozzles are separated by a divider such that the pressure wave exits each of the nozzles with a generally equal intensity. 6. A sootblower as in claim 4, wherein the delivery assembly includes a lance tube and the outlet portion includes a pair of diametrically opposed slots formed in a distal end of the lance tube. 7. A sootblower as in claim 1, wherein the outlet portion is configured to emit the pressure wave in a direction substantially parallel with the pressure wave path. 8. A sootblower as in claim 7, wherein the outlet portion includes a generally linear profile. 9. A sootblower as in claim 1, wherein the outlet portion is configured to rotate with respect to the surfaces of the combustion device to control a projection of the pressure wave. 10. A sootblower as in claim 1, wherein the combustion assembly is configured to generate the pressure wave via a detonation combustion event. 11. A sootblower as in claim 1, wherein the combustion assembly is configured to generate the pressure wave via a deflagration combustion event. 12. A sootblower as in claim 1, wherein the delivery assembly includes at least one obstruction extending an obstruction length along the fuel/oxidizer flow path, downstream of ignition chamber, to increase the velocity of the combustion flame, wherein the at least one obstruction defines an obstruction diameter and the obstruction length is at least 10 times greater than the obstruction diameter. 13. A sootblower as in claim 12, wherein the at least one obstruction is a generally spiral-shaped ridge extending from a wall of the delivery assembly. 14. A sootblower as in claim 12, wherein the at least one obstruction is integrally formed with a wall of the delivery assembly. 15. A sootblower as in claim 1, wherein the combustion assembly includes an ignition chamber configured to receive fuel and an oxidizer, an obstruction to increase turbulence within the ignition chamber and to promote mixing of the fuel and the oxidizer, and an ignition element configured to ignite the fuel. 16. A sootblower as in claim 15, wherein the ignition chamber defines an ignition chamber diameter, the delivery assembly defines a delivery assembly diameter, and a ratio of the ignition chamber diameter to the delivery assembly diameter is between 1 and 3. 17. A sootblower as in claim 15, wherein the ignition chamber defines an ignition chamber axial length and a ratio of the ignition chamber axial length to the ignition chamber diameter is between 1 and 4. 18. A sootblower as in claim 1, wherein the combustion assembly is configured to generate repeated pressure waves. 19. A sootblower as in claim 1, further comprising an injection block coupled with the combustion assembly, wherein the injection block includes an intake valve to deliver a fluid to the combustion assembly and an exhaust valve to purge the combustion assembly, wherein the intake valve and the exhaust valve are both mechanically driven. 20. A sootblower for cleaning a plurality of surfaces within an interior volume of a combustion device, the sootblower comprising: a combustion assembly configured to generate a pressure wave; a delivery assembly coupled to the combustion assembly and configured to deliver the pressure wave to the interior volume and remove deposits from the surfaces of the combustion device; and a combustion detection assembly coupled to the delivery assembly and including a temperature sensor directly connected to the delivery assembly to measure a sootblower temperature for detecting an unsuccessful detonation event. 21. A sootblower as in claim 20, further comprising a controller electrically connected with the temperature sensor and configured to control the combustion assembly based on a gradient of the sootblower temperature. 22. A sootblower as in claim 20, wherein the combustion assembly is configured to generate repeated pressure waves. 23. A sootblower for cleaning a plurality of surfaces within an interior volume of a combustion device, the sootblower comprising: a combustion assembly configured to generate a pressure wave; and a delivery assembly defining a pressure wave path extending between the combustion assembly and an outlet portion of the delivery assembly, wherein the delivery assembly includes a first section and a second section slidably received within the first section to define an overlapping portion having an adjustable overlapping length wherein the second section is a feed tube and the first section is a lance tube configured to rotate with respect to the feed tube, wherein the delivery assembly is configured to deliver the pressure wave from the outlet portion to the interior volume to remove deposits from the surfaces of the combustion device, wherein the pressure wave path has an adjustable length, and wherein the first section is movable between a first position second section and wherein a portion of the first section is positioned within the interior volume when the first section is in the second position. 24. A sootblower as in claim 23, wherein the delivery assembly is able to deliver the pressure wave from the outlet portion at various lengths of the adjustable length. 25. A sootblower as in claim 23, further comprising a seal assembly connected with the first section and the second section to define a pressure chamber having a seal pressure that is greater than an operating pressure within the delivery assembly to prevent gas from leaking through the seal assembly. 26. A method of cleaning a plurality of surfaces within an interior volume of a combustion device with a sootblower having a combustion assembly and a delivery assembly, the method comprising: generating a pressure wave within the combustion assembly; translating the delivery assembly along a delivery assembly path extending into the interior volume of the combustion device; and delivering the pressure wave, along a pressure wave path between the combustion assembly and an outlet portion of the delivery assembly, to the interior volume of the combustion device to remove deposits from the surfaces of the combustion device while translating the delivery assembly along the delivery assembly path, wherein the pressure wave path and the delivery assembly path are generally parallel with each other. 27. A method of cleaning as in claim 26, further comprising rotating a portion the delivery assembly to control a direction of the pressure wave within the combustion assembly. 28. A method of cleaning as in claim 26, further comprising measuring a sootblower temperature of at least one of the combustion assembly and the delivery assembly. 29. A method of cleaning as in claim 26, further comprising controlling the combustion assembly based on detecting a threshold pressure measured by a pressure signal. 30. A method of cleaning as in claim 26, further comprising generating a plurality of repeated pressure waves within the combustion assembly. 31. A method of cleaning as in claim 26, further comprising controlling a fuel/oxidant fill length to adjust an intensity of the pressure wave.
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