Embodiments disclosed herein generally relate to sootblowers. More specifically, embodiments disclosed herein relate to an improved sootblower used to project a stream of a sootblower medium within a combustion device.
Generally when combusting fuel in large boilers, as used in electric and steam generating plants, or in recovery boilers, as used in paper and pulp mills, large quantities of particulate matter from burned fuel may quickly accumulate within the interior surfaces and tubes of the boilers. Specifically, the particulate matter, such as soot and tar, may accumulate on the heat exchanger surfaces and tubes in these boilers to significantly reduce the boilers' efficiencies. To prevent such particulate matter buildup, sootblowers may be used to provide a substantially continuous cleaning of the interior surfaces of the boilers.
Typically, sootblowers are permanently installed between adjacent rows of heat exchanger tubes within a boiler so that the sootblowers may provide regular, if not substantially continuous, cleaning without the need for the boiler to be taken out of service during the cleaning. As such, it is common for each of the large boilers and the paper mill boilers to have up to fifty or more sootblowers attached for cleaning. To maintain operating efficiency, each sootblower may be operated on a regular cycle, such as about once an hour, depending on the size of the boiler and severity of the accumulation of particulate matter.
One commonly used sootblower are long retracting sootblowers. Examples of long retracting sootblowers are shown and described in U.S. Pat. Nos. 5,675,863 and 5,745,950, which are incorporated by reference in their entirety. These sootblowers generally include a long pipe or lance having a nozzle at the end for directing a blowing medium, such as steam or another vapor, onto the surfaces of the heat exchanger tubes. An example of a lance 102 cleaning a boiler 190 is shown in
When actuated and reciprocated into and out-of the boiler, the lance generally will follow a standard helical path, as shown in
In one aspect, embodiments disclosed herein relate to a sootblower to project a blowing medium into a boiler. The sootblower includes a hub, in which a first end of the hub is configured to receive a lance and a second end of the hub is configured to receive the blowing medium. The sootblower further includes a drive assembly configured to convert bidirectional rotation from a drive shaft to bidirectional rotation for the hub. The drive assembly then includes a rotation delay mechanism configured to delay a transition between a first directional rotation and a second directional rotation of the bidirectional rotation for the hub with respect to the drive shaft when the drive shaft is transitioning from a first directional rotation to a second directional rotation of the bidirectional rotation for the hub.
In another aspect, embodiments disclosed herein relate to a drive assembly for a sootblower to project a blowing medium into a boiler. The drive assembly includes a drive shaft, a static member attached to the drive shaft, and a spur gear disposed about and configured to rotate about the drive shaft. One of the static member and the spur gear includes a pint attached thereto, and the other of the static member and the spur gear includes a slot formed therein. The pin then slidably engages the slot.
In yet another aspect, embodiments disclosed herein relate to a sootblower used to project a blowing medium. The sootblower includes a housing having a lubricant disposed therein, roller rotatably attached to the housing and configured to travel along tracks, and bearing disposed inside of the rollers. The bearings of the rollers are in fluid communication with the housing.
Other aspects and advantages of the invention will be apparent from the following description and the appended claims.
In one aspect, embodiments disclosed herein relate to an improved sootblower with a rotation delay mechanism. The rotation delay mechanism may include one member with a pin to engage or another member with a slot. In another aspect, embodiments disclosed herein relate to a drive assembly having a static member attached to a drive shaft and a spur gear disposed about the drive shaft. A pin is attached to one of the static member and the spur gear, and a slot is formed in the other of the static member and the spur gear. In yet another aspect, embodiments disclosed herein relate to a sootblower configured to have bearings of rollers in fluid communication with a housing of the sootblower, thereby allowing lubricant disposed within the housing to flow between the bearings and the rollers.
Referring to
Hub 310 may be rotationally disposed within housing 301 such that hub 310 is able to rotate with respect to housing 301. As such, when hub 310 rotates, lance 302 will accordingly rotate therewith. Further, hub 310 is configured to receive a blowing medium, such as through a feed tube 317. As shown, a valve 316 may supply the blowing medium to feed tube 317, in which the blowing medium may then be transported through hub 310 to lance 302 to exert the blowing medium through nozzle 304. In one embodiment, the blowing medium used may be steam, such as superheated steam of about 750° F. (400° C.); however, any high-pressure and/or high-temperature vapor or gas known in the art may be used.
Sootblower 300 further includes a motor 318 configured to supply power and provide rotational movement to hub 310 and translational movement to housing 301. Specifically, using a drive assembly disposed within housing 301, motor 318 rotates hub 310 and lance 302, in addition to moving housing 301 along tracks 322. In one embodiment, rollers 320 may be rotatably attached to housing 301. As shown in
Referring now to
For example, when the sootblower is translationally moving along the track towards the boiler with the lance being extended into the boiler, the motor and the hub/lance may rotate in the clockwise direction. Then, when the sootblower is translationally moving along the track away from the boiler with the lance being retracted from the boiler, the motor and the hub/lance may reverse directions to rotate in the counter-clockwise direction. Thus, bidirectional rotation from the motor is convened into bidirectional rotation for the hub and the lance attached thereto.
Further, in addition to converting the rotation from the motor to the hub 310, drive assembly 330 may be used to delay the transition between the rotational directions from the motor to hub 310. Such a delay may include temporarily stopping the hub or discontinuing to provide rotation to the hub when the motor switches directions. For example, when the motor transitions from rotating in a clockwise direction to rotating in a counter-clockwise direction, the transition of rotation of the hub/lance may have a delay from the transition of rotation of the motor. This delay between the transition of the motor and the transition of the hub/lance may thereby allow the nozzle of the lance to provide more coverage when cleaning the sootblowers, essentially allowing the nozzle to follow different helical paths when extending within and retracting from a boiler. This delay between the transition of the motor and the transition of the hub/lance is described further below.
Referring still to
Drive shaft 340, powered by the motor using, for example, worm 326 and worm gear 342, may then be used to provide translational motion for housing 301, in addition to providing rotation for hub 310. As such, to provide translational motion for housing 301, pinion gears 346 may be attached to the ends of drive shaft 340. Pinion gears 346 may be configured to engage a rack 348, as shown formed along the bottom of tracks 322. Specifically, for example, teeth of pinion gears 346 may be configured to engage teeth of rack 348 to transfer the rotation from drive shaft 340 and pinion gears 346 into translational motion for housing 301 of sootblower 300. Thus, by switching rotational directions of the motor, the translational direction of housing 301 may be controlled through drive shaft 340 with pinion gears 346 and rack 348.
Further, to provide rotation for hub 310, a rotation delay mechanism 350 is attached to drive shaft 340. Rotation delay mechanism 350 is configured to transmit rotation from drive shaft 340 to a gear train 360. As such, when rotation delay mechanism 350 is engaged and transmitting rotation from drive shaft 340 to gear train 360, rotation delay mechanism 350 will delay the transition between rotational directions from drive shaft 340 to gear train 360.
Referring still to
For example, referring briefly to
Referring again to
As shown, gear train 360 is configured to rotate hub 310, corresponding to the direction of rotation of drive shaft 340. In this embodiment, gear train 360 includes a spur gear 362 with a bevel gear 364 attached thereto. Spur gear 354 of rotation delay mechanism 350 is configured to engage spur gear 362 of gear train 360 through, for example, the engagement of teeth (not shown) formed thereon. As spur gear 354 rotate, this rotational motion is translated through spur gear 362 to rotate bevel gear 364. Bevel gear 364 is then configured to engage and rotate hub 310. Specifically, bevel gear 364 may engage a bevel gear 311 attached to and/or formed upon hub 310. As such, through engagement of teeth (not shown), for example, bevel gear 364 may rotate bevel gear 311 of hub 310.
Referring to
However, because of the inclusion of the rotation delay mechanism within the sootblower, the hub and lance may have a delay in transitioning rotational directions from the drive shaft to the hub. Thus, when retracted from the boiler, the nozzle may follow a retraction path 684, distinct and offset from extension path 682. For example, by including rotation delay mechanism 350 in sootblower 300, which includes slots 358 allowing pins 356 to rotate by about 60 degrees with respect to drive shaft axis 341, extension and retraction paths 682 and 684 may be offset by about 60 degrees from one another. As such, when the extension and retraction paths are distinct and offset, the path of the nozzle may be improved to cover more area than that of the standard helical path (shown in
Those having ordinary skill in the art will appreciate that the present disclosure is not limited to a specific arrangement for the rotation delay mechanism. For example, other arrangements of the pins and slots may be used instead. In one embodiment, rather than having the pins attached to the static member and the slots formed in the spur gear in
Further, the hub, the drive shaft, and the drive assembly may be disposed within the housing of the sootblower and submerged in a lubricant. For example, a lubricant of synthetic oil, or any other lubricant known in the art, may be disposed and sealed within the housing of the sootblower. This may be used to preserve and maintain the moving parts disposed within the housing of the sootblower. In such an embodiment, the rollers rotatably attached to the housing and bearings disposed therein may be in fluid communication with the housing. For example, referring back to
Furthermore, as also shown in
Embodiments of the present disclosure may provide for one or more of the following advantages. First, embodiments disclosed herein may provide a more efficient cleaning of boilers because of the different and varying paths used by the nozzles. Specifically, the nozzle may have an increased amount of paths to follow when cleaning boilers, thereby improving coverage when cleaning. Next, embodiments disclosed herein may provide a more economical sootblower for cleaning of boilers. For example, as shown, the sootblower described herein may only include one motor, thereby preventing cost of an additional motor. Further, embodiments disclosed herein may provide for a sootblower with an increased working life. For example, because the sootblower described herein may incorporate a balanced design, in addition to lubricant disposed therein, the working life of the sootblower may be extended by preventing unnecessary wear of parts.
While the invention has been described with respect to a limited number of embodiments, those skilled in the art, having benefit of this disclosure, will appreciate that other embodiments can be devised which do not depart from the scope of the invention as disclosed herein. Accordingly, the scope of the invention should be limited only by the attached claims.
This application claims benefit, under 35 U.S.C. § 119, of U.S. Provisional Application Ser. No. 60/911,245, filed on Apr. 11, 2007 and entitled “Sootblower Having a Rotational Delay Mechanism” in the name of W. Wayne Holden and Michael C. Holden. The disclosure of this U.S. Provisional Application is incorporated herein by reference in its entirety.
Number | Date | Country | |
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60911245 | Apr 2007 | US |