Patent Application
20070272130
a is a side view of a smelt discharge assembly according the principles of the present invention, having a smelt spout connected to a boiler wall and a cleaning tool for dislodging hardened smelt from the smelt spout, where the cleaning tool is in a retracted position;
b is a side view of the smelt discharge assembly shown in
a is a cross-sectional view taken along line 3-3 in
b is a cross-sectional view taken along line 3-3 in
a is a cross-sectional view taken along line 4a-4a in
b is a cross-sectional view taken along line 4b-4b in
a is a cross-sectional view taken along line 5a-5a in
b is a cross-sectional view taken along line 5b-5b in
Referring now to the present invention,
The boiler 14 is a combustion device, such as a chemical recovery furnace, that drains recycled byproducts, such as molten smelt 18, from an internal volume 20 of the boiler 14 to a collection tank (not shown) via the smelt spout 12. The boiler internal volume 20 is defined by boiler side walls 22 having generally vertical steam tubes (not shown) that capture and utilize heat energy from the boiler internal volume 20 and by a generally horizontal boiler bottom wall 24 that intersects the boiler side wall 22 adjacent to a point where the smelt spout 12 is mounted so that the molten smelt 18 is able to flow into the smelt spout 12. The smelt spout 12 is secured to the boiler 14 by a mounting plate 26 and is in fluid connection with the boiler internal volume 20 via an outlet port 28 formed in the boiler side wall 22.
The smelt spout 12 includes a collar 30 extending through the outlet port 28 and a trough 32 connected to the collar 30 and extending away therefrom towards the collection tank. The collar 30 preferably has an annular ring shape and is fluidly connected to the boiler internal volume 20 to minimize potential damage from smelt splashing or overflow to the following: the boiler side wall outlet port 28, another other nearby component, or a nearby worker. More specifically, the collar 30 preferably defines a generally oval-shaped passageway 34 (as best shown in
The trough 32 of the smelt spout extends away from the collar 30 at a downward slope so that gravitational forces cause the molten smelt 18 to flow towards the collection tank. Unlike the collar 30, the trough 32 is preferably open along the top thereof so that the molten smelt 18 is accessible while flowing through the smelt spout 12. This configuration is particularly advantageous for cleaning the trough 32, as will be discussed further below. The trough 32 preferably has a U-shaped cross section defined by a pair of side walls 36, 38 and a bottom wall 40 so that the opening along the top of the smelt spout 12 is at least as wide as the widest portion of the trough 32 to further improve access to the molten smelt 18. Although the smelt spout 12 shown in the figures is a single, unitary component, it may be formed from several components that are fastened together or unitarily formed with each other.
When the molten smelt 18 exits the internal volume 20 of the boiler 14 and is exposed to ambient air, the molten smelt 18 cools and may become hardened. For example, hardened deposits 42 (as best shown in
Although it is desirable to maintain the molten smelt 18 at a relatively high temperature within the smelt spout 12 to minimize the formation of the hardened deposits 42, it is also undesirable for the smelt spout 12 to become overheated. Therefore, a water jacket 44 is present within the smelt spout 12 to maintain a desired internal temperature. The water jacket 44 shown in the figures includes an inlet 46 near the top of the smelt spout 12, an outlet 48 near the lower end of the smelt spout 12, and a network of cooling ducts 50 (best shown in
As mentioned above, the cleaning tool 16 is connected to the smelt spout 12 for dislodging hardened smelt from the smelt spout 12. The cleaning tool 16 is movably coupled with the smelt spout 12 via a support assembly, such as the hood 52, that is connected to the smelt spout 12, as will be discussed in more detail below. As best shown in
The blades 54, 56 are relatively large sheets that each are aligned with respective side walls 36, 38 of the smelt spout trough 32 and extend therealong. More specifically, the blades 54, 56 are each aligned with respective side walls 36, 38 of the smelt spout trough 32 so as to slide along the side walls 36, 38 when the cleaning tool is moved into the extended position 16b. Additionally, the blades 54, 56 are each preferably relatively large, planar blades made from sheet metal. The blades 54, 56 are coupled with each other via one or more bridge portions 60 (
The blades 54, 56 each have a cleaning edge 62, 64 for dislodging the hardened deposits 42 from the respective side walls 36, 38 of the trough 32. More specifically, the cleaning edges 62, 64 are designed to shear the hardened deposits 42 from the side walls 36, 38 so that the hardened deposits 42 are permitted to flow with the molten smelt 18 down the trough 32. The cleaning edges 62, 64 are preferably formed from a hardened metal that is capable of maintaining its properties throughout frequent exposure to molten materials. Additionally, although the cleaning edges 62, 64 shown in the figures are generally square edges, they may alternatively have a tapered shape or any other suitable design.
The cleaning edges 62, 64 of the blades 54, 56 each preferably extend substantially completely along a length 72 of the smelt spout 12 so that the hardened deposits 42 can be removed in a single stroke of the cleaning tool 16, thereby reducing the time required to clean the smelt spout 12. More specifically, the cleaning edges 62, 64 each preferably extend substantially completely along a flow path 73 of the molten smelt 18 between the boiler 14 and the collection tank.
As best shown in
Referring back to
Similarly to the blades 54, 56, the punch 58 includes a cleaning edge 66 designed to shear the hardened deposits 42 from the walls of the collar 30 so that the hardened deposits 42 flow with the molten smelt 18 along the smelt spout 12 and into the collection tank. The cleaning edge 66 is therefore preferably formed from a hardened metal that is capable of maintaining its properties throughout frequent exposure to molten materials. The cleaning edge 66 may have any suitable shape such as a tapered or a squared design.
As mentioned above, the cleaning tool 16 is movable from the retracted position 16a (shown in
As also mentioned above, the hood 52 movably couples the cleaning tool 16 with the smelt spout 12 so that the cleaning tool 16 is movable between the retracted position 16a and the extended position 16b. The hood 52 includes a pair of side walls 80, 82 that are each connected to the respective sides of the trough 32 and that each extend generally parallel to the blades 54, 56 so that the outboard side or each blade 54, 56 engages the inboard side of the respective side wall 80, 82. More specifically, each of the side walls 80, 82 have a horizontal connection flange 88, 90 extending along the length thereof and each side wall 36, 38 of the trough 32 has a corresponding connecting flange 84, 86 extending along the length thereof. The respective sets of connection flanges 84, 88 and 86, 90 are connected with each other via appropriate connection means such as fasteners, clamps, or welding.
A safety wall may connect the hood side walls 80, 82 along a top 85 and/or a back 87 of the hood 52. The safety wall provides stability to the hood 52 and/or provides protection against smelt splashing and/or accidental access to the smelt spout 12. The safety wall may be movably connected to the hood 52 so as to permit selective access to the smelt spout 12 for inspection, maintenance, or manual smelt rodding. For example, the top 85 and/or the back 87 of the hood 52 may include a removable safety wall, a pivoting safety wall, or another suitable design granting temporary access to the smelt spout 12. If the safety wall completely encloses the cleaning tool 16, it may be beneficial to provide a video camera or another surveillance device to monitor the buildup of hardened smelt 42. Alternatively, a control mechanism may be utilized to automatically actuate the cleaning tool 16 every desired time period. Alternatively, it may be advantageous to leave the back 87 of the hood 52 open to provide manual access to the smelt spout when the assembly 10 is in use.
The hood 52 also includes a plurality of connection assemblies 92, 94, 96, 98 that slidably couple the cleaning tool 16 to the hood 52. More specifically, each of the connection assemblies 92, 94, 96, 98 includes a pair of base mounts 100, 102 that are connected to the side walls of the hood 52 and that support a rod 104 extending therebetween and a sleeve mount 106 that is connected to the blades of the cleaning tool 16 through a slot 108 in the side walls 80, 82 and that slidably receives the rod 104. Alternatively, the cleaning tool 16 may be movably coupled to the hood 52 by an integral portion of the hood 52.
The base mounts 100, 102 are each preferably metal blocks that are connected to the outboard sides of the side walls 80, 82 of the hood 52 and that have indentations or channels formed therein for receiving the respective rods 104. The base mounts 100, 102 serve to provide a stable connection between the cleaning tool 16 and the hood 52 and to limit the distance that the cleaning tool 16 can travel, as will be discussed in further detail below.
The sleeve mount 106 is preferably a cylindrical shaped sleeve that has an inner surface corresponding to the outer diameter of the rod 104 and an outer surface that is connected to one of the blades 54, 56 via a connecting arm (not shown) that extends through the slot 108. The sleeve mount 106 has a longitudinal length that is sufficient to prevent binding between the sleeve mount 106 and the rod 104. Similarly, the inner surface of the sleeve mount 106 and the outer surface of the rod 104 each preferably have relatively low coefficients of friction to prevent binding.
The slots 108 each at least extend substantially completely between the respective base mounts 100, 102 to permit travel of the sleeve mount therebetween. However, the design shown in the figures have slots 108 extending from the far base mount 100 to the edge of the side walls 80, 82 so that the blades 54, 56 can be easily removed from the hood 52 during assembly and maintenance, by removing the base mounts 100, 102 and sliding the sleeve mounts 106 along the slots 108.
The respective slots 108 and the rods 104 are preferably parallel with each other so that the sleeve mounts 106 all move in unison with each other along the same path. Therefore, the cleaning tool 16 moves along a cleaning path 110 between the retracted position 16a and the extended position 16b. The cleaning path 110 is preferably nonparallel to the flow path 73 so that the hardened deposits 42 are quickly sheared from the trough rather than being dragged therealong in a drawn-out motion. This configuration minimizes the time required to perform the cleaning operation.
The cleaning path 110 cooperates with the molten smelt flow path 73 to define a cleaning angle 112 between the cleaning path 110 and a normal line 113 that is generally perpendicular to the molten smelt flow path 73. To increase the effectiveness of the cleaning tool 16, the cleaning angle 112 is preferably less than or equal to 60 degrees. More preferably, cleaning angle 112 is preferably between less than or equal to 45 degrees. The cleaning path 110 is also preferably generally parallel with the upper surface of the collar 30 so that the outer surface of the punch 58 slides along the inner surface of the collar 30 when the cleaning tool 16 moves between the respective positions 16a, 16b. the cleaning path 110 shown in the figures is linear, but the cleaning tool 16 may travel along any other suitable path, such as an arcuate cleaning path.
When the cleaning tool 16 moves from the retracted position 16a to the extended position 16b, the cleaning tool 16 moves in a cleaning direction 114 that is generally downward towards the trough bottom wall 40. This configuration is desirable because the hardened deposits 42 are driven into the molten smelt 18 rather than being dragged along the top surface of the smelt flow or being lifted out of the smelt flow. For example, as the cleaning tool 16 moves downward toward the extended position 16b, the hardened deposits 42 are forced into the molten smelt 18 and are able to flow along the trough 32. The hardened deposits 42 forced into the molten smelt 18 may become molten, thereby improving the flow along the smelt spout 12. Also, the downward cleaning direction 114 minimizes smelt splash and/or overflow.
The side walls 36, 38 of the trough 32 are generally arcuate. Furthermore, the blades 54, 56 are positioned flat against the hood side walls 80, 82 so as to minimize lateral movement of the blades 54, 56. Therefore, as the cleaning tool 16 moves from the retracted position 16a to the extended position 16b, the cleaning edges 62, 64 remain engaged with the side walls 36, 38 of the trough 32, thereby deflecting inward toward each other. This configuration maximizes the scraping force on the side walls 36, 38 for removing the hardened deposits 42. Although the blades 54, 56 may bend in a generally linear fashion so as to form gaps 37, the gaps 37 are relatively small so that the effective width 77 of the trough 32 is not substantially diminished. Alternatively, the blades 54, 56 may each have a blade stiffness suitable to substantially prevent inward deflection of the blades 54, 56 when the cleaning tool is in the extended position 16b such as to remove hardened deposits 42 without deflecting.
Additionally, the arcuate side walls 36, 38 generally prevent the blades from reaching the bottom wall 40 of the trough, thereby preventing unnecessary wear to a component of the trough that does not regularly have hardened deposits 42 formed thereon and thereby minimizing the likelihood of damage to the water jacket 44. Additionally, the base mounts 100, 102 are positioned such that the sleeve mount 106 abuts the lower base mount 100 when the cleaning edges 62, 64, 66 are at a desired level in the smelt spout 12, thereby also preventing the cleaning tool 16 from contacting the smelt spout bottom walls 40. For example, as best shown in
The smelt discharge assembly 10 further includes an actuating mechanism, such as a linear actuator in the form of a piston assembly 116 coupled with the hood 52 and the cleaning tool 16 so as to actuate the cleaning tool 16 from the retracted position 16a to the extended 16b position. The piston assembly 116 shown in the figures includes a piston body 118 attached to the hood 52 and a piston arm 120 slidably received within the piston body 118 that is attached to the cleaning tool 16. Also, the piston assembly includes a power source 122, such as a hydraulic or pneumatic hose that actuates the piston arm 120. Alternatively, the actuating mechanism may include screw drive mechanism or another suitable device for controlling the position of the cleaning tool 16.
It is therefore intended that the foregoing detailed description be regarded as illustrative rather than limiting, and that it be understood that it is the following claims, including all equivalents, that are intending to define the spirit and scope of this invention. More particularly, the apparatus and assembly described are merely an exemplary apparatus and assembly, and they are not intended to be limiting. Many of the steps and devices for performing the steps described above may be eliminated or replaced by alternative steps and devices.
