This patent is directed to a conveyor for and a method of conveying heated material, and, in particular, to a vibratory conveyor for and method of conveying heated material, such as hot ash, for example.
In one aspect, a conveyor includes a frame, a trough supported on the frame, and a vibratory generator operatively coupled to the trough. The trough has a trough wall with a first plurality of apertures in the trough wall, and a plurality of baffles are spaced above the first plurality of apertures in the trough wall, the baffles defining a second plurality of apertures through which air exiting the first plurality of apertures may pass.
In another aspect, a conveyor system includes a frame, a trough assembly supported on the frame, and a vibratory generator operatively coupled to the trough. The trough assembly includes a plurality of trough assembly segments, each trough assembly segment including a trough segment having a trough wall and a plenum disposed beneath the trough wall. The trough wall of each trough segment has a first plurality of apertures through which air exiting the plenum may pass, and a plurality of baffles are spaced above the apertures in the trough wall of each trough segment, the baffles attached to the trough wall and defining a second plurality of apertures through which air exiting the first plurality of apertures may pass.
In an additional aspect, a method of conveying a heated material includes receiving heated material in a trough and vibrating the trough to direct material along the trough. The method also includes directing air through passages in the trough in a first direction, and diverting air that has passed through the passages in a second direction along a surface of the trough.
Additional aspects of the disclosure are defined by the claims of this patent.
Although the following text sets forth a detailed description of different embodiments of the invention, it should be understood that the legal scope of the invention is defined by the words of the claims set forth at the end of this patent. The detailed description is to be construed as exemplary only and does not describe every possible embodiment of the invention since describing every possible embodiment would be impractical, if not impossible. Numerous alternative embodiments could be implemented, using either current technology or technology developed after the filing date of this patent, which would still fall within the scope of the claims defining the invention.
It should also be understood that, unless a term is expressly defined in this patent using the sentence “As used herein, the term ‘—————’ is hereby defined to mean . . . ” or a similar sentence, there is no intent to limit the meaning of that term, either expressly or by implication, beyond its plain or ordinary meaning, and such term should not be interpreted to be limited in scope based on any statement made in any section of this patent (other than the language of the claims). To the extent that any term recited in the claims at the end of this patent is referred to in this patent in a manner consistent with a single meaning, that is done for sake of clarity only so as to not confuse the reader, and it is not intended that such claim term be limited, by implication or otherwise, to that single meaning. Finally, unless a claim element is defined by reciting the word “means” and a function without the recital of any structure, it is not intended that the scope of any claim element be interpreted based on the application of 35 U.S.C. §112, sixth paragraph.
As illustrated, the system 20 may be used in conjunction with a transition hopper 26 to facilitate the movement of heated material into the conveyor 22. The inner surface of the hopper 26 may be lined with refractory bricks to improve resistance to high temperatures.
The transition hopper 26 may have sloped ends 28, 30 (
As illustrated, the hopper 26 is supported independently from the conveyor 22. However, a seal assembly 60 (
Turning to
Turning first to the trough assembly 80, with reference to
As shown in
As shown in
As also shown in
It will be recognized, however, that while the baffles 174 are defined by an L-shaped plate as illustrated, other shapes are possible for the baffles 174. Moreover, while the apertures 176 are disposed on a single side of the baffles 174, the apertures 176 may be disposed on both sides of the baffles 174, if desired. Furthermore, while the apertures 176 direct the air flow along a section of the upper surface 178 of the trough segment 92, the air flow may be directed in another pattern entirely. The embodiment illustrated is thus one exemplary embodiment.
Returning then to
To join the trough segments 92 together, a series of butt joints 200 may be formed, as illustrated in
Each butt joint 200 may include an inner band 202 and an outer band 204. The inner band 202 may be connected to the outer band 204 by a fastener set 206, as illustrated. In particular, the fastener set 206 includes a bolt 208, which has a head 210 that is received in a countersunk aperture 212 formed in the inner band 202, and a nut 214, which may be threadably connected to the shaft 216 of the bolt 208. An edge 218 of an upstream trough segment 92a may be disposed between the first ends 220, 222 of the inner and outer bands 202, 204, and an edge 224 of a downstream trough segment 92b may be disposed between the second ends 226, 228 of the inner and outer bands 202, 204. The fastener set 206 may then be tightened to grip the edges 218, 224 between the inner and outer bands 202, 204. The space 230 between the edges 218, 224 may allow relative motion between adjacent trough segments 92a, 92b caused by differences in thermal expansion.
Disposed within the space 230 may be spacer 236, such as may be formed of key stock. This spacer 236 may have a width that is slightly less than that of segments 92a, 92b. By placing the spacer 236 in the space 230, it is believed that the deflection and/or dishing of the inner and outer bands 202, 204 into the space 230 may be limited. By limiting the deflection and/or dishing of the inner and outer bands 202, 204, the relative thermal expansion of the segments 92a, 94b along the longitudinal axis of the trough may be facilitated.
Also of note relative to the butt joint 200, as illustrated, is the angled edge 240 of the inner band 202 at the first end 220. It is believed that the angled edge 240 of the inner band 202 may permit material flowing along the length of the conveyor to make a smoother transition from an upstream trough segment 92a to a downstream trough segment 92b. Alternatively, the butt joint 200 may be formed without the angled edge 240.
As mentioned previously, the trough assembly 80 is supported on a wheeled frame 82. As seen in
As seen in
As also is visible in
Coupled between the trough assembly 80 and the counterbalance 282 is the vibratory generator 84, as seen in
Additionally, as illustrated in
Having thus described the conveyor 22, the conveyor 24 may be described as similar to the conveyor 22, except that the conveyor 24 is not mounted on wheels so as to be moveable. Instead, the frame of the conveyor 24 is attached to the floor. As seen in
Associated with the conveyor system 20 and illustrated in
The air supply and control system 350 may include a fan or blower 352, an inlet filter 354, the afore-mentioned conduit 154 (which connects to the plenum 156 of various trough assembly segments 90), and an adjustable damper 356 disposed between the blower 352 and the conduit 154. The system 350 may also include a controller 358, which controller 358 may be operatively coupled to a temperature sensor 360 and an actuator 362 operatively coupled to the damper 356, as well as other sensors or equipment 364. In response to signals returned to the controller 358 from the sensor 360, the controller 358 may send a signal to the actuator 362 to move the damper 356 to vary the air flowing through the conduit 154 into the plenum 156. It will be recognized, that a plurality of sensors 360 and a plurality of dampers 356 (with associated actuators 362) may be included so as to provide a more focused and localized response to variations along the conveyor 22, 24.
It will be recognized that the system 350 discussed above is only one possible system 350 that may be used. Alternatives are possible. For example, the fan 352 may be equipped with a variable frequency drive (VFD) so as to permit the speed of the fan to be controlled. With such a VFD-equipped fan, the speed of the fan may be controlled to control the flow of the air in conjunction with or in substitution for control via the damper 356. Moreover, rather than a single controller 358 operating in a closed loop with a temperature sensor 360, a programmable logic controller (PLC) may be used to permit other control algorithms to be implemented.
Thus, according to one method of operation, heated material may be received in the hopper 26. When the doors 36, 38 are selectively move from their closed position 36a, 38a to their open position 36b, 38b (or some position therebetween), the heated material may be received in the conveyor 22, and in particular the trough. The material may be directed along the conveyor 22 in accordance with the vibrations provided by the vibratory generator 84. The frequency of the motor associated with the vibratory generator 84 may be used to control, for example, the speed of translation of the material along the conveyor 22.
As the material moves along the conveyor 22, and in particular along the trough segments 92, air may be blown onto, and, according to the consistency of the heated material, through, the heated material. In particular, in accordance with the signals provided by the temperature sensor 360, the controller 358 may vary the position of the damper 356 (through control of the associated actuator 362) to provide a certain flow of air into the plenum 156 associated with the various segments 90 of the conveyor 22. Air passing through the conduit 154 and entering the plenum 156 passes through the apertures 170, 176 so as to be directed onto the heated material moving along the conveyor 22. When the material reaches the downstream end 330 of the conveyor 22, the material passes through the chute 332.
The operation of the conveyor 24 is similar to that of the conveyor 22: as the material passes along the conveyor 24, air flowing from the plenum 156 of the segments 90 passes through the apertures 170, 176 and is directed onto the heated material. When the material reaches the downstream end 334 of the conveyor 24, it passes through the chute 336.
The above-described conveyor system 32 and method conveying heated material may be particularly advantageous for use in hot ash recovery, and in particular dry hot ash recovery.
Ash (also referred to as bottom ash) produced by coal-fired boilers can be beneficially used in a variety of construction and manufacturing applications, including as structural and engineering fill, cement raw material, aggregate for concrete and asphalt products and general reclamation purposes. A utility-sized, coal-fired boiler can produce large volumes of this ash. However, standard methods of ash recovery involve the use of water as a cooling fluid for the hot ash. The use of water for cooling purposes results creates operational and maintenance difficulties and inefficiencies, including the issues associated with drying the wet ash out once it is cooled so that it may be used in the afore-mentioned construction and manufacturing applications.
Use of the conveyor and conveying system according to the present disclosure may provide a way to avoid the difficulties and inefficiencies of the prior wet ash recovery methods. A coal-fired boiler plant may be equipped with one or more transition hoppers 26. These hoppers 26 may be sealed to the bottom of the boilers using a dry-type or water-impounded seal. The hoppers 26 may be independently supported from the boiler.
One or more conveyors 22 may be disposed beneath the hoppers 26 to receive the hot ash contained therein. The hot ash material moves forward by “throws and catches” from one point to the next because of the action of the vibratory generator 84, which motion also may minimize the sliding abrasion on the conveyor 22. It is believed that as air enters the trough through the apertures 170, 176, it passes over the trough surface and through the hot ash as the ash continues its motion along the hopper 26. It is further believed that this intimate, direct contact between the air and the ash as the air moves through the ash bed minimizes the amount of cooling air required for a specific ash temperature drop. It is also believed that the velocity of the air flow over the trough surface may be controlled so that it is not so fast as to fluidize the ash bed, thus permitting conveyance of the ash up an incline. It is also thought that one advantage of using air, rather than water, as the cooling fluid is that combustion of unburnt carbon pieces in the hot ash may continue, thus potentially improving overall heat recovery and boiler efficiency.
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Number | Date | Country | |
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20070108023 A1 | May 2007 | US |