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Title	Effect of Surface Temperature on Coal Mineral Deposition in Heat Engines
Creator	Richards, G. A.; Meyer, C.; Logan, R.; Anderson, R. J.
Publisher	Digitized by J. Willard Marriott Library, University of Utah
Date	1988
Spatial Coverage	presented at Pittsburgh, Pennsylvania
Abstract	Growing interest in the utilization of coal as a primary fuel for power-generating gas turbines has emphasized the need for further investigation of the problem of mineral ash deposition. In particular, it has been demonstrated [1] that successful operation of a coal-fired gas turbine will require some method to reduce the fraction of ash which adheres to the surfaces of the turbine blades. In a gas turbine application, the products of coal combustion will be directed through a series of stators and vanes which comprise the turbine. Referring to Figure 1, mineral ash deposits have been observed to form on the surface of the blade by particle impaction and capture on the surface of the blade. Not all of the ash particles which collide with the blade stick to form a deposit; some particles rebound and are carried away by the main flow. It has become customary [2,3] to denote the fraction of impacting particles which actually adhere as the sticking fraction, or sticking coefficient. In an effort to find a method to reduce the sticking coefficient to levels acceptable for gas turbine applications, this paper considers the effect of actively cooling the deposition surface. The results suggest that careful control of blade temperatures and combustion temperatures may be part of an effective strategy to control ash deposition.
Type	Text
Format	application/pdf
Language	eng
Rights	This material may be protected by copyright. Permission required for use in any form. For further information please contact the American Flame Research Committee.
Conversion Specifications	Original scanned with Canon EOS-1Ds Mark II, 16.7 megapixel digital camera and saved as 400 ppi uncompressed TIFF, 16 bit depth.
Scanning Technician	Cliodhna Davis
ARK	ark:/87278/s6hm5c0t
Setname	uu_afrc
ID	4894
Reference URL	https://collections.lib.utah.edu/ark:/87278/s6hm5c0t

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Title	Page 2
Format	application/pdf
OCR Text	Show COER System Design Specifications Tabl~ I. A.b Cornpo.itioD Item Te.I Section Arlc:"Tight Pilubureh '""l"V.t. A"OLUTl. '"" "'" 'LOW RATL "ttl I~?OO YUSU UNCiTH. ... 10 YUSEl OVTSIO( .. OIA"[T( . . ... WAll TMlC.N[U. ... If. lac" ~'lUI ""OCUS ""[A" (lIT ' .no n"'[ .. T""l. "t( YUSEl S.,N < '22 n .. '[IU T""l. "t( IlE .. [HTAl n .... l.ATURE '.US c ..... Iot\.,..,~"t( HEA TtHC U["[NTS ItANTMAL SVPER ~, II,. H[AT[. OVT~ . wtlll ,"OWl. IV"'l Y. Y/A EIHAVST 'lOW COM'OSITION ?,0I0 ",no OllVTl COAL ,"Oel 'tLTEJlEO EIHAUST now < 2 •• < nS"I( ,.usV.[/T( .... [RATVRE FIGURE 2. ---- U" KeYlON rank .,. ASTM ash ash comp, Wl ,. SiD, AI:O, Fe,O, TiDl P20~ C"O MeO K,O Na20 SO, bitumihou, 6.93 48.09 25.07 10.95 1.27 0.18 5.78 1.25 1.16 0.90 5.34 this study was Arkwright Pittsburgh Bituminous having properties as listed in Table 1. The coal (ground to -400 mesh) falls through the drop tube with a residence time greater than 400 ms. The products of combustion flow through a reducing nozzle ending in a 3.2 mm exit diameter. The exiting gas/ash jet is characterized by a speed of 250 m/s and impacts a perpendicular deposition target 6 mm below the nozzle exit (Figure 3). The stagnation flow configuration was designed so that all particles larger than 0.5 microns would be driven into the target surface by inertia, as would occur in a gas turbine. The target is a removable 12.7 mm platinum disk, 0.254 mm thick. Platinum was chosen as a target material because the inert reactivity was thought to make the results independent of specific surface reactions which would be peculiar to any particular blade material. COER Nozzle/Target AssefTlbly '\ \ 1~.~'.::· \ \ \ _- STREAMLINE \ \ ~ TA"-J£CT()Av (y '( ~'OP'.'oC\' FIGURE 3. \ , "- ,
Setname	uu_afrc
ID	4890
Reference URL	https://collections.lib.utah.edu/ark:/87278/s6hm5c0t/4890