This invention relates to a pulveriser mill for crushing or grinding raw material, for e.g. fossil fuels, into fine particles suitable for combustion in a fossil fuel furnace. In particular, the invention relates to a rotatable throat or port ring of the mill which is provided around a periphery of a rotary grinding member of the mill.
A pulveriser mill has a rotary grinding table or yoke, known as a grinding ring, which in most applications is positioned below a stationary upper ring, known as a top ring. The grinding ring is configured to rotate about a vertical rotation axis whilst the top ring remains stationary. A number of grinding elements in the form of steel balls is provided between the top ring and the grinding ring in order to crush raw material fed into the mill in gyratory fashion. That said, the grinding elements may be fixed or may be free to precess. A passage or air port is provided between an outer periphery of the grinding ring and an inner surface of the housing of the mill. Air sweeps upward through the air port and transports fines (crushed raw material) to a classifier provided above the top ring.
A port ring or rotatable throat is provided in the passage and is mounted around the outer periphery of the grinding ring such that it is co-rotatable therewith. The throat includes a plurality of inclined, planar vanes which project radially outwardly and are angularly spaced apart such that openings are defined between the vanes to allow air to flow from below the grinding ring to above the grinding ring.
In conventional pulveriser mills, as air passes through the throat from a plenum chamber below the grinding ring, it undergoes rapid acceleration as well as a change in direction which creates a large pressure shock which is undesirable and gives rise to an increased pressure drop across the mill. As a result of an increased pressure drop, the mill consumes more energy which leads to a reduction in efficiency as well as a reduction in mill throughput.
The Applicant desires a pulveriser mill which at least alleviates the above drawbacks.
In accordance with the invention, there is provided a pulveriser mill which includes a rotary grinding member and a port ring which is arranged around a periphery of the rotary grinding member for rotation with the rotary grinding member about an axis, the port ring including a plurality of vanes which are angularly spaced about the axis in a configuration which allows air to flow from below the port ring to above the port ring, at least one of the vanes having an operatively upstream portion and a downstream portion and a non-planar leading surface which extends between the upstream portion and the downstream portion.
The non-planar leading surface may be curved. More particularly, the leading surface may have a concave curvature. Alternatively, the leading surface may have a convex curvature. In a different embodiment, the leading surface may have a serpentine or undulating curvature.
The vane may be inclined relative to the vertical and the upstream portion may have an upstream end and the downstream portion may have a downstream end, the non-planar leading surface extending between the upstream end and the downstream end.
A line tangential to the leading surface drawn from one of the upstream end or the downstream end may not pass through the other end when the vane is viewed radially. A line tangential to the leading surface drawn from the upstream end may form a first angle relative to the vertical which is greater than a second angle formed between a line tangential to the leading surface drawn from the downstream end and the vertical, when the vane is viewed radially. Therefore, a straight line projection of the upstream end is staggered relative to a straight line projection of the downstream end when the vane is viewed radially.
At least one of the vanes may have a curved cross-sectional profile when viewed radially. The vanes may be arcuately curved when viewed radially.
At least one of the vanes may have a cross-sectional profile which diverges, when viewed radially, from the upstream portion to the downstream portion.
The port ring may define a plurality of openings between the vanes, the ring having an upstream inlet which is defined in part by upstream ends of adjacent vanes and a downstream outlet defined in part by downstream ends of adjacent vanes such that the openings between adjacent vanes converge or decrease in area from the inlet to the outlet. Alternatively, each vane may have a teardrop or aerofoil cross-sectional profile when viewed radially. A leading surface of each vane extending between an upstream portion and a downstream portion may be inclined with respect to the vertical and may have a curved cross-sectional profile when viewed radially.
Each vane may have a triangular cross-sectional profile when viewed radially. Furthermore, each vane may be a composite vane comprising a first leading member, a second trailing member diverging from the leading member in a downstream direction at an upstream end of the vane and a third downstream member extending circumferentially between the leading member and the trailing member. The vanes may have a non-uniform radial width in the axial direction.
Each vane may be inclined with respect to the vertical and may have an upstream end and a downstream end, a radial width of the upstream end being greater than a radial width of the downstream end.
At least one side of the vane may be slanted when the vane is viewed face on. Furthermore, opposing sides of the vane may converge toward the downstream end when the vane is viewed face on such that the vane tapers from the upstream end to the downstream end.
The invention extends to a method of modifying a pulveriser mill which includes a rotary grinding member and a port ring arranged around a periphery of the rotary grinding member for rotation with the rotary grinding member about an axis, the port ring including a plurality of inclined planar vanes, the method including replacing the port ring with a port ring including a plurality of vanes which are angularly spaced about the axis in a configuration which allows air to flow from below the port ring to above the port ring, wherein at least one of the vanes has an operatively upstream portion and a downstream portion and a non-planar leading surface which extends between the upstream portion and the downstream portion.
According to yet another aspect of the invention, there is provided a pulveriser mill including a rotary grinding member and a port ring which is arranged around a periphery of the rotary grinding member for rotation with the rotary grinding member about an axis, the port ring including a plurality of vanes which are angularly spaced about the axis in a configuration which allows air to flow from below the port ring to above the port ring, at least one of the vanes having a cross-sectional profile which diverges, when viewed radially, from an upstream portion to a downstream portion.
The invention will now be further described, by way of example, with reference to the accompanying diagrammatic drawings.
In the drawings:
The operation of vertical pulveriser mills is well known to those skilled in the art and will therefore not be expounded upon in the description that follows. In
The throat 10 comprises a rotor 12 which includes a plurality of segments (not illustrated) which are attached to the grinding ring for rotation therewith and are interconnected at angularly spaced positions around the periphery of the grinding ring. The throat 10 further includes a stator 14 which is attached to the inner wall of the housing of the pulveriser mill.
The rotor 12 comprises an inner ring 13 which includes a plurality of angularly spaced apart mounting formations 15 for attaching the inner ring 13 to the grinding ring of the mill. The inner ring 13 comprises an annular, upright lower section 13.1 and a partially outwardly and upwardly slanted upper section 13.2. The upper section 13.2 comprises a frusto-conical panel 17 which is connected to the upright lower section 13.1 below, an upright panel 18 which is connected to the frusto-conical panel 17 below, a horizontal disc 16, a radially outer edge of which is connected to an upper edge of the upright panel 18 and a depending lip 20 which depends from a radially inner edge of the horizontal disc 16. The depending lip 20 is configured to hook around an edge of the grinding ring. A dam ring 21 is provided on top of the horizontal disc 16 and overlaps connection points of the segmented disc 16 below in order to rigidify the inner ring 13.
The rotor 12 further includes a partially outwardly and downwardly slanted outer ring 19 which is radially spaced from the inner ring 13. A plurality of angularly spaced apart vanes 22 extend between the inner ring 13 and the outer ring 19.
With reference to
Referring now to
Referring back to
In a known configuration, a conical ledge cover of the stator 14 has a linear cross-sectional profile. The Applicant has established that by altering the profile of the ledge cover to that illustrated in
The invention extends to a further embodiment of a rotatable throat, reference numeral 100 referring generally to this further embodiment of the throat in
The throat 100 includes a rotor 120 which comprises an inner ring 13 and a plurality of vanes 220 which are angularly spaced apart about an outer periphery of the inner ring 13. Each vane 220 has a triangular profile when viewed radially and has an operatively upstream end 220.1 and an operatively downstream end 220.2. Furthermore, each vane 220 comprises a leading member 221, a trailing member 222, diverging from the leading member 221 in a downstream direction from the upstream end 220.1 and a third downstream member 223 which extends circumferentially between the leading member 221 and the trailing member 222. The leading member 221 is a vane 22 as described above and accordingly has a leading face 24 and an arcuately curved profile when viewed radially. In similar fashion to the vanes 22 described above, the vanes 220 have a non-uniform radial width in the axial direction and taper radially from their upstream end 220.1 to their downstream end 220.2. The third downstream member 223 serves to blank or block a portion of the air port. This allows the vanes 220 to have a greater radial width without this significantly increasing the overall size of the air port or openings provided between the vanes 220. The size and distribution of the third downstream members 223 is such that they collectively cover less than 180° of the 360° degree extent of the air port or less than 50% of the circumferential area of the throat.
Referring now to
A further embodiment of a rotatable throat or port ring is designated by reference numeral 300 in
Yet another embodiment of a rotatable throat or port ring in accordance with the invention is designated by reference numeral 400 in
The throats 10, 100, 300, 400 in accordance with the invention aim to improve mill performance by optimising air flow through the throats. Air flow velocity through a throat is dependent upon the rotational speed of the grinding ring of the mill and the average air flow velocity at the inlet of the throat. In a known rotatable throat configuration, planar vanes are angled at 60° relative to the horizontal irrespective of the angular velocity of the grinding ring and the air velocity incident upon the throat. Consequently, a vortex forms above the throat which hampers throughput and increases turbulence and component wear. Ideally, a vertical air flow pattern without any swirl is required above the throat in order to optimise performance. It is to be appreciated that air passing through the throat 10, 100 accelerates from the inlet 230.1 to the outlet 230.2. For this reason, the leading face 24 is arcuately curved to account for the change in air velocity across the vanes 22, 220 in order to ensure a vertical resultant air flow at the outlet 230.2. As a result of the slower air flow rate at the upstream end 22.1, 220.1, the first angle β at the inlet is greater than the second angle α at the outlet which gives rise to the arcuate profile of the vane 22, 220 (see
In the event that flow incident upon the inlet of the throat has a strong flow component in the same direction as rotation of the rotary grinding member, i.e. in the same direction (A) as rotation of the vanes, then the design of the throats 300, 400 illustrated in
Number | Date | Country | Kind |
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2013/09420 | Dec 2013 | ZA | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2014/066834 | 12/12/2014 | WO | 00 |