• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The present invention relates to a cooler for cooling particulate material which has been subjected to heat treatment in an industrial kiln, such as a rotary kiln for manufacturing cement clinker. This cooler comprises an inlet, an outlet, end wall, side walls, a bottom and a ceiling, at least three reciprocating supporting lanes for receiving, supporting and transporting the material to be cooled, the lanes are moving following the walking floor principles as well as means for injecting cooling gas into the material through grate plates in the lanes. The present invention relates to an increasing in the vertical shearing height, and still having stationary clinker on top of the grate plates, see fig. 5. The length of the tilted part (16) is L and the distance (13) between two devices is G. The angle between the part (16) and horizontal is alfa (18). Since the air is distributed evenly from the full grate plate area it is obvious and understandable that the L*cosines(alfa) becomes a shadow area where all air from the region in the grate plate will go through the stationary clinker and leave the tip of L at this one point only. Again, it is not good for the heat recuperation to have a shadow area too big – as it, again, gives an uneven air flow through the clinker bed, damaging the heat recuperation. The vertical shearing height is on the other hand L*sinus(alfa). But if alfa becomes too large (approximately above 60 deg), it will block the sliding effect, as now the clinker will not get forced over the plate’s L-part, and then the wishedlarger vertical shearing is not achieved. It is hereby a compromise to get a certain vertical shearing: L*sinus(alfa) by not having a too large shadow area L*cosines(alfa), but still having the angle alfa so low that the clinker will slide at L – see fig. 5.
    公开号:DK201800097A1
    申请号:DKP201800097
    申请日:2018-02-28
    公开日:2019-05-13
    发明作者:Juhl Føns Mogens
    申请人:Føns Companies Aps;
    IPC主号:
    专利说明:

    Description,
    The present invention relates to a cooler for cooling particulate material which has been subjected to heat treatment in an industrial kiln, such as a rotary kiln for manufacturing cement clinker. This cooler comprises an inlet, an outlet, end wall, side walls, a bottom and a ceiling, at least three reciprocating supporting lanes for receiving, supporting and transporting the material to be cooled, the lanes are moving following the walking floor principles as well as means for injecting cooling gas into the material through grate plates in the lanes.
    In PA 199901403 a cooler of the above-mentioned kind is described. Furthermore, is described that unfortunately, due to the physical laws a cold channel problem of the cooling can occur. Assuming that the clinker lay is locally having a lower air flow resistance. This could be due following reasons: larger void between the clinker, less clinker height or less clinker temperature. All three reasons will make an easier path for the air. Consequently, more air will pass here, and less air in the surrounding areas not having this local reduced air flow resistance phenomenon. This is actually an evil circle, because now the clinker temperature in the locally established cold channel will get cooled further and even more than the surrounding areas. Once the clinker is getting colder in relation to the surroundings, it will become an even more attractive pass for the following air. Hereby the evil circle of uneven cooling is born and will only accelerate. In other words: the physical laws and the mathematic describe the instability when cooling with a compressible media - which air is - through a bulk material. The instability is damaging the heat recuperation of the air temperature going back to the kiln, now diluted with the colder air coming through the cold channels. The main purpose of the cooler is to gain as much heat back from the hot clinker to the air returning to the kiln, so fuel can be saved in the burner. The recuperated air is the amount going thought the clinker layer and returning to the kiln. See the recuperated air as the amount to the left of the dotted line in Fig. 2
    In reciprocating clinker coolers like DE19542013(A1) - where every second or third grate row is horizontally and perpendicularly to the clinker transport direction - the clinker layer will have an automatically vertical displacement (vertical shearing) in the layer when dropping over one grate plate end tip to the following grate plate, when clinker is moved towards the outlet of the cooler. Vertical shearing (vertical displacement) is NOT a mixing of top clinker to a bottom position and visa versa. On the contrary the clinker stays in the same vertical position after being subject to a vertical displacement (vertical shearing), only it is having a small plus and minus vertical distance to a neighbor clinker during vertical shearing.
    In push bar coolers like WO9848231(A1) some bars are moving back and forth inside the clinker bed and hereby transporting the clinker towards the outlet. In this type of cooler, the clinker layer will automatically have a vertical displacement (vertical shearing) in the layer when the push bar is moving toward the inlet trough the clinker, and hereby forcing the clinker over the cross-sectional shape of the push bar.
    In PA199901403 the above required vertical displacement (vertical shearing) is also published and described in details. Here some vertical elements are mounted between the aerated grate plates, the vertical elements' top are at a higher position than the top
    DK 2018 00097 A1 of the grate plates. The vertical element is perpendicular to the transport direction across the lane. The distance between two vertical elements will leave a pocket of stationary clinker in relation to the lane. The walking floor principle will move the clinker forward, when all lanes move together towards the outlet of the cooler. But when one lane retracts and the two neighbor lanes are not moving, then the friction force from the stationary clinker above the two stationary neighbor lanes will ensure that the clinker above the moving lane has at least only moved back a fraction of the distance which the lane is moving. Hereby the transport of the clinker is established. The clinker above the moving lane will be forced over the vertical element. But between two vertical elements the broader between moving clinker and stationary clinker will be at a lower position in relation to the top of the vertical elements. In PA199901403 is mentioned different height of the vertical elements. This is to ensure that still stationary clinker is present in the middle of the grate plate, to ensure that the grate plate is not getting exposed to wear from moving clinker, and created a sufficient vertical displacement (vertical shearing).
    The heat recuperation theoretically improves when the clinker bed height is increased, as the heat exchanger principle in the heat recuperation zone will act more like a counter-flow-heat-exchanger than the less efficient cross-flow-heat-exchanger. But at some point, the vertical shearing - as explained is implanted from the bottom only cannot be realized anymore. Hereby the cold channel problem will again start to damage the heat recuperation of the cooler.
    The present invention relates to an increasing in the vertical shearing height, and still having stationary clinker on top of the grate plates, see fig. 5.
    The friction coefficient between clinker and clinker is significantly higher than the friction coefficient between clinker and a plan plate e.g. made of steel or ceramic.
    The before named vertical plate will be replaced by a mounting device of any shape used to support the plan part tilted toward the outlet end of the cooler, having an angle with horizontal - alfa. The length of the tilted part is L and the distance between two devices is G. The height H of the mounting device should only be sufficient to ensure no wear on the grate plates.
    Since the air is distributed evenly from the full grate plate area it is obvious and understandable that the L*cosines(alfa) becomes a shadow area where all air from the region in the grate plate will go through the stationary clinker and leave the tip of L at this one point only. Again, it is not good for the heat recuperation to have a shadow area too big - as it, again, gives an uneven air flow through the clinker bed, damaging the heat recuperation.
    The vertical shearing is on the other hand L*sinus(alfa).
    But if alfa becomes too large (approximately above 60 deg), it will act as before mentioned vertical plate, as now the clinker will not get forced over the plate's L-part, and then the wished larger vertical shearing is not achieved.
    It is hereby a compromise to get a certain vertical shearing: L*sinus(alfa) by not having a too large shadow area L*cosines(alfa), but still having the angle alfa so low that the clinker will slide at L - see fig. 5.
    权利要求:
    Claims (9)
    [1] Claims
    1. A cooler (1) for cooling particulate material (2) which has been subjected to heat treatment in an industrial kiln (3), such as a rotary kiln for manufacturing cement clinker, which cooler (1) comprises an inlet (4), an outlet (5), end walls (6), side walls (7), a bottom (8) and a ceiling (9), at least three reciprocating supporting lanes (10) for receiving, supporting and transporting the material to be cooled, the lanes (10) are moving following the walking floor principles, cooling gas is injected between the bottom (8) and the lanes (10), the cooling gas is going through grate plate (12) in the lanes (10), the cooling gas is then going through the material (2) and the air to the left of the heat recuperation boarder (11) will go to the kiln (3) CHARACTERIZED IN THAT between each grate plate zone G (13) is mounted a plate (16), which is tilted towards the outlet end of the cooler, which is having the length L (17) with an angle alfa (18) between the tilted part (16) and horizontal.
    [2] 2. A cooler according to claim 1, CHARACTERIZED IN THAT
    L (17) is more than 1/40 of G (13) and the angle alfa (18) is more than 5 deg and less than 80 deg.
    [3] 3. A cooler according to claim 1, CHARACTERIZED IN THAT
    L (17) is more than 1/20 of G (13) and the angle alfa (18) is more than 5 deg and less than 80 deg.
    [4] 4. A cooler according to claim 1, CHARACTERIZED IN THAT
    L (17) is more than 1/10 of G (13) and the angle alfa (18) is more than 5 deg and less than 80 deg.
    [5] 5. A cooler according to claim 1, CHARACTERIZED IN THAT
    L (17) is more than 1/5 of G (13) and the angle alfa (18) is more than 5 deg and less than 80 deg.
    [6] 6. A cooler according to claim 1, CHARACTERIZED IN THAT
    L (17) is more than 1/40 of G (13) and the angle alfa (18) is more than 15 deg and less than 80 deg.
    [7] 7. A cooler according to claim 1, CHARACTERIZED IN THAT
    L (17) is more than 1/20 of G (13) and the angle alfa (18) is more than 15 deg and less than 80 deg.
    [8] 8. A cooler according to claim 1, CHARACTERIZED IN THAT
    L (17) is more than 1/10 of G (13) and the angle alfa (18) is more than 15 deg and less than 80 deg.
    [9] 9. A cooler according to claim 1, CHARACTERIZED IN THAT
    L (17) is more than 1/5 of G (13) and the angle alfa (18) is more than 15 deg and less than 80 deg.
    类似技术:
    公开号 | 公开日 | 专利标题
    CN100465566C|2009-03-04|Bulk material cooler for cooling hot materials to be cooled
    CN102564143B|2015-09-30|For regulating the method for the operation of bulk good grate cooler
    JP6192819B2|2017-09-06|Clinker cooler
    KR101812364B1|2017-12-26|Grate plate
    CN105783506A|2016-07-20|Grate cooler for a cement clinker kiln
    DK201800097A1|2019-05-13|Walking Floor Cooler for particulate material with increased vertical shearing
    CN1977136B|2010-05-26|Method and cooler for cooling hot particulate material
    RU2606671C2|2017-01-10|Device for transferring metallurgical material
    RU2486421C2|2013-06-27|Refrigerator grid lock
    RU2602573C2|2016-11-20|Device for pre-heating of transported scrap
    WO2002023112A1|2002-03-21|A grate cooler for granular material
    RU117594U1|2012-06-27|GARRIER GRAIN COOLER COOLER TYPE
    KR101767772B1|2017-08-14|Heat Insulation Apparatus for a Slab
    WO2000031483A1|2000-06-02|Cooler for cooling of particulate material
    WO2006040610A1|2006-04-20|Cooler for cooling hot particulate material
    US751720A|1904-02-09|Discharging device for furnaces
    RU2640701C1|2018-01-11|Cooler grate with shearing grate grids
    SU759820A1|1980-08-30|Grate refrigerator
    RU174873U1|2017-11-08|Cooler grate with repulsive grate
    JP2006029597A|2006-02-02|Burning device
    CN108291777B|2019-12-20|Grate plate for grate cooler
    JP6838955B2|2021-03-03|Cooler device
    RU2610083C2|2017-02-07|Electric graphitisation furnace
    RU1768904C|1992-10-15|Cooler grate
    CN1922459A|2007-02-28|Bulk material cooling device for cooling hot materials that are to be cooled
    同族专利:
    公开号 | 公开日
    WO2019166067A1|2019-09-06|
    EP3759410A1|2021-01-06|
    US20210003346A1|2021-01-07|
    DK179762B1|2019-05-13|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    DE19542013B4|1995-11-10|2004-09-16|Karl Von Wedel|Sideboard for a cooling grate|
    ZA982104B|1997-04-22|1998-09-16|Smidth & Co As F L|Cooler for cooling of particulate material|
    DK199901403A|1999-10-01|2001-04-02|Smidth & Co As F L|Air cooler for particulate material|
    法律状态:
    2019-05-13| PME| Patent granted|Effective date: 20190513 |
    2019-05-13| PAT| Application published|Effective date: 20190513 |
    2021-09-15| PBP| Patent lapsed|Effective date: 20210228 |
    优先权:
    申请号 | 申请日 | 专利标题
    DKPA201800097A|DK179762B1|2018-02-28|2018-02-28|Walking Floor Cooler for particulate material with increased vertical shearing|DKPA201800097A| DK179762B1|2018-02-28|2018-02-28|Walking Floor Cooler for particulate material with increased vertical shearing|
    PCT/DK2019/050066| WO2019166067A1|2018-02-28|2019-02-22|Cooler|
    EP19708937.8A| EP3759410A1|2018-02-28|2019-02-22|Cooler|
    US16/976,107| US20210003346A1|2018-02-28|2019-02-22|Cooler|
    [返回顶部]