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US2174066A - Process for sintering or calcining raw materials - Google Patents

Process for sintering or calcining raw materials Download PDF

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US2174066A
US2174066A US252124A US25212439A US2174066A US 2174066 A US2174066 A US 2174066A US 252124 A US252124 A US 252124A US 25212439 A US25212439 A US 25212439A US 2174066 A US2174066 A US 2174066A
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layer
recuperative
gas
heat
sintering
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US252124A
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Ahlmann Nikolai
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FLSmidth and Co AS
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FLSmidth and Co AS
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    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22BPRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
    • C22B1/00Preliminary treatment of ores or scrap
    • C22B1/14Agglomerating; Briquetting; Binding; Granulating
    • C22B1/16Sintering; Agglomerating
    • C22B1/20Sintering; Agglomerating in sintering machines with movable grates
    • CCHEMISTRY; METALLURGY
    • C04CEMENTS; CONCRETE; ARTIFICIAL STONE; CERAMICS; REFRACTORIES
    • C04BLIME, MAGNESIA; SLAG; CEMENTS; COMPOSITIONS THEREOF, e.g. MORTARS, CONCRETE OR LIKE BUILDING MATERIALS; ARTIFICIAL STONE; CERAMICS; REFRACTORIES; TREATMENT OF NATURAL STONE
    • C04B7/00Hydraulic cements
    • C04B7/36Manufacture of hydraulic cements in general
    • C04B7/43Heat treatment, e.g. precalcining, burning, melting; Cooling
    • C04B7/44Burning; Melting
    • C04B7/4461Grate sintering

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  • This invention relates to the sintering or calcining of raw materials such as cement raw materials by means of gas which is caused to ow through a layer of the material, and the main object is to utilize part of the waste heatl of the process 'whether the gas is itself so hot that it brings about the sintering or calcining, or Whether it only supports the combustion of fuel in the layer.
  • the material to be sintered or calcined should be' formed into a porous iine-grained layer having an average grain size of about l mm.
  • a porous iine-grained layer having an average grain size of about l mm.
  • the layer is that the heat penetrates the layer with a. sharp front, that is to say the distance in the layer between the material that is still cold and that which is already 50 highly heated is small.
  • the absorption of heat from the gas by the layer is indeed so great that the temperature of the gas leaving the layer will be very little above the temperature of the surrounding air during a considerable part of i5 the time taken by the sintering or calcining procing drawing, in which the abscissae show the time that has elapsed from the beginning of the sintering or calcining process and the ordinates show the temperature of the gas leaving a layer of cement raw material in a process in which the burning of the cement raw material is eiiected by forcing gases through the layer at an initial temperature of 1450 C.
  • the layer of raw material is not very porous and ne-grained the variation in temperature is shown by the curve l, that is to say, for example, after a time a has elapsed the temperature of the gas just as it leaves the layer is b. It will be appreciated that up to this moment the amount of heat supplied is proportional to the rectangle c--b-da, but that only the amount of heat proportional to the area c-b-d is effectively utilized and the remainder, proportional to the area c--d--a,
  • the curve obtainable in practice is indicated at 3 and is formed by the lines f, g and h. It will be seen that until the point n is reached there is substantially no heat wasted at all and that the inevitable waste heat is represented by the area n-e-m; The object of the invention is to make use of this waste heat.
  • the gas leavingvthe layer of material to be sintered or calcined is caused to ow also through a layer beneath consisting of inert material with a view to take up during the later part of the sintering or calcining process some of the heat contained in the gas.
  • the recuperative layer should for the same reasons as stated above in connection with the ilrst layer be formed of a porous, fine-grained material.
  • the recuperative layer should be so thick and of such heat-absorbing capacity that substantially the whole of the waste heat in the gas is taken up by the layer and accumulated there, which is as a rule obtained when the two layers are almost equal in thickness and grain size.
  • the second or recuperative layer may thus conveniently be of the same thickness as the layer of raw material and consist of small clinker of the kind obtained by the burning of the rst layer, but in this or other cases it may consist of other fine-grained inert material having the desired qualities as regards large surface and great capacity for heat.
  • the heat accumulated in the recuperative layer is utilized again by passing cold gas through it to take up the heat and use the gas in the sintering or calcining process.
  • a protective layer is often provided between a grate and material which is to be sintered on the grate with a view to protect the grate against the hot gases. It should be noted that such protective layer in contradistlnctlon to a recuperative layer need not be as fine-grained or of such heat capacity as stated above, because the same thermal requirements to be fullled by a recuperative layer are not required by a protective layer. The temperature of the gas leaving the recuperative layer should not exceed 150 C.
  • the process according to the invention may be carried out in two Ways depending on whether the sintering or calcining is effected by the hot gas or by fuel contained in the raw material layer.
  • first vcase cold gas may be caused to flow through the layer in the same direction when the burning or sintering is complete. to transfer the heat remaining in the layer to the recuperative layer, and the burnt or sintered layer may then be removed before the cold gas flows through the recuperative layer to take up heat from it.
  • the layer contains fuel it is flrst preheated by passing gas of such low temperature through the layers that the fuel is not ignited.
  • the ignition takes place and the combustion is supported by cold air which is now passed through the layers whereby the first layer is cooled and the waste heat transferred to the recuperative layer. Then the first layer is removed and cold gas is passed through the recuperative layer to take up the heat which is utilized to preheat new raw material.
  • the process may advantageously be carried on continuously and in such a case a continuously advancing grate may be used.
  • Two layers of material may then be spread on this grate, that is to say, a layer cf recuperative material on the grate itself, and ⁇ a layer of material to be burnt or sintered on the layer of recuperative material.
  • a Fig. 2 is a longitudinal section of an apparatus capable of carrying out the other modification oi the process.
  • Fig. 3 is an explanatory chart which has been previously referred to and described.
  • Fig. 1 it is assumed that the layer to be sintered or calcined does not contain any fuel.
  • the layer in question is numbered I and is spread on the recuperative layer 2 which again rests on the travelling grate I running over drums 4 and 5 supported by bearings not shown and being advanced by some external driving means, which is not to be seen either.
  • Various rooms and passages are arranged above the layers the limitations being the constructions 6 and 1 and the partition I6 as well as the side-walls of which the one to be seen in the figure is numbered 29.
  • the whole construction is made of fireproof brickwork.
  • the layer to be heat-treated and the recuperative layer are supplied to the grate through the hoppers I and 9, and during the travelling of the grate the layers enter first the sintering or calcining zone in which hot gas is passeddownwards through the layers and the grate to the room beneath limited by a housing III communi'cating with a pipe II.
  • This pipe is connected to the suction side of a fan, not shown, whereas the pressure side leads to a stack.
  • Hot gas comes from the channel I2 and enters vthe combustion chamber I3 where it serves as preheated secondary combustion air for an oilburner, the flame of which is indicated -by numeral I4, and to which oil together with compressed primary air is introduced through the pipe I5 into the chamber I3, in which the gases attain a temperature sufficient for bringing about the sintering or calcining process.
  • the grate When the sintering or calcining is substantially completed the grate has advanced the layers so far that the next zone is reached. This zone is limited by the front wall of the casing 1 and the partition I6.
  • a pipe I1 carries cold air into the room above the layer, and as the room under the grate is also under the influence of the suction through the pipe I I the cold air is sucked through the two layers and the grate transferring thereby the heat remaining in the layer which has been sintered or calcined from this layer into the recuperative layer.
  • plough I8 and the worm conveyor may sometimes be expedient to replace the plough I8 and the worm conveyor by some other means, for example a chain conveyor, capable of separating the two layers and of discharging the first layer.
  • recuperative layer 2 which now contains the waste heat is travelling further alone and reaches a zone where it is passed by lcold air which takes up the heat.
  • the atmospheric air is owing in through the pipe 22 due to the suction action exterted through the pipe II.
  • First the chamber 23 below the grate is reached, and after the passage through the grate and the recuperative layer the air passes the chamber 24 and further the channel I2, whereafter the air is used in the sintering or calcining process as described above.
  • the recuperative layer which is now cooled down almost to the temperature of the surroundings falls oif the grate at 25 due to the action of gravity when the grate passes the drum 5 and drops into the chute 26.
  • the same recuperative layer may be used several times and is therefore returned to the hopper I9 as indicated by the arrow.
  • Fig. 2 it is assumed that the layer to be sintered or calcined contains itself the fuelto carry through the process.
  • the apparatus illustrated in this figure is similar to the apparatus according to Fig. 1, and the corresponding parts in the two figures are therefore marked with the same reference numerals.
  • the two layers are first preheated in the preheating zone 21 by being traversed by warm gas subjected to sucking through the pipe I I.
  • the next zone is the sintei-, ing or calcining zone in which the fuel is ignited by means of a small flame 28, whereafter to support the combustion of the fuel atmospheric air is passed through the layers and the grate to be led away through the pipe II.
  • the layer will be lcold and can be removed in the next zone exactly as indicated in the description to Fig. 1.
  • the heat accumulated in the recuperative layer is in this case used to preheat the material in the zone 2l.
  • a process for sintering or calcining raw material which comprises forming a layer of porous fine-grained heat recuperative material on a traveling gas-pervious support, forming on top of said rst named layer a porous fine-grained layer of the material to be sintered or calcined, passing a heated gas transversely through the layers as at least a part of the sintering or calcining operation, thereafter passing downwardly through the layers an unheated gas which transfers the heat contained in the top layer of the material to the underlying heat recuperative layer, then removing the top layer of material from the underlying layer, thereafter passing a cooling gas through the recuperative layer from which the top layer has been removed to absorb in said gas the heat in the recuperative layer, and utilizing said last mentioned gas as the first mentioned heated gas which is used as part of the sintering or calcining operat on.
  • a process for sintering or calcining raw material which comprises forming a layer of porous fine-grained heat recuperative material on a traveling gas-pervious support, forming on top of said first named layer a porous fine-grained layer of the material to be sintered or calcined, passing transversely through the layers a gas whose teming takes place to thereby sinter or calcine the material in the top layer, thereafter passing downwardly through the layers a cold gas which transfers the heat contained in the top layer of the material to the underlying heat recuperative layer, then removing the top layer of material from the underlying layer, thereafter passing a cold gas through the recuperative layer from which the top layer has been removed to absorb in said gas the waste heat in the recuperative layer, and utilizing said last mentioned gas in the sintering or calcining operation.

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  • Ceramic Engineering (AREA)
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Description

Sept.
26 1939. N. AHLMANN 2,174,066
PROCESS `FOR SINTERING 0Rv CALCINING RAW MATERIALS Filed Jan. 21, 1939 7 6 /2/27 /7 AfA/7 /9/20 /29 ATTORNEYS Patented Sept. 26, 1939 PATENT OFFICE PROCESS FOR SINTERING OR CAILINING RAW MATERIALS Nikolai Ahlmann, Frederiksberg, near Copenhagen, Denmark, assignor to F. L. Smidth & Company, New York, N. Y., a corporation of New Jersey Application January 21, 1939, Serial No. 252,124
In Great Britain January 5, 1938 3 Claims.
This invention relates to the sintering or calcining of raw materials such as cement raw materials by means of gas which is caused to ow through a layer of the material, and the main object is to utilize part of the waste heatl of the process 'whether the gas is itself so hot that it brings about the sintering or calcining, or Whether it only supports the combustion of fuel in the layer.
To obtain the desired result the material to be sintered or calcined should be' formed into a porous iine-grained layer having an average grain size of about l mm. Such a layer possesses certain important qualities as will appear from the following.
One characteristic of the layer is that the heat penetrates the layer with a. sharp front, that is to say the distance in the layer between the material that is still cold and that which is already 50 highly heated is small. The absorption of heat from the gas by the layer is indeed so great that the temperature of the gas leaving the layer will be very little above the temperature of the surrounding air during a considerable part of i5 the time taken by the sintering or calcining procing drawing, in which the abscissae show the time that has elapsed from the beginning of the sintering or calcining process and the ordinates show the temperature of the gas leaving a layer of cement raw material in a process in which the burning of the cement raw material is eiiected by forcing gases through the layer at an initial temperature of 1450 C. If the layer of raw material is not very porous and ne-grained the variation in temperature is shown by the curve l, that is to say, for example, after a time a has elapsed the temperature of the gas just as it leaves the layer is b. It will be appreciated that up to this moment the amount of heat supplied is proportional to the rectangle c--b-da, but that only the amount of heat proportional to the area c-b-d is effectively utilized and the remainder, proportional to the area c--d--a,
is waste heat. 'I'he process is continuous u ntil If the layer were ideal, that is to say, were porous and of iniinitely fine grain, the curve 2 consisting of the two lines f and k would result and there would be no waste heat at all.
The curve obtainable in practice is indicated at 3 and is formed by the lines f, g and h. It will be seen that until the point n is reached there is substantially no heat wasted at all and that the inevitable waste heat is represented by the area n-e-m; The object of the invention is to make use of this waste heat.
According to one feature of the invention the gas leavingvthe layer of material to be sintered or calcined is caused to ow also through a layer beneath consisting of inert material with a view to take up during the later part of the sintering or calcining process some of the heat contained in the gas. In order to obtain thehighest possible heat economy this second layer, the recuperative layer, should for the same reasons as stated above in connection with the ilrst layer be formed of a porous, fine-grained material. The recuperative layer should be so thick and of such heat-absorbing capacity that substantially the whole of the waste heat in the gas is taken up by the layer and accumulated there, which is as a rule obtained when the two layers are almost equal in thickness and grain size.
When cement is being burnt the second or recuperative layer may thus conveniently be of the same thickness as the layer of raw material and consist of small clinker of the kind obtained by the burning of the rst layer, but in this or other cases it may consist of other fine-grained inert material having the desired qualities as regards large surface and great capacity for heat.
The heat accumulated in the recuperative layer is utilized again by passing cold gas through it to take up the heat and use the gas in the sintering or calcining process.
A protective layer is often provided between a grate and material which is to be sintered on the grate with a view to protect the grate against the hot gases. It should be noted that such protective layer in contradistlnctlon to a recuperative layer need not be as fine-grained or of such heat capacity as stated above, because the same thermal requirements to be fullled by a recuperative layer are not required by a protective layer. The temperature of the gas leaving the recuperative layer should not exceed 150 C.
The process according to the invention may be carried out in two Ways depending on whether the sintering or calcining is effected by the hot gas or by fuel contained in the raw material layer.
In the first vcase cold gas may be caused to flow through the layer in the same direction when the burning or sintering is complete. to transfer the heat remaining in the layer to the recuperative layer, and the burnt or sintered layer may then be removed before the cold gas flows through the recuperative layer to take up heat from it. A
If, however, the layer contains fuel it is flrst preheated by passing gas of such low temperature through the layers that the fuel is not ignited. When the, preheating is complete the ignition takes place and the combustion is supported by cold air which is now passed through the layers whereby the first layer is cooled and the waste heat transferred to the recuperative layer. Then the first layer is removed and cold gas is passed through the recuperative layer to take up the heat which is utilized to preheat new raw material.
In practice the process may advantageously be carried on continuously and in such a case a continuously advancing grate may be used. Two layers of material may then be spread on this grate, that is to say, a layer cf recuperative material on the grate itself, and` a layer of material to be burnt or sintered on the layer of recuperative material.
Two somewhat differing apparatus for carrylng out the two modifications of the process mentioned above are illustrated diagrammatically in the accompanying drawing, but it will be' understood that any appropriate apparatus capable of carrying out the process may be used. In order that the invention may be clearly understood and readily carried into effect two modifications of the process in accordance therewith will now be described by way of example with reference to the drawing, in which Figure 1 is a longitudinal section of an apparatus capable of carrying out one modification of the process;
a Fig. 2 is a longitudinal section of an apparatus capable of carrying out the other modification oi the process; and
Fig. 3 is an explanatory chart which has been previously referred to and described.
In Fig. 1 it is assumed that the layer to be sintered or calcined does not contain any fuel. The layer in question is numbered I and is spread on the recuperative layer 2 which again rests on the travelling grate I running over drums 4 and 5 supported by bearings not shown and being advanced by some external driving means, which is not to be seen either. Various rooms and passages are arranged above the layers the limitations being the constructions 6 and 1 and the partition I6 as well as the side-walls of which the one to be seen in the figure is numbered 29. The whole construction is made of fireproof brickwork. The layer to be heat-treated and the recuperative layer are supplied to the grate through the hoppers I and 9, and during the travelling of the grate the layers enter first the sintering or calcining zone in which hot gas is passeddownwards through the layers and the grate to the room beneath limited by a housing III communi'cating with a pipe II. This pipe is connected to the suction side of a fan, not shown, whereas the pressure side leads to a stack. Hot gas comes from the channel I2 and enters vthe combustion chamber I3 where it serves as preheated secondary combustion air for an oilburner, the flame of which is indicated -by numeral I4, and to which oil together with compressed primary air is introduced through the pipe I5 into the chamber I3, in which the gases attain a temperature sufficient for bringing about the sintering or calcining process.
When the sintering or calcining is substantially completed the grate has advanced the layers so far that the next zone is reached. This zone is limited by the front wall of the casing 1 and the partition I6. A pipe I1 carries cold air into the room above the layer, and as the room under the grate is also under the influence of the suction through the pipe I I the cold air is sucked through the two layers and the grate transferring thereby the heat remaining in the layer which has been sintered or calcined from this layer into the recuperative layer.
In the next zone limited by the partition I6 and the rear wall of the casing 1 the removing of the sintered or calcined layer which is now cold takes place by means of a curved metal plate IB 'acting as a plough and separating the two l'ayers so that the sintered or calcined layer is peeled off and lifted. The cold nished material is next seized by a worm conveyor I9 rotating in a trough 20 s o that the material is moved in a direction at a right angle to its previous movement on the grate. The material is discharged at the end of the worm conveyor which projects through the side wall 29. It is to be understood that there is a slot in the bottom of the trough 2Il as indicated at 2| through which the material enters the trough.
It may sometimes be expedient to replace the plough I8 and the worm conveyor by some other means, for example a chain conveyor, capable of separating the two layers and of discharging the first layer.
'I'he recuperative layer 2 which now contains the waste heat is travelling further alone and reaches a zone where it is passed by lcold air which takes up the heat. The atmospheric air is owing in through the pipe 22 due to the suction action exterted through the pipe II. First the chamber 23 below the grate is reached, and after the passage through the grate and the recuperative layer the air passes the chamber 24 and further the channel I2, whereafter the air is used in the sintering or calcining process as described above. The recuperative layer which is now cooled down almost to the temperature of the surroundings falls oif the grate at 25 due to the action of gravity when the grate passes the drum 5 and drops into the chute 26. The same recuperative layer may be used several times and is therefore returned to the hopper I9 as indicated by the arrow.
In Fig. 2 it is assumed that the layer to be sintered or calcined contains itself the fuelto carry through the process. The apparatus illustrated in this figure is similar to the apparatus according to Fig. 1, and the corresponding parts in the two figures are therefore marked with the same reference numerals. The two layers are first preheated in the preheating zone 21 by being traversed by warm gas subjected to sucking through the pipe I I. The next zone is the sintei-, ing or calcining zone in which the fuel is ignited by means of a small flame 28, whereafter to support the combustion of the fuel atmospheric air is passed through the layers and the grate to be led away through the pipe II. When the process is completed the layer will be lcold and can be removed in the next zone exactly as indicated in the description to Fig. 1. The heat accumulated in the recuperative layer is in this case used to preheat the material in the zone 2l.
I claim:
1. A process for sintering or calcining raw material which comprises forming a layer of porous fine-grained heat recuperative material on a traveling gas-pervious support, forming on top of said rst named layer a porous fine-grained layer of the material to be sintered or calcined, passing a heated gas transversely through the layers as at least a part of the sintering or calcining operation, thereafter passing downwardly through the layers an unheated gas which transfers the heat contained in the top layer of the material to the underlying heat recuperative layer, then removing the top layer of material from the underlying layer, thereafter passing a cooling gas through the recuperative layer from which the top layer has been removed to absorb in said gas the heat in the recuperative layer, and utilizing said last mentioned gas as the first mentioned heated gas which is used as part of the sintering or calcining operat on.
2. A process for sintering or calcining raw material which comprises forming a layer of porous fine-grained heat recuperative material on a traveling gas-pervious support, forming on top of said first named layer a porous fine-grained layer of the material to be sintered or calcined, passing transversely through the layers a gas whose teming takes place to thereby sinter or calcine the material in the top layer, thereafter passing downwardly through the layers a cold gas which transfers the heat contained in the top layer of the material to the underlying heat recuperative layer, then removing the top layer of material from the underlying layer, thereafter passing a cold gas through the recuperative layer from which the top layer has been removed to absorb in said gas the waste heat in the recuperative layer, and utilizing said last mentioned gas in the sintering or calcining operation.
through the layers to preheat the material to be sintered or calcined, igniting the fuel in the top layer, passing downwardly through the layers a cold gas to support combustion of the fuel in the top layer and to transfer the heat contained in the top layer of the material tothe underlying heat recuperative material, then removing the top layer of material from the underlying material. thereafter passing a cold gas through the recuperative layer from which the top layer has been removed to absorb in said gas the heat in the recuperative layer, and utilizing said last mentioned gas in said preheating operation.
NIKOLAI AHLMANN.
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Cited By (15)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2457557A (en) * 1943-09-24 1948-12-28 Guy Stedman May Ashby Projector for liquid and pulverulent or small material
US2521591A (en) * 1945-06-01 1950-09-05 Warren S Martin Apparatus for converting crushed material
US2578357A (en) * 1949-06-18 1951-12-11 Consolidation Coal Co Method for treating granular solids
US2580235A (en) * 1947-02-28 1951-12-25 Lellep Otto George Manufacturing wet process cement
US2603471A (en) * 1947-08-08 1952-07-15 George H Mcdonald Apparatus for expanding perlite
US2627399A (en) * 1947-11-18 1953-02-03 Erie Mining Co Cement manufacture
US2671968A (en) * 1950-03-23 1954-03-16 Heyl & Patterson Drier system
US2776129A (en) * 1951-10-23 1957-01-01 Robert Koster Production of sintered building material
US2945688A (en) * 1958-03-18 1960-07-19 Dyckerhoff Zementwerke Ag Process for manufacturing white cement
US3030090A (en) * 1959-02-26 1962-04-17 Carolina Tuff Lite Corp Heat treatment of minerals
US3076248A (en) * 1960-11-17 1963-02-05 Fmc Corp Process for the production of calcined phosphate agglomerates
US3100106A (en) * 1960-01-13 1963-08-06 Knapsack Ag Process and apparatus for the drying and burning of pellets
FR2492414A1 (en) * 1980-10-20 1982-04-23 Alcan Int Ltd REMOVAL OF COATINGS FROM ALUMINUM WASTE
US20070063172A1 (en) * 2004-03-02 2007-03-22 Premier Horticulture Ltee; Canada Furnace and method for expanding material
CH711261A1 (en) * 2015-06-30 2016-12-30 Lehmann Markus Plant for the implementation of a continuous, multi-stage industrial process.

Cited By (21)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2457557A (en) * 1943-09-24 1948-12-28 Guy Stedman May Ashby Projector for liquid and pulverulent or small material
US2521591A (en) * 1945-06-01 1950-09-05 Warren S Martin Apparatus for converting crushed material
US2580235A (en) * 1947-02-28 1951-12-25 Lellep Otto George Manufacturing wet process cement
US2603471A (en) * 1947-08-08 1952-07-15 George H Mcdonald Apparatus for expanding perlite
US2627399A (en) * 1947-11-18 1953-02-03 Erie Mining Co Cement manufacture
US2578357A (en) * 1949-06-18 1951-12-11 Consolidation Coal Co Method for treating granular solids
US2671968A (en) * 1950-03-23 1954-03-16 Heyl & Patterson Drier system
US2776129A (en) * 1951-10-23 1957-01-01 Robert Koster Production of sintered building material
US2945688A (en) * 1958-03-18 1960-07-19 Dyckerhoff Zementwerke Ag Process for manufacturing white cement
US3030090A (en) * 1959-02-26 1962-04-17 Carolina Tuff Lite Corp Heat treatment of minerals
US3100106A (en) * 1960-01-13 1963-08-06 Knapsack Ag Process and apparatus for the drying and burning of pellets
US3076248A (en) * 1960-11-17 1963-02-05 Fmc Corp Process for the production of calcined phosphate agglomerates
FR2492414A1 (en) * 1980-10-20 1982-04-23 Alcan Int Ltd REMOVAL OF COATINGS FROM ALUMINUM WASTE
US20070063172A1 (en) * 2004-03-02 2007-03-22 Premier Horticulture Ltee; Canada Furnace and method for expanding material
CH711261A1 (en) * 2015-06-30 2016-12-30 Lehmann Markus Plant for the implementation of a continuous, multi-stage industrial process.
WO2017001465A1 (en) * 2015-06-30 2017-01-05 Markus Lehmann Continuous multi-chamber process
CN109564063A (en) * 2015-06-30 2019-04-02 M·莱曼 Continuous multi-cavity process
JP2019520975A (en) * 2015-06-30 2019-07-25 マルクス、レーマンMarkus Lehmann Continuous multi-chamber process
CN109564063B (en) * 2015-06-30 2021-09-14 M·莱曼 Continuous multi-chamber process
US11439961B2 (en) * 2015-06-30 2022-09-13 Markus Lehmann Continuous multi-chamber process
AU2016287354B2 (en) * 2015-06-30 2022-10-06 Markus Lehmann Continuous multi-chamber process

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