WO2015189131A1 - Grinding system and method for comminution of grinding stock - Google Patents

Abstract

The grinding system for comminution of grinding stock substantially consists of one first grinding circuit comprising a roller press and a first separator, and a second grinding circuit comprising a dynamic separator and a ball mill. The first separator is designed as a static separator and arranged below the roller press, whereas the dynamic separator is arranged at the height of the roller press or below the roller press. In the method for comminuting grinding stock, the grinding stock is comminuted in a first grinding circuit comprising a roller press and a first separator, and in a second grinding circuit comprising a dynamic separator and a ball mill, wherein a first separator designed as a static separator and arranged below the roller press and a dynamic separator arranged at the height of the roller press or below the roller press are used.

Description

 Grinding plant and process for the comminution of regrind

The invention relates to a grinding plant and a method for comminuting grinding stock with a first grinding circuit having a roller press and a first classifier and a second grinding circuit having a dynamic classifier and a ball mill.

The grinding stock used in comminution preferably consists of a brittle material, such as limestone, dolomite or ore material. In the case of cement production, the ground material moreover consists preferably of clinker, slag and / or fly ash. From DE 43 03 987 AI is a grinding plant with a first and a second

Mahlkreislauf known, the first grinding circuit is operated with a high-pressure roller press and a dynamic classifier arranged above. The fines of the first grinding cycle pass into a cyclone and from there into a ball mill. The ground in the ball mill estate is separated in a second dynamic classifier in finished goods and grits, the gries zur

Ball mill to be returned.

High-pressure roller presses usually have two rollers driven in opposite directions and forming a grinding gap between them, which rollers are subjected to grinding pressures of 50 MPa and more by means of a pressing device. Such high pressures lead in the grinding gap to a so-called

Good bed comminution, with the result that the comminuted regrind comes out partially in the form of slugs or agglomerates from the roll press. To sift such regrind in a dynamic classifier, a deagglomerator is often connected upstream. In one known from EP 1 506 058 Bl Fertigmahlkreis with a

Roller press, the disagglomerator is replaced by a static classifier. For the transport of the ground material to the dynamic classifier is usually a delivery unit, in particular a bucket elevator used, which is adapted to the amount to be transported and causes considerable investment and operating costs. In EP 1 506 058 B1, it is the object of the invention to provide a compact circuit grinding plant with roller press and classifier, in which the problem of mechanical transport of the circulated ground material is minimized. The solution to this problem was that a static cascade classifier was placed below the nip of the roller press, while a dynamic Nachsichter was provided with its Grobgutauslass above the roller press. The static cascade classifier has mainly the task of disagglomerating the agglomerates and to view the material to be viewed simultaneously in cross-flow. The visible goods discharge of the static cascade classifier arrives pneumatically via a riser channel with the classifying air into the Nachsichter. Through this solution, investment costs, operating costs and space for installing an otherwise necessary mechanical delivery unit, such as a bucket elevator, saved.

With a finished grinding circle, it is usually possible to achieve finenesses of the final product of the order of about 3,000 cm ² / g. However, if greater subtleties and especially in the field of cement production different types of blended cements are required, it is necessary for energetic reasons to resort to a combined grinding plant with a first and a second grinding circuit.

The invention is therefore based on the object of specifying a grinding plant and a method for the comminution of regrind with a first and a second grinding circuit, which are characterized by reduced investment and operating costs.

According to the invention, this object is solved by the features of claims 1 and 5. Advantageous embodiments of the invention are the subject of the other claims. The grinding system according to the invention for the comminution of ground material consists essentially of a first grinding circuit having a roller press and a first classifier and a second grinding circuit having a dynamic classifier and a ball mill. The first classifier is designed as a static classifier and arranged below the roller press, while the dynamic classifier is provided at the level of the roller press or below the roller press.

In the method according to the invention for the comminution of millbase, the millbase is comminuted in a first mill cycle comprising a roller press and a first classifier and a second mill cycle having a dynamic classifier and a ball mill, wherein a first classifier designed as a static classifier and arranged below the roller compactor and one on Height of the roller press or below the roller press arranged dynamic classifier are used.

Under a roller press in the context of the invention, a roller mill with two counter-driven and while maintaining a grinding gap pressed against each other grinding rollers understood. In contrast to the dynamic sifter, the static sifter is distinguished above all by the fact that it has no rotating or rotating components during operation. Usually, it consists of an obliquely arranged ventilation floor, which may also be cascade-shaped and is flowed through by a classifying air flow. The dynamic classifier usually has a rotating rod basket or rotor.

By arranged below the roller press static classifier of the first grinding circuit and the maximum arranged on the level of the roller press dynamic classifier in the second grinding circuit, the conveying paths can be minimized in the circulation circuits.

According to a further embodiment of the invention, the first grinding circuit further comprises a first conveying unit arranged between a coarse material outlet of the static classifier and a feed shaft of the roller press. Farther is provided in the second grinding circuit arranged between a discharge opening of the ball mill and a feed opening of the dynamic classifier second delivery unit. By this interconnection only the coarse material of the static classifier is returned to the roller press. The space provided for this first delivery unit can therefore be made correspondingly smaller, which investment and operating costs can be saved.

The dynamic sifter may include a finished product outlet and a semen outlet. The grinding system according to the invention is preferably designed so that the grits of the dynamic classifier are merely passed to the ball mill. A return of the grits to the first grinding cycle should only take place in exceptional cases, especially if the amount of grits exceeds the processing capacity of the ball mill. According to a further embodiment of the invention, therefore, a buffer storage is provided between the dynamic classifier and the ball mill, which has an overflow associated with the first grinding circuit. Instead of or in addition to the overflow, it may also be provided that the amount of grime accumulated is adjusted to the capacity of the ball mill by influencing the amount of fines of the static sifter. This can be done by quantitatively influencing the grinding stock (fresh material) applied to the first grinding cycle and / or by regulating a classifying air stream used in the static classifier such that the amount of the greens produced in the dynamic classifier is adapted to the capacity of the ball mill. By this or other measures should be ensured that more than 80%, preferably more than 90 or more than 95%, most preferably the entire amount of the grits are passed to the ball mill.

By clearly, preferably completely, reduced Grießerückführung to the first grinding circuit, the delivery volume of the first delivery unit can be dimensioned correspondingly smaller. Due to the reduced delivery volume of the first delivery unit and the reduced delivery of the second delivery unit results in significant investment and operating cost savings. By the renunciation a dynamic classifier above the roll press also results in a relatively compact overall arrangement of the grinding plant.

The invention will be explained in more detail below with reference to the description of some embodiments and the drawing.

In the drawing show

1 is a schematic representation of a grinding plant with a arranged at the level of the roller press dynamic classifier,

2 is a schematic representation of a grinding plant with a arranged below the roller press dynamic classifier,

Fig. 3 schematic representation of a dynamic classifier with a buffer memory with overflow and

Fig. 4 schematic representation of a dynamic classifier with a level measuring device in the buffer memory.

In Fig. 1, a grinding plant for crushing brittle grinding material, such as limestone, clinker, dolomite or ore material is shown. It essentially consists of a first grinding circuit 3 having a roller press 1 and a static classifier 2 and a second grinding circuit 6 having a dynamic classifier 4 and a ball mill 5. The roller press has two counter-rotating grinding rollers 1a, 1b in a conventional manner. About a pressing device not shown, the two grinding rollers are applied while maintaining a Mahlspalts with grinding pressures of 50 MPa and more.

The first grinding circuit 3 further comprises a first conveying unit 7, in particular a bucket elevator, arranged between a coarse material outlet 2b of the static classifier 2 and a feed chute 1c of the roller press 1. The roller press is further provided via an outlet opening ld with a feed opening 2a of the static classifier 2 connected. The connection between roller press and static sifter is expediently carried out via a chute 8 so that the comminuted material is guided by means of gravity into the static sifter without any expenditure of energy. The grinding stock (fresh material 9) to be fed to the first grinding circuit 3 is fed in the area of the chute 8 or the feed opening 2a of the static classifier 2. The fresh material 9, which may already contain a certain amount of fines, is thus sighted only in the static classifier in coarse material and fine material, so that only the coarse material is conveyed to the feed chute lc of the roll press 1.

The static classifier 2 has an obliquely arranged aeration bottom 2d, through which a classifying air stream 10 flows. While the coarse material passes by gravity to the coarse material outlet 2b, the fine material is guided together with the classifying air flow via the fine material outlet 2c into the dynamic classifier 4.

The dynamic classifier 4 is designed, for example, as a rod basket sifter with a tangentially arranged inlet opening 4a. The millbase fed to the dynamic sifter is screened in gruel and finished product, the gruel being sent to the ball mill 5 via a pouring outlet 4b. In this case, the connection may be formed, for example, by a chute or, in the case of an insufficient gradient, as an airflow channel. The finished product is fed together with the classifying air flow via a finished product outlet 4c to a separator 11, where the finished product 12 is separated from the classifying air stream 10. In the ball mill 5, the grits are further crushed and then optionally returned to the dynamic classifier 4 via another separator 13 or directly via a second conveyor 14. The further separator 13 may be required in particular when the ball mill 5 is operated with an air flow.

The embodiment of FIG. 2 differs from the first embodiment essentially only in that the dynamic classifier 4 "of the 2nd grinding circuit 6 is arranged below the roller press 1. Die Static The sifter 2 is again arranged below the dynamic sifter 4 ^" . The inlet opening 4" a of the dynamic sifter 4 is arranged at the lower end of the sifter, so that the sifting air stream 10 together with the fines of the static sifter 2 from bottom to top into the dynamic sifter The further details of this second grinding plant and its mode of action are the same as those of the first grinding plant, and it goes without saying that the sifter 4 "can also be used instead of the sifter 4 and vice versa.

The two grinding systems are preferably operated in such a way that the greases produced in the dynamic sifter 4 or 4 "are returned to the first grinding cycle only in a small amount, but preferably not at all (return line 15 shown in dashed lines) 4 ^"is equipped with a semolina cone or buffer 16 (Figures 3 and 4). About a metering device 17, for example, a cell sluice or a screw, the ball mill 5, the required amount can be supplied dosed. The buffer memory 16 according to FIG. 3 is provided with an overflow 18, which is connected via the return line 15 to the first grinding circuit 3. The return line 15 expediently opens in the region of the first conveyor 7.

However, the overflow 18 should only be used in exceptional cases, so that the aim is to operate the grinding plant so that no grues are returned via the return line 15 to the first grinding cycle. The amount of resulting grits depends primarily on the fines content of the static classifier 2. By suitable measurements, such as a Durchfiussmessung in the return line 15 for determining the recirculated Grießemassenstromes or a measurement of the current consumption of the first conveyor 7 and / or a Einrollengurtwaage after the first conveyor 7 for determining the circulating mass flow of the first grinding circuit, it can be determined whether the Amount of the resulting grits is too big. An optionally required influencing of the fines content of the static classifier can essentially be achieved by the adjustment of the amount of the classifying air stream 10 or a regulation of the feed quantity of the fresh material 9 take place.

FIG. 4 shows yet another variant in which a return line 15 is dispensed with. The dynamic sifter is in turn equipped with a buffer memory 16, which has a level measuring device 19. If the level is too low, for example, the amount of fresh product and / or the classifying air stream 10 is increased. If the level is too high, the amount of fresh material and / or the classifying air stream 10 is reduced.

Claims

Claims: 1. Mahlanlage for crushing of ground material with a roller press (1) and a first classifier having first Mahlkreislauf (3) and a dynamic classifier (4, 4 ") and a ball mill (5) having second Mahlkreislauf (6), characterized in that the first classifier is designed as a static classifier (2) and arranged below the roll press (1), while the dynamic classifier (4, 4 ^" ) is provided at the level of the roll press or below the roll press. 2. grinding plant according to claim 1, characterized in that the first grinding circuit (3) further comprises a between a Grobgutauslass (2b) of the static separator (2) and a feed shaft (lc) of the roller press (1) arranged first delivery unit (7) and in the second grinding circuit (6) between a discharge opening of the ball mill (5) and an inlet opening (4a) of the dynamic separator (4) arranged second delivery unit (14) is provided. 3. Grinding plant according to claim 1, characterized in that the static separator (2) has a fine material outlet (2d) provided with an inlet opening (4a) of the dynamic classifier (4) for feeding fines of the static classifier (2) to the dynamic classifier communicates. 4. grinding plant according to claim 1, characterized in that the dynamic separator (4) has a Fertiggutauslass (4c) and a Grießeauslass (4b) and between Grießeauslass (4b) and ball mill (5) a buffer memory (16) is provided, the one comprising overflow (18) in communication with the first grinding circuit (3). 5. A method for comminution of millbase, wherein the millbase in a roller press (1) and a first classifier having first grinding circuit (3) and a dynamic classifier (4) and a ball mill (5) having second grinding circuit (6) is comminuted , characterized in that as a static separator (2) formed and below the roller press (1) arranged first classifier and at the height of the roller press (1) or below the roller press arranged dynamic classifier (4) is used. 6. The method according to claim 5, characterized in that in the roller press (1) comminuted millbase in static sifter (2) is seen in coarse material and fine material, wherein the coarse material to the roller press (1) returned and the fines the dynamic sifter (4 ) is abandoned. 7. The method according to claim 5, characterized in that a dynamic sifter (4) supplied regrind is screened in meal and finished product, wherein the grits are passed to the ball mill (5). 8. The method according to claim 7, characterized in that the entire amount of the dynamic sifter (4) resulting grain to the ball mill (5) are passed and the amount of the resulting grime by influencing the amount of fines of the static separator (2) to the Capacity of the ball mill (5) is adjusted. 9. The method according to claim 8, characterized in that the amount of fines of the static classifier (2) by quantitatively influencing the first grinding circuit (3) abandoned grinding material and / or by regulating a static classifier (2) used classifying air flow (10) so is adapted, that the amount of the in the dynamic classifier (4) accumulating grits adapted to the capacity of the ball mill (5). 10. The method according to claim 5, characterized in that in the static classifier (2) for sifting in the roll press (1) comminuted material a classifying air stream (10) is used, with which the fine material arising there is transported to the dynamic classifier (4) ,