JPH0753245B2 - Vertical crusher - Google Patents

Description

TECHNICAL FIELD The present invention relates to a vertical crusher for crushing cement raw material, coal, chemicals, etc. by cooperation of a rotary table and a crushing roller.

[Prior Art] A vertical crusher equipped with a rotary table and a roller is widely used as a kind of crusher which crushes powder such as cement raw material, coal, and chemicals into fine powder. This type of crusher is a disk-shaped rotary table that is driven by a motor with a speed reducer and rotates at a low speed in the lower part of a cylindrical casing, and is pressed by hydraulic pressure or the like to a portion that equally divides the outer peripheral portion of the upper surface in the circumferential direction. And a plurality of rollers that are driven to rotate.

In this vertical pulverizer, the powder as a raw material supplied to the center of the rotary table by the supply pipe receives centrifugal force in the radial direction of the table due to the rotation of the table, and when sliding on the table, the force in the direction of rotation by the table is applied. In response, it slides between itself and the table to make a rotation slightly slower than the table rotation speed. The above two forces, that is, the force in the radial direction and the force in the rotation direction are combined, and the powder moves to the outer peripheral portion of the rotary table in a spiral trajectory on the table. Since the roller is pressed against the outer periphery of the roller and is rotating, the granular material in which the spiral is drawn enters between the roller and the rotary table from a direction forming an angle with the roller axial direction and is bitten therein. Smash.

On the other hand, hot air is guided by a duct to the base of the casing, and this hot air is used to blow airflow between the outer peripheral surface of the rotary table and the inner peripheral surface of the casing (this passage is referred to as an annular space portion in this specification). That is, the fine powder rises in the casing while being dried, and is discharged from the discharge port as a mixture with the hot air and sent to the next step.

By the way, the object to be crushed supplied to the crusher is rarely crushed to the fine grain size required by this crusher even if it is subjected to the crushing action by the crushing roller once, and it falls to the center of the rotary table. Since all the crushed objects are not bitten by the crushing roller, even if the powder and granules reaching the outer peripheral end of the rotary table ride on the hot air flow rising from the annular space and rise, By the time it reaches the separator installed in the upper part, it falls on the way depending on its particle size, or is classified and eliminated by the separator and returned to the rotary table.

In this way, the material to be pulverized, which is supplied from moment to moment in the crusher, rises from the rotary table to the separator or reaches the rotary table until it reaches the desired fine grain size of the final product and flows out of the crusher. To a separator, the particles are gradually crushed many times from the middle to reach a desired particle size.

[Problems to be Solved by the Invention] In the conventional vertical crusher as described above, a considerable amount of the crushed objects reaching the meshing side of the rollers are not caught in the rollers on the table. It is usually washed away into the annular space. Then, of the objects to be crushed that are pushed into the annular space on the biting side of the roller, those with a large particle size become stones and fall into the annular space, increasing the amount of stones and increasing the amount of processing work. Let Further, among the objects to be crushed that have been swept into the annular space, those having a small particle size are scattered again, so that the load applied to the separator is increased and the classification efficiency is likely to be lowered. Further, since a large amount of the object to be crushed is forced to flow into the annular space portion, a ventilation pressure loss in the annular space portion increases, which increases fan power.

As described above, in the crusher, an air blower having several times the required air volume for blowing up and circulating the overflow granules is required, and a large air volume and air pressure are required due to the increase in the circulation volume, resulting in equipment cost. Not only does this significantly increase power consumption, but especially when ultra-fine pulverizing a raw material having physical properties that are relatively poor in grindability, mill vibration often occurs, and the vibration value (amplitude) is particularly high. If it is large, the equipment may be damaged or it may become inoperable, and the operation may be stopped without stopping.

Therefore, as a measure against large vibrations, the frequency of the raw material layer of the crushing part is changed to move away from the resonance range. It is conceivable to change the crushing pressure and the number of rotations of the table, but of these, making the drive of the rotating table variable makes the equipment cost too high and the feasibility is low. Changing the (dam ring height) requires internal work after stopping the operation of the crusher, and changing the crushing pressure has the drawback that the product particle size changes to the desired one, so the mill throughput The actual situation is to reduce and respond to this, which would impair a stable production plan. Therefore, even if mill vibration occurs, the frequency of milling raw material layer is changed and the vibration amplitude is reduced without causing a significant reduction in the amount of mill processing, so that a normal and stable motion state with small vibration is quickly recovered. There was a longing for something. The generation of these vibrations tends to occur more frequently in the finely crushed or ultra-finely crushed regions than in the medium crushed region.

[Means for Solving the Problems] In order to achieve the above object, that is, in order to prevent large mill vibration from occurring during operation, the vertical crusher of the present invention is provided with a plurality of rotary table upper surfaces. A vertical pulverizer in which a rotatable pulverizing roller is arranged, and the raw material supplied to the center of the rotary table is pulverized between the upper surface of the rotary table and the peripheral surface of the pulverizing roller by applying a predetermined pulverizing pressure to the pulverizing roller. A rotatable auxiliary roller for compressing the layer of the raw material to be bitten into the crushing roller by the peripheral surface is provided on the upper surface of the outer circumference of the rotary table between the roller and the crushing roller, and the auxiliary roller and the position downstream of the auxiliary roller are provided. A scraper capable of moving up and down is disposed between the scraping roller and the crushing roller, and a means for moving the scraper up and down is provided.

[Operation] The raw material supplied from the raw material feeding chute to the upper surface of the central part of the rotary table draws a spiral locus on the rotary table and moves to the outer peripheral side of the rotary table to reach the biting side of the auxiliary roller, and the auxiliary roller and the rotary table. When flowing in between, the auxiliary roller compresses the raw material particles with a required pressing force on the peripheral surface while rotating, and each compressed raw material particle is in a dense state, so-called, It is said that This consolidation layer reaches the biting side of the crushing roller by the rotation of the rotary table, and a high pressing force is applied by the crushing roller to perform high-level crushing. Further, the raw material particles, which are crushed by the crushing roller and finely divided, and which are discharged from the non-meshing side of the crushing roller and flow as a so-called coarse and dense layer, are subjected to a compaction action similar to this auxiliary roller and are positioned next to the crushing roller. With a high probability of being bitten into and crushed efficiently. The pressing force of the auxiliary roller in the direction of the upper surface of the rotary table does not contribute to the crushing, but compresses the raw material particles to form a layer in which the particles are closely packed, so-called, (Hereinafter, the action of forming such a layer may be referred to as consolidation.) It is a force to such an extent that it is formed, and is a force significantly smaller than the pressing force of the crushing roller.

When the auxiliary roller is arranged close to the raw material catching side of the crushing roller, new raw material from the raw material charging chute guided to the outer peripheral portion of the rotary table is less likely to flow into the raw material catching side of the crushing roller, and the auxiliary roller is Since the ratio of the material flowing into the raw material entrapment side increases, the new raw material is less likely to disturb the consolidation layer in which the raw material particles are compressed and the raw material particles are densely packed, and the entrainment into the crushing roller is performed more reliably. .
Of course, the raw material crushed by the previous crushing roller and the new raw material are combined and compacted by this auxiliary roller.

At the same time, the second main function of the auxiliary roller is to keep the peculiar frequency of the raw material layer constant by making the consolidation layer of a constant thickness with the auxiliary roller to make the vibration less likely to occur.

In this way, the powder layer compacted by the auxiliary roller is efficiently crushed by the crushing roller arranged in the subsequent stage of the auxiliary roller, and the raw material layer is kept at a constant height to prevent vibration. However, nevertheless, the layer thickness increased for some reason and the mill vibration suddenly became violent.

In this case, the properties of the pulverized raw material (such as hardness and particle size distribution) and the water content change, and the pulverizability of the raw material deteriorates. Therefore, the raw material layer thickness on the rotary table is larger than in the normal state. In the vertical crusher of the present invention, a scraper is arranged between the auxiliary roller and the crushing roller, that is, on the downstream side of the auxiliary roller, and when the mill vibration increases, the increased raw material layer thickness is rotated. By overflowing to the outside of the table, the thickness of the raw material layer constantly flowing into the auxiliary roller is kept constant. Therefore, even if there is a change in the raw material properties, only a certain layer thickness is supplied to the auxiliary roller, the raw material layer having an excessive height above that is removed from the rotary table, and only the remaining consolidation layer is regularized by the crushing roller. Since a crushing action can be given to continue the small vibration of the mill,
The crushing ability can be maintained.

Embodiments Embodiments of the present invention will be described in detail below with reference to the drawings.

1 to 3 show an embodiment of the present invention, FIG. 1 is an overall schematic vertical sectional view, FIG. 2 is an enlarged view of a main part of a crushing section, and FIG. 2 (a) is a vertical sectional view. 2 (b) is a plan view, FIG. 2 (c) is a side view, FIG. 3 shows an arrangement of a scraper, an auxiliary roller, and a crushing roller, and FIG. 3 (a) is a plane arrangement view. FIG. 3 (b) is a front development view of FIG. 3 (a).

In FIG. 1, a crusher 1 includes a rotary table 3 described later.
Equipped with a casing 20 that houses the entire crushing unit such as
The casing 20 includes a lower casing 20a formed in a cylindrical shape and fixed to the floor surface, a middle casing 20b in which an inner cone 20c having a circular cross section is provided, and an upper portion joined to the upper end thereof. It has a casing 20d.

A speed reducer 2 with a motor is arranged in the center of the lower casing 20a, and a rotary table 3 formed in a disk shape is axially mounted on an output shaft extending upward of the motor. It is driven and rotated clockwise when viewed from above in FIG. Reference numeral 5 denotes a roller boss arm, and a plurality of roller boss arms are arranged at the outer peripheral end of the upper portion of the rotary table 3, and the lower end of each is provided with a crushing roller 4 having a truncated cone shape that is axially mounted in a substantially horizontal state. There is.

A pressure frame 6 having an annular shape (annular shape in this embodiment) is fixedly mounted on the upper surface of the inner peripheral end of the roller boss arm 5 by means such as bolt tightening. The boss arm 5 and the pressure frame 6 are integrally formed and mounted on the upper surface of the rotary table 3. On the other hand, the upper outer peripheral end of each roller boss 5 is rotatably connected to the hydraulic cylinder 10 by the pin 7 and the fork end 7a via the connecting rod 8, the turnbuckle 9 and the cylinder rod 10a, and the lower end of the hydraulic cylinder 10 rotates. Pin 11 and rotary seat
It is connected to the base plate 13 by 12.

Each crushing roller 4 is rotatably supported by a roller boss 5 via a roller shaft 4a, and its peripheral surface is in contact with the outer peripheral surface of the upper end of the rotary table 3, so that it is driven as the rotary table rotates. It is rotatable.

In addition, the crushing roller 4 is provided on the upper surface of the outer peripheral portion of the rotary table 3 where the crushing roller 4 and the adjacent crushing roller 4 are located.
An auxiliary roller 30 having a diameter smaller than that of the crushing roller 4 is arranged at a position closer to the raw material biting side.

As shown in FIG. 2C, the auxiliary roller 30 is rotatably mounted on a roller shaft 35 fixed to the tip of a substantially U-shaped arm 31 rotatably supported on the casing 20 by a shaft 33. It is pivotally mounted. A piston rod 32a of a hydraulic cylinder 32 is rotatably connected to the lower end of the arm 31, and a constant pressure of hydraulic pressure is applied to the rod end chamber 32b of the hydraulic cylinder 32 to apply a compressive force to the raw material layer. An end of the hydraulic cylinder 32 on the side opposite to the piston rod is rotatably supported by the casing 20.

This compressive force is applied to the rod end chamber 32 of the hydraulic cylinder 32.
This is done by adjusting the hydraulic pressure by a pressure adjusting valve (not shown) attached to the hydraulic line connected to b. An accumulator is connected to this hydraulic line so that the rod end chamber 32b of the hydraulic cylinder 32 is kept at a constant pressure. By expanding and contracting the piston rod 32a of the hydraulic cylinder 32, the arm 31 is rotated around the shaft 33 as a rotation center, and the auxiliary roller 30 moves up and down. A gap adjuster 34 for adjusting and setting a gap between the auxiliary roller 30 and the upper surface of the rotary table 3 is provided below the arm 31, and the gap adjuster 34 is fixed to the casing 20 and has a screw hole. The base 34b and the screw shaft 34a screwed into and supported by the screw holes of the base 34b are supported. By bringing the tip of the screw shaft 34a into contact with the side end of the arm 31, the auxiliary roller It is configured so that a gap between 30 and the upper surface of the rotary table 3 can be set.

When the weight of the auxiliary roller 30 is sufficient as the compression force of the raw material layer, the hydraulic cylinder 30 is set free.

On the other hand, a discharge port 22a is opened above the center of the rotary table 3, and a final fine powder discharge pipe 22 is connected to the discharge port 22a. Further, from above the casing, the raw material supply pipe 16 penetrates the ceiling wall of the discharge pipe 22 and is inserted into the discharge port 22a,
Further, the lower end portion is arranged so as to reach near the lower portion of the separator 15. The raw material supply pipe 16 is supported by the casing 20d via a discharge pipe 22, and a separator 15 formed of an inverted conical cylinder is provided around the raw material supply pipe 16 by a stay (not shown) in the middle casing 20b. Supported by. On the upper peripheral outer surface of this separator 15,
A plurality of movable vanes 15a for imparting a swirling force to the inflowing dust gas are evenly arranged in the circumferential direction, and one end of the bearing 1a
It is rotatably adjustable from the outside by a shaft 15b supported by 5c and a handle 15d.

On the other hand, below the outer peripheral portion of the rotary table 3, an annular hot air passage 21 is connected to the hot air generator by a duct 18.
Above the hot air passage 21, an annular space 14 is defined between the rotary table 3 and the casing 20a by the inner peripheral wall 14a and the outer peripheral wall 14b. In the annular space portion 14, a plurality of plate-shaped blades 14c are arranged and fixed at equal intervals on the circumference while maintaining a required inclination angle with respect to the horizontal plane.

Further, at the lower part of the hot air passage, there is a discharge chute 19 for temporarily discharging a foreign substance during crushing and an excessive crushed object in case of overload.
Is installed and is rotatable around the rotating pin 19a 1
It has a structure that can be taken out from 9b.

On the other hand, on the biting side of each auxiliary roller 30, the height from the lower surface of the rotary table of the raw material layer toward the auxiliary roller 30 to the surface of the raw material layer, that is, the layer thickness of the raw material layer (H in FIG. 2A) is set. The restricting scraper 100 is arranged horizontally in the radial direction or in an inclined direction (see FIGS. 2 (b), 3 (a) and 3 (b)) somewhat from the radial direction. The scraper 100 can be rotated around the pin fulcrum 110 of the pin support 120 via the connecting rod 100a, and the other end of the hydraulic cylinder 1 pin-supported by the frame 140 by the pin 100b.
The piston rod 130a is connected to the tip of the piston rod 130a, and can be moved up and down in accordance with the vertical movement of the piston rod 130a.

A flexible air seal 150 is provided at a portion of the connecting rod 100a that penetrates the casing to maintain air tightness inside and outside the mill.

The operation of the embodiment of the vertical crusher of the present invention configured as above will be described below.

The raw material supplied from the raw material charging chute 16 to the upper surface of the central portion of the rotary table 3 receives the centrifugal force of the rotary table 3 and draws a spiral trajectory on the rotary table, and is bitten by the auxiliary roller 30 to be compacted. It becomes a consolidation layer and is further sent to the crushing roller 4 arranged in the subsequent stage to be crushed. Then, the crushed powder rises faster than the annular space portion 14. The powder is blown up by hot air and is conveyed to the separator 15. The fine powder below the classification point is discharged by the discharge pipe 22 by the classification action of the separator 15, while the coarse powder above the classification point is returned to the rotary table 3 again.

By repeating the above-described operation, the crusher can continuously crush the raw material to continuously obtain fine powder as a product.

However, lowering the classification point of the separator to obtain ultra-fine powder, changing the raw material properties due to some cause during operation, or changing the content of water due to the change in the water content changes the pulverizability of the raw material until now. Even if the mill number, rotation table rotation speed, tension of the crushing roller against the rotation table surface, dam ring height, separator classification point, etc.) are the same, the proper balance between them is lost and the layer thickness is The phenomenon is that the mill vibration value increases and becomes abnormally high.

In this case, as shown in FIG. 3 (a) and FIG. 3 (b), by setting the height of the bottom surface of the scraper 100 to an appropriate height H, the consolidation of the appropriate raw material layer thickness H or more is performed. Raw material is G in the figure
As shown in (Overflow flow), it is removed by the scraper 100, the direction is changed to the outer peripheral side of the rotary table 3 to cause overflow, and it is sent upward by hot air as described above. On the other hand, the raw material up to the raw material layer thickness H follows the same trajectory as the conventional one as shown in F (bite flow) of the auxiliary roller 30.
Is supplied to. In addition, 4A indicates a biting side (upstream side) of the crushing roller, 4B indicates a downstream side of the crushing roller, reference numeral 50 indicates a coarse and dense layer, and reference numeral 60 indicates a compaction layer.

Therefore, even if the phenomenon that the thickness of the raw material layer temporarily increases, the thickness of the raw material layer that is bitten into the crushing roller 4 does not change, and therefore the natural frequency of the raw material layer does not change, so that the vibration suddenly increases. There is no increase and stable operation can be continued.

With the above-described structure and operation, the present invention can eliminate the increase in the thickness of the raw material layer, which causes the increase in mill vibration, by the scraper, so that the rapid increase in mill vibration can be prevented.

In addition, if the raw material overflowed from the outer circumference of the rotary table 3 by the scraper 100 is directly discharged to the outside of the crusher system, mixed into the raw material of the new feed and supplied to the crusher again, the present invention can be further improved in the mill. It is possible to reduce the pressure loss, reduce the running cost, and improve the grinding efficiency.

[Effects of the Invention] As is clear from the above description, in the vertical crusher of the present invention, the material layer thickness that is constantly supplied to the crushing roller can be kept substantially constant, so that a rapid increase in mill vibration is suppressed. It is possible to continue stable and continuous operation,
The productivity is improved and at the same time the equipment is prevented from being damaged and the life of the equipment can be extended.

[Brief description of drawings]

1 to 3 show an embodiment of the present invention, FIG. 1 is an overall schematic vertical sectional view, FIG. 2 is an enlarged view of a main part of a crushing section, and FIG. 2 (a) is a vertical sectional view. 2 (b) is a plan view, FIG. 2 (c) is a side view, FIG. 3 shows an arrangement of a scraper, an auxiliary roller, and a crushing roller, and FIG. 3 (a) is a plane arrangement view. FIG. 3 (b) is a front development view of FIG. 3 (a). 1 ... Vertical crusher, 3 ... Rotary table, 4 ... Grinding roller, 4 ... Annular space, 20 ... Casing, 30 ... Auxiliary roller, 32 ... Hydraulic cylinder, 34 ... Gap adjuster , 100 scraper, 100a connecting rod, 100b pin, 110 pin support, 120 pin support, 130 hydraulic cylinder, 130a piston rod, 140 mount, 150 air seal , H: raw material layer thickness, F: bite flow, G: overflow flow.

Claims (1)

[Claims] 1. A plurality of rotatable crushing rollers are arranged on the upper surface of the outer peripheral portion of a rotary table, and a predetermined crushing pressure is applied to the raw material supplied to the central portion of the rotary table to apply a predetermined crushing pressure to the upper surface of the rotary table and the peripheral surface of the crushing roller. In the vertical crusher for crushing between the crushing surface and the surface, a rotatable auxiliary roller for compressing the layer of the raw material for biting into the crushing roller on the peripheral surface is provided on the upper surface of the outer periphery of the rotary table between the crushing rollers. A vertical type in which a scraper capable of moving up and down is provided between the auxiliary roller and a crushing roller located downstream of the auxiliary roller, and a vertical moving means for moving the scraper is provided. Crusher.