JPH06343884A - Water adding device for gyratory crusher - Google Patents

Abstract

PURPOSE:To effectively perform crushing without the difference in partial packing, the throughput in the circumferential direction of a crusher and the wear of a tooth plate being generated by sufficiently performing the mixing of a material to be treated and water. CONSTITUTION:A chute in the form of a funnel 17 which is arranged in the center above an inlet hopper and for guiding a material to be treated M thrown in by a feeder 16 onto a cap 9 of the main shaft, a pressure water introducing pass 20 which is arranged along the upper edge of the chute and into which pressure water is introduced, and a lot of nozzles which are fitted to the pressure water introducing pass away from each other in its circumferential direction and for jetting pressure water toward the upper surface of the cap are provided, causing the dynamic change in the material to be treated to be increased, allowing the mixing of it with water.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water adding device for a rotary crusher such as a corn crusher or a gyratory crusher.

[0002]

2. Description of the Related Art In general, the water content in a treated product has a great influence on the treated amount (passage amount) of a rotary crusher, and sometimes a packing phenomenon occurs. Such a tendency becomes remarkable especially when the treated product has tackiness due to adhesion of water, mud, clay and the like. That is, the processing amount is as shown in FIG.
As shown in, the water content decreases as the water content increases, and when it exceeds a certain ratio, it starts to increase (curve a) and sometimes exceeds the throughput in the dry state (curve b). In addition, the water content value (water weight / (stone weight + water weight) × 100%) at which the treatment amount is the smallest also differs depending on the treated products as shown by the curves c and d. The processing amount becomes zero and the crusher may be blocked.

[0003] Conventionally, in order to address the above-mentioned problems, an annular water supply pipe is attached to the upper part of the inlet hopper with the intention of shifting the throughput from the lowest point to the increasing side by adding water.
A watering device for a rotary crusher is known, which is configured to uniformly and continuously supply water to the entire crushing chamber through a penetrating water discharge port provided over the entire inner circumference thereof (Japanese Patent Publication No. 60-57375).

[0004]

However, in the conventional watering device of the rotary crusher, even if water is evenly and continuously supplied from above the treated material put in the crushing chamber, the treated material and water are Was not sufficiently mixed. By the way, it has been clarified by experiments that the method of adding water at the position where the treated product changes dynamically is the most efficient in the case of uniformly mixing the treated product and water. For this reason, partial packing occurs in the crushing chamber, which causes a difference in the processing capacity in the circumferential direction in the crushing chamber and the wear of the tooth plate. Therefore, the present invention makes it possible to sufficiently mix the treated material and water so that there is no partial packing, and there is a difference in the treatment capacity in the circumferential direction in the crushing chamber and the wear of the tooth plate. It is an object of the present invention to provide a watering device for a rotary crusher that can efficiently crush without causing crushing.

[0005]

In order to solve the above-mentioned problems, the water supply device of the first rotary crusher of the present invention is arranged in the center of the upper part of the inlet hopper, and treats the processed material fed from the feeder. A funnel-shaped chute that guides onto the cap of the main shaft, a ring-shaped pressurized water introduction path that is arranged along the upper edge of the chute and into which pressurized water is introduced, and is installed in the pressurized water introduction path so as to be spaced apart in the circumferential direction. , A plurality of nozzles for injecting pressurized water toward the upper surface of the cap. Also, the water addition device of the second rotary crusher is the same as the first water addition device.
In the water adding device of the rotary crusher, a circular second pressurized water introducing passage which is arranged along the inner circumference of the upper edge of the inlet hopper and into which pressurized water is introduced, and the second pressurized water introducing passage in the circumferential direction thereof. And a plurality of second nozzles for spraying pressurized water toward the entrance of the crushing chamber.

[0006]

In the first means described above, a part of the processed material introduced from the feeder undergoes a dynamic change due to the collision with the chute through the water, and at the same time, the water slides on the chute using the water as a lubricant. The remaining portion directly falling from the feeder collides with that falling from the chute through water, and further, these collide with the cap of the main spindle through water and are introduced into the crushing chamber. Further, in the second means, in addition to the function of the first means, water is directly and evenly supplied directly to the processed material in the crushing chamber. Further, it is characterized in that the jetting direction of the nozzle and the generatrix of the chute make an angle of 0 to 5 °, and both the treated material and the water are provided so as to gather on the cap of the main shaft.

[0007]

Embodiments of the present invention will be described below with reference to the drawings. 1 and 2 are a sectional view in which a part of a cone crusher showing an embodiment of the present invention is omitted, and an enlarged sectional view of an essential part. In the figure, reference numeral 1 denotes an upper frame, which is connected to an upper portion of a lower frame 3 placed on a pedestal 2. On the upper part of the upper frame 1, a cylindrical inlet hopper 4 that serves as an inlet for raw stones as a processed material is continuously provided, while on the inside of the upper frame 1, a truncated cone-shaped cone cave 5 is mounted. ing. A sleeve having an eccentric shaft hole is rotatably fitted in a boss (not shown) of the lower frame 3, and a main shaft 6 is rotatably inserted in the eccentric shaft hole of the sleeve. The lower end of the main shaft 6 is supported by a lower bearing (not shown), and the upper end thereof is supported by an upper bearing 8 attached to the upper frame 1 via a spider 7, and the upper bearing 8 is supported by a cap 9 Is covered by. Spindle 6
A frustoconical cylindrical mantle 11 which cooperates with the cone cave 5 to form a crushing chamber 10 having a wedge-shaped cross section is attached via a mantle (not shown). On the other hand, a driven bevel gear, not shown, is attached to the lower end of the sleeve through which the main shaft 6 is inserted, and the driven bevel gear attached to the inner end of the horizontal rotary shaft 12 meshes with this driven bevel gear. Has been done. A pulley 13 is attached to the outer end of the horizontal rotary shaft 12 so as to be interlocked with an electric motor (both not shown) via a belt. The lower end of the main shaft 6 rotates eccentrically according to the amount of eccentricity of the sleeve due to the rotation of the sleeve accompanying the driving of the electric motor. Together with this, it rotates in the direction opposite to the above-mentioned turning motion.

A first watering device 14 and a second watering device 15 are mounted on the upper part of the inlet hopper 4. First
The water adding device 14 is a device for adding water to the processed material fed from the feeder 16 (see FIG. 3) to uniformly mix the two.
It is configured as follows. That is, the entrance hopper 4
A funnel-shaped chute 17 is arranged in the center of the upper part of the machine via a plurality of arms 18, and a generatrix on the inner peripheral surface of the chute 17 guides the processed material introduced from the feeder 16 onto the cap 9 of the spindle 6. Therefore, the cap 9 is provided so as to intersect at the center of the upper surface. At the upper edge of the chute 17, an annular first pressurized water introducing passage 20 through which pressurized water is introduced from a pressurized water source (not shown) through the pressurized water introducing pipe 19 is arranged along the entire circumference. 1 pressurized water introduction path 20
The inner peripheral wall 21 is appropriately extended in the vertical direction so as to also serve as a nozzle protection described later. On the lower surface of the first pressurized water introducing passage 19, a large number of first nozzles 22 for injecting pressurized water toward the upper surface of the cap 9 are provided, and the ejection direction thereof is 0 to 5 ° with the generatrix of the inner peripheral surface of the chute 17. At an angle θ (see FIG. 3), and are mounted at appropriate intervals in the circumferential direction.

The second watering device 15 compensates for the shortage of an appropriate amount of water due to the increase in the surface area of the processed material due to the crushing in the crushing chamber 10, and is constructed as follows. That is, in the inner circumference near the upper edge of the inlet hopper 4, a second annular pressurized water introduction passage 24 through which pressurized water is introduced from a pressurized water source through the pressurized water introduction pipe 23 is provided along the entire circumference through the arm 18. Are arranged. On the lower surface of the second pressurized water introducing passage 24, a large number of second nozzles 25 for uniformly injecting the pressurized water toward the inlet of the crushing chamber 10 are attached at appropriate intervals in the circumferential direction.

In FIGS. 1 and 2, 26 is a curtain suspended around the lower outer periphery of the chute 17, and 27 is a curtain suspended around the inner periphery of the second pressurized water introducing passage 24. The passage 24 and the second nozzle 25 are prevented from being damaged.

In the cone crusher having the above construction, when the electric motor is driven to rotate the mantle 11, the pressurized water is supplied from the pressurized water source to the first and second watering devices 14 and 15, and the processed material is fed from the feeder 16. as shown in FIG. 4, the processing object M is changing the potential energy to velocity energy, partly collides with the chute 17 of the first water adding unit 14 at a velocity v ₀ m / sec, where the speed v ₁ m / The dynamic change of sec is performed through the water from the first nozzle 22, and the water slides on the chute 17 using the water as a lubricant. Therefore, the processed product M
Does not adhere to the chute 17, and the water and the treated product M are rationally mixed. On the other hand, the rest of the processed material M directly falling from the feeder 16 at a speed of v ₂ m / sec collides with that falling from the chute 17 through water, and further collides with the cap 9 of the main shaft 6 through water. And speed v ₃
m / sec, the treated material M and water are evenly and sufficiently mixed and introduced into the crushing chamber 10. Therefore, in the crushing chamber 10, due to the rotational movement of the mantle 11 with the object to be treated M interposed between the crushing chamber 5 and the cone cave 5, partial packing does not occur, and the processing capacity in the circumferential direction in the crushing chamber 10 is high. The processed material M is efficiently crushed without causing a difference in wear of the tooth plate (cone cave and mantle). The surface area of the crushing chamber 10 increases with the progress of crushing of the processed material.
From the second nozzle 25 of the crushing chamber 10 as shown in FIG.
Water is evenly and evenly supplied directly to the treated material M inside, and an appropriate amount of water shortage due to the increase in surface area is replenished, so that partial packing, treatment capacity and tooth plate wear do not occur. Efficient crushing is performed.

[0012]

As described above, according to the first rotation type crusher water adding device of the present invention, a part of the processed material fed from the feeder is dynamically changed due to collision with the chute. While sliding through the chute with water as a lubricant, the rest directly falling from the feeder collides with the thing falling from the chute through the water, and these also pass through the cap of the spindle and the water. Since it collides and is introduced into the crushing chamber, it is possible to mix the treated material and water evenly and sufficiently, and eventually, when crushing the treated material in the crushing chamber, partial packing does not occur, and
There is no difference in the processing capacity in the circumferential direction in the crushing chamber and the wear of the tooth plate, and the processed material can be crushed efficiently. Further, according to the water addition device of the second rotary crusher, in addition to the action and effect of the first one, the water is evenly distributed directly to the treated material in the crushing chamber, which is about to be crushed to form a new surface. Since it is supplied evenly, it is possible to compensate for the shortage of an appropriate amount of water due to the increase in the surface area of the treated product due to crushing, and it is possible to crush more efficiently.

[Brief description of drawings]

FIG. 1 is a cross-sectional view in which a cone crusher showing an embodiment of the present invention is partially omitted.

FIG. 2 is an enlarged sectional view of a main part of the cone crusher shown in FIG.

FIG. 3 is an explanatory view illustrating an operation of a first nozzle of the first watering device in the cone crusher shown in FIG.

FIG. 4 is an explanatory view explaining the operation of the first watering device in the corn crusher shown in FIG. 1.

FIG. 5 is an explanatory view explaining the operation of the second watering device in the corn crusher shown in FIG. 1.

FIG. 6 is an explanatory diagram illustrating a relationship between a moisture value and a treatment amount of a treated product in the rotary crusher.

[Explanation of symbols] 4 inlet hopper 6 main shaft 9 cap 16 feeder 17 chute 20 first pressurized water introducing passage 22 first nozzle 24 second pressurized water introducing passage 25 second nozzle

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Yozo Kudo 1780 Kamitakano, Yachiyo-shi, Chiba Kawasaki Heavy Industries, Ltd. Yachiyo factory (72) Toru Nakanishi 1780 Uetakano, Yachiyo-shi, Chiba Kawasaki Heavy Industries Ltd. Company Yachiyo factory

Claims (2)

[Claims] 1. A funnel-shaped chute arranged in the center of the upper part of the inlet hopper for guiding the processed material introduced from the feeder onto the cap of the main shaft, and arranged along the upper edge of the chute to introduce pressurized water. An annular pressurized water introduction passage,
A watering device for a rotary crusher, comprising: a plurality of nozzles that are mounted in a pressurized water introduction path in a circumferentially spaced manner and that sprays pressurized water toward the upper surface of the cap. 2. An annular second pressurized water introducing passage, which is disposed along the inner circumference of the upper edge of the inlet hopper, and into which pressurized water is introduced, and is installed in the second pressurized water introducing passage so as to be spaced apart in the circumferential direction. , A large number of second jets of pressurized water towards the entrance of the crushing chamber
A watering device for a rotary crusher according to claim 1, further comprising a nozzle.