JPH06106085A - Method and device for shock crushing of rock and ore lump - Google Patents

Abstract

PURPOSE: To improve the efficiency of crushing system and to decrease the number of crushing processes by specifying the min. moment given to lump by primary impact force and increasing the moment given to the lump by secondary impact force by specific times that by the primary impact force. CONSTITUTION: The rock and the ore lump are coarsely crushed into small chips by applying the primary impact force with a primary crushing rotor 1 and are thrown toward secondary crushing rotors 2, 3 by the rotation of the primary crushing rotor 1. Because the secondary crushing rotors 2, 3 are constituted so as to be rotated synchronously with the primary crushing rotor 1, the small chips collide vertically with the impact reflecting surfaces of the secondary crushing rotors 2, 3 to be crushed into fine particles. The min. moment given to the lump by the primary impact force is controlled to 180 kgm/sec and the moment given to the lump by the secondary impact force is controlled to 0.3-70 times the moment given to the lump by the primary impact force. As a result, the crushing efficiency by the secondary crushing rotors 2, 3 is increased.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for impact crushing rock and ore blocks and an apparatus for carrying out the method.

INDUSTRIAL APPLICABILITY The present invention can be applied to the mining industry, the chemical industry, the construction industry and the coal industry for crushing raw materials and processing mineral fertilizers and mineral feeds.

[0003]

BACKGROUND OF THE INVENTION Impact crushing techniques are well known and are carried out by equipment that includes multiple hammers and rotating crushers.

The conventional impact crushing method is performed in several steps. In the first step, the impact tool or hammer of the crusher hits the feed lump placed in the crushing chamber. Each mass to which the first impact force is applied is partially crushed and thrown toward the reflecting member at a constant speed.

In the second step, a secondary impact force is applied to the lump projected on the reflecting member to crush the lump into a certain size. In the simple case of crushing the mass in two steps using one reflecting member, the crushing effect is small.

The reflecting members which are continuously arranged in the front and back are metal plates, grid rods, rods, rods or nets.

To improve the crushing effect, three or four
One reflection member, and rarely five or more reflection members are provided. In this case, the mass is crushed in 4 to 6 steps.

From the point of view of transmitted energy, the effect is the smallest when hitting a stationary wall. (EV Alexandrov, buoy
VV Sokolinsky, `` Applied Theory and Calculatio
n of Impact Systems ") Nedra Publisher, Moscow, 1969, see pages 15-17.

In the above method, the surface of the reflecting member has only a single function and only returns the fed mass of material toward the impact member of the primary crushing rotor, so the crushing effect is small. In this case, the energy of the reflection member itself is not effectively used.

An impact crusher using centrifugal force is also widely used, and a rock mass comes into contact with an accelerating rotor or a disc,
High speeds of 100 to 120 m / s are provided. Centrifugal force throws the mass towards a ring-shaped wall that is fixed or rotatably mounted about a rotation axis.

The state of impact and subsequent crushing of the rock mass on the annular wall is not substantially different from the usual impact crushing method. Further, this method has a disadvantage that the configuration becomes extremely complicated and the use efficiency of electric power is poor.

Another conventional crusher is two AP-CMs.
It is equipped with a horizontal rotor of the mold. (For example,
Dresser Holmes route (Roo
t) See the instructions for the Holmes Hazemag factory, which is a division).

The two rotors are vertically arranged in the crusher and are mounted on a rotating shaft inclined at an angle with respect to the horizontal plane. In this crusher, rock mass is 1
Continuous crushing by a secondary crushing rotor and then by a reflective member installed along the periphery, and further by a secondary crushing rotor also equipped with a fixed or spring-biased reflective member along the peripheral edge. To be done.

Crushing is performed in 6 to 8 steps.
To increase the number of collisions, one rotor is equipped with six hammers.

This crusher also has the above-mentioned drawbacks, namely, high power consumption and low efficiency.

Still other conventional shredders (eg 19
In French Patent No. 2,091,446 issued in 1972), two rotors having axes inclined at a certain angle with respect to the horizontal plane are arranged vertically.

These two rotors rotate in opposite directions. The two rotors continuously crush rocks,
It also has a fixed reflection member. This crusher requires a large size of equipment, is inconvenient to operate, and requires a large amount of power and materials.

In still another conventional crusher, a primary crushing rotor and two secondary crushing rotors are mounted in a housing, and a charging port is provided above the primary crushing rotor. Is used as a charging chute for feeding into a primary crushing rotor, and an outlet is provided at the bottom (for example, the Soviet Socialist Republic Federal Inventor Certificate, No. 18).
No. 3,053).

This crusher is for crushing rocks and ore blocks by impact, applying a primary impact force to the lumps of rock and breaking them into small pieces, and then a secondary impact force of the vector force distributed stochastically. Is to add.

In operation, the material to be crushed is applied to the primary crushing rotor and then thrown towards the hammer of the secondary crushing rotor. In this crusher, the hammer of the secondary crushing rotor is used as the reflecting means.

The rock mass is crushed in three steps. First
In the process, the material is crushed by engaging the hammer of the primary crushing rotor. In the second step, the material is crushed by engaging the hammer of the secondary crushing rotor. In the third step, the mass is finally crushed and sent to a grid rod.

Although this crusher can improve the efficiency of crushing and the quality of materials to some extent, it has many drawbacks as follows.

Since the operation of all the rotors is not synchronized in terms of time, the stochastic pattern of rock mass fragmentation is not uniform.

Since the rotation speed of the secondary crushing rotor is low and the impact force is not essentially directed to the center, the efficiency of the impact force applied to the rock mass by the secondary crushing rotor is poor.

Since the mass of the secondary crushing rotor that performs the reflecting action converges on the center, the crushing effect of the rotor does not work sufficiently.

Since the primary and secondary crushing rotors are mounted on the vertical shaft, the degree of improvement in crushing efficiency is low, the crusher becomes large, and operation and maintenance are troublesome.

[0027]

DISCLOSURE OF THE INVENTION The present invention solves the above problems in impact crushing of rock and ore lumps, and the primary crushing force applied to large sized lumps and the secondary crushing applied to small sized lumps. Impact crushing method, which can significantly increase the efficiency of the crushing method, crush extremely hard rock into small dimensions, and reduce the number of crushing steps by the effect of synchronization with force The purpose is to provide a crusher.

[0028]

In order to achieve the above object, the present invention is configured as follows.

A primary impact force is applied to a rock mass to crush it into a large number of small pieces, and then a secondary impact force in which a vector force is stochastically distributed is applied to impact-crush a rock mass and an ore mass. Method, the primary impact force P ₁ being applied to a large sized mass
Is time-synchronized with the secondary impact force P ₂ applied to the crushed pieces, and the vector of the velocity vector V ₁ and the secondary impact force P ₂ given to the mass by the primary impact force P ₁ is defined as the mass of the mass. When the minimum moment given to the mass along the line passing through the center and given to the mass by the primary impact force P ₁ is 180 Kgm / sec, the secondary impact force P _{2 with} respect to the moment given to the mass by the primary impact force P ₁ A method for impact crushing rock or ore lumps, characterized in that the moment given to the lumps is set in the range of 0.3 to 70.0 times.

A housing (4) having a primary crushing rotor (1) therein and a secondary crushing rotor (2) and a charging port (5) is provided above the housing, and the wall surface of the housing (4) is provided. In a device for impact crushing rocks and ore lumps, which is a feed chute (6) for feeding rocks and ore lumps to the primary crushing rotor (1), and a discharge port (7) provided below it, a primary crushing rotor (1) and the secondary crushing rotor (2) are dynamically connected to each other, and the secondary crushing rotor (2) is equipped with at least two hammers. (a ₂ ) A shock-reflecting surface with a curved cross-section in a plane perpendicular to the plane is provided, and the mass along the axis of symmetry in the length direction is increased according to the distance from the rotation axis to make The moment of inertia along the transverse axis of symmetry to more than 5 times the moment of inertia Impact crusher, characterized in that the.

In this apparatus, a secondary crushing rotor and 1
The means for rotating the sub-crushing rotor synchronously may be a chain type transmission in which the sprockets 9 and 10 are fixed to the respective rotor shafts.

The means for synchronously rotating the secondary crushing rotor and the primary crushing rotor may be a chain gear type transmission in which gears are mounted on the respective rotor shafts.

The means for synchronously rotating the secondary crushing rotor and the primary crushing rotor may be a gear type transmission.

The means for synchronously rotating the secondary crushing rotor and the primary crushing rotor may be a continuously variable transmission.

The impact-reflecting surface of the secondary crushing rotor (2) is formed into an arcuate surface, and its radius of curvature R is set to the feeding chute (6).
Secondary crushing at a position where the radius of curvature concerned is orthogonal to the longitudinal axis of the secondary crushing rotor (2) from the intersection (O) of the surface of the secondary crushing rotor (1) with the circumference of the maximum radius of gyration rotor
It is desirable to make it equal to the distance to the impact reflection surface of (2).

The shock-reflecting surface of the secondary crushing rotor (2) may be formed in a wavy shape.

A second secondary crushing rotor (3), which is a mirror image of the first secondary crushing rotor (2), is attached to each rotor (2).
The longitudinal axes X-X and Y-Y of (3) are the rotors (2).
It is provided at a position that is orthogonal to the radius of curvature of the impact reflection surface that passes through the rotation center of (3) and at a position where the gap between the two is minimized.
It is desirable to provide a means for mechanically connecting the sub-crushing rotors (2) and (3) to rotate them in opposite directions.

The impact-reflecting surface of the secondary crushing rotor (2) may be two concave surfaces in a cross section orthogonal to the rotation axis of the rotor.

The impact-reflecting surface of the secondary crushing rotor (2) may be formed by a straight line portion and a curved portion connected to the straight line portion on the plane orthogonal to the rotation axis.

[0040]

[Operation] First, the primary crushing rotor applies a primary impact force P ₁ to the rocks and ore lumps to roughly crush them into small pieces, which are projected toward the secondary crushing rotor by rotation of the primary crushing rotor. Since the secondary crushing rotor is configured to rotate in synchronization with the primary crushing rotor, the small pieces collide vertically with the impact reflection surface of the secondary crushing rotor and are crushed into fine particles.

[0041]

EXAMPLES The method of impact crushing rocks and ore blocks of the present invention is carried out as follows. 1 to 4 are schematic views showing the steps of an impact crushing method of the present invention for making a rock mass fine by using two rotors of a primary crushing rotor and a secondary crushing rotor according to the present invention.

First, the rock is sent to a crusher equipped with a single primary crushing rotor and a single secondary crushing rotor to be finely crushed.

In FIG. 1, a rock mass is sent to a primary crushing rotor (1) at a speed V along an inclined chute and is crushed by a primary impact force.

The impact force breaks the mass into a number of small pieces,
As shown in, the velocity V ₁ toward the secondary rotor (2) is given. The primary rotor (1) rotates at an angular velocity ω ₁ .

The secondary rotor (2) rotates at an angular velocity ω ₂ in the direction opposite to that of the primary rotor (1). As shown in FIG. 3, the small pieces reach the secondary crushing rotor (2) and receive the secondary impact force. The method is performed in such a way that the primary impact force applied to the large mass is synchronized with the secondary impact force applied to the small pieces.

The direction of the velocity vector V ₁ of the primary impact force applied to the mass P ₁ and the secondary impact force P ₂ vectors, are oriented so as to pass through the center of mass of the mass.

The reflecting member of the secondary crushing rotor (2) not only has the function of reflecting a lump and partially crushing it,
It also acts to break up the mass with the kinetic energy transmitted to it.

[0048] applied to the mass by the secondary impact force P ₂ moment is proportional to the moment applied to the mass by the primary impact force P _1, when the minimum moment by the primary impact force P ₁ is a 180kgm / sec, P A value of ₁ of 0.3
It is double to 70 times.

The secondary impact force P ₂ is crushed into smaller particles pieces, as shown in FIG. 4, the speed toward the lattice bars V
Project with ₂ .

As shown in FIGS. 5 to 8, one primary crushing rotor (1) and two secondary crushing rotors (2) and (3)
If a crusher equipped with and is used, the crushing can be performed more effectively.

In this case, the rock mass is first sent to the primary crushing rotor (1) at a speed V along an inclined chute as shown in FIG. 5 to give a primary impact force. The primary crushing rotor (1) is rotating at an angular velocity ω ₁ .

As shown in FIG. 6, the mass is crushed into a number of small pieces and is given an impact vector V ₁ towards the secondary crushing rotors (2) and (3). Secondary crushing rotor (2) and (3)
Rotate in opposite directions with equal angular velocity ω ₂ = ω ₃ .

As shown in FIG. 7, the crushed pieces reach the secondary crushing rotors (2) and (3), and the secondary impact force P ₂
Can be added.

The impact forces P ₁ and P ₂ are synchronized in time. The vector of the velocity V ₁ given to the mass by the primary impact force P ₁ and the vector of the secondary impact force P ₂ are oriented so as to pass through the mass center of the mass.

The operation mode imparted to the reflecting members of the secondary crushing rotors (2) and (3) which partially transmit kinetic energy depends on the energy received by the mass by the effect of the primary impact force P ₁ and The mass can be crushed sufficiently finely.

The time for the lumps to collide with the reflector to release all kinetic energy is considerably shorter than the standard impact time in a conventional impact crusher. The supercritical stress field produced by this energy is greater than the strength of rocks of all kinds.

Upon impact, the solid-state rock is irreversibly converted and rapidly crushed into small size particles, as shown in FIG. An important feature of this method is that it imparts new properties to the crushing process, in particular that it rapidly improves the efficiency of the crushing and results in the formation of microparticulate products of substantially uniform grain size.

By varying the collision conditions, ie, adjusting the magnitude and velocity parameters of the force vector, the crushing process is controlled to obtain a product of the desired particle size composition and the crushed product discharged is It is recognized that resistance can be reduced.

FIG. 9 is a schematic view of an impact crusher in which one primary crushing rotor (1) is mounted in the housing (4) and one secondary crushing rotor (2) is mounted above it. Is.

The housing (4) has a charging port (5) above the rotor (1), and the wall of the housing (4) acting as a feeding chute (6) is used for primary crushing of rocks and ore blocks. Send to the rotor (1). Below the rotor (1) there is a discharge hole (7) with a grid rod (8).

This crusher comprises means for synchronizing the primary crushing rotor and the secondary crushing rotor, which means
Dynamically connected to the two rotors (1) and (2).

Next, one embodiment of means for synchronizing the rotations of the secondary crushing rotor and the primary crushing rotor will be described.

In the embodiment of FIG. 9, the secondary crushing rotor
(2) is equipped with two hammers and a shock reflecting surface whose curvature changes in a plane perpendicular to the rotation axis a ₂ , and the mass of the rotor (2) along the axis of symmetry XX is measured. , And is increased according to the distance from the rotation axis (a ₂ ). The moment of inertia along the longitudinal axis of symmetry XX of the rotor (2) is more than five times the moment of inertia along the lateral axis of symmetry YY.

In this embodiment, the means for synchronously rotating the secondary crushing rotor and the primary crushing rotor is of the chain transmission type.

In FIG. 10, the sprocket (9) is fixed to the primary crushing rotor (1) by a shaft (not shown), and the sprocket (10) is fixed to the secondary crushing rotor (2). (11) is a tension sprocket, (12) is a guide sprocket, and (13) is a chain.

In another embodiment (not shown), a gear train transmission rotates one secondary crushing rotor synchronously with the primary crushing rotor. In this embodiment, similarly to the above, the gears of the transmission are fixed to the respective shafts of the rotors (1) and (2).

FIG. 11 shows one primary crushing rotor (1)
FIG. 3 is a schematic view showing another embodiment of an impact crusher including a secondary crushing rotor (2) and two secondary crushing rotors (3).

The rotors (2) and (3) are arranged at symmetrical mirror image positions. The longitudinal axes X-X and Y-Y of each rotor (2) and (3) are perpendicular to the radius of curvature of the impact reflecting surface passing through the center of rotation of each rotor.

This crusher is provided with means for rotating the secondary crushing rotor and the primary crushing rotor in synchronization.
Further, this crusher is provided with means for rotating two secondary crushing rotors in opposite directions.

As means for synchronously rotating the secondary crushing rotor and the primary crushing rotor, a chain transmission type means is provided. As with the previous embodiment, the transmission sprockets are fixed to the shaft of each rotor.

In FIG. 12, the sprocket (14) is fixed to the rotor (1) coaxially, the sprocket (15) is fixed to the rotor (2) coaxially, and the sprocket (16) is fixed to the rotor (3) coaxially. is there. Illustration of these axes is omitted in FIG.

(17) is a tension sprocket and (18) is a chain. With this configuration, the secondary crushing rotor (2)
It rotates in the opposite direction to (3).

Another embodiment of synchronously rotating the secondary crushing rotor and the primary crushing rotor is a gear chain type transmission. In the embodiment shown in FIG. 13, each rotor shaft is equipped with a gear or, alternatively, a rotor (2)
And the transmission is constituted by a device dynamically connected to the shaft of (3).

In this embodiment, the gears are fixed coaxially with the respective rotors. The gear (19) is fixed to the shaft of the rotor (1), the gear (20) is fixed to the shaft of the rotor (2), and the gear (21) is fixed to the shaft of the rotor (3). (22) is a tension sprocket, (23) is a guide sprocket, and (24) is a chain.

FIG. 14 is a schematic view showing an embodiment in which the secondary crushing rotor and the primary crushing rotor are synchronously rotated by the gear type transmission. The gear 25 is fixed to the shaft of the rotor 1, the gear 26 is fixed to the shaft of the rotor 2, and the gear 27 is fixed to the shaft of the rotor 3. Gears (28) and (29) are gears for interlocking.

In another embodiment, the means for synchronously rotating the secondary crushing rotor and the primary crushing rotor is a continuously variable transmission (not shown) such as an expansion pulley or a friction clutch.

In the above-mentioned embodiment, the impact reflection surface of the secondary crushing rotor (2) shown in FIG. 11 is an arc surface, and its radius of curvature R is the surface of the feeding chute (6) and the primary crushing rotor (2). The impact reflection surface of the secondary crushing rotor (2) at a position where this radius of curvature is orthogonal to the longitudinal axis XX of the secondary crushing rotor (2) from the intersection point O with the maximum turning radius R ₁ of 1). It is equal to the distance to.

Normally, this shock-reflecting surface is designated by the symbol (3
It is smooth as shown in (0). In another embodiment, the code
As shown in (31), it is wavy.

The cross section of the secondary crushing rotor (2) perpendicular to the axis of rotation may be two concave surfaces.

Secondary crushing rotor in another embodiment (2)
As shown in FIG. 16, the cross-sectional shape perpendicular to the axis of rotation is a straight line portion (32) and a curved portion (33) connected at point A.

The operation of the impact crusher of the present invention is as follows.

In FIG. 11, the rock mass is the primary crushing rotor along the feeding chute (6) from the charging port (5).
(1) Delivered on one of the hammers.

The rock mass subjected to the primary impact force from the hammer is crushed into small pieces and thrown toward the secondary crushing rotors (2) and (3).

The projection path of the rock fragments is the primary crushing rotor.
Starting from point O on the front edge of the hammer in (1), it spreads in a fan shape with a vector R in the radial direction.

The rotation of the secondary crushing rotors (2) and (3) is
It is synchronized with the rotation of the primary crushing rotor (1) through the interlocking link mechanism, and at the moment when the rock fragment collides, the reflecting surface forming the curved surface with the radius of curvature R is in the radial direction of the rock fragment. The vector is positioned perpendicular to each point on the reflecting surface.

Due to this collision, the rock fragments absorb more energy than necessary to break them, according to the following equation: WΣ = W ₁ + W ₀ Here, WΣ is the total energy absorbed by the material to be crushed, W ₁ is the energy obtained by the rock fragments by the primary impact, and W ₀ is the energy of the reflecting member.

The second impacted rock fragments are divided into extremely fine particles, and the whole process is repeated rapidly, and the primary crushing rotor and the secondary crushing rotor rotate in opposite directions. The crushed product is
It is discharged through (7) and collected.

[0088]

(A) By using a simple device having a small number of constituent parts and a small number of steps, rocks or ore blocks can be efficiently crushed, and equipment cost and labor can be reduced. .

(B) Compared with the conventional crushing method and apparatus,
Even harder rocks can be crushed.

(C) A granular product of desired size and quality can be obtained in one step.

(D) Power consumption and metal materials can be saved as compared with the conventional device.

(E) It is possible to obtain a crushed product having a substantially uniform shape as compared with the conventional method and apparatus.

(F) Lower operating costs and lower original costs of treated storage minerals compared to conventional methods and equipment.

[Brief description of drawings]

FIG. 1 is an explanatory view showing a first step of an impact crushing method of the present invention in which a rock mass is crushed by two rotors.

FIG. 2 is likewise an explanatory view showing a second step.

FIG. 3 is likewise an explanatory view showing a third step.

FIG. 4 is likewise an explanatory view showing a fourth step.

FIG. 5 is an explanatory view showing a first step of the impact crushing method of the present invention for crushing a rock mass by using three rotors, one primary crushing rotor and two secondary crushing rotors. .

FIG. 6 is likewise an explanatory view showing a second step.

FIG. 7 is an explanatory diagram similarly showing a third step.

FIG. 8 is an explanatory diagram similarly showing a fourth step.

FIG. 9 is a sectional view of an impact crusher of the present invention including one primary crushing rotor and one secondary crushing rotor.

FIG. 10 shows a secondary crushing rotor and a primary crushing rotor,
FIG. 6 is a schematic view of a means for synchronously rotating in a chain conduction mode.

FIG. 11 is a sectional view of an impact crusher of the present invention including one primary crushing rotor and two secondary crushing rotors.

FIG. 12 is a schematic view of means for synchronously rotating two secondary crushing rotors and one primary crushing rotor in a chain conduction mode.

FIG. 13 is a schematic view of means for synchronously rotating two secondary crushing rotors and one primary crushing rotor in a gear chain conduction mode.

FIG. 14 is a schematic view of means for synchronously rotating two secondary crushing rotors and one primary crushing rotor in a gear transmission type.

FIG. 15 is a cross-sectional view of a secondary crushing rotor in which a part of the impact reflecting surface is formed in a wavy shape.

FIG. 16 is a cross-sectional view of a secondary crushing rotor in which a cross section orthogonal to the rotation axis of the impact reflection surface is formed by a straight portion and a curved portion.

[Explanation of symbols]

(1) Primary crushing rotor (2) (3) Secondary crushing rotor (4) Housing (5) Loading port (6) Feed chute (7) Discharge port (8) Lattice bar (9) (10) Sprocket ( 11) Tension sprocket (12) Guide sprocket (13) Chain (14) (15) (16) Sprocket (17) Tension sprocket (18) Chain (19) (20) (21) Gear (22) Tension sprocket (23) Guide sprocket (24) Chain (25) (26) (27) (28) (29) Gear (30) Smooth surface (31) Ruffled surface (32) Straight part (32) Curved part

Claims (11)

[Claims] 1. A first impact force is applied to a rock mass to crush it into a large number of small pieces, and then a second impact force in which a vector force is stochastically distributed is applied to impact the rock and ore mass. A method of crushing, in which the primary impact force P ₁ applied to a large sized mass is synchronized in time with the secondary impact force P ₂ applied to a crushed piece, and 1
The velocity vector V ₁ and the vector of the secondary impact force P ₂ given to the lump by the primary impact force P ₁ are given along the line passing through the center of mass of the lump, and the minimum given to the lump by the primary impact force P ₁ When the moment is 180 Kgm / sec, the moment given to the mass by the primary impact force P ₁ is 2
A method of impact crushing rock and ore lumps, characterized in that the moment given to the lump by the next impact force P ₂ is in the range of 0.3 to 70.0 times. 2. A housing (4) comprising a primary crushing rotor (1) inside and a secondary crushing rotor (2) and a charging port (5) above the housing (4). In a device for impact crushing rocks and ore lumps, the wall surface is a feed chute (6) for feeding rocks and ore lumps to the primary crushing rotor (1), and the discharge port (7) is provided below it. The secondary crushing rotor (1) and the secondary crushing rotor (2) are dynamically connected to each other, and the secondary crushing rotor (2) is equipped with at least two hammers. , A shock-reflecting surface having a curved cross-section in a plane perpendicular to the axis of rotation (a ₂ ), and increasing the mass along the axis of symmetry in the length direction according to the distance from the axis of rotation, The moment of inertia along the axis of symmetry should be less than 5 times the moment of inertia along the transverse axis of symmetry. Impact crusher, characterized in that the the. 3. A chain type transmission device having sprockets (9) and (10) fixed to respective rotor shafts as means for synchronously rotating the secondary crushing rotor and the primary crushing rotor. The impact crusher according to claim 2. 4. The impact according to claim 2, wherein the means for synchronously rotating the secondary crushing rotor and the primary crushing rotor is a chain gear type transmission having gears mounted on respective rotor shafts. Crushing machine. 5. The impact crushing machine according to claim 2, wherein the means for synchronously rotating the secondary crushing rotor and the primary crushing rotor is a gear transmission. 6. The impact crusher according to claim 2, wherein the means for synchronously rotating the secondary crushing rotor and the primary crushing rotor is a continuously variable transmission. 7. A secondary crushing rotor (2) is provided with an impact reflecting surface formed in an arcuate surface, and its radius of curvature R is fed into a chute.
From the intersection (O) of the plane of (6) and the circumference of the maximum turning radius of the primary crushing rotor (1), the radius of curvature concerned is the secondary crushing rotor.
7. The impact crusher according to any one of claims 2 to 6, wherein the distance is equal to the impact reflection surface of the secondary crushing rotor (2) at a position orthogonal to the longitudinal axis of (2). . 8. The impact crusher according to claim 2, wherein the impact reflection surface of the secondary crushing rotor (2) is formed in a wavy shape. 9. A second secondary crushing rotor (3), which is a mirror image of the first secondary crushing rotor (2), is provided with each rotor.
(2) The axes XX and YY in the length direction of (3) are the rotors.
(2) The secondary crushing rotors (2) and (3) are installed dynamically at a position that is orthogonal to the radius of curvature of the impact reflection surface that passes through the rotation center of (3) and the gap between them is minimized. Combined with
The impact crusher according to claim 2, further comprising means for rotating in the reverse direction. 10. The impact crusher according to claim 2, wherein the impact reflection surface of the secondary crushing rotor (2) is two concave surfaces in a cross section orthogonal to the rotation axis of the rotor. 11. The impact according to claim 2, wherein the impact-reflecting surface of the secondary crushing rotor (2) is formed by a straight line portion and a curved portion connected to the straight line portion in a plane orthogonal to the rotation axis. Crushing machine.