Background of the Invention
Field of the Invention
[0001] The present invention relates to apparatus and method of breaking pieces of solid
mineral material by feeding pieces of solid mineral material along the axle of a rotor
and rotating said rotor at an increased speed to throw said pieces of solid mineral
material from the radial outlets of said rotor in tangential directions to cause said
pieces of solid mineral material to strike against the "dead bed" of fragments of
solid mineral material which encircles said rotor and cause said pieces of solid mineral
material to reduce to fragments, and method of sorting resulting fragments of solid
mineral material according to size.
Description of the Prior Art
[0002] In a conventional method of breaking pieces of solid mineral material into fragments,
fragments of solid mineral material is heaped up to encircle a rotor and the rotor
is made to rotate to throw pieces of solid mineral material to the heap or "dead bed"
of fragments. Then, these pieces of solid mineral material strike the "dead bed" to
reduce to fragments, which are allowed to fall from the space between the rotor and
the breaking chamber. After leaving the lower part of the breaking apparatus the fragments
of solid mineral material are sorted according to size.
[0003] The breaking force available in such a breaking apparatus will depend on the force
with which pieces of solid mineral material can strike against the "dead bed", and
as a matter of course, the breaking g effect increases with the striking force. The
"dead bed", however, will be covered thick with fragments of relatively small size
because collision takes place on the surface of the "dead bed". Therefore pieces of
solid mineral material when thrown at the "dead bed" are likely to land soft on the
"dead bed", thereby causing thrown pieces of solid mineral material to lose their
kinetic energy, which otherwise, would be used to break pieces of solid mineral material
into fragments.
[0004] Also, disadvantageously fragments of different sizes are mixed, and therefore, subsequent
screening is necessitated
Summary of the Invention
[0005] With the above in mind one object of the present invention is to provide solid mineral
material breaking apparatus and method which can make full use of the kinetic energy
of thrown pieces of mineral material in breaking themselves in fragments, thereby
substantially increasing the breaking efficiency. Another object of the present invention
is to provide a method of sorting fragments of solid mineral material according to
size.
[0006] According to a first aspect of the present invention there is provided a centrifugal
breaking apparatus including. in a breaking chamber, a rotor and a hopper arranged
to supply pieces of solid mineral material along the axle of said rotor, thereby permitting
said rotor when rotating at an increased speed, to throw said pieces of solid mineral
material from the radial outlets of said rotor in tangential directions to cause said
pieces of solid mineral material to strike against the "dead bed" of fragments of
solid mineral material which encircles said rotor, and cause said pieces of solid
mineral material to reduce to fragments, characterized in that said breaking chamber
is open at its bottom floor and that said centrifugal breaking apparatus comprises
a vibrator, said breaking chamber having a support box fixed to its undersurface,
said support box being connected to said vibrator. According to a second aspect of
the present invention there is provided such a centrifugal breaking apparatus which
has a frame structure isolated from the breaking chamber, but still supporting the
breaking chamber so as to permit the vibration of the breaking chamber as separate
from the frame structure. According to a third aspect of the present invention there
is provided such a centrifugal breaking apparatus which has upper and lower frame
sections and that the upper frame section has a breaking chamber formed therein.
[0007] According to a fourth aspect of the present invention there is provided such a centrifugal
breaking apparatus which has a vibrating frame structure and a vibrator, said vibrator
along with a rotor drive motor being connected to the frame structure.
[0008] According to a fifth aspect of the present invention there is provided a method of
breaking pieces of solid mineral material by feeding pieces of solid mineral material
along the axle of a rotor and rotating said rotor at an increased speed to throw said
pieces of solid mineral material from the radial outlets of said rotor in tangential
directions to cause said pieces of solid mineral material to strike against the "dead
bed" of fragments of solid mineral material which encircles said rotor and cause said
pieces of solid mineral material to reduce to fragments, characterized in that said
"dead bed" of fragments of solid mineral material is subjected to vibration. In the
breaking apparatus and method just described, the "dead bed" is subjected to vibration
to cause fragments of relatively large size to come up on the surface of the "dead
bed", and therefore, pieces of solid mineral material when thrown to the "dead bed",
will strike against relatively large fragments on the surface of the "dead bed" so
that the kinetic energy of the flying pieces of solid mineral material may be fully
used in breaking themselves into fragments. Thus. the breaking efficiency will be
substantially increased.
[0009] According to a sixth aspect of the present invention there is provided a fragment-sorting
method in combination with such a breaking method just described in which fragment-sorting
method a separator plate is provided on the course on which fragments of solid mineral
material fall from the "dead bed", and when the "dead bed" is subjected to vibration,
fragments of relatively large size will come up on the surface of the "dead bed" to
permit these fragments of relatively large size to fall inside and fragments of relatively
small size to fall outside of the separator plate. Finally, according to a seventh
aspect of the present invention there is provided a fragment-sorting method in combination
with such a breaking method as described above in which fragment-sortering method
an outlet is provided in the vicinity of the "dead bed", and when the "dead bed" is
subjected to vibration, fragments of relatively large size will come up on the surface
of the "dead bed" to leave fragments of relatively small size inside and fall from
the outlet. In the fragment-sorting method just described, fragments of relatively
large size which come up on the surface of the "dead bed" as a result of vibration,
will be automatically selected and removed as separate from fragments of relatively
small size, which are left inside the "dead bed" as a result of the vibration.
[0010] Other objects and advantages of the present invention will be understood from the
following description of a breaking apparatus according to one embodiment of the present
invention, which is shown in the accompanying drawings:
Fig. 1 is a longitudinal section of a breaking apparatus according to one embodiment
of the present invention; and
Fig. 2 is a graphic representation showing the distribution of fragment sizes in a
conventional breaking method and a breaking method using vibration of the "dead bed"
according to the present invention.
[0011] Fig. 1 shows a centrifugal breaking apparatus according to one embodiment of the
present invention as including a rotor 1 in a breaking chamber 2. The rotor 1 is designed
to be driven at an increased speed by an associated motor (not shown). A hopper is
arranged above the rotor 1 to supply pieces of solid mineral material along the axle
of the rotor, thereby permitting the rotor 1 when rotating at an increased speed to
throw pieces of solid mineral material from its radial outlets in tangential directions
to cause pieces of solid mineral material to strike against the "dead bed" 3 of fragments
of solid mineral material which encircles the rotor 1. Then, the pieces of solid mineral
material reduce to fragments.
[0012] As shown, the centrifugal breaking apparatus has lower and upper frame sections 5a
and 8b coupled together. The breaking chamber 2 is built in the upper frame section
5b. The hopper (not shown) is connected to the top of the upper frame section 6b to
supply pieces of solid mineral material along the axle of the rotor 1 as described
above. The lower frame section 8a has an outlet 11 at the center of the bottom of
the lower frame section, an annular opening 12 encircling the outlet 11 and a chute
13 to collect fragments of solid mineral material falling from the annular opening
12.
[0013] As shown, the breaking chamber 2 of the upper frame section 5b is open at its bottom
floor, and the opening of the bottom floor is encircled by a cylindrical wall. The
breaking chamber 2 has an annular support box 4 connected to its undersurface. The
annular support box 4 is resiliently supported by springs 15 as indicated at the lower
frame section 6a, thus preventing transmission of vibration to the lower frame section
5a. The support box 4 is connected to a vibrator 5, which comprises a motor and an
associated eccentric can to vibrate the "dead bed" vertically. The support box 4 is
also connected to the upper and lower frame sections 6b and 8a by flexible material
such as rubber plates 7, thereby permitting the vertical vibration of the annular
box 4.
[0014] The lower frame section 6a has a cylindrical separator 8 arranged coaxial with the
lower frame section. When the support box 4 vibrates, fragments of relatively large
size come up on the surface of the "dead bed" to fall inside the cylindrical separator
8 whereas fragments of relatively small size fall between the cylindrical separator
8 and the lower frame section 6. Then, the fragments of relatively large size are
ejected from the exit 11 of the breaking system whereas the fragments of relatively
small size are ejected from the chute 13.
[0015] Fig. 2 shows the relationship between the fragment size and the weight of fragments
of diffferent sizes. Curve 1 shows the result of a conventional centrifugal breaking
system using no vibration whereas curves 2 shows the results of a centrifugal breaking
system using vibration according to the present invention. Taff having been supplied
to the rotor, particulars of the experiments are as follows:
[0016] Feeding rate of pieces of solid mineral material 40t/h
Circumferential speed of the rotor 55m/sec
Amplitude of the vibration of the support box 2. 5mm
Frequency of vibration 58Hz
[0017] As seen from Fig. 2, the rate of fragments of relatively small size is large in a
centrifugal breaking apparatus using vibration according to the present invention.
compared with a conventional centrifugal breaking apparatus using no vibration. This
shows that pieces of solid mineral material reduce to fragments at an increased efficiency
in the centrifugal breaking apparatus using vibration according to the present invention.
[0018] This particular embodiment uses a cylindrical separator to separate fragments of
solid mineral material according to size. In place of the cylindrical separator, however,
an outlet may be provided to the support box or the side wall of the breaking chamber
to allow fragments of relatively small size to leave the "dead bed" while fragments
of relatively large size slide and roll on the slant of the "dead bed" to fall in
the center hollow space of the centrifugal breaking apparatus. If occasions demand,
a net may be applied to the outlet of the breaking apparatus, thereby screening fragments
of solid mineral material.
[0019] This particular embodiment uses a support box as vibrating means. Alternatively the
breaking chamber, the upper frame section having a braking chamber, or the framework
itself may be designed to vibrate. When the framework is designed to vibrate as a
whole, a motor for driving the rotor is fixed to the framework so as to vibrate together
while rotating the rotor.
1. A centrifugal breaking apparatus including, in a breaking chamber, a rotor and
a hopper arranged to supply pieces of solid mineral material along the axle of said
rotor, thereby permitting said rotor when rotating at an increased speed to throw
said pieces of solid mineral material from the radial outlets of said rotor in tangential
directions to cause said pieces of solid mineral material to strike against the "dead
bed" of fragments of solid mineral material which encircles said rotor and cause said
pieces of solid mineral material to reduce to fragments, characterized in that said
breaking chamber is open at its bottom floor and that said centrifugal breaking apparatus
comprises a vibrator, said breaking chamber having a support box fixed to its undersurface,
said support box being connected to said vibrator.
2. A centrifugal breaking apparatus including, in a breaking chamber, a rotor and
a hopper arranged to supply pieces of solid mineral material along the axle of said
rotor, thereby permitting said rotor when rotating at an increased speed to throw
said pieces of solid mineral material from the radial outlets of said rotor in tangential
directions to cause said pieces of solid mineral material to strike against the "dead
bed" of fragments of solid mineral material which encircles said rotor and cause said
pieces of solid mineral material to reduce to fragments, characterized in that said
centrifugal breaking apparatus has a frame structure isolated from said breaking chamber,
but still supporting said. breaking chamber so as to permit the vibration of said
breaking chamber as separate from said frame structure.
3. A centrifugal breaking apparatus including, in a breaking chamber, a rotor and
a hopper arranged to supply pieces of solid mineral material along the axle of said
rotor, thereby permitting said rotor when rotating at an increased speed to throw
said pieces of solid mineral material from the radial outlets of said rotor in tangential
directions to cause said pieces of solid mineral material to strike against the "dead
bed" of fragments of solid mineral material which encircles said rotor and cause said
pieces of solid mineral material to reduce to fragments, characterized in that said
centrifugal breaking apparatus has upper and lower frame sections and that the upper
frame section has said breaking chamber formed therein.
4. A centrifugal breaking apparatus including, in a breaking chamber, a rotor and
a hopper arranged to supply pieces of solid mineral material along the axle of said
rotor, thereby permitting said rotor when rotating at an increased speed to throw
said pieces of solid mineral material from the radial outlets of said rotor in tangential
directions to cause said pieces of solid mineral material to strike against the "dead
bed" of fragments of solid mineral material which encircles said rotor and cause said
pieces of solid mineral material to reduce to fragments, characterized in that said
centrifugal breaking apparatus has a vibrating frame structure and a vibrator, said
vibrator along with a rotor drive motor being connected to said frame structure.
5. A method of breaking pieces of solid mineral material by feeding pieces of solid
mineral material along the axle of a rotor and rotating said rotor at an increased
speed to throw said pieces of solid mineral material from the radial outlets of said
rotor in tangential directions to cause said pieces of solid mineral material to strike
against the "dead bed" of fragments of solid mineral material which encircles said
rotor and cause said pieces of solid mineral material to reduce to fragments, characterized
in that said "dead bed" of fragments of solid mineral material is subjected to vibration.
6. In combination with a method of breaking pieces of solid mineral material by feeding
pieces of solid mineral material along the axle of a rotor and rotating said rotor
at an increased speed to throw said pieces of solid mineral material from the radial
outlets of said rotor in tangential directions to cause said pieces of solid mineral
material to strike against the "dead bed" of fragments of solid mineral material which
encircles said rotor and cause said pieces of solid mineral material to reduce to
fragments, a method of sorting fragments according to size characterized in that a
separator plate is provided on the course on which fragments of solid mineral material
fall from said "dead bed", and that said "dead bed" is subjected to vibration, thereby
causing fragments of relatively large size to come up on the surface of said "dead
bed" to permit these fragments of relatively large size to fall inside and permit
fragments of relatively small size to fall outside of said separator plate.
7. In combination with a method of breaking pieces of solid mineral material by feeding
pieces of solid mineral material along the axle of a rotor and rotating said rotor
at an increased speed to throw said pieces of solid mineral material from the radial
outlets of said rotor in tangential directions to cause said pieces of solid mineral
material to strike against the "dead bed" of fragments of solid mineral material which
encircles said rotor and cause said pieces of solid mineral material to reduce to
fragments, a method of sorting fragments according to size characterized in that an
outlet is provided in the vicinity of said "dead bed", and that said "dead bed" is
subjected to vibration, thereby causing fragments of relatively large size to come
up on the surface of said "dead bed" to leave fragments of relatively small size inside
and fall from said outlet.