• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    Centrifugal force grinder 20 for firstly crushing the solid mass 9 supplied from the hopper 8 using a centrifugal force to the plate, and a guide tube for guiding the movement of the first pulverized solid grain 29 ( 80, an intermediate separation member 30 in which a supply passageway 31 for supplying the solid grains 29 is formed, and a blow blade 44 for rotating the solid grains 29 supplied through the supply passageway 31 at high speed. It provides a pulverizing device consisting of a blow crusher 40 for secondary crushing by). The centrifugal force pulverizing device 20 is a rotary cylinder 24 for imparting centrifugal force to the solid mass 9, a vertical flange 23 installed in the rotary cylinder 24 to receive the rotational force, and a vertical flange 23 to rotate. The vertical collision plate 26 in which the vertical shaft 22 supporting the rotating cylinder 24 and the solid lump 9 protruding from the circumferential surface of the rotating cylinder 24 by the centrifugal force collides with each other and is primarily crushed. It consists of. The blow crusher 40 has a horizontal collision plate 46 installed in the intermediate separating member 30, a horizontal axis 42 provided at a predetermined distance from the horizontal collision plate 46, and a circumference around the horizontal axis 42. Strike blade 44 is installed by dividing at predetermined intervals, and a rotating device 50 for rotating the horizontal axis (42).
    公开号:KR19980066224A
    申请号:KR1019970001616
    申请日:1997-01-21
    公开日:1998-10-15
    发明作者:이경목
    申请人:이경목;
    IPC主号:
    专利说明:

    Crusher
    The present invention relates to a crushing apparatus for producing sand by performing primary crushing by colliding gravel and construction waste materials with walls using centrifugal force, and performing secondary crushing by blow blades rotating at high speed.
    In general, the crushing device is a device that crushes large chunks into powder, which is weak in strength and cannot be used for gravel or concrete agglomeration, which is a construction waste material that must be recycled in order to protect the environment that is becoming severe. It is also used to make sand by breaking it into pieces.
    Conventional crusher is a large solid lumps of gravel or construction waste material from the top through the hopper is rotated at high speed and supplied to the rotating cylinder with the circumferential surface open, the centrifugal force to the gravel or construction waste material by the rotation of the rotating cylinder The vertical axis impact crusher produces sand by crushing by colliding with a collision plate installed at predetermined intervals from the rotating cylinder through the open circumferential surface of the rotating cylinder. (vertical shaft impact crusher) is used a lot.
    In addition, instead of manufacturing sand to produce grain flour, a cone grinding machine (cone crusher) and grinding mill (grinding mill) using a millstone principle is also used as a grinding device.
    Conventional pulverizers, such as the vertical axis impact crusher is configured as described above crushes the gravel in one impact, so there is a problem that the particle size of the sand is large and not uniform.
    In addition, since the shaft for rotating the rotating shaft is installed vertically, there is a disadvantage in terms of durability of the bearing, there is a limit to increase the rotation speed, there is a problem that can not sufficiently increase the collision speed.
    An object of the present invention is to solve the above problems, the first grinding by a rotating cylinder installed on the vertical axis and the second grinding using the blow blades installed on the horizontal axis to grind to produce sand of a uniform particle size To provide a device.
    The pulverizing apparatus of the present invention is a centrifugal force pulverizing apparatus which firstly pulverizes a solid mass supplied from a hopper by using a centrifugal force to a predetermined plate, and a solid grain which is a pulverized product of the solid mass pulverized first by the centrifugal force crushing apparatus. An intermediate separation member having one or more supply passages for distributing and supplying the guide particles for guiding the movement of the solid granules, and for distributing and supplying the first pulverized solid grains moved along the guide cylinders; It is composed of a blow crushing device for secondary crushing by the blow blades rotating at high speed the primary pulverized solid grains supplied through the supply passage formed in the intermediate separating member.
    The centrifugal force pulverizing device is a rotary cylinder that imparts centrifugal force to the solid mass supplied from the hopper and the circumferential surface is opened, a vertical flange installed on the lower surface of the rotary cylinder and receiving the rotational force, and the vertical flange and rotation The solid shaft, which is coupled so as to be rotatably supporting the rotating cylinder, is installed at predetermined intervals from the rotating cylinder and protrudes into the open circumferential surface of the rotating cylinder by centrifugal force, It consists of a vertical impact plate that is first crushed.
    The impact crushing device is divided into a horizontal impingement plate provided on the lower surface of the intermediate separating member, a horizontal axis provided at a predetermined distance from the horizontal impingement plate, and the circumference is divided into a predetermined interval on the horizontal axis It consists of a plurality of striking blades installed, and a rotating device for rotating the horizontal axis.
    In the pulverizing apparatus of the present invention configured as described above, when the solid mass is supplied from the hopper to the rotary cylinder of the centrifugal force grinding apparatus, the rotary cylinder rotates to impart the centrifugal force to the solid mass, and the solid mass is the centrifugal force. It protrudes into the open circumferential surface of the rotating cylinder, collides with the vertical collision plate, and is first crushed by the impact force.
    As described above, the solid grains, which are the pulverized products of the primary pulverized solid mass, fall downward through the supply passages of the guide tube and the intermediate separation member and collide with the strike blades of the above-described blow grinding apparatus rotating at high speed. It is boiled as it is pulverized and then crushed more finely by impinging on a horizontal impingement plate, thus transforming it into sand, which is an even and small-sized solid grain.
    1 is a front partial cross-sectional view showing an embodiment of a crushing apparatus according to the present invention.
    2 is a sectional view taken along the line A-A in FIG.
    3 is a cross-sectional view taken along line B-B in FIG.
    Figure 4 is a side partial cross-sectional view showing an embodiment of a crushing apparatus according to the present invention.
    5 is a plan view showing one embodiment of a rotating cylinder.
    Figure 6 is a schematic diagram showing a process in which the rotational force is transmitted to the centrifugal force crusher.
    Next, the most preferred embodiment of the grinding apparatus according to the present invention will be described in detail with reference to the drawings.
    First, as shown in Figs. 1 to 4, one embodiment of the crushing apparatus according to the present invention is a centrifugal force for first crushing the solid mass (9) supplied from the hopper (8) to a predetermined plate by using a centrifugal force The pulverizing device 20 and the above-described centrifugal force pulverizing device 20 prevent the solid grains 29, which are the pulverization products of the pulverized solid mass 9, from flowing out to the outside and prevent the movement of the solid grains 29. Intermediate separating member (30) formed with at least one guide passage (80) for guiding and at least one supply passageway (31) for distributing and supplying the primary pulverized solid grains (29) moved along the guide passage (80). ) And a blow crusher for crushing the second crushed solid grains 29, which are supplied through the supply passageway 31 formed in the intermediate separating member 30, by the blow blades 44 which rotate at high speed. It consists of 40.
    Said hopper 8 consists of a conical cylinder and is fixedly mounted to the upper plate 10 supported by the support column 4 provided in the base 2.
    The support column 4 is preferably composed of a plurality of H-shaped beams having a high cross-sectional coefficient and high mechanical strength against bending and buckling.
    In addition, the upper plate 10 is also preferably configured by combining a plurality of H-shaped beams horizontally and vertically.
    The upper portion of the hopper 8 is fixed to the hopper support plate 14 supported by the longitudinal support 12 installed in the upper plate 10, the lower portion of the hopper 8 is the upper plate 10 It is fixed to). The vertical support 12 and the hopper support plate 14 are preferably configured using a plurality of H-shaped beams.
    The centrifugal force pulverizing device 20 is a rotary tube with a centrifugal force applied to a solid mass 9 supplied from a hopper, namely, a concrete mass that is weak in strength and cannot be used for gravel, or a concrete mass that is a construction waste material. (24), the vertical flange 23 is installed on the lower surface of the rotary cylinder 24, and receives the rotational force, and the rotatable cylinder 24 is rotatably coupled to the vertical flange 23 described above. The solid shaft 9 which is rotatably supported by the vertical shaft 22 and the rotating cylinder 24 which is provided at predetermined intervals and protrudes to the open circumferential surface of the rotating cylinder 24 by centrifugal force. It is composed of a vertical collision plate 26 is collided and primary crushed.
    As shown in Fig. 5, the rotary cylinder 24 is formed of a base plate, divided into a predetermined angle, and a plurality of partitions 25 are provided on the bottom plate in the radial direction so that the hopper 8 It is preferable to separate the solid mass 9 supplied through a predetermined amount so as to give a centrifugal force. The partition 25 is formed to have a substantially Z-shaped cross section, and it is preferable to install a cemented carbide piece on the outer circumferential side of the rotary cylinder 24 to reinforce the strength of the partition 25.
    In addition, unlike the above, the rotating cylinder 24 is formed by the upper plate in an annular shape, and is provided between the disc-shaped bottom plate and the upper plate by a support bar which is partitioned at a predetermined interval, and the solid supplied through the hopper 8. It is also possible to form a plurality of escape holes on the circumferential surface, in which the mass 9 protrudes by centrifugal force.
    Furthermore, the rotating cylinder 24 forms a plurality of escape holes by installing support plates formed in a cycloid or involute shape at predetermined intervals on the bottom plate, and through the hopper 8. It is also possible to form the supplied solid mass 9 so as to naturally guide the movement when it is ejected by centrifugal force.
    The rotating cylinder 24 may be formed in the same manner as the rotating cylinder used in the vertical crusher, which is a conventional grinding device.
    It is preferable to rotate the said rotating cylinder 24 so that a circumferential speed may be maintained at 80-90 m / s.
    The vertical collision plate 26 may be formed in a cylindrical shape, and may be installed at a predetermined interval from the circumferential surface of the rotary cylinder 24, or may be formed in a rectangular or polygonal cylinder for ease of manufacture. It is possible.
    In addition, the vertical collision plate 26 may be formed using a steel plate or an iron plate having a predetermined strength, or may be formed using a plurality of wide H-shaped beams having high mechanical strength. .
    The vertical collision plate 26 is supported by a plurality of support pillars 4 installed on the base 2, and the upper portion of the guide cylinder 80 is fixed. The support column 4 is preferably formed by combining a plurality of H-shaped beams having a high cross-sectional coefficient and a high mechanical strength against bending and buckling in the horizontal and vertical directions.
    The intermediate separating member 30 is formed in a plate shape and is supported by a plurality of vertical columns 6 installed in the base 2. In addition, the lower portion of the guide cylinder 80 is fixed to the intermediate separation member 30 is supported.
    In addition, the intermediate separation member 30 is distributed by the above-described centrifugal force crushing device 20 to disperse the solid particles 29 (for example, solids composed of sand having a relatively large particle size). One or more feed passages 31 are formed which feed downwards where the device 40 is installed.
    In addition, the intermediate separation member 30 is formed with a vertical shaft hole 33 through which the vertical axis 22 of the centrifugal force crushing device 20 passes.
    The intermediate separating member 30 is preferably formed by combining a plurality of H-shaped beams having a high cross-sectional coefficient and a high mechanical strength for bending and buckling in a horizontal and vertical direction, and the supply passage 31 and the vertical shaft hole. It consists of the central horizontal beam 34, the support beam 36, and the separation beam 38 forming 33.
    The impact crusher 40 is a horizontal collision plate 46 is provided on the lower surface of the intermediate separating member 30, and the horizontal axis 42 is provided at a predetermined interval from the horizontal collision plate 46. ), A plurality of striking blades 44 installed by dividing the circumference at predetermined intervals on the horizontal axis 42, and a rotating device 50 for rotating the horizontal axis 42.
    The horizontal collision plate 46 is formed in a plate shape is installed on the lower surface of the intermediate separating member (30). The horizontal collision plate 46 may be formed of a steel plate or iron plate having a predetermined strength, or may be formed by combining a plurality of H-shaped beams having high mechanical strength.
    The horizontal shaft 42 is rotatably supported through the bearing 43 on the horizontal shaft support 3 installed on the support pillar 4 installed on the base 2, and the driven pulley 54 is installed to rotate the above. It is rotated by being connected via a drive pulley 52 of the device 50 and a belt 56 which is a rotational force transmission means.
    The rotating device 50 may use a motor, or may use a vehicle engine or the like.
    If the horizontal shaft support 3 is directly installed on the ground, it is not necessary to perform the ground work separately, and the horizontal shaft support 3 may be installed using a vehicle tire or the like in the sand of the soft ground.
    The strike blades 44 are provided in plural by two pairs of wing bodies 45 divided by predetermined intervals in the circumferential direction on the horizontal axis 42, and in the longitudinal direction of the horizontal axis 42. It is formed and installed in accordance with the length of the supply passage 31 formed in the intermediate separation member 30. The wing body 45 is fixed to the plurality of horizontal flanges 41 respectively provided on the horizontal shaft 42.
    In addition, the hitting blade 44 is divided into a plurality of wings in the longitudinal direction of the supply passageway 31 is provided with a plurality of blades 45 are installed in a plurality of predetermined intervals in the circumferential direction on the horizontal axis 42 The wing body 45 of the hitting blade 44, which is installed and divided in the longitudinal direction of the supply passage 31, has a predetermined angle with the wing body 45 of the hitting blade 44, which is adjacently installed. It is preferable to provide so that a phase difference may exist. That is, as shown in Fig. 4 by rotating a predetermined angle so that the wing body 45a installed on the far right and the wing body 45b installed in the middle are located in different planes in the longitudinal direction of the horizontal axis 42, respectively. In addition, the wing body 45c installed on the left side, the wing body 45a installed on the right side, and the wing body 45b installed in the middle are also located in different planes in the longitudinal direction of the horizontal axis 42, respectively. It is preferable to install by shifting an angle and shifting it.
    As described above, when the wing bodies 45 of the strike wings 44 which are adjacently installed as described above are rotated so as to have a phase difference of a predetermined angle, the strike blades 44 and the solid grains 29 are disposed on the horizontal axis 42. Since the torsion due to the impact that collides with each other does not work at the same time, it is dispersed and works so that the durability of the horizontal shaft 42 and the bearing 43 is improved.
    It is preferable to maintain the circumferential speed of the above-mentioned strike blade 44 at 100-130 m / s.
    When the rotation speed of the horizontal axis 42 is 1500rpm and the distance from the center of the horizontal axis 42 to the tip of the strike blade 44 is 1.5m, the circumferential speed of the strike blade 44 is approximately 117.75 m / s.
    In the above embodiment, the striking blade 44 is divided into eight equal parts in the circumferential direction of the horizontal axis 42 so that the wing bodies 45 are installed in pairs two by two, and the length of the supply passage 31 is also provided. Since it is divided into each subdivision in the direction, the number of wings of the blow blade 44 corresponding to one supply passageway 31 is made of 48 pieces.
    In the above embodiment, four supply passages 31 are formed, and two horizontal axes 42 are provided in parallel with the supply passages 31 positioned on the same line. 44 are provided at four positions corresponding to the above-described supply passage 31, two on each of the horizontal shafts 42, respectively. Therefore, 96 wing bodies 45 are installed on one horizontal shaft 42, respectively.
    In the above embodiment, the rotary device 50 for rotating the horizontal axis 42 is provided corresponding to each horizontal axis 42.
    The pulleys 55 provided at both ends of the horizontal shaft 42 are ground when the solid mass 9 and the solid grains 29 are crushed by the centrifugal force crusher 20 and the blow crusher 40. It is used to transmit the rotational force for driving the dust collector for removing the generated powder and dust.
    Sand dust and dust collected by the dust collector as described above is preferably collected in a separately installed puddle.
    6 shows an example of a method of transmitting a rotational force to the centrifugal force crusher 20 described above. As shown in FIG. 6, the centrifugal force grinding device 20 of the above-described embodiment has a horizontal bevel gear shaft 57 parallel to the horizontal axis 42 and a vertical bevel gear shaft 58 parallel to the vertical axis 22. By connecting the driven pulley 54 provided on the horizontal shaft 42 and the intermediate pulley 59 provided on the horizontal bevel gear shaft 57 with a belt 61, and the centrifugal force crushing apparatus 20 described above. Rotational force of the horizontal shaft 42 by connecting the driven pulley 64 provided on the vertical flange 23 of the < RTI ID = 0.0 >) < / RTI > Is transmitted to the horizontal bevel gear shaft (57) through the belt (61), and the bevel gear (60) installed on the horizontal bevel gear shaft (57) and the vertical bevel gear shaft (58) is engaged at 90 degrees. By the rotation direction is changed by the rotational force of the horizontal bevel gear shaft 57 is transmitted to the vertical bevel gear shaft 58, the rotation of the vertical bevel gear shaft 58 Through the belt 62 is transmitted to the vertical flange 23 is configured to rotate the one tumbler (24).
    In addition, unlike the above, it is also possible to rotate the rotary cylinder 24 by connecting the driven pulley 64 installed on the vertical flange 23 and the driving pulley of the rotating device made of a motor or a vehicle engine through a belt. It is possible.
    The vertical flange 23 installed in the vertical shaft 22 and the rotary cylinder 24 in the above is rotatably coupled using a thrust bearing 27 and a plurality of tapered bearings 28.
    A storage container 76 is formed between the horizontal shaft support 3 and the base 2 to form a space of a predetermined size, and a transport device 70 for transporting sand, which is finely pulverized solid grains, is further installed. do. The transfer device 70 is made using a conveyor belt (72).
    Next will be described the operation of the grinding device according to the present invention configured as described above.
    First, when the solid mass 9 is supplied from the hopper 8 to the rotary cylinder 24 of the centrifugal force crusher 20, the rotary cylinder 24 rotates by the rotational force of the vertical flange 23, and the solid The centrifugal force is imparted to the mass (9), and the solid mass (9) sticks out to the open circumferential surface of the rotary cylinder (24) by the centrifugal force and impinges on the vertical collision plate (26) and is affected by the impact force. Tea is crushed.
    As described above, the solid grains 29, which are the pulverized products of the primary pulverized solid mass 9, fall naturally downward through the supply passage 31 of the guide tube 80 and the intermediate separation member 30, and rotate at high speed. By colliding with the striking blade 44 of the above-mentioned striking crusher 40, it is bounced while being secondary crushed, and again crushed finely while colliding with the horizontal impingement plate 46. Sand, for example).
    When the above-mentioned horizontal impact plate 46 is formed as an H-shaped beam when the solid grain 29 collides with the striking blade 44 and bounces while colliding with the horizontal collision plate 46, the H In the c-shaped groove of the beam which is a shape, the bottom surface and both sides collide with the triplet, so that the crushing effect by the collision is further improved.
    In addition, the solid grains 29 may be crushed again by colliding with the other striking blades 44, which protrude and face each other while being collided with each other by colliding with the striking blades 44 of the striking mill 40.
    Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. Naturally, it belongs to the scope of the invention.
    According to the pulverizing apparatus according to the present invention configured and operated as described above, the size of the sand, which is the crushed grains, is small and the particle size is evenly formed by performing the second pulverization by the rotating blow blades in addition to the first pulverization using the centrifugal force. do.
    In addition, since the blow blades for the second grinding are installed on the horizontal axis, and each wing body is installed to have a phase difference of a predetermined angle from each other, it is possible to increase the rotational speed at high speed without excessively burdening the parts, thereby increasing the size of the grains. Small, even sand can be produced.
    Furthermore, the crushing apparatus according to the present invention can be rotated not only by the motor driven by the electric motor but also by the engine of the vehicle, so that it is not limited to the installation place.
    权利要求:
    Claims (5)
    [1" claim-type="Currently amended] A centrifugal force pulverizer for first crushing the solid mass supplied from the hopper to a predetermined plate by using a centrifugal force, and preventing the first pulverized solid grains from flowing out by the centrifugal force pulverizer. A guide passage for guiding movement, an intermediate separation member having at least one supply passage for distributing and supplying the first pulverized solid grains moved along the guide passage, and a supply passage formed at the intermediate separation member. A pulverizer composed of a blow crusher for crushing the first pulverized solid pellets supplied by secondary blow blades rotating at high speed.
    [2" claim-type="Currently amended] The method according to claim 1, wherein the centrifugal force crushing apparatus is a rotary cylinder that gives a centrifugal force to the solid mass supplied from the hopper and the circumferential surface is open, a vertical flange installed on the lower surface of the rotary cylinder and receiving the rotational force, A vertical shaft rotatably coupled to a vertical flange to rotatably support the rotating cylinder, and installed at predetermined intervals from the rotating cylinder and protruding from the open circumferential surface of the rotating cylinder by centrifugal force. Grinding device consisting of a vertical impact plate that is primarily crushed by the solid mass impact.
    [3" claim-type="Currently amended] The method of claim 1, wherein the impact crushing device is a horizontal collision plate provided on the lower surface of the intermediate separating member, a horizontal axis provided at a predetermined distance from the horizontal collision plate, and the circumferential circumference on the horizontal axis A pulverizing device composed of a plurality of blow blades are provided by dividing at intervals of the interval, and a rotating device for rotating the horizontal axis.
    [4" claim-type="Currently amended] The method of claim 3, wherein the blow wing is provided with a plurality of wing body is divided into a predetermined interval in the circumferential direction on the horizontal axis of the plurality of installed, the supply passage formed in the intermediate separation member in the longitudinal direction of the horizontal axis Crusher formed to length.
    [5" claim-type="Currently amended] The method of claim 4, wherein the blow blade is divided into a plurality of wings in the longitudinal direction of the supply passage is provided by dividing a plurality of wings in the circumferential direction at a predetermined interval in the horizontal axis, The wing body of the hitting blade dividedly installed in the longitudinal direction is installed to have a phase difference by a predetermined angle with the wing body of the hitting wings are installed adjacent to each other.
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    同族专利:
    公开号 | 公开日
    KR100214861B1|1999-08-02|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    法律状态:
    1997-01-21|Application filed by 이경목
    1997-01-21|Priority to KR1019970001616A
    1998-10-15|Publication of KR19980066224A
    1999-08-02|Application granted
    1999-08-02|Publication of KR100214861B1
    优先权:
    申请号 | 申请日 | 专利标题
    KR1019970001616A|KR100214861B1|1997-01-21|1997-01-21|Apparatus for crushing|
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