RU2200627C2 - Annular vibratory grater - Google Patents

Abstract

FIELD: hard rock grating equipment. SUBSTANCE: annular vibratory grater has supporting frame, outer grinding member fixed on supporting frame, vibration exciter, flexible members, and central destructing tool. Outer grinding member is made in the form of hollow cylinder assembled from rings arranged one above another and fixed inside frame for oscillating displacement around vertical axis. Adjacent rings are arranged for vibratory rocking in opposite phase. Flexible members of each ring are fixed on supporting frame for oscillating around vertical axis. Internal working surface of rings is made corrugated. Central destructing tool is formed as drum arranged coaxially inside hollow cylinder and is equipped with disk rigidly fixed on its lower end. Peripheral part of disk is arranged under terminating ring of hollow cylinder so as to define discharge slot and is provided with ground ore discharge device formed as plow. EFFECT: increased efficiency in destructing kimberlite ore while keeping diamond crystal. 2 dwg

Description

 The present invention relates to the grinding of solid rocks, and in particular to devices for vibration destruction, and can be used in the processing of mineral raw materials, for example, kimberlite ore.

 Known vibration eraser (see AS USSR 1727904, B 02 C, 19/16, publ. BI 15, 1992), comprising a housing with an unbalanced vibrator mounted on it and grinding chambers mounted on it with vertical axes, and the centers the severity of the vibrator and vibrating tables are located in one horizontal plane.

 The disadvantage of this method is the limited performance.

 Known vibration shredder (see AS USSR 1782659, 02 C 19/16, publ. BI 47, 1992), comprising a housing with an external crushing cone, an internal crushing cone and a vibration exciter of mechanical vibrations, made in the form of a pulsator, consisting of an annular hydraulic chamber made in the housing with an opening for connecting a hydraulic pump and connected via a membrane with an internal crushing cone.

 A disadvantage of the known technical solution is the limited performance and the possibility of destruction of diamond crystals by impact loads.

 The closest in technical essence is a jaw vibration crusher (see a. S. USSR 1072902, B 02 C 19/16, publ. BI 6, 1984), containing a supporting frame, at least two external crushing jaws with vibration exciters and a centrally mounted the internal crushing organ, which is equipped with a drive and bearings of rotation around the central vertical axis and is made in the form of a cone with spiral corrugation, and the outer cheeks have conically concave crushing surfaces.

 A disadvantage of the known technical solution is the destruction of diamond crystals by impact loads during crushing of kimberlite ore.

 The technical task of the invention is to increase the efficiency of destruction of kimberlite ore while maintaining diamond crystals due to the destruction of kimberlite ore by pulsating, abrasive loads simultaneously in three planes, sufficient to destroy fragile kimberlite, while at the same time not destroying strong diamond crystals.

 The problem is solved as follows.

 An annular vibration eraser includes a support frame, an external grinding element mounted on a support frame, a vibration exciter, elastic elements, a central damaging body with corrugations, equipped with a drive for rotation around a vertical axis and a discharge gap.

 According to the technical solution, the external grinding element is made in the form of a hollow cylinder, assembled from rings mounted one above the other and fixed to the frame with the possibility of oscillatory movement around the vertical axis by means of vibration exciters mounted on them, and adjacent rings are connected in antiphase oscillations to each other.

 The elastic elements of each of the rings are fixed on the support frame with the possibility of ensuring their vibrations around the vertical axis.

 The inner surface of each of the rings is made with a working surface provided with corrugations.

 The central destructive body is made in the form of a drum with a lateral working surface and is installed coaxially inside the hollow cylinder to form an annular working space, between the working surfaces of the hollow cylinder rings and the lateral working surface of the central destructive drum.

 The central demolition drum is equipped with disks rigidly fixed at its lower end, while the peripheral part of the disk is placed under the last ring of the hollow cylinder with the formation of a discharge gap overlapped by the crushed ore at an angle of repose placed on the plane of the peripheral part of the disk and equipped with a device for unloading the crushed ore made in the form of a plow mounted on a support frame with the possibility of a fixed regulation of its position relative to the discharge gap.

 Significant differences of the invention.

 The external grinding element is made in the form of a hollow cylinder assembled from rings mounted one above the other and attached to the frame with the possibility of oscillatory movement around the vertical axis by means of vibration exciters mounted on them, and adjacent rings are connected in antiphase oscillations to each other, and the elastic elements of each of the rings mounted on a support frame with the ability to ensure their vibrations around the vertical axis, and the inner surface of each of the rings is made with a working surface, provided wife corrugations.

 The above allows you to create shear pulsating loads in the working space of the eraser with the help of a vibration exciter and shear constantly acting loads using corrugation of a slowly rotating central destructive organ. In addition, shear grinding loads are carried out due to the inclusion in the antiphase oscillations of each of the adjacent rings. On the plane of contact of adjacent rings in kimberlite ore, shear-grinding loads are carried out, which also significantly increases the fracture efficiency.

 The destruction of kimberlite ore is carried out by shearing and grinding, which will ensure the preservation of diamond crystals, which are not destroyed by these loads, being in fragile kimberlite. In addition, diamond crystals, located in the working space of the abrasion, contribute to the destruction of fragile kimberlite ore.

 Moreover, the dimensions of the working space should provide free passage of diamond crystals and not create conditions for their destruction.

 The speeds created by the pulsating load should not reach values at which the destruction of diamond crystals will occur.

 The grinding effect of relatively fine kimberlite ore will help to clean the diamond face from kimberlite particles.

 To create pulsating loads, electromagnetic, electromechanical, unbalanced, hydraulic, pneumatic, as well as crank mechanisms can be used. At present, vibration exciters with a disturbing force of hundreds to tens of thousands of newtons with a frequency of several hertz to 100 Hz and above have been created. Research can select the necessary disturbing force and the frequency of effective destruction of kimberlite ores without violating the integrity of diamond crystals.

 To reduce energy consumption, it is advisable to choose elastic elements to fix each of the rings, providing near-resonant operation.

 In this case, the central destructive body, made in the form of a drum with a lateral working surface, is installed non-coaxially inside the hollow cylinder with the formation of an annular working space, between the working surfaces of the rings of the hollow cylinder and the lateral working surface of the central destructive drum, and the central destructive drum is equipped with a disk rigidly fixed to its lower end, while the peripheral part of the disk is placed under the last ring of the hollow cylinder with the formation of a discharge gap, blocking crushed ore at an angle of repose, placed on the plane of the peripheral part of the disk, and is equipped with a device for unloading crushed ore, made in the form of a plow mounted on a support frame with the possibility of a fixed adjustment of its position relative to the discharge gap.

 The dimensions of the discharge gap allow diamond crystals to pass without jamming, and in order to create the necessary support for the kimberlite ore in the working space of the abrasion device, a shutter made of crushed kimberlite ore located at an angle of repose in the plane under the discharge gap is proposed.

 This shutter provides reliable overlapping of the discharge gap with an increased stress-strain state of crushed kimberlite ore. At the same time, it provides the passage of large crystals commensurate with the size of the working space.

 In order to unload the crushed material from under the discharge gap, on which the slope from the kimberlite ore is located, this plane is made rotating together with the central destructive drum. This simplifies the design of the device for removing crushed kimberlite ore, which is made in the form of a plow with the possibility of fixing its position relative to the discharge gap.

 By fixing and fixing the plow on the frame, its position relative to the discharge gap is ensured. This allows you to adjust the amount of unloading for each revolution of the disk and, therefore, the performance of the ring vibratory grinder.

 An exemplary embodiment of an annular vibration eraser is shown in FIG. 1-2, where in Fig.1 is a schematic diagram of a ring vibration eraser, a vertical section; figure 2 is the same, section I-I.

 The annular vibration eraser consists of a support frame 1 in which a hollow cylinder 2 is mounted, assembled from rings 3 mounted on the frame 1 with the possibility of oscillatory movement around the vertical axis 3, the hollow cylinder assembled from the rings is made, for example, suspended on the rods 5 through elastic elements 6. The inner part of each ring is made with a working surface 7 provided with corrugations 8. Each ring 3 is provided with an element 9 for connecting the vibration exciter 10.

 In order to increase the efficiency of the ring vibration eraser, it is advisable to use several vibration exciters at the same time 10. The above example shows the simultaneous use of four vibration exciters or one vibration exciter 10 for each two rings 3, and the circuit is selected so that the rings 3 are alternated from different vibration exciters 10. This ensures during operation the vibrational movement of adjacent rings in antiphase oscillations. Each ring 3 is equipped with stops 11 and elastic elements 12, through which it is fixed on the uprights 13 connected to the frame 1 (connection not shown). The elastic elements 12 provide vibrational movement of the rings 3 around the vertical axis 4.

 As the vibration exciters 10, electromechanical, electromagnetic, hydraulic, pneumatic exciters and crank mechanisms can be used.

 A destructive body in the form of a drum 14 with a lateral working surface 15 with corrugations 16 is cooxically mounted inside the rings made of the hollow cylinder 2, with the formation of an annular working space 17 between the working surfaces 7 of the rings 3 and the lateral working surface 15 of the central destructive drum 14. The central destructive drum is provided with a drive 18 (only the drive gear is shown) and is made with a bearing assembly 19 in the frame 1.

 The central demolition drum 14 is provided with a disk 20 rigidly fixed at its lower end, while the peripheral part 21 of the disk is placed under the last ring 3 of the pre-assembled hollow cylinder 2 with the formation of an unloading gap 22 overlapped by the crushed ore 23 at an angle of repose placed on the plane of the peripheral part 21 of the disk 20. For unloading the crushed ore from the plane of the peripheral part of the disk, a device in the form of a plow 24 is mounted on the support frame 1 with the possibility of fixed regulation of its position tions relative to the discharge slot 22.

 The bore of the discharge gap 22 is larger than the bore of the working space 17.

 Under the unloading plow 24 installed shelves 25 for receiving crushed ore.

 The eraser is loaded by means of a feeder 26, which is installed with the possibility of regulating the performance.

 Ring vibration eraser works as follows.

 The drive 18 of the central destroying drum 14 and the vibration exciters 10 are turned on, then the feeder 26 for feeding the kimberlite ore is turned on.

 Kimberlite ore under the influence of its own weight enters the annular working space 17. The filling of the working space is facilitated by the resulting slope 23 under the discharge gap 22, the rotation of the central destroying drum 14 and the oscillations of the working surfaces 17 of the rings 3.

 During the movement of kimberlite ore in the working space, pulsating loads created by vibration exciters 10 act on it. The surface of each ring creates around its corrugation zones of displacement at an angle of internal friction (ore in ore).

 The kimberlite ore in the working area will be in complex loading due to the slowly rotating destructive drum, and static loads are created in the ore. In the area of each ring due to fluctuations in the corrugations of the working surface, pulsating loads will be imposed on the ore. In addition, the rings oscillate in antiphase, which creates additional grinding on the plane between adjacent rings. Due to these complex deformations, weak kimberlite is destroyed, while diamond crystals located in the relatively weak kimberlite material are not destroyed by these loads. The pressure inside the workspace is controlled by the amount of shredded ore shipped by means of a plow 24.

 You can choose a mode in which you can minimize unloading from the discharge gap. In this case, all supplied energy will be spent on the abrasion of kimberlite ore. Diamond crystals will be preserved and will contribute to the grinding of kimberlite minerals.

 The working space should be 15-20% larger than the largest diamond crystal in a linear dimension. This will ensure their free passage through the workspace, without creating conditions for breaking and exiting the crushed ore at an angle of repose without jams.

Claims (1)

 An annular vibration eraser, including a support frame, an external grinding element mounted on a supporting frame, a vibration exciter, elastic elements, a central breaking body provided with a drive for rotation around a vertical axis, and an unloading slot, characterized in that the external grinding element is made in the form of a hollow cylinder assembled from rings mounted one above the other and fixed to the frame with the possibility of oscillatory movement around the vertical axis by means of vibration excitations mounted on them lei, and adjacent rings are connected in antiphase to each other, and the elastic elements of each of the rings are fixed to the support frame with the possibility of their vibrations around the vertical axis, and the inner parts of each of the rings are made with a working surface provided with corrugations, while the central destructive organ made in the form of a drum with a lateral working surface, mounted coaxially inside a hollow cylinder drawn from rings to form an annular working space between the working surfaces the hollow cylinder rings and the lateral working surface of the central demolition drum, the central demolition drum provided with a disk rigidly fixed to its lower end, while the peripheral part of the disk is placed under the last ring of the hollow cylinder with the formation of a discharge gap overlapped by the crushed ore at an angle of repose, placed on the plane of the peripheral part of the disk and equipped with a device for unloading the crushed ore, made in the form of a plow mounted on a support frame with ozhnostyu fixed adjustment of its position relative to the discharge gap.

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