RU20732U1 - VIBRATION DRUM KIMBERLITE ORE GRINDER - Google Patents

Abstract

A kimberlite ore vibratory drum grinder comprising a support frame, an external grinding element mounted on a support frame, a vibration exciter, elastic elements, a central working body with corrugations 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 an outer drum with an inner working surface and an end ring mounted in a support frame with the possibility of oscillatory movement around vertically th axis by means of a vibration exciter fixed on it, and the elastic elements of the outer drum are fixed on the supporting frame with the possibility of oscillatory movement around the vertical axis, while the central working body is made in the form of a central drum coaxially mounted inside the outer drum with the formation of an annular cross-section of the working space between the inner working surface of the outer drum and the outer working surface of the Central drum, and the Central drum is equipped with a disk rigidly fixed at its lower end, while the peripheral part of the disk is placed under the end ring of the outer drum with the formation of a discharge gap overlapped by crushed kimberlite ore at an angle of repose, located on the plane of the peripheral part of the disk, and equipped with a device for unloading crushed kimberlite ore with the peripheral part of the disk, 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 unloading

Description

Bn6pauHOfJHbifi drummer kamberlite ore grinder

The proposed utility model relates to the grinding of hard rocks, and, of course, to the mechanisms of vibration destruction., And can be used np} i processing of mineral raw materials, for example, kimberlite ore.

Kimberlite ore is a rock that has some strengths (1-5 on the scale of Prof. M. M. Protodyakonov) and contains the hardest minerals - diamonds. At the same time, crystals of P11ases can be destroyed by shock loads.

Known vibraion shredder (see AS USSR No. 1782659, 02 02 19/16, published in BI jNl 47, 1992), comprising a housing with an external crushing cone, an internal crushing cone and a causative agent of mechanical vibrations, the causative agent 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 to the internal crushing cone.

A disadvantage of the known technical solution is that with the destruction of kimberlite, diamond crystals can be destroyed by impact noses.

Known vibration crusher (see AS USSR No. 1673215, 02 02 19/16, published in BI No. 32, 1991), containing a frame, external and internal crushing cones with vibration exciters of antiphase vertical vibrations and thrust rings, elastic connection cones and vibration isolation. The elastic connections of the cones are made in the form of paired rubber elements with an intermediate plate between their two, the plates being connected to the frame, and the rubber elements being sandwiched between the support rings of the cones with the possibility of shear deformation in the direction of movement of the corresponding cone. The working surfaces of the outer and inner cones are equipped with vertical

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conical ribs, the bases of which are placed in the unloading zone and are (0.2-0.3) §, while the length of the ribs is (4.05.0) 6, the distance A1 between the ribs on each cone is 28, and the ribs of one cone of displacement are relatively the ribs of the other cone at half a step, where and is the load gap of the discharge gap.

A disadvantage of the known technical solution is the one-ring one with the destruction of kimberlite, the possible destruction of diamond crystals by impact loads.

The closest in technical essence is a vibratory shake crusher (see a, p. USSR No. 1072902, B 02 C 19/16, ubl. In BI No. 6, 1984), containing a support frame but at least two external crushing cheeks with vibration exciters and and a centrally mounted internal crushing organ, which is provided with a drive and supports of rotation around a central vertical axis and is made in the form of a cone with a spiral corrugation, and the outer cheeks have conically concave crushing surfaces.

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

The technical problem in creating a useful model is to increase the efficiency of crushing to sherlite ore while preserving diamond crystals due to the destruction of kimberlite ore by pulsating and static 11 micron loads in two planes, sufficient to destroy non-phosphorous kimberlite, while at the same time not crushing durable diamond crystals.

The task is solved as follows.

The kimberlite ore vibratory drum grinder includes a support frame, an external grinding element mounted on a support frame, vibration exciter, elastic elements, a central working body with corrugations, equipped with a drive for

rotation around the vertical axis, and the discharge gap. To solve this problem, the external grinding element is made in the form of an external drum with an inner working surface and an end ring mounted in the support frame with the possibility of oscillatory movement around the vertical axis by means of a vibration exciter, and the elastic elements of the outer drum a are mounted on the support frame with the possibility of oscillating move in01fug vertical axis. in this case, the central working body is made in the form of a central drum, which is coaxially mounted inside a hollow outside drum with the formation of a circular cross-section of the working space between the external working surface of the external drum and the external working surface of the central drum, the central drum being provided with a disk that is rigidly fixed to its lower end , At the same time, the peripheral part of the disk is placed under the end ring of the outer drum with the formation of a discharge gap overlapping the first crushed kimberlite 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 kimberlite ore from the peripheral part of the disk, 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 significant differences of the proposed utility model are as follows.

“The external grinding element is made in the form of an external drum with an inner working surface and an end ring mounted in a supporting frame with the possibility of oscillating movement of the vertical axis through a vibration exciter fixed on it, and the elastic elements of the external drum are fixed to

support frame "with the ability to provide oscillatory motion around the vertical axis.

The above allows in the working space of the vibratory drum mill mill 1a of maberlite ore to create shear pulsating loads using the exciter of the outer drum and shear constant acting loads using corrugations of a slowly growing neutral drum. The destruction of kimberlite ore is carried out by shearing and grinding, which ensures the preservation of diamond crystals, which are not destroyed under the influence of these nafuzah while in fragile kimberlite. In addition, crystals of atmases located in the working space of the device contribute to the destruction of fragile kimberlate ore.

Moreover, the dimensions of the working space should provide free passage of the crystals of the dies and not create conditions for their fractures. The speeds created by the pulsating load should not reach the values at which the destruction of the crystals will occur. The flaking effects of relatively soft kimberlite ores will help to clean diamond faces from strong adhesion to particles of kimberlite ores.

To create pulsating loads, electromechanical, de-expansion, hydraulic, pneumatic, as well as crank mechanisms can be used. At present, vibration exciters have been created with a disturbing force from hundreds of Newtons to dozens of Kshu Newtons, with a frequency of several Hertz up to 100 Hz and higher. Studies can select the necessary disturbing forces and frequency for the effective destruction of kimberlite ores, without violating the integrity of diamond crystals. To reduce energy consumption, it is advisable to choose elastic elements for fixing the outer drum, providing near-resonance

mode of operation. It is advisable to be able to control the frequency and disturbing forces of the vibration exciter,

In this case, the central organ is made in the form of a central drum (axially mounted inside the outer drum to form an annular cross-section of the working space between the inner working surface of the outer drum and the outer working surface of the non-draper drum, the central drum being provided with a disk, the dust is rigidly fixed to its lower end, the peripheral part of the disk is placed under the end ring of the outer drum with the formation of the discharge shelle, overlapping crushed kimberlite ore at an angle of repose, located on the plane of the tseripherical part of the disk, and is equipped with a device for unloading the crushed kimberlite ore from the peripheral part of the disk, made in the form of a plow clamped on a support frame with the possibility of a fixed adjustment of its position relative to the unloading shelf.

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 grinder working space, a shutter made of crushed kimberlite ore is located, which is located at an angle of repose in the plane under the discharge helmet.

This shutter provides the best possible recovery of the unloading shell in the saturated high-defective state of the ground kimberlite ore. At the same time, the passage of large crystals, commensurate with the size of the working space of the device, is provided, while their integrity is not violated. In order to unload the crushed material from the center of the discharge gap, the plane on which the slope of the usherlite ore is located is made rotating together with the insertion of the central drum. This simplifies the construction of the crusher unloading device.

kimberlite ore, which is made in a plow, with the possibility of a fixed regulation of its position relative to the discharge gap. Due to the closure of the boot on the frame with fixation, its position relative to the discharge gap is ensured. This allows you to adjust the amount of unloading si for each revolution of the disk, therefore, the performance of the bumblebee.

An example of a vibrating kimberlite ore drum grinder is shown in the principle diagram shown in the drawing — vertical section.

The vibrating drum 1 the kimberlite ore grinder consists of a support frame 1, in which the outer drum 2 is mounted with the vibrational oscillation in the horizontal plane around the vertical axis 5 using vibration exciter 4.

To ensure the oscillatory movement of the outer drum 2 in a horizontal plane, it is fixed in the supporting frame 1, for example, by means of bearings 5. Another type of fastening is possible in the form of a hinged suspension or special torsion elastic elements.

As the vibration exciter 4, mechanical unbalanced vibration exciters of both directed and non-directed action should be used. electromagnetic, hydraulic, pneumatic exciters and crank mechanisms should be used.

The outer drum 2 is mounted on the supporting frame 1 of its stand 6 on the elastic elements 7 with the possibility of oscillatory movement of the vertical axis 3. In the cavity of the outer drum 2, a central drum 8 is axially mounted, fixed by means of the bearing unit 9 on the supporting frame 1.

The central drum 8 is provided with a drive 10 (only the drive gear is shown) for rotation around the vertical axis 3 with a relatively low speed (not more than 100 rpm).

The outer working surface P of the central drum 8 is made with corrugations 12, preferably at an angle a arc tg / tde / angle of friction of the kimberlite ore on the steel surface. The corrugations 12 could be multi-snapped. Between the working surface 13 of the outer drum 2 and the outer working surface 1 of the centrum drum 8, an annular (in cross section) working space 14 is formed.

The working surface 1 13 of the outer drum 2 is provided with corrugations A and 15. The annular working space 14 in cross section should provide free passage of large diamond crystals. C, ent}) the drum 8 is equipped with a disk 16, rigidly mounted on its lower end. The peripheral part 17 of the disk 16 provides the discharge of crushed kimberlite ore from the working space 14 through a different slit 18 formed between the disk 16 and the end ring 19 of the outer drum 2. The passage section of the discharge gap 18 is larger than the passage section of the working space 14.

The work slot 18 during operation is blocked by crushed kimberlite ore 20 at an angle of natural slope, located on the plane 21 of the peripheral part 17 of the disk 16.

To unload the crushed kimberlite ore from the plane 21, the grinder is equipped with a device in the form of a plow 22 fixed by a hinge 23 on the support frame 1 with the possibility of fixing in a certain position relative to the discharge gap 18. The crushed kimberlite ore is discharged from the grinder through the groove 24. The grinder is fed through the feeder 25 installed with the ability to regulate performance.

Vibratory drum grinder kimberlite ore works as follows.

The drive Ш of the central drum 8 and the vibration exciter 4 are included in the work, then the feeder 25 is turned on to supply kimberlite ore. Under the influence of its own weight and corrugations 12, the kimberlite ore moves down along the working space 14. In this case, the weak kimberlite ore is destroyed by corrugations 12 on the central drum 8. Due to the low rotation speed of the central drum 8 and the relatively low pressure developed by the corrugations 12, the destruction of diamond crystals not happening. The moving flow of kimberlite ore in the working space is affected by the oscillatory movement of the hand drum 2 through the corrugations 15. The kimberlite ore is subjected to pulsating loads from the corrugations 15 created by the vibration exciter 4 in the vertical plane and corrugations 12 in the horizontal plane. The stresses created by the above disturbances are dissipated in such a way that they ensure the destruction of kimberlite ore and are insufficient for the destruction of diamond crystals. In turn, diamond crystals will themselves be stress concentrators, which will contribute to the destruction of kimberlite ore.

The crushed kimberlite ore with non-crushed crystals of the lubricants is poured through the discharge slit 18 at an angle of 20 slope to the slope 21 of the peripheral part 17 of the disk 16. By means of the plow 22, it is discharged into the groove 24. Using the plow 22, the discharge performance of the crushed kimberlite ore can be adjusted. You can also adjust the operating mode of the device for grinding kimberlite ore in such a way that it will be crushed to pulp and at the same time crystals of achmaz will be completely preserved. This is possible with minimal performance.

feeding kimberlite ore by means of feeder 25, the minimum discharge capacity of crushed kimberlite ore using a plow 22, with the maximum possible disturbing usb created by the vibration exciter 4 and setting the elastic elements 6 to the operating mode, b; short to resonant. 9 (

Claims (1)

A vibratory kimberlite ore drum grinder comprising a support frame, an external grinding element mounted on a support frame, a vibration exciter, elastic elements, a central working body with corrugations 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 an outer drum with an inner working surface and an end ring mounted in a support frame with the possibility of oscillatory movement around vertically th axis by means of a vibration exciter fixed on it, and the elastic elements of the outer drum are fixed on the supporting frame with the possibility of oscillatory movement around the vertical axis, while the central working body is made in the form of a central drum coaxially mounted inside the outer drum with the formation of an annular cross-section of the working space between the inner working surface of the outer drum and the outer working surface of the Central drum, and the Central drum is equipped with a disk rigidly fixed at its lower end, while the peripheral part of the disk is placed under the end ring of the outer drum with the formation of a discharge gap overlapped by crushed kimberlite ore at an angle of repose, located on the plane of the peripheral part of the disk, and equipped with a device for unloading crushed kimberlite ore with the peripheral part of the disk, 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 unloading cracks.