DE2339853A1 - BALL MILL COUPLED WITH A PLANETARY GEAR - Google Patents

Description

Coupled with a planetary gear
Ball mill.

The invention relates to a centrifugal ball mill with a device for introducing a planetary rotary motion and separate devices for utilizing the rotary motion of the ball mill about its axis of rotation. The axis of the ball mill can be parallel to the axis of rotation of the planetary gear or perpendicular
to be here. If the axis of rotation of the ball mill is perpendicular to the axis of rotation of the planetary gear, then the axis of rotation of the ball mill can be adjusted to the radius of the planetary motion.

Ball mills are widely used in industry or in

the laboratories for grinding and mixing various substances

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OfiKaJNAL INSPECTED

in use. The substances to be milled or mixed are filled into the ball mill, its balls or .. other tulle bodies consist of a: 'hard'., material, on which the: .-. i \. vertical axis of rotation operated ball mills with a predetermined Speed can be put into circulation. That cheer and Mixing of the filling material takes place under the accelerator Bullets.

If, on the other hand, gravitational forces are still used, an even better effect is achieved, which increases with the increase in the diameter of the ball mill A certain ratio with respect to the speed of rotation is maintained , otherwise the balls will remain stationary with respect to the rear end of the ball mill and will rotate with it without any grinding effect.

Line improvement over a simple .ech / eri rotating ball mill results from the arrangement of a ί lanetengetritbe on or near the circumference of a rotating piping. In such a design, centrifugal forces are used, which results in a better effect of the grinding or mixing process, the planetary motion is brought about by a transmission or a piston drive, a ball mill designed in this way is from ': .. 31och and C. rosetti developed v / orden beispielsv / else in Chemiker Zeitung 15 ^ 2, page 1 ¹ ^ 'and - described.. The use of the centrifugal force provided there results in a good grinding effect in a ball mill with a capacity of 300 ml. The ground material is

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received back without loss. For driving the planetary gear and a motor is used to rotate the ball mill around the axis. The two parts are coupled to one another, and the speed cannot be regulated independently.

with

The invention relates to a new design of a centrifugal force operated ball mill, with independent I means for Twisting a round support member for the ball mill and for rotating it around its axis are provided. By that new training, it is possible to the round support member with the ball mill or mills at any desired speed give. One can choose the most favorable combination of the two rotational speeds depending on the type of material to be ground Good and choose the balls. The independent adjustability of these two rotational speeds leads to one significantly better grinding result. If the axis of rotation of the ball mill is perpendicular to the axis of the rotating support member stands and if further means are provided to the angle between the axis of rotation of the ball mill with respect to the Adjusting the radius of the support member as desired, a better performance of the ball mill can be achieved.

The design according to the invention is explained in more detail below with reference to the exemplary embodiments shown in the drawing. It shows in a schematic representation:

Fig. 1 is a partially sectioned side view of a first embodiment,

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FIG. 2 shows a plan view of FIG. 1, FIG. 3 shows a partially sectioned side view of a

second embodiment and
FIG. 4 shows a plan view of FIG. 3.

Since ball mills are known in terms of the basic design and also the mode of operation of a planetary gear, Explanation of details of these parts is omitted in the drawings.

According to FIGS. 1 and 2, two ball mills 11 are each light arranged eccentrically on support disks 12. The support disks 12 sit on a rotatable disk 13 driven by a motor 14 can be driven via a counter gear 15. The two Ball mills 11 can be driven by a motor 16 located between them and a belt drive 17. The two ball mills 11 face each other. The axes of the ball mills 11 and the motors 14, 16 are aligned parallel to one another. As a result of this arrangement and design, the ball mills 11 can within certain limits at any speed are driven by regulating the motors 16. Also the speed of circulation the disk 13 can be changed by controlling the motor 14.

The two ball mills 11 are advantageously opposed to one another driven. When the support disks 12, 13 rotate clockwise, the ball mills 11 are advantageous driven in opposite directions.

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It is also possible to drive each ball mill 11 by its own motor 16, so that the two ball mills 11 rotate at different speeds. These two motors 1b can then also operate at different speeds can be operated by a special transformer connected upstream of one motor, for example. Also can by choosing different Countershaft 17, the speed of the two ball mills 11 can be kept different.

In the modification according to FIGS. 3 and 4, the two ball mills are 11 arranged lying on the disks 12 and 13. the 4 shows, in solid lines, the axes of the ball mills 11 in a position perpendicular to the rotor axes 14, 16. An inclined position with respect to the radius is indicated by dotted lines. This inclination gives the opportunity to increase the speed in the unit of time without the balls reaching the critical speed. Due to the inclination, they hit Balls on the wall of the ball mill at a speed that is lower than the speed at the position according to the solid lines is reached.

The new training can do the same for small laboratory ball mills and also used for large work mills, for example for grinding ores.

In a laboratory test, a ball mill with a capacity of 500 ml according to FIGS. 1 and 2 was used, wherein the eccentricity of the axes of rotation of the shells 11 against the disks 12 was about 17 cm. Two balls were used

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with a diameter of 1.5 cm. The speed of the ball mills 11 was 300 revolutions / min. The speed of rotation of the disk was also 300 revolutions / min.

The experiment was carried out with rock crystals with the following tab sizes. 21% residue remained on an I-mesh sieve of 4-9 I-meshes / cm ^. 72% residue remained on a mesh sieve of 169 lbs / cm and 7% residue remained on a sieve of 225 leashes / cir /.

After 15 minutes of marriage at the aforementioned speeds the following residues resulted:

on a 169-mesh set. = 0 ;;, on a 225 hash strainer = 7 _{/ Jf} on a 1600 hash strainer = 33 Ά and on a 4900 hash strainer = 20 %.

Here remained at a 49öO-iIaschensieb still kO '■ /> tand as Default reset.

When the speed of rotation of the balls increases, they rotate about their axis to 600 revolutions / min and with constant speed of the disc 13 is already after a Verraahlzeit of 7 min the ^ the aforementioned result achieved.

Lit the new training, it is possible that Dre: .rer; ohv / indigkeit the ball mills to near the critical Geschv; inc.i _w ness to increase by slow the speed of the Ku.-elmühlen ^ e; is increased over the speed of the support member.

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Corresponding tests with an arrangement according to FIGS. 3 and 4 led to the same result. These attempts were also carried out with an angular position of the ball mills to the disk 13. These attempts were also made because of the independently adjustable and controllable speed of the support disk 13 and the ball mills 11 much better results achieved.

The exemplary embodiments described above can be changed within wide limits within the scope of the claims, without the inventive concept to give up.

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Claims (6)

Patent claims: Ball mill operated using centrifugal force, characterized in that separate, individually controllable operating means (14, 16) for bringing about a planetary motion and the orbital motion the ball mill (11) are present around its axis. 2. Ball mill according to claim 1, characterized in that that the axis of rotation of the ball mill (11) is parallel to the axis of rotation of the planetary drive (13 »14, 15). 3. Ball mill according to claim 1 and 2, characterized in that the axis of rotation of the ball mill (11) is parallel to the plane of movement of the planetary drive (13, 14, 15) and at right angles to the radius that the the ball mill (11) bearing support member (13) occupies. 4. Ball mill according to claims 1-3, characterized in that the Kugelmüzle (11) opposite the support member (13) is angled. 5. Ball mill according to claim 1τ · 4, characterized by two ball mills (11) lying opposite one another on the support member (13). 409808/0477 6. Ball mill according to / nspruch 1-5, characterized that the ball mills (11) and the planetary drive (13, 1A-, 15) by independent Motors (14, 1o) are operated. 409808/0477