DE3001378A1 - SPIN DRUM FOR SWASH CENTRIFUGE - Google Patents

Description

In tumbling centrifuges, to transport the solids over the filter surface of the conical screen jacket drum, the additional periodically acting transport impulse required for this is generated on the solids by a tumbling or precession movement superimposed on the rotation of the centrifugal drum. The drum is mounted inclined to the vertical in a hollow shaft at the wobble angle f. The drive takes place via coaxially arranged shafts (core shaft and hollow shaft) with different speeds (n ,,, n ^).

The purpose of the tumbling movement of the centrifugal drum is that every location on the inner surface of the centrifugal drum is briefly spaced at such an angle to the effect of the centrifugal force that the sliding angle of the material to be centrifuged is reached or exceeded. Process slides this under constant delivery of · moisture contained in it to the open edge of the spinning drum and in this way from the centrifugal drum played "As a result, the inclination of the inner surface does not need the centrifugal drum deiH glide angle of the centrifuged adapted to advertising

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den, but can be relatively small, which has structural advantages.

From the laws of kinematics it can be deduced that due to the tumbling or precession movement superimposed in addition to the drum rotation, a so-called gyroscopic torque M ™ is effective, which tries to erect or tilt the inclined drum axis, depending on the set speed ratio Hp / ni · ^ ^as Tilting or erecting is prevented by the drum mounting in the wobble head housing, which is to be regarded as an additional bearing load. From this it can be deduced that there is a certain limit for the centrifugal value of the tumbling centrifuge (depending on the speed values).

The invention is based on the object of specifying a centrifugal drum which, when operated in a tumbling centrifuge allows a higher centrifugal value, thus that of the gyroscopic torque Around loaded bearings - the core and hollow shaft relatively relieved by reducing the gyroscopic torque,

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This problem is solved by the measure according to the characterizing part of claim 1.

The decisive influencing variables for the size of the gyroscopic torque IL are the speed of the core shaft n ^ and thus of the centrifugal drum, the wobble speed of the hollow shaft n ₂ and the mass moment of inertia ratio θ / θ of the centrifugal drum including all components rotating at the speed n ^ which are below the swash angle "are inclined c. 9 is the mass moment of inertia about the axis of rotation w of the centrifugal drum and G _and the moment of inertia about the tilt axis and the centrifugal drum. the tilting axis and perpendicular w to the rotation axis and passing through the point of intersection of the centrifugal drum axis with the hollow shaft axis. the moments of inertia θ and θ can be determined from the following relationships known in mechanics:

where r is the radius of the particle dm to the axis w or u. The integration takes place across all Particles of the rotating drum,

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The invention is based on the knowledge that an analysis of the mathematical relationships between the gyroscopic torque M ^ and the associated influencing parameters shows a certain relationship, namely that there is an approximately parabolic relationship between the gyro torque M ^ and the speed ratio n ^ / to, in such a way that the gyroscopic torque Μ ™ initially increases with increasing speed ratio np / n ^, but then becomes smaller and to zero and then increases with a negative value. For a certain speed ratio n ₂ / n, the gyroscopic torque Mm is thus zero.

This zero position is in turn dependent on the moment of inertia ratio θ / θ dependent. By appropriate choice of this moment of inertia ratio can be for determine the speed ratio np / n ^ a value that is in a possible operating speed range of a tumble centrifuge.

The previously known centrifugal drums have a related value-to-inertia ratio the empty centrifugal drum from about 1.25. This value is the zero point of the gyroscopic torque far from a possible operating range of the

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The tumbling centrifuge is removed, and a gyroscopic torque M "occurs, which has limited the centrifugal values that could be achieved up to now due to the bearing load limits. The invention enables the zero point of the gyroscopic torque M _{m to be placed} in the operating speed range or in any case close to it. Thus higher centrifugal values can be achieved with constant bearing load, ie higher values of the speeds η., And n ₂ with constant speed ratio np / n ^.

Claim 2 gives an optimal range for the moment of inertia ratio with product filled centrifugal drum, i.e., in the case of a centrifugal drum, the product on the inner surface is distributed in layers.

Claim 3 allows, by changing the speed ratio n ₂ / n ^ during operation, to set the optimal speed ratio with regard to the bearing load, for example due to the vibrations to which the tumble centrifuge is exposed. It is of particular advantage

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part, a vibration sensor attached to the tumble centrifuge with the control of the variable speed gearbox to bring into operative connection (claim 5).

The measure according to claim 4 ensures that the speed ratio n ^ / n ^ exactly constant is held. In the case of the higher centrifugal values possible according to the invention, one can in fact Change of the speed ratio e.g. through increased Slip of a V-belt, the load limit of the tumble centrifuge can be reached.

The invention is shown in the drawing on the basis of some exemplary embodiments. It shows

1 shows a tumble centrifuge that can be driven by two motors in a longitudinal section,

FIG. 2 shows a cross section from FIG. 1 with a drive by one motor via two Timing belt,

FIG. 3 shows a detail from FIG. 1 with a

Drive by a motor with the interposition of a variable speed gearbox and

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4 shows a schematic representation of the one on the centrifugal drum of a tumble centrifuge acting forces.

With the aid of three columns 1 fastened to the foundation 1a, only one of which is shown in FIG. 1, the bottom 2 of the centrifuge housing is suspended in a pendulous manner. A core shaft 3 mounted in a hub 2a via bearings 2b and 2c is provided with a belt pulley 4 which is connected to a belt pulley 5a of a motor 5 via V-belt 4a. At the upper end of the core shaft 3, a joint driver 8 (universal joint) is provided, on the opposite side of which the actual drum shaft 9 is arranged. Connected to this is a conical collecting bowl 14 to which a conical centrifugal drum 15 with the cone angle "C is attached by means of ribs 20, the casing of which is designed as a sieve. The collecting bowl 14 is screwed together with the drum shaft 9 through a nut _? -.mit the "inclined sliding surface between a slide washer 11 11a und.einem coupling piece 12 is arranged rotatably a. slider 1O.

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The sliding washer 11 and the union piece 12 are in place in fixed connection with a hollow shaft 7, which is rotatable on the core shaft 5 and axially through the Joint driver 8 and an adjusting ring 3a is guided and mounted on its underside in a pulley 6 passes. The pulley 6 is via V-belt 6a with a pulley 19a another motor 19 in connection, which in a manner not shown by a control device 19b is speed controllable. At different speeds n ^ and n ~ or different Direction of rotation between the core shaft 3 and the hollow shaft 7, the catch disk 14 wobbles together with it the centrifugal drum 15 around the hollow shaft 7.

In Fig. 1, 17 is a hopper with a filling tube 17 a, while 16 denotes a Outside on the centrifugal drum arranged cone shell for draining off the centrifuged liquid over the edge 16a, 18 the outer centrifuge housing with liquid channel 18a and 21 represents the inner centrifuge housing with discharge cone 21a ο

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According to FIG. 2, there is only a single motor 5, of which two pulleys 5a and 19a, via toothed belts 22 and 23, pulley 4 and thus core shaft 3 and the hollow shaft 7 are driven. The speed ratio of both Waves 3 and 7 is therefore exactly constant.

Fig. 3 shows a further modification of the drive.

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In this case, the motor drives the belt pulley 4 of the core shaft 3 via V-belt 27. The torque from the input shaft of a control gear 24 is taken from the V-belt 27. Its output shaft is connected to the hollow shaft 7 via V-belt 26. The control gear 24 enables a speed ratio that can be changed by means of a lever 25. If necessary, the V-belts 26 and 27 can be designed as toothed belts.

Fig. 4 shows in the scheme the relationships that occur during the rotation of the centrifugal drum 15 around the core shaft (3 according to FIG. 1) around the axis a with the speed n ^, and around the hollow shaft (7 according to FIG. 1) around the axis b occur with speed n ~. The axis a is the axis of rotation w, which is inclined by the wobble angle ν ζην axis b and with the rotational

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number n ₂ rotates around the axis b. The tilt axis u is perpendicular to the axis of rotation and passes through the intersection point O of the "two axes a and b. The moment of inertia of the centrifugal drum 15 and the parts rotating with it - according to FIG. 1, for example, parts 14, 16 and 20 - around the axis of rotation w is denoted by 0, _r and is determined by integrating all mass points dm of the rotating particles, multiplied by the square of the respective distance r of the particle in the axis of rotation w. Correspondingly, the moment of inertia θ is calculated by integrating the product of the mass points dm of the rotating particles and the square of the respective distance r to the tilt axis u.

The tilting moment Mm, which occurs during rotation about the two axes a and b, is n, for the same direction of rotation of the speeds. and ru (at the upper end of the centrifugal drum 15) rotating to the right, i.e. in a clockwise direction. Effective, uad the centrifugal drum 15 erecting .... Is. the direction of rotation is opposite- (n, | and ^ n ₂ K-ISt the tilting moment directed counterclockwise, so -Mm; it ver »

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seeks to tilt the centrifugal drum 15 more strongly, ie to increase the wobble angle tr. Both tilting moments are a load on the bearings carrying the centrifugal drum 15 (including 2b and 2c) and are therefore the reason why the absolute speeds n ,. and n ₂ must not exceed certain values unless use is made of the teaching of the invention explained above.

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Claims (4)

. 300 Krauss-Maffei Aktiengesellschaft 8000 München 50 TT 418 centrifugal drum for tumble centrifuge Patent claims 1. Centrifugal drum, which has a sieve shell and is extended to the discharge end, for a tumbling centrifuge, in which the centrifugal drum performs a tumbling movement (tumbling frequency) causing the material discharge during its rotation, in which the shaft that causes the tumbling movement, designed as a hollow shaft, is the core shaft formed drum axis intersects at the wobble angle t and in which the core shaft is designed to be drivable at speed n ^ and the hollow shaft at speed np and furthermore the moment of inertia of the centrifugal drum is about the drum axis Q _w and about an axis θ perpendicular to the drum axis, ge · Jt- e η η · ζ e i. ch η et by a ratio of the two moments of inertia of those not filled with product, i.e. empty 130030/0308 bath Centrifugal drum (15) including all parts inclined at the wobble angle t with the speed n ^ rotating parts in the range of θ / O = 0.55 to 1.1, preferably in the range of 0 * 70 to 0.80, in a per se known Speed range np / n ^ from 0.7 to 1.25. 2. centrifugal drum according to claim 1, characterized by the ratio of the moments of inertia of the centrifugal drum (15) filled with product during operation of the tumble centrifuge of Ö _w / ö _u = 0.7 to 1.25, preferably in the range from 0.85 to 1, 00. 3. Orbital centrifuge with a centrifugal drum according to claim 1 or 2, characterized in that that the drive of the core shaft (3) and the hollow shaft (7), in particular the drive the hollow shaft, is speed controllable, preferably by means of an between the core shaft and the hollow shaft intermediate control gear (24). 130030/0308 RiVn 4. Tumbling centrifuge with a centrifugal drum according to claim 1 or 2 or according to claim 3, characterized by a form-fitting Connection between the core shaft (3) and the hollow shaft (7), e.g. by means of gear wheels or toothed belt (22, 23). 5 ' tumbling centrifuge according to claim 3 »characterized by a vibration sensor which is in operative connection with the control gear in the sense of minimizing the vibrations of the tumbling centrifuge. The invention relates to the centrifugal drum for a tumble centrifuge according to the preamble of Claim 1 (see e.g. DE-OS 27 10 586). "4 _ 130030/0306