DE628949C - Conveying bulk goods through vibrating screens or channels - Google Patents

Description

Conveying bulk goods through vibrating screens or chutes For conveying (Movement) of bulk goods is known to be known in many cases as the so-called conveyance litter served. The machine equipment required for this usually consists of sieves or conveyor troughs that stand or hang at a certain angle on trailing arms are attached and the bulk goods periodically in an oblique to the plane of this promotional Accelerate parts in moving direction.

It was known that the conveying effect can be achieved by changing the amplitude, to influence the number of exciters and the inclination of the springs within wide limits able. But it was also known that many other properties of the sieves, the channels and the goods influence the conveying process, and could from all this with the difficulty a treatment of these processes, which partly affect the vibration, partly the throwing and follow the laws of fall, oppose them, do not exactly overlook the inner context. In other words, it was impossible to predict at what fixed deflection (Amplitude), at which fixed frequency and at which fixed inclination of the springs, a certain material to be screened or conveyed is screened or conveyed with the best possible efficiency. is promoted.

The solution to this problem is the subject of the present invention. It is based primarily on an investigation, -what questions in the funding throw in general, whether it is used for sieves or conveyor troughs, validity to have. So one turns on the actual determination that the sieve of the conveyor chute distinguishes between granular and dusty goods according to grain size, thereby from that one sees the sieve practically as a conveyor trough, one per period has to convey a certain conveying path, namely depending on the division of the screen fabric, so the conveying process itself remains of the same movement processes in both cases and dependent on the same structural means, d. H. Sieves can be used for the present Investigations are treated according to the same criteria as Rinnen. Because either a mass particle is larger than the openings of the tissue in question, then with every oscillation of the sieve it is conveyed on in exactly the same way - as on the Gutter, or it is smaller than the mesh size, then it is only conveyed as long as until it hits an open stitch. Here, of course, it fails and separates thus for the promotion.

The task set above is thus intended to meet the general legal requirements Relationship between throw and vibration, d. H. the principle of so-called litter promotion, clarify: You can therefore not come down to it, only the conditions for the to set up the highest conveying speed, but it should be a teaching for the Be an expert as he achieves maximum performance in every practical individual case able to achieve.

The one observable during a funding throw Movement process can be clearly illustrated with the help of the curves (Fig: - i to 3): -In Fig. I shows a curve I, through which the changing speed of the periodically oscillating surface (channel or sieve) illustrated in centimeter seconds will.

The line AB indicates the position of the trailing arm springs. The drawn lines C, - Dl to C, 5-D, 5 show the path that any fixed points C1 C5, which can be seen on the surface of a channel or a sieve, travel in terms of size and direction in the state of motion.

The upper boundary line of the channel surface is indicated by the line D1-D5, the lower one by the line C1-C5 and the middle layer by the line 0-0 (Fig. i) marked.

The lines D1 to C17 C5 D5 are under the assumption that an infinite start trailing arms are used, straight and close-Ben with the line 0-0 the angle of attack a. If the spring length is finite, the lines CI-D1 to C, -D become too few circular arcs deviating from the straight line, but this remains of negligible small influence.

The curve I can be imagined as a result of the fact that a strip of paper, inclined in the direction of the line C1 D1, is drawn past the vibrating groove perpendicular to the plane of the paper in such a way that a pen attached to A records the course of movement: Now judge the speed of the passed one Paper strip in such a way that the sine curve I folded over according to Fig. I intersects the central position 0-0 at the angle a , then the following results from Fig occupies the lowest limit position, in point C1. As the speed increases, it is accelerated to point A, where the channel and m are at their maximum speed. From A in the direction to D1 the speed of the channel decreases more and more rapidly, so that because of its inertia, na has to detach itself from it at the moment when the speed difference per second exceeds the acceleration due to gravity of 981 cm / s2. If one assumes that this occurs at the moment when m has reached the height h, then from this moment on the mass body m is subject to the laws of throwing and the channel to the laws of vibration. The solution to the problem is thus to be seen, according to a new finding on which the present invention is based, in the determination of the conditions under which the interlocking of the throwing process proceeding according to special laws and the oscillation process underlying other laws results in an optimum.

If one follows the course of the free space according to the trajectory parabola II (Fig. I) moving mass particle m, one recognizes that it differs only slightly from the conveying surface was able to lift off and remove and about at that moment hits the channel again when it approaches its lowest limit.

If one continues to assume that the same process occurs with other things being the same Circumstances, but with a higher frequency of the oscillating surface according to the trajectory parabola IV takes place, it becomes, because the mass body experiences a stronger acceleration, the trajectory parabola run higher. Partly because of this and partly because of the higher frequency the conveying surface must therefore m the channel only again on the ascending branch of the Reach oscillation curve I. The mass particle in meets the curve IV Channel at a point in the room where the channel speed is already at its maximum Va exceeded and quickly assigned the value zero.

An acceleration at this point in the oscillation curve I, at which In the example of curve II, the mass particle is already overcoming the Earth gravity had detached from the gutter is therefore not possible. It must first remain on the gutter and can only be promoted during the next period will. o Fig. i thus shows that curve II is the lower and curve IV the upper Represents the limit below or above which a trouble-free delivery throw dry, easily removable good is impossible.

Fig. I also shows that there is a maximum value and that this is between the two limit values according to curve II and curve IV must be located.

So if you choose the angle of attack already determined by Fig. I a and the deflection f (of the amplitude) to be calculated from the center position 0-0 Oscillation frequency, which roughly corresponds to the trajectory curve III, results in the surprising one The fact that the mass particle in point F, i.e. H. in an instant on the gutter falls back where this is the middle position 0-0 and thus. their top speed approaching.

This has the consequence that i. m the maximum imaginable throw per period, ie the distance between C, 7 D1 and C4 D4 , while according to curve II only the distance between C1 D1 and C3-D3 per period and according to curve IV the distance between C1 Dl and C per two periods ,, - D.5, ie half of this calculated on the period, ie approximately the distance between C, -D1 and C2-D., Is achieved; also that 2. expand the security and regularity of the throwing and falling process in percentage terms. Limits guaranteed and thus voltage and load fluctuations can be easily overcome.

From the laws that govern throwing, on the one hand, and the laws of vibration on the other hand, one can now find the right interlocking for every conceivable case calculate the two movement processes.

Here, however, the surprising fact continued to emerge, that that correct optimal interlocking through a very definite one Combination and that this is in turn characterized by a number, which follows below Code number should be mentioned.

In other words: If, as has been done in Fig. 2, the variables influencing the discharge throw are plotted: deflection (amplitude) f in centimeters, the square of the number of revolutions n = and the sine of the angle of attack sin a at the three spatial coordinates, this results the conveying throw optimum from the product of these quantities f - 7a = - sin a as a number that falls in the vicinity of 2öö ooo.

If the possible combinations between f - yi 'and sin a are represented in spatial coordinates as a prismatic body, the optimum of the throwing movement, as shown in Fig. 2, runs as a curved surface through this space, so that all imaginable combinations , depending on their distance from this optimum, are to be regarded as less good or completely useless.

Mathematical examination shows that the optical surface has a limitation in the direction of the Z-axis because, for example, at an angle of incidence of the trailing arms from go °, d. H. in the case of a vertical throw, every horizontal component is switched off and funding is impossible. The situation is similar with horizontal throw, i. H. at angle zero, at which the vertical component disappears and thus no lifting he follows. This relatively sudden transition is still through in practice Friction processes etc. influences, but does not change anything in terms of validity and correctness of the above.

In the direction of the X and Y axes, an arbitrary limitation of the optimal area at n @ = r ooo ooo and f = ro cm has been chosen, beyond which one imagines the optimal area to be practically extended within wide limits and mathematically to an unlimited extent can. The limitation by the sine of the angle a can be seen from Fig. 2, if one thinks that the resulting limiting curves of the optimal surface are extended to point A on the one hand, and to points B and C on the other.

The two limiting curves converge in A, so that the total value f si = - sin a = zero.

At points B, D and C, sinx = r, so that the curve here merges into the two straight lines BDC, which are perpendicular to one another. Because the throwing process is independent of the oscillation process from the moment the mass particle is lifted off the channel and the oscillation process is independent of the throwing process from the same moment onwards, as can be seen without further ado, an inner, natural-law relationship between the two must regulate the correct interlocking.

The product is characterized by this natural law relationship the quantities f - n = '- sin a, which must always result in the same constant numerical value, to meet the condition of intervention, and therefore referred to as an index number has been.

The code number thus indicates the best possible interlocking of the throwing process that takes place periodically in the earth's field with the harmonic or inharmonic oscillation process, e.g. B. with periodically promoting gutters or sieves.

If the best possible interlocking of both processes is not guaranteed, d. H. Perhaps the time to accelerate the conveyed goods is too short or slows down If the conveyed material leaves the chute too late, both times, as shown, the Delivery rate decreases quickly.

From the infinite number of combinations that fill the space between the frequency axis X, the amplitude axis Y and the Z axis with the sin a from 0 to 90 °, the code number cuts out a two-dimensional body containing the maximum value and its approximate values , which, as can be seen from Fig. 2, hugs the coordinate system relatively strongly. The much larger part of the room remains untouched.

From the structure of the mathematical formula it follows without further ado, that the constant value, the index number (the optimum), for the correct meshing of the two processes mentioned, for example, can only be achieved for high frequencies is when due to a relatively small deflection (amplitude) and corresponding The value of sin - the total product gives the index value.

Conversely, a large deflection (large amplitude) causes a corresponding sin u a low frequency.

So you can - and this gives you the extraordinary advantage of the disclosed teaching - if there are practical requirements, such as the requirement: that the conveyance throw at a certain angle of attack depending on the grain size i mm, should be 10 mm or 10 mm, the most favorable frequency for this in each individual case determine.

Of course, if practical information is available, you can do all of it Falling out of the box, determine the direction in which a change should take place must be made.

From this one can see that the most favorable ones are also obtained from the code number Can calculate values for the highest conveying speed, as can be seen from Fig. 3 results.

If one plots the angle of attack a, measured in straight lines, as shown in Fig. 3 the X-axis and the conveyor speed, measured in meter-minutes, on the Y-axis on, one obtains the surprising result that the conveying speed, in Meter measured, increases with decreasing frequency of the conveying part.

From the diagram in Fig. 3 it can be seen that if one calculates the associated oscillation amplitudes for any combinations selected, ie for an angle of attack of 15 ', 30' and 450 and the frequencies 1000, 500 and a50, these are linear Increase in frequency decrease in the quadratic ratio. This means that if the most favorable interlocking between the throwing process and the oscillation process is determined in a group of curves on the basis of the code number for each individual calculated point, the maximum conveying speed moves in the direction of low frequencies, small angles of attack and high amplitudes .

The most favorable effect for sieves depending on the mesh size moves in the opposite direction, as can be seen from the same observation, d. H. the finer-grained the material to be screened and, accordingly, the mesh size -The sieve is, the more the most favorable that can be calculated from the index tends Result after a large angle of attack and high frequency with a small deflection.

This shows that in order to achieve the highest levels of performance Future sieves - depending on the grain size to be separated by their external shape and dimensions by their angle of attack and by their frequency according to the above the resulting conditions must differ from each other. Similar, in a different direction The conveyor troughs also have running marks.

There are two practical examples in Figs. 4 and 5 Devices for sieving or conveying shown schematically.

In the embodiment according to Fig. 4 known per se, d means a sieve box or a conveyor trough, b, b the oblique trailing arm springs and 37 an electric motor which, by means of an EZcentre drive e, sets the sieve or the conveying trough in necessarily oscillating movements.

If the arrangement is built for sieving purposes, one can deduce the throwing distance from the mesh division of the sieve and from this the frequency to be used and calculate from this with the help of the code numbers f, n and a. But you can also determine the conveying speed of the screen and thus its performance.

If, on the other hand, the arrangement is to be used for conveyor troughs, then is to make the throwing distance dependent on the goods to be conveyed insofar as this, if it is coal, etc., it must not be damaged. With goods can, if the highest performance is desired, be dimensioned for the greatest throw.

If it is a question of moist, baking goods, then naturally must be excepted the acceleration of gravity nor the baking effect of the goods on the vibrating mass (Sieve or conveyor trough) in the form of a constant to be determined on a case-by-case basis must be taken into account.

But now has the embodiment according to Fig.4 for sieves and channels Disadvantage that it has poor mechanical efficiency, the advantages of the optimal delivery litter, the greater the swinging one, the more it can cancel Mass on the one hand and the number of vibrations ia or n = on the other hand from the above Conditions.

If, on the other hand, one chooses an embodiment according to Fig. 5, in which the masses are designed to be able to vibrate using elastic means and are driven by loose coupling within the resonance range, this is how you achieve mechanical, screening and conveying technology the maximum if you are within the optimal limits given above emotional.

In Fig. 5, ai means the upper mass of the sieve or a conveyor trough, a2 the lower mass. Both masses are U-shaped through designed Struts b1, b2 connected to one another and supported loosely against the earth. the Excitation by the motor lbI, the eccentric drive e and the loose coupling'k takes place in such a way that a phase shift of z8 degrees occurs between the two masses and thus the overall arrangement in terms of force and mass effects on the foundation works trouble-free.

The combination of such a known device that the Conditions of mass balance and the most favorable mechanical and vibration technology Corresponds to efficiency, built, measured and operated according to the disclosed teaching is, allows the most favorable performance in relation to the conveyance process and to enrich the sieve and channel technology «.

The teaching disclosed herein can, apart from those specified Examples, of course, can be used wherever a periodic Throwing process through an inevitable (stroke-limited) system of a known type or where a periodic throwing process through an oscillating (force-limited) system - known designs are used for the purpose of work performance.

A mere change in the numerical value by applying a different one System of measurement or by funding over every second, third or nth period caused, of course, does not change anything in the nature of the subject matter of the invention.

Claims (1)

PATENT CLAIM: Conveying bulk goods through vibrating screens or Troughs, characterized in that the product of the oscillation amplitude (half Stroke) (f in centimeters), the square of the number of vibrations (n2) and the sine of the angle of attack (a) gives a most favorable value near Zoo ooo.