DE3901156A1 - Vibratory conveyor - Google Patents

Abstract

In the case of a vibratory conveyor having a dual frequency unbalance generator; two pairs of balancing weights, the two weights of which are of equal size and point in opposite directions; a drive which imparts rotary movements to the balancing weights via belts, the speed of rotation of the balancing weights of one of the pairs of balancing weights being twice as fast as the speed of rotation of the other pair of balancing weights and the centrifugal forces of all the balancing weights being equal; and a connected component for conveying a multiplicity of parts, in order to make it possible to convey and feed piece goods in a sliding oriented manner, the drive takes the form of an electric motor and a belt which has toothing on both sides connects the driving spindle of the electric motor to all the spindles of the four balancing weights and the connected component is a trough for conveying piece goods.

Description

The innovation concerns a vibratory conveyor, with one Double frequency unbalance exciter, with two balance mass pairs, whose two masses are the same size and in point in the opposite direction, with a drive that the Balancing masses set in rotation by means of belts, the The speed of the balancing masses of one of the balancing mass pairs is double is as large as the speed of the other pair of balancing masses and the centrifugal forces of all balancing masses are the same and with a coupled component to promote a Variety of parts.

Such a vibratory conveyor is from the publication by Dipl.-Ing. F. Substance entitled "Behavior of Bulk material on vibrating surfaces and vibrating channels " appeared in the communications of Carl Schenck Maschinenfabrik GmbH, 6100 Darmstadt, Issue 11, 1969, p. 29, 30 known. The vibratory conveyor consists of one Dual frequency unbalance exciter with two balance mass pairs, whose two masses are the same size and in point in the opposite direction. The smaller balancing masses of a pair of balancing masses rotate twice as fast as the balancing masses of the other pair of balancing masses. The Centrifugal forces of all balancing masses are of the same size. The two balancing masses of a pair of balancing masses are in driven in the opposite direction. To the Imbalance exciter is connected to a conveyor trough for bulk material. Through this arrangement and this direction of rotation of the balancing masses vibrations are only in the horizontal conveying direction generated. Swinging movements vertical to the conveying direction do not occur. By changing the direction of motor rotation the conveying direction is reversible. The bulk material slides with the Funding in the funding trough.  

With the known vibratory conveyor it turns out to be Disadvantage that one for each pair of balancing masses for driving Motor is provided, the two balancing masses over a V-belt set in rotation. The use of two Motors as drives are not inexpensive and increase the Noise emission. In addition, the use of the Vibratory conveyor on the conveyance of large quantities Bulk goods. The sponsors show grants from about 50 t / h, with conveyor lengths up to 15 m.

The innovation is based on the task, one Vibratory conveyor to create that inexpensive and easy can be manufactured and operated, the low maintenance, is gentle on the material and reduces noise and general cargo smoothly promotes and feeds in a situation-oriented manner.

The object is achieved in that the drive Electric motor is that a double-sided belt Drive axis of the electric motor with all axes of rotation of the four balancing masses connects, and that the coupled Component is a general cargo conveyor trough.

The fact that the drive is an electric motor results in the advantage over the known vibratory conveyor that the manufacture and operation of the subject matter of the invention is easier and cheaper and that less noise is emitted. In this context, it is advantageous that a double-sided toothed belt the drive axis of the Electric motor with all axes of rotation of the four balancing masses connects, because in addition to the advantages of Maintenance effort and material wear reduced becomes. In addition, through this phase-locked connection Balancing masses ensure that this is the one for optimal operation of the innovation object required take predetermined positions to each other.

It is also advantageous that the coupled The component of a general cargo conveyor trough is because of this  General cargo, such as B. electrical or electronic Components and flat components stamped from strip material are promoted and fed on a sliding basis can.

Further advantageous refinements and developments of The subject of the innovation is evident from the subclaims.

You can arrange all the balancing masses in one level, around which in the bearings of the axes of rotation of the balancing masses To keep forces as small as possible, so undesirable Vibration components can be avoided. This reduces the Wear and the maintenance effort of the innovation item.

It is also advantageous that a coupling rod Coupled drive part to the general cargo conveyor trough in order to Contrary to the previously known vibratory conveyor no Bulk goods, but piece goods sliding in a position-oriented manner to promote long conveyor lines.

The fact that the general cargo conveyor trough over the first and second Parts that have inclined planes rising in the direction of conveyance form, is stored on the basic mass, the results Advantage that in addition to the horizontal swinging movement vertical motion component can be generated. Know the general cargo conveyor trough one in the conveying direction increasing inclined plane, so general cargo to be promoted in a progressive, position-oriented manner.

It is advantageous if the general cargo conveyor trough linear sorting trough is because so general cargo during the Funding can be sorted. Because the General cargo conveyor trough firmly on the top of the Drive part is mounted, there is the advantage that the Innovation object can be built particularly compact. In this context, the balancing masses in at least one row parallel to the general cargo conveyor trough  arrange to run the drive part as low as possible can.

It is advantageous that between the drive part and the Basic mass at least one damping element is arranged, because this, especially when switching on and off the Subject of innovation, a cancellation or reduction of unwanted harmonics caused by the low damping properties of the steering springs be achieved.

Embodiments of the innovation object are in the Drawings are shown and are based on the Drawings described in more detail.

Show it

Fig. 1 shows a vibration conveyor according to the innovation in side view

Fig. 2 shows a modern vibratory conveyor in side view, with a general cargo conveyor trough for the upward conveyance of bulk goods

Fig. 3 shows another Asuführungsbeispiel an inventive vibratory conveyor in side view.

In Fig. 1, a vibration conveyor according to the innovation is shown in side view. The basic mass ( G ) is for decoupling via supports ( S ) made of elastic material such as. B. rubber, stored on a base ( SO ). For a cost-effective and simple construction and operation of the innovation object, an electric motor ( E ) is permanently attached as a drive on the underside of the base mass ( G ). The vibratory conveyor also consists of a drive part ( A ) that contains the four balancing masses ( M 1 , M 2 , M 3 , M 4 ) with the axes of rotation ( D ). To generate oscillating movements in the direction of conveyance, the rotary movement of the electric motor ( E ) is transmitted to all axes of rotation ( D ) of the four balancing masses ( M 1 , M 2 , M 3 , M 4 ) via a double-sided toothed belt ( Z ), which reduces maintenance costs and material wear is reduced. The arrows indicate an example of a running direction of the double-sided toothed belt ( Z ). The direction of rotation of the balancing masses ( M 1 , M 2 , M 3 , M 4 ) is determined by the arrangement of the belt ( Z ). The balancing masses ( M 1 , M 2 , M 3 , M 4 ) within a pair of balancing masses ( M 1 , M 2 and M 3 , M 4 ) are driven in the opposite direction of rotation. The balancing masses ( M 1 , M 3 ) and the balancing masses ( M 2 , M 4 ) are each driven in the same direction of rotation. In the basic position shown, the balancing masses ( M 1 , M 2 , M 3 , M 4 ) within a pair of balancing masses ( M 1 , M 2 and M 3 , M 4 ) point in the opposite direction, which are perpendicular to the direction of vibration generated, in particular perpendicular to the Delivery direction is.

This arrangement and direction of rotation of the balancing masses only vibrations in the horizontal conveying direction generated. By reversing the direction of rotation Conveying direction reversible.

The balancing masses ( M 1 , M 2 , M 3 , M 4 ) are arranged in one plane to reduce unwanted vibration components and to reduce the wear on the bearings of the rotary axes ( D ).

For the sliding, position-oriented conveyance of piece goods, a piece goods conveying trough ( F ), which rests on the basic mass ( G ), is firmly coupled to the drive part ( A ) via a coupling rod ( K ), which consists here of strip steel which has proven to be advantageous.

The piece goods conveyor trough ( F ) is designed so that piece goods, such as. B. electrical or electronic components or flat components stamped from strip material can be promoted slidingly oriented.

Flat components cannot slide over each other because a vertical acceleration component, the one Throwing movement can not exist.

The structure of the subject matter of the invention thus consists of a two-mass system. The general cargo conveyor trough ( F ) forms a first mass together with the drive part ( A ). The basic mass ( G ) forms a second mass together with the electric motor ( E ). To generate the restoring forces required to operate the vibratory conveyor to return the first mass to the starting position and to create an oscillatable two-mass system, the drive part ( A ) is fixed to the four steering springs ( L ), which are arranged perpendicular to the conveying direction Base compound ( G ) connected. The natural frequency of the two-mass system is chosen so that there is a sufficient distance from the working frequency (delivery frequency) to avoid undesirable vibrations.

In Fig. 2, a modern vibratory conveyor is shown in side view with a piece goods conveyor trough ( F ) for the upward conveyance of piece goods. The same or equivalent components as in Fig. 1 are provided with the same reference numerals in Fig. 2.

To produce a vertical acceleration component, the general cargo conveyor trough ( F ) is mounted on the base mass ( G ) via first parts ( T 1 ) and second parts ( T 2 ), which form inclined planes that rise in the conveying direction. The slope of the inclined planes is designed so that the vertical acceleration of the piece goods to be conveyed is less than the acceleration due to gravity. A throwing movement of the piece goods is thus avoided, which ensures smooth conveyance and flat components cannot slide over one another.

In order to reduce the required restoring forces which have to be applied by the steering springs ( L ), it has proven to be advantageous to roll the first parts ( T 1 ) on the second parts ( T 2 ).

So that general cargo can be conveyed upwards, the general cargo conveyor trough ( F ) has an inclined plane ( B ) that rises in the conveying direction.

Fig. 3 shows a further embodiment of a vibratory conveyor according to the invention in side view. The same or equivalent components as in FIGS. 1 and 2 are provided with the same reference numerals in FIG. 3.

The basic mass ( G ) is firmly connected to the base ( SO ). In addition, the basic mass ( G ) has a recess ( C ) for receiving and installing the electric motor ( E ). The general cargo conveyor trough ( F ) is firmly connected to the top of the drive part ( A ). It has proven to be advantageous if the piece goods conveyor trough ( F ) projects beyond the drive part ( A ) at its two ends by an equally large amount. In order to be able to build the drive part ( A ) as flat as possible, the balancing masses ( M 1 , M 2 , M 3 , M 4 ) are arranged in two rows parallel to the general cargo conveyor trough ( F ). This arrangement of the axes of rotation ( D ) of the balancing masses ( M 1 , M 2 , M 3 , M 4 ) enables optimal guidance of the double-sided toothed belt ( Z ), which supports all balancing masses ( M 1 , M 2 , M 3 , M 4 ) connects to the drive shaft of the electric motor ( E ). The drive part ( A ) is connected to the basic mass ( G ) via four steering springs ( L ). A damping element ( W ) is fitted between the drive part ( A ) and the base mass ( G ) to dampen undesired, harmonic harmonics, which occur in particular when the vibratory conveyor is switched on and off and is caused by the low damping properties of the steering springs ( L ) . As an example of a damping element ( W ), a right-angled leaf spring is attached to the drive part ( A ) and has a thickened portion at its free, downward-facing end. This thickening is in contact with a sliding material which is applied to the top of a component attached to the base mass ( G ).

Claims (14)

1. Vibratory conveyor, with a double-frequency unbalance exciter, with two balancing mass pairs, the two masses of which are each the same size and point in opposite directions, with a drive that sets the balancing masses in rotation by means of belts, the rotational speed of the balancing masses of one of the balancing mass pairs being twice as large how the speed of the other pair of balancing masses and the centrifugal forces of all balancing masses are the same and with a coupled component for conveying a large number of parts, characterized in that the drive is an electric motor ( E ), that a two-sided toothed belt ( Z ) drives the drive axle of the electric motor ( E ) with all axes of rotation ( D ) of the four balancing masses ( M 1 , M 2 , M 3 , M 4 ) and that the coupled component is a piece goods conveyor trough ( F ). 2. Vibratory conveyor, according to claim 1, characterized in that all balancing masses ( M 1 , M 2 , M 3 , M 4 ) are arranged in one plane. 3. Vibratory conveyor according to claim 1, characterized in that a coupling rod ( K ) couples a drive part ( A ) to the piece goods conveyor trough ( F ). 4. Vibratory conveyor according to claim 1, characterized in that the drive part ( A ) via four steering springs ( L ), which are arranged in particular perpendicular to the conveying direction, with a basic mass ( G ). 5. Vibratory conveyor according to claim 1, characterized in that the electric motor ( E ) is fixedly adjustable in height with the basic mass ( G ). 6. Vibratory conveyor according to claim 1, characterized in that supports ( S ), which consist of elastic material, connect the basic mass ( G ) with a base (SO) . 7. Vibratory conveyor according to claim 1, characterized in that the piece goods conveyor trough ( F ) via first parts ( T 1 ) and second parts ( T 2 ) form the inclined planes rising in the conveying direction, is mounted on the base mass ( G ). 8. Vibratory conveyor according to claim 7, characterized in that the piece goods conveyor trough ( F ) has an inclined plane (B) rising in the conveying direction. 9. Vibratory conveyor according to claim 7, characterized in that the first parts ( T 1 ) on the second parts ( T 2 ) are mounted on a roller. 10. Vibratory conveyor according to claim 1, characterized in that the piece goods conveyor trough ( F ) is a linear sorting trough. 11. Vibratory conveyor according to claim 1, characterized in that the piece goods conveyor trough ( F ) is fixedly mounted on the top of the drive part ( A ). 12. Vibratory conveyor according to claim 11, characterized in that the balancing masses ( M 1 , M 2 , M 3 , M 4 ) are arranged in at least one row parallel to the general cargo conveyor trough ( F ). 13. Vibratory conveyor according to claim 11, characterized in that the basic mass ( G ) is firmly connected to the base ( SO ). 14. Vibratory conveyor according to claim 11, characterized in that at least one damping element ( W ) is arranged between the drive part ( A ) and the base material ( G ).