DE3402138C2 - - Google Patents

Description

The invention relates to a vibratory conveyor according to the preamble of claim 1.

Such a shaker is with DE-AS 22 55 024 known. This known vibratory conveyor has Leaf springs inclined to the vertical, and serve for elastic storage of the shell carrier. Shaker feeders of this type are usually replaced by a electromagnetic exciter shaken. The frequency of the Operation of the exciter is dependent on the mains frequency Energy source prescribed. The excitation frequency can therefore generally not to be changed.

The known vibratory conveyor has the major disadvantage that it cannot be adapted to different materials can. Different devices must therefore be switched on be set when the feed speeds for different Materials or items should vary, or if below different materials fed with the same conveyor should be.

The present invention is based on the object To create vibratory conveyor of the type mentioned, the in a simple way to different Feed speeds and / or different materials and Objects can be customized.

This object is achieved by the subject of Claim 1 solved. Advantageous embodiments of the Erfin Applications are the subject of the subclaims.  

The vertical acceleration of the feed tray can partially controlled or chosen by the Mon day angle of the springs supporting the shell becomes. The invention allows the adjustability of the Angle by using a set of components, which support the bowl.

The invention is described below using exemplary embodiments explained in more detail with reference to the drawing. In the drawing shows

Fig. 1 is a plan view of a Schalenzuführer which can be set in vibration,

Fig. 2 is a side view of the device according to Fig. 1,

Holders Fig. 3, 4 and 5 single leaf spring assemblies having different combinations of ver distance which various different result Liche leaf spring angle.

In Fig. 1, a vibratory tray feeder 10 is shown as a top view with a bottom 12 which element supports a carrier or a Querträgerele 14 , to which a tray, not shown, is attached in a conventional manner. Each of the ends 16 of the cross member 14 is attached to an individual bundle of leaf springs 20 . Each leaf spring bundle or package 20 can be composed of either a single leaf or a plurality of leaves, the two leaf spring stacks shown are only shown as an example.

In FIG. 2, the cross member 14 is shown as a supported member, and the ends 16 are adequately supported by the four leaf spring packets 20 on the bottom 12. The bottom 12 is a generally rectangular plate of considerable mass, which is seen with cutouts 22 to accommodate the arrangement of the leaf springs within the general circumference of the machine. Each cut-out 22 extends at a right angle from the edges of the floor towards the center and is generally machined so bear, as shown in Fig. 2, so that at least a first surface 24 , hereinafter referred to as the base of the floor cutout, is formed at an angle to the Verti cal 26 . In a preferred embodiment, this base angle is 25 °.

In Fig. 2 it is also shown that the ends 16 are provided with end surfaces 30 , each working at an angle to the vertical reference line 26 in a direction which is the opposite of that of the first surface angle of the Bodenaus section. In a preferred embodiment, this can be an angle of 15 °.

Each end of each leaf spring 20 is provided with an opening to receive a spring clamp bolt 32 . In the embodiment shown, eight identical bolts are used, but other fastening devices are also possible. The bolts are ultimately received in drilled threaded holes in corresponding base surfaces 24 and end surfaces 30 of the base 12 and the cross member 14 . The spring clamp bolts on the bores are drilled at an angle to the horizontal plane of the same inclination. In this embodiment, the holes are drilled at 20 ° to the horizontal and parallel to each other.

A large number of flat spacers and wedges are provided in order to make it possible to adjust the leaf spring mounting angles. For purposes of illustration, a flat spacer is a rectangular piece of material that has a given thickness and large flat areas on each side, which areas are generally parallel to one another. These flat spacers 40 in FIG. 2 are also provided with a hole which allows the spring clamp bolt 32 to pass through.

The wedges 42 in Fig. 2 are similar to the flat spacers 40 with the exception that the opposite large flat surfaces are formed at different angles to the normal plane. For example, a first surface 44 is parallel to the normal plane, while a second surface 46 is formed at 5 ° to the normal plane so that it has an angle of 5 ° with respect to the first surface 44 . The wedges are also provided with a hole to receive the spring clamp bolts 32 .

The flat spacers 40 and wedges 42 are positioned with respect to the leaf spring assembly 20 to provide different leaf spring angles, as shown in Figures 3-5.

In Fig. 3, the leaf spring bundles are arranged at an angle of 15 ° to the vertical, as indicated by the angle A. In this drawing it is shown that the end face 30 is formed at the end 16 of the cross member at an angle 50 of 15 ° with respect to the vertical reference line 26 Be. At the bottom 12 it can be seen that the surface 24 is worked at an angle 52 of 25 ° to the vertical reference line 26 . This surface angle of the end surface 30 and the cut-out surface 24 are constant in all exemplary embodiments, but he could be changed if necessary.

In order to obtain the angle A of 15 ° by the leaf spring arrangement according to FIG. 3, the following arrangement of spacers is used. Because the cross-support end surface is worked at an angle of 15 ° 30, no spacers are required between the upper ends of the leaf spring packets and the end face 30th A wedge 42 is required outside the leaf spring assemblies to ensure that the head of the spring clamping bolt touches an upper surface which remains perpendicular to the main axis of the bore 34 and that the bolt is not deflected by eccentric forces. The wedge 42 creates a surface that is parallel to the end surface 30 of the cross member end. At the bottom cutout 22 , where the base 24 is formed at an angle of 25 ° to the vertical, two identical forces 42 a and 42 b between the leaf spring assemblies and the base 24 are required. The two wedges 42 a and 42 b lie with their normal surfaces against each other, so that a wedge of 10 ° is formed, so that the actual angle of the base surface is brought from 25 ° to 15 °. Outside the springs, a single wedge 42 c is arranged to ensure that the bolt head 32 a touches a surface that is at an angle of 20 ° to the vertical reference, while further ensuring that the bolt is not deflected by eccentric loads becomes.

In the embodiment according to FIG. 4, a 20 ° including transmitting angle B is formed between the leaf spring assembly 20 and the vertical cover 26 . Of course, the elements used here are the same as the elements used in the embodiments according to FIGS. 1, 2 and 3 with the exception that the flat spacers and the wedges are arranged differently. In particular, a wedge 42 b is arranged on the cross member between the leaf spring 20 and the end surface 30 in order to change the surface angle 50 from 15 to 20 °. Since this surface creates a complementary angle for the spring clamp bolt 32 , a flat spacer 40 is used outside the springs. On the floor, on which the base has an angle 52 of 25 °, a wedge 42 e is used to bring the angle between the leaf spring 20 and the vertical reference 26 to 20 °. Outside the leaf spring 20 , only a flat spacer is required to ensure a concentric loading of the spring clamping bolt 32 a .

In the embodiment of FIG. 5, a 25 ° including transmitter angle C is created by inserting wedges of 10 ° ge, namely by wedges 42 f and 42 g with 5 ° each, which are arranged between the leaf spring bundles and the end face 30 . Outside at the upper end of the leaf spring bundle, a third wedge 42 l is required to achieve a contact surface alignment of 20 °, so that the spring clamp bolt 32 is loaded concentrically. No wedges are required on the floor because the base area 24 is formed at an angle of 25 °, so that the leaf spring bundle is arranged directly on the base area 24 . A wedge 42 j is meanwhile used to realign the spring clamp bolt 32 a and the threaded hole in the cross member.

Although wedges with a surface angle of 5 ° against the Normal plane and special angular displacements of the end  surface and cut-out area are explained raised that this is a preferred embodiment games and thus minor changes in the angle values are within the essence of the invention. Furthermore is the number of elements is not critical, so that also for example floors with more than four cutouts and cross carriers with a large number of arms are possible.

Claims (5)

1. Shake conveyor with an elastically mounted carrier for a bowl or the like, the elastic mounting being carried out by leaf springs arranged at an angle to the vertical, which connect the carrier to a floor, and wherein mounting surfaces which are inclined on the carrier and on the floor are arranged, to which these leaf springs are fastened, characterized in that exchangeable wedges ( 42 ) are provided between the carrier ( 14 ) and the leaf springs ( 20 ) and / or between the leaf springs ( 20 ) and the bottom ( 12 ). 2. Device according to claim 1, characterized in that the angle which the on the carrier ( 14 ) arranged Montageflä Chen ( 30 ) include with the vertical, and the angle that the mounting surfaces ( 24 ) of the bottom ( 12 ) with the countersink include right, are different. 3. Device according to claim 1 or 2, characterized in that at least two wedges ( 42 ) are provided between the leaf springs ( 20 ) and the mounting surfaces ( 24, 30 ), the wedges ( 42 ) being arranged in a sandwich-like manner. 4. Device according to one of claims 1-3, characterized in that the leaf springs ( 20 ) by spring clamp bolts ( 32 ) on the mounting surfaces ( 24, 30 ) are attached, and that on the mounting surface ( 24, 30 ) facing away Additional wedges ( 42 h , 42 j) can be used on the side of the leaf springs. 5. Device according to one of claims 2-4, characterized in that the angle between the mounting surface ( 30 ) of the carrier ( 14 ) and the vertical is approximately 15 ° in that the angle between the mounting surface ( 24 ) of the bottom ( 12 ) and the vertical is about 25 ° and that the angle of inclination of the wedges ( 42 ) is about 5 °.