DE2028901C3 - Silo arm for a silo discharge device - Google Patents

Description

The invention relates to a rotor arm for a silo discharge device according to the preamble of Claim 1.

The elastic bending of this known rotor arm (DE-GM 69 11 857) acts as overload protection. The rotor arm can therefore increase from its working position counter to the direction of rotation of the rotor be bent if the resistance in the bulk material is too great. However, if the bulk resistance suddenly decreases, for example due to the silo running empty or due to cavities in the bulk material, so quickly the rotor arm returns to its original position. During this springback, the rotor arm is subjected to heavy loads exposed, especially when it springs in the opposite direction beyond its normal position

ίο The rebound often causes such high peak loads that that the leaf springs tire or break after a while.

The invention is based on the object of the rotor arm according to the preamble of claim 1 so to train that the leaf springs are not overloaded even with a sudden decrease in the bulk resistance will.

This object is achieved according to the invention with the characterizing part of claim 1

The damping device according to the invention takes up part of that which is released during the spring back kinetic energy of the rotor arm and therefore counteracts the kickback movement. The leaf springs are thereby protected from damage caused by excessive springing back.

Further features of the invention emerge from the subclaims.

The invention is explained in more detail using an exemplary embodiment shown in the drawings. It shows

F i g. 1 a plan view of a rotor with two rotor arms in a schematic representation,

F i g. 2 excerpts one of the rotor arms according to FIG. 1 in longitudinal section, shown enlarged,

F i g. 3 shows a section along the line HI-HI in FIG. 2.

Rotor arms 1 are attached tangentially to the circumference of a cylindrical rotor 2. The rotor is centric in a, for example, cylindrical silo 3 is stored directly above the silo bottom 4

The rotor arms 1 are each formed by several adjacent leaf springs 5 to 7, whose radially inner ends lie next to one another at the inner end 8 of the rotor arm 1 and in the direction of the free End 9 of the rotor arm have stepped lengths so that the cross section of the rotor arm 1 in the direction of free end 9 decreases The respective shorter leaf springs are in the direction of rotation 10 of the rotor 2 behind the longer leaf springs. The leaf springs 5 to 7 are held together by holders that are shown in

so the longitudinal direction of each rotor arm are arranged at a distance one behind the other.

When the rotor 2 rotates in the direction 10, the rotor arms 1 are resiliently counter to the direction of rotation in the direction shown in FIG. 1 bent position la indicated by dashed lines. As soon as the rotor arm 1 no longer counteracts any resistance, for example due to the silo running empty or through cavities in the silo material column, it relaxes in the direction of the position shown in FIG. 1 position shown, the force of the relaxation movement can be so great that the rotor arm 1, if it has no damping device, strikes back beyond the relaxed position into the position Xb indicated in FIG. 1 by dash-dotted lines.

The recoil movement of the rotor arm 1 is now damped in that at least one damping device 11 (Fig.2 and 3) is provided, which is part of one of the holders. The damping device 11 is

pivotally connected to the rotor arm 1 and has a spring 21 which is arranged so that their Tension increases when the rotor arm 1 is unloaded. The pivot axis 16 of the damping device 11 is parallel to the plane of the leaf springs 5 to 7 and perpendicular to their longitudinal axis and is through a hinge pin one Lever 12 is formed, which carries a stop 13 resting against one side of the Biattfederpaketes The spring 21 is on the lever 12 on the side of the leaf spring assembly opposite the hinge pin 16 a bolt 27 is supported. The lever 12 is supported by two plates on either side of the leaf spring assembly 17 formed with rounded corners which are connected to one another by the hinge pin 16. the In a plan view according to FIG. 2 the shape of right triangles. The stop 13 is a cylindrical bolt with which the plates 17 are rigidly connected to one another and in the area of about 50 ° having corners of the unequal-sided dieieck-shaped plates

In the area of the other two plate corners, the hinge pin 16 and the pin 27 are releasable on the Plates 17 attached The hinge pin 16 located in the area of the right-angled corners of the plates 17 rests on it the same side of the leaf spring assembly as the stop 13. The one in the area of approximately 40 ° The corners of the plates and the bolts 27 on the opposite side of the leaf spring assembly are spaced apart from the leaf spring assembly An axial plane containing the axes of the bolts 16,27 lies in the non-damping position Damping device 11 at right angles to the longitudinal axis of the rotor arm 1 (FIGS. 1 and 2).

The ends of the bolts are each provided with an annular groove 29, the width of which corresponds to the thickness of the plates 17 corresponds to The plates have mutually aligned, the outer diameter of each associated Bolt corresponding holes 28 through which the bolts are inserted and then by radial movement in this way can be locked so that the edge areas of the bores 28 each into the associated annular groove 29 intervene positively (FIG. 3).

The hinge pin 16 is connected to the outer leaf spring 5 located on the rear side of the rotor arm 1 in FIG an eyelet 15 formed by it at its end cannot be displaced, but is rotatably mounted. The hinge pin 16 can also be set with respect to the leaf spring 5, so that the plates 17 relative to the Swivel the pivot pin.

The plates 17 have a small lateral distance from the leaf spring package, so that the leaf springs 5 to 7 in can be moved laterally against each other to a small extent. Also in the longitudinal direction 19 des Rotor arm 1, the leaf springs can be slid against each other, whereby to increase the Slidability between the individual leaf springs intermediate layers 18, for. B. polyamide strips or thin, hardened spring steel strips, can be arranged.

The spring 21 is designed as a spring clip which is symmetrical to that in the non-damping position by the Axis of the hinge pin 16 extending axial plane of the pin 27 is formed. The spring clip 21 is supported with its free ends 22 sliding on the outside 23 of the leaf spring assembly. The ends 22 are on their contact surface 24 is convexly curved in such a way that they with predetermined friction on the outside 23 can slide. Half its length is the spring 21, which is bent from a sheet metal strip and the same width as the leaf springs has a side view according to FIG. 2 approximately semicircular curved clamping part 25, whose concave, outwardly open side 26 facing away from the leaf spring assembly The inner diameter of the clamping part 25 corresponds to the outer diameter of the bolt 27, which is pivotable in the by the clamping part formed bearing shell lies.

The spring 21 is to achieve a flat spring characteristic by two superposed Single bracket formed, but only one of them

ίο Contact leg for contact with the leaf spring 7 It can, however, also be provided more than two individual brackets. The spring 21 becomes like this pressed against the leaf spring assembly that it rests with its ends under pretension on the leaf spring 7; as a result, the leaf springs 4 to 7 are in turn closed when the damping device 11 is in the non-damping position pressed against each other in constant spring pressure, through which the friction of the leaf springs against each other is determined and prevents the leaf springs from being able to lift off the intermediate layers 18. In addition, the bolts 16, 27 are held in their locked positions as a result of the spring force.

In the non-damping position of the damping device 11, the stop 13, which is located radially outside with respect to the rotor arm, rests on the outside 14 of the leaf spring 6 adjacent to the leaf spring 5. The Hsbel 12 can thereby pivot from the non-damping position only in the direction in which the stop 13 lifts from the outside 14 of the stop outer leaf springs 6, 7 opposite one another in directions 19 "and 19 '. As a result, a clockwise torque acts on the lever 12 according to FIG of the lever 12 so that the outside 23 of the leaf spring 7 slides along the ends 22 of the spring 21. However, as soon as the rotor arm moves from its position 1.3 in the direction of the relaxed position, the relative sliding movement between the two outer leaf springs 6, 7 so that a left-turning moment is exerted on the lever 12 as a result of the contact of the spring 21 according to FIG Lever 12, in which the stop 13 lifts off the outside 14. At the same time, the bolt 27 approaches the outside 23 of the leaf spring 7 during this pivoting movement. The pressing force of the spring 21 increases on the leaf spring 7, and the leaf springs are correspondingly more compressed. This increases the friction between the leaf springs, so that the relaxation movement of the rotor arm is dampened. With correspondingly strong relaxation movements, the bolt 27 of the damping device 11 is brought so close to the leaf spring 7 that the clamping part 25 of the spring 21 rests against the outside 23 of the leaf spring 7, whereby the leaf springs 5 to 7 are no longer clamped in a resilient manner. At the beginning of the relaxation movement, however, the damping device 11 is resiliently supported on the leaf springs. The spring 21 is influenced via its ends 22 by the relative movement of the leaf spring to one another and accordingly displaces the damping device 11 in positions of different damping. As a result of the damping, it is avoided that the rotor arm 1 can reach the rollover position \ b according to FIG. The lever 12 is an angle lever on

One arm of which the stop 13 is seated and the spring 21 is supported on the other arm.

As a result of the training described has a full relaxation of the rotor arm 1 from the tensioned Situation la a strong, a partial relaxation, however, a weaker dampening of the relaxation movement as a result, so that the damping exactly matches the character of the respective tension movement is adapted.

Even when springing back over the relaxation or In addition, the rotor arm is supported by the Damping device 11 so strongly damped that overstretching of the leaf springs is not to be feared.

For this purpose 2 sheets of drawings

Claims (10)

Patent claims: 1. Rotor arm for a silo discharge device for discharging the lower area of a bulk material column, with a leaf spring package, the leaf springs of which are slidably adjacent to one another in their longitudinal direction and are held together with holders, one end of which is on a rotor of the silo discharge device is attached and according to the resistance of the bulk material relative to the direction of rotation of the rotor is elastically bendable, characterized in that the rotor arm (1) has a snap-back movement engages the rotor arm damping device (11) 2. rotor arm according to claim 1, characterized in that the damping device (11) with the Rotor arm (1) is pivotally connected 3. rotor arm according to claim 1 or 2, characterized in that the damping device (11) Is part of one of the holders 4. Rotor arm according to one of claims 1 to 3, characterized in that the damping device (11) has a spring (21) which is arranged in such a way that its tension when the rotor arm is relieved of load increases. 5. Rotor arm according to one of claims 2 to 4, characterized in that the pivot axis (16) the damping device (11) parallel to the plane of the leaf springs (6,7) and perpendicular to their longitudinal axis lies. 6. rotor arm according to claim 4 and 5, characterized in that the pivot axis (16) through a hinge pin of a lever (12) is formed, the one on one side of the leaf spring assembly abutting stop (13) and on which the spring (21) on the hinge pin (16) opposite Side of the leaf spring assembly is supported 7. rotor arm according to claim 6, characterized in that the hinge pin (16) with one of the two outer leaf springs (5, 7) immovably connected, for example in one of these Leaf spring formed eyelet (15) is mounted. 8. rotor arm according to one of claims 4 to 7, characterized in that the spring (21) as Spring clip is formed, which slides with its free ends (22) on the leaf spring assembly is supported. 9. rotor arm according to one of claims 6 to 8, characterized in that the lever (12) is a Angle lever is on one arm of which the stop (13) sits and the spring (21) on the other arm is trimmed. 10. Rotor arm according to one of claims 6 to 9, characterized in that the lever (12) through two plates (17) lying on both sides of the leaf spring assembly are formed, which are supported by the hinge pin (16) are interconnected.