DE2427907C2 - Device for adjusting the vibrations of a component that is driven to vibrate - Google Patents

Description

The invention relates to a device for adjusting the vibrations of an oscillating driven Component, in particular a vibratory conveyor driven by imbalance.

From the magazine "promote and lift" 17 (1967), No. 6, pp. 334-337 is a vibratory conveyor with a controllable Unbalance drive known, which consists of a closed resonance drive with unbalance motor excitation exists and is screwed onto the vibratory conveyor rings as a complete unit. With this drive system two separate unbalanced masses are arranged in a common housing and are driven individually. The housing is elastic on an intermediate wall via two pairs of helical springs that work against one another supported, of which one spring of each pair is adjusted via a common spindle can be to change the effective spring force. The springs are self-stabilizing coupling springs with highly progressive spring characteristic and by adjusting its preload during operation, the spring characteristic and thus the natural frequency can be adjusted in the subcritical range. The excitation frequency is regulated in a conventional manner by a customary adjustment of the exciter speeds of the drive motors for the unbalanced masses.

Furthermore, in the journal "building materials industry", 1970, issue 12, pp. 412-414 different systems for Generating circular, elliptical, linear and torsional vibrations are described in which for a Influencing or changing the respective form of oscillation, the position of the unbalanced masses of two counter-rotating flywheels is adjusted. This is a prerequisite for this tax principle Provision of two separate centrifugal masses, each with an individually adjustable position of the unbalanced masses. The bearings of the unbalance shaft are highly stressed and therefore only have a limited service life. Because of the far supercritical coordination of the oscillation system, they use the full inertial forces have to record at relatively high speeds.

The object of the invention is to control the vibrations of a body vibrating in circular or elliptical paths or component in direction and amplitude to be controlled or adjusted in a simple manner.

This object is achieved according to the invention in that at least one separate oscillating system is arranged on the oscillatingly driven component, which executes such linear oscillations of adjustable amplitude and frequency that the oscillations of the component 1 are damped and / or amplified in certain directions.
Advantageously, the separate oscillation system generates linear secondary oscillations which are superimposed on the primary oscillations of the component and in this way result in new two-dimensional oscillation patterns in the desired shape.

A major advantage of the invention is that the separate oscillation systems oscillate automatically, ie via the? driven component itself, are activated and thus fulfill their control function without the need for external driving forces.
For use in special machines, for example vibratory conveyors or the like working mainly in the vicinity of the critical resonance ranges, the use of air springs is particularly useful, the spring characteristics of which can be adjusted within wide limits by adjusting their internal pressure (claim 5). With simple pneumatic regulators the amplitude can be adjusted as well as d ^; e Adjust the vibration mode of the vibrating component during operation, using only a single unbalance drive and avoiding large bearing loads.

In the following a preferred embodiment of the invention is explained in detail with reference to the drawing. It shows
F i g. 1 shows a schematic side view of a vibratory conveyor or a manufacturing or processing unit and the control for setting the vibrating elements, and

Fig. 2 is a graph showing the relationship between inflation pressure and vibration amplitudes the vibrating component and the vibration elements.

A vibratory bowl feeder or other vibrating device for conveying material in any direction or for classifying, mixing or sorting materials, has a container (component) 1, which is on air springs 2 is mounted and is caused to vibrate by eccentric weights 3, which are mounted on a container 1 mounted shaft 4 are attached. The shaft 4 is arranged in the vicinity of the container center of gravity and is driven by an external motor 5 or by a motor 5 arranged on the container 1, either directly or via belts. Without a vibration damper (vibration system) 6 to 9, the container 1 would have an approximately circular path vibrate by the centrifugal force of the eccentric weights 3.

The direction and amplitude of the oscillation of the container 1 is matched by several dynamic Vibration dampers 6 to 9 controlled. Everyone

Vibration damper has a mass 10 which is guided by rocker arm 11 with respect to container 1 will. The movement of the oscillating mass 10 is controlled by two air springs 12, the spring constant of which is adjustable by adjusting their inflation pressure. The air springs 12 are on opposite sides the mass 10 and act against each other. Because during the oscillation one spring expands and the other Compresses the spring is the effective spring constant of the pair of springs is equal to the sum of the individual spring constants.

In a preferred embodiment, the vibration dampers are arranged in pairs or in sets, the elements of each pair being substantially equidistant from the center of gravity of the container 1. The vibration dampers 6 and 9 form a pair and can be in one shown in FIG. 1 pointing to the top left Swing direction.

The vibration dampers 7 and 8 form a second pair and can be in one shown in FIG. 1 to the top right swing in the pointing direction.

If a pair of vibration dampers 6, 9 ^ o matched is that the masses in connection with the springs 12 at the nominal speed of the eccentric weights 3 vibrate in resonance, then the forces acting in the direction of vibration of the masses 10 are eccentric Weights practically compensated, so that only little or no vibrations of the container 1 in occur in this direction.

The other pair of vibration dampers 7, 8 is set so that the container 1 and a first element the masses 10 with the air springs of the vibration dampers 7, 8 form a two-mass vibration system, which resonates in the vicinity, preferably just below the nominal frequency. With this setting c ^ hwinapn the masses 10 of the vibration damper 7, 8 in phase with the eccentric weights 3 and amplify the vibration of the container 1 in the Direction of oscillation of the masses 10. The increase in force can be varied by changing the setting and change the vibration amplitude of the container 1.

The relationship between the amplitude and the phase of the vibration of the container and the masses 10 with respect to the eccentric weights 3 is shown in FIG. 2 shown. When the inflation pressure on the left side of the figure is low, the resonance frequency is low and the tub or container I vibrates with an amplitude X 1, while the masses 10 vibrate with an amplitude X 2. At a pressure P1 , the amplitude of the oscillation X 1 of the tub 1 is approximately twice as large as its undamped oscillation. When the pressure is increased, the vibration amplitudes increase up to a maximum determined by the action of the springs 12. A further increase in pressure increases the resonance frequency until the amplitudes of the container 1 are practically zero at a pressure P1.

Since the vibration dampers 6 to 9 are arranged in pairs and act in different directions, both the direction of the vibration conveyance and the vibration amplitude can be set to suitable pressures by inflating the individual air springs. Although effective vibration amplitudes can be obtained even with inflation pressures above or below the resonance pressure PR, the operating pressure is suitably maintained at just above the resonant pressure PR. For reasons of stability, lower pressures are used during the start-up phase of the container.

Since the pressure P 2 for vibration damping and the preferred pressure Pi for increasing the working amplitude differ by the pressure PR at resonance, and since the system is self-destructive at resonance, the direction of oscillation cannot be reversed during the rotation of the eccentric weights JO at the nominal speed . Since, furthermore, at the desired working pressure P 1, the working frequency

ίο is just above the resonance frequency of the system, it is practically impossible to accelerate the eccentric weights through the resonance frequency. In practice, therefore, before starting the engine 5, the air springs of those of the damping vibration dampers must be acted upon with the pressure P2 , while the prevailing pressure in the other air springs is reduced compared to the working rack P 1. As soon as the motor 5 is running and the eccentric weights? rotating at nominal speed, the air springs at a low pressure can au ^f ^ .en working pressure F i are inflated.

The control device for correctly inflating the air springs for vibratory conveyance in both directions is shown in the lower part in FIG. 1 shown. The control device has a connection 20 to a compressed air source, a first pressure regulator 21, a pressure gauge 22 and a filter 23 for supplying clean compressed air to a branch 24.
From the branch 24 air is fed through pressure regulators, needle valves and three-way valves to the air springs of each vibration damper 6 to 9. For setting, for example, for a delivery to the right, the air pressure in the air filters of the dampers 6 and 9 is set to the value P 2 and the pressure in the vibration dampers 7 and 8 is set in the vicinity of the pressure P 1. The branch 24 is connected in this way through the pressure regulator 25 (with the pressure P2) and the needle valve 26 to a pressure line 27 and via the three-way switching valves 28, 29 and lines 30, 31 to the springs of the vibration dampers 6, 9 .

The vibration dampers 7 and 8 are pressurized simultaneously via lines 32 and 33, these lines being connected to lines 38,39 via a switching valve 34 and 35 and starting valves 36,37 and lines 38, 39 by pressure regulators 40, 41 and Needle valves 43,43 are controlled. All of the needle valves are operated to control the rate of pressure changes. The pressure regulators 40 and 41 set the pressures in the vibration dampers 7, 8 to a pressure P 1 (cf. FIG. 2) in order to control the vibration amplitudes. Ez be used · ;, allow individual controllers to a fine adjustment to compensate for changes in the air springs and other system components. During the working condition, a solenoid valve 44 is activated so that the line pressure from the branch 24 via the valve

44 to the actuating elements of the starter valves 36,37,45 and 46 is applied and these valves connect lines 38 and 39 with the changeover valves, while in the start-up phase are the starter valves 36, 37,

45 and 46 in the positions shown before the activation of the solenoid valve 44, so that one of the pressure regulator 47 controlled pressure is applied to the air springs of the vibration dampers 7 and 8. Pressure switch 48, 49, 50 are connected to each controlled pressure line and in the electrical start and operation control of the motor 5 is provided in order to

the motor and shut down the motor in the event of unfavorable pressures in the respective lines to rule.

When the system is deactivated, the air springs of the vibration dampers 7 and 8 are connected to the controller 47 and have low pressure to close the contacts of the switch 48 so that the engine can be started. The other switches 49, 50 are in the Haltesiromkreis of the motor starter to deactivate the motor, so that the motor is switched off if the pressure PX is too high or the pressure P 2 in the line 27 is too low.

When the conveying direction is to be switched, a solenoid valve 51 is actuated in order to apply pressure to the actuating elements of the switchover valves 28, 29, 34 and 35. This has the effect that a pressure P 2 from the line 27 to the air springs of the vibration

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lines 30 and 31 of the vibration damper 6 and 9 via the starter valves 45 and 46 to the lines 52, 53 connected, these lines being controlled by pressure regulators 54,55. The way of working in the opposite conveying direction is designed in the manner described above with reference to the forward direction of the promotion.

Since there is a loss of pressure in the air springs, which also act as isolators, 2 severe damage to the Conveyors can occur, the air springs 2 are fed via a line 56, which is from a pressure regulator 57 is controlled and monitored by a pressure switch 58, which switches the motor 5 turns off.

By arranging the various vibration damper sets on the container or on another Working organ that is subjected to centrifugal force by the rotating eccentric weights. the direction and amplitude of the vibrations can be chosen and changed by changing the air pressure in the springs the vibration damper can be controlled.

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For this purpose 2 sheets of drawings

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Claims (5)

Patent claims: 1. Device for adjusting the vibrations of a component driven to vibrate, in particular a vibratory conveyor driven by imbalance, characterized in that at least a separate oscillation system (6 to 9) is arranged, the such linear oscillations of adjustable amplitude and frequency executes that the vibrations of the component (1) in certain Directions are dampened and / or amplified. 2. Device according to claim 1, characterized in that that on the component (1) at least two separate vibration systems (6; 9 or 7; 8) under different Angles are arranged that perform linear oscillations in different directions. 3. Apparatus according to claim 1 or 2, characterized in that each oscillating system (6 to 9) from an oscillating mass (10) movably held on the component (1) and one air spring (12) each to the opposite sides of the oscillating mass (10) 4. Apparatus according to claim 3, characterized in that each oscillating system (6 to 9) consists of two separate oscillating masses (10) with air springs (12) on their opposite sides. 5. Apparatus according to claim 3 or 4, characterized in that the air pressure in the air springs (12) is adjustable.