LT4238B - Vibration generator and machine with such a generator - Google Patents

Abstract

The balanced vibration generator for the operation of the amplified resonance of the mechanism or device (2) has at least one set of non-swinging masses (5, 4, 2) hanging on a system of springs (6), where there, resonance springs are the cylinder springs, that also support the masses. The generator has a balanced gear system (10, 12, 11) installed. The generator is hanged on fastening elements (9, 7) with special regulation fastenings (8), which are interconnected with the resonance springs (6) and are made so, that the resonance springs, when turned around their longitudinal axes (17) may change the length of the springs.

Description

The present invention relates to a balanced vibration generator of the type described in the preamble of claim 1 and to a mechanism having a vibration generator of the type as described in the preamble of claim 8.

Vibration generators are used in many industrial applications where properly controlled, controlled vibration is required, such as vibration troughs, vibration feeders, vibration screens.

Known vibration generators can be formed as vibration motors, viz. electric motors with counterweights mounted on the axle necks, as a mechanical vibrator with axes connected together and having axles that are driven by an external motor, or so-called electromagnetic vibrators, where the electromagnet forms the driving unit in its own frequency system.

Known vibration generators are mounted on an object or mechanism that is desired to provide vibration. Usually, the mechanism is connected to the base by springs. In well-known designs, particularly those with larger vibration mechanisms, unwanted vibrations are transmitted through the supports of the mechanism to the substrate with consequent adverse environmental effects and unwanted energy loss.

By designing vibration mechanisms in a so-called self-frequency system, the transmission of unwanted vibrations from the mechanism to the base can be significantly reduced, while significantly reducing energy requirements during operation. Therefore, great efforts have been made to form vibration generators and vibration mechanisms as eigenfrequency systems, and therefore the present invention relates also to an eigenfrequency system.

The eigenfrequency systems are often made in such a way that the two masses are connected to the spring elements and are oscillating during operation when the energy is periodically moved from the tensioned springs to the moving masses and back again to the tensioned springs. The great advantage of eigenfrequency systems is that they require only a small amount of energy when the system is initially given a vibration close to the resonant frequency. In addition, it is known that the individual, elastic suspension of each non-oscillating mass can reduce the problems of transmitting vibration to the substrate.

From DE publication no. 1 017 530 is a known method of hanging an eigenfrequency mechanism in which the centers of two non-oscillating masses are in a so-called line of motion, wherein two intermediate resonant springs are so arranged relative to the center of total mass that each mass defines its own elastic connection to the base is formed with spring constants proportional to the respective mass.

From EP publication no. 512 261 is known as a so-called circular feeder with a vibration generator having non-oscillating masses and which is arranged so that the spring constant for the whole spring system can be changed by adjusting the flywheel. The springs are secured to a support mechanism having a bracket extending through the axis of the spring windings and having a flywheel at each end for adjusting the overall length of the springs.

In this way it is possible to adjust the resonant or native frequency of the system. During the adjustment of the mechanism, possible imbalances due to weight cannot be eliminated immediately, so that the energy of vibration resulting from the imbalance is directed to the base or similar.

From U.S. Pat. 3,291,289, moreover, is known a vibratory conveyor, wherein the non-oscillating masses have an eigenfrequency system and wherein the non-oscillating masses form a conveyor. All spring systems forming part of the vibration system are composed of two springs arranged in series with respect to each other in axial direction and connected to each other. The coupling point must form the center point of the elastic springs. This significantly reduces the transmission of vibrations to the substrate, depending on how close the support is to the center of the elastic spring.

The formation of a vibration generator according to the invention as disclosed and characterized in claim 1, or a vibration mechanism as disclosed and characterized in claim 8, provides a particularly practical means of completely avoiding vibration and thus of energy transfer to the substrate. Cylindrical resonant springs are used both as a supporting element and as resonant springs of non-oscillating masses. According to the invention, the cylindrical springs can be rotated about their axis with respect to the actual stroke length of the non-oscillating masses so that the point of the spring wire (winding) which is connected to the frame and thus to the floor or base is completely stationary. vibration energy transfer to the floor or foundation.

This capability is provided in a simple manner by enabling subsequent adjustment of the vibration mechanism or by installing a vibration generator relative to the mechanism to which it is coupled so as to completely prevent the transmission of vibrations to the base or mechanism of the mechanism.

In addition, practice has shown that the losses of the present invention are less than those of known generators or mechanisms. Weight is also reduced, while costs and noise levels are reduced, as movements are harmonious and obsessive obertons in known designs are avoided. Finally, many of the advantages offer a much wider range of applications than known designs. The generator itself and its outer casing or housing are completely stationary, so that they can be mounted on the scales without causing vibrations to interfere with weighing. The generator can also be mounted on special machines such as vehicles.

In respective embodiments of the vibration generator mechanism according to the invention and according to claim 8, the generator may be provided with a balanced drive system.

Usually, the non-oscillating masses which are suspended on the resonant springs, as described in the preamble of claim 1, are supported only by the springs, such that the only fixed attachment to the base or similar support rises from the point of attachment of the springs. In some types of mechanisms, one or more guide plates or the like may be attached in a known manner, for example, from the trough to the base at the end of the trough discharge, so-called vibratory feeder, thereby providing proper mass transfer motion.

Preferably, the vibration generator or mechanism is formed as disclosed and characterized in claims 2 and 9, where it is completed by halving the number of springs relative to known mechanisms, reducing production costs and weight without causing any drawbacks. In addition, problems of joining two springs into groups are avoided, as in U.S. Pat. 3,291,289.

According to the invention, it is desirable that the vibration generator or mechanism is formed as disclosed and characterized in claims 3 or 10. The suspension thus obtained provides a sufficiently rigid connection to the mechanism or installation into which the vibration is to be transmitted without causing any noise, loss or other defect.

The balanced vibration generator according to the invention has a balanced drive system which can be formed as disclosed and characterized in claims 4, 5 or 6. In this way, it is possible to produce simple, robust structures, without the drawbacks of known systems, and with a much greater stroke length than with known vibrators. The construction according to the invention is particularly suitable for operation and control with frequency converters when a standard motor is used which provides a simple connection to the main power sources with frequencies other than those for which the motor is intended, mobile generating units or the like.

The balanced vibration oscillator according to the invention may be formed as a completely independent unit as disclosed and characterized in claim 7. This results in a whole new type of compact vibrator block vibrator that can be mounted on all types of vibration mechanisms such as feeders, conveyors, sieves and the like. When the vibration generator is mounted on the installation or mechanism into which the vibration energy is to be supplied, the resonant springs are adjusted so as to obtain a mechanism with optimum characteristics, in particular to prevent any transfer of vibration and vibration energy to the frame or base of the mechanism.

The invention will now be described in detail with reference to the drawings in which: FIG. 1 shows a vibration generator according to the invention, in section and connected to a feed trough, FIG. 2 shows a vibration generator of FIG. 1, but without housing and without feed trough, and is seen in the direction II-II of FIG. 1, FIG. Figure 3 is a top view of a vibration generator in the direction III-III; 1 and a partial sectional view thereof, FIG. Fig. 4 is a larger sectional view of a part of an adjustable cylindrical spring suspension member, fig. 5 is the same as that of FIG. 4, but seen in the V-V direction of FIG. 4, FIG. 6 shows a feed trough with a partial section of a funnel and with a vibration generator according to the invention and FIG. 7 illustrates a second embodiment of an adjustable suspension of cylindrical springs.

FIG. 1-3 shows a balanced vibration generator 1 according to the invention, which in the example shown is connected to a feed trough 2, only a part of which is shown. The vibration generator 1 is connected to the supply trough 2 by a rigid vibration bracket 3 such that the supply trough 2, the vibration bracket 3 and the plate 4 form one of two non-oscillating masses and the second non-oscillating mass consists of the main plate 5 and possible additional plates mounted on said motherboards.

Between plates 4 and 5 are shown resonant springs 6, which in the illustrated example are formed by four resonant springs 6. The resonant springs are fixed to plates 4 and 5 in a known manner. At a resilient central point of the resonant springs, they are fixed to a rigid steel frame 7 by adjustable clamps 8, which are described below, in Figures 4 and 5. The rigid steel frame 7 is attached to the beam 9 so that the total weight of the vibration generator 1 and the feed trough 2 are supported by this beam.

The two non-oscillating masses are each connected via a separate drive link or connecting link 10 to a drive motor, which in the case illustrated is an electric motor 11, a so-called standard motor having two eccentric 12 on its axle set at an angle of 180 ° to each other. . The two connecting rods 10 are fixedly connected to two plates 4, 5 by rubber cylinders 13.

A metal enclosure 14 is provided around the entire vibration generator, which covers the entire vibration generator but has a hole for the vibration bracket 3.

When the motor 11 is actuated, two non-oscillating masses are moved in a resonant system having four cylindrical springs. If the clamps 8 are positioned at an exactly stationary point on the springs, there will be no vibrational energy transmitted to the beam 9 and thus to the base of the mechanism, but all energy will move between the non-oscillating masses and the resonant springs. .

The suspension arrangement of the resonant springs is explained below with reference to Figures 4 and 5, which illustrate the fastening elements to a greater extent. These consist of clamps 8 of rubber or other flexible material which are rigidly fixed to the steel frame 7 plate 15 by bolts 16. After loosening the bolts 16 and possibly the resonant spring rear mounting brackets, the springs 6 can be rotated about their longitudinal axes 17 as long as each of the springs the fixed point of the wire 18 engages with the clamps 8. Once this position is reached, the screws 16 are tightened again and the vibrator can now operate as desired.

FIG. 6 shows a second embodiment, wherein the vibration generator 1 is suspended under a funnel 19 from which the material is fed to a feed trough.

2. The generator 1 is mounted on a beam 9, which in turn is suspended by a special bracket 20 which is rotatable with a point 21. The balanced vibrator with the feed trough is so mounted on the funnel that the slope of the trough 2 can be easily adjusted as required. adjusting element 22. Finally, FIG. 7 shows a second embodiment of an adjustable fastener, wherein the fastener comprises a lug 23 which includes one of the windings 18 of the spring 6, said eyelet can be tightened or released by a screw 24 so that the spring 6 can be adjusted by rotating it about an axis 17. so that the engagement of the lug 23 with the winding 18 is exactly at the point where the spring is stationary. The 25th position indicates the frame of the mechanism and the eyelet 23 may have a flexible portion 26 which allows a slight inclination of the bracket when the spring is in operation and furthermore prevents possible vibrations from reaching the frame of the mechanism.

The resonant spring (s) 6 may, for example, terminate at each end with a central loop 27 for bolting to non-oscillating masses. In this way, it is very easy to mount the spring so that it can withstand pulling, which means that even greater vibration amplitudes are possible.

Claims (10)

DEFINITION OF INVENTION A balanced vibration oscillator (1) for working in the mechanism or installation of enhanced resonance and having at least one set of non-oscillating masses (5, 4, 2) suspended in a spring system (6), wherein the resonant springs are cylindrical springs (6), which also substantially support the masses, also having a balanced drive system (3,12,11) mounted in the generator, and wherein the vibration generator is suspended on fasteners (9, 7) which are coupled to the resonant springs (6) around a central point of their elasticity, characterized in that the resonant springs are mounted in the fastening elements (8, 23) which are fixedly connected to the base or support so that the springs, when rotated about their longitudinal axes (17), can change the relationship between the springs. from the fastener to the non-oscillating masses. 2. A balanced vibration oscillator according to claim 1, characterized in that each fastener (8,23) has a continuous spring (6) divided into resonant springs, in that the coupling of the fastener to the active spring winding (18) is adjustable. . 3. Balanced vibration generator according to claims 1 and 2, characterized in that the fastening elements have elastic clamps (8, 26), for example made of rubber. 4. A balanced vibration generator according to any one of claims 1 to 3, characterized in that the balanced drive system has an electric motor (11), such as a so-called standard motor, whose drive shaft has eccentric (12) or crank arms which through the drive links, such as the connecting links (10), are connected to non-oscillating masses (5, 4, 2). 5. A balanced vibration generator according to any one of claims 1-3, wherein the drive system comprises at least one pneumatic or hydraulic motor. 6. A balanced vibration generator according to any one of claims 1-3, wherein the actuator system comprises an electromagnetic actuator. 7. A balanced vibration generator according to any one of claims 1 to 6, characterized in that it is made as a single independent mechanism element (1) with means (9, 7) for attaching the mechanism element to the mechanism or mechanism frame and means (3). ) for connection to the part (2) which forms one or part of one of the non-oscillating masses. 8. Mechanism with vibration generator for enhanced resonance operation and having at least one set of non-oscillating masses suspended in a spring system in which the resonant springs are cylindrical springs which also substantially support the masses and having a balanced drive system and wherein the vibration generator is suspended in a part of the mechanism having fasteners which are coupled to resonant springs about their elastic center, characterized in that the resonant springs are mounted on fasteners (8, 23) which are fixedly fixed to the base or support so that the springs are rotated about their longitudinal axes (17) can change the relationship between the lengths of the springs from the fastener to the non-oscillating masses. 9. A mechanism according to claim 8, characterized in that each of the fasteners is provided with a continuous spring divided into resonant springs, in that the coupling of the fastener to the active spring winding is adjustable. 10. A mechanism according to claims 8 and 9, characterized in that the fastening elements have elastic clamps, for example rubber.