DE19523030C2 - Vibration exciter, method for mechanical vibration generation. and vibrating plate - Google Patents

Description

The invention relates to a vibration exciter with a exciter mass for the Vibration generation according to the preamble of claim 1, an associated procedure according to the preamble of the An saying 8, and a vibrating plate according to claim 11.

An application example for such vibration exciters are, for example, vibrations used in road construction plates.

In such devices used for soil compaction two directional vibrations in unbalance waves horizontally arranged side by side, of which an unbalanced shaft connected to a drive unit is while the second unbalance shaft is over from the first a gear is driven. The phase position of the unbalance is adjustable on the respective unbalanced shafts, whereby a forward movement of the vibrating plate back and forth is infinitely adjustable. A variation of the Striking power is generally only with special mechani effort and is, for example, real  lized that each unbalanced mass another small nere unbalanced mass has been assigned, which is in a Direction of rotation of the unbalanced shafts to the large unbalance mass added and in the other direction of rotation of the Un balancing waves subtracted from the large unbalanced mass.

With such a device, only two are under different impact power values adjustable.

From DE-GM 17 68 865 a trained as a handheld device ter vibration exciter known in which a drive piston mechanically in a housing with constant amplitude and being moved. It transmits via an air column Drive piston as excitation mass an oscillatory movement on a freely movable in the same cylindrical housing Chen working piston, which is connected to the An drive piston is coupled. On the air column against Overlying side of the working piston is another Air column provided, the volume of the two air column is adjustable so that the vibration of the work piston and its amplitude over the air volume of the Air columns is variably adjustable. The working piston transmits an impact pulse to a tool. At a another embodiment provides that the Ar beitskolben is firmly connected to the tool, so that the tool is oscillating.

This vibrator can therefore only one Transfer impulse to a tool or a Schwin movement.

The invention has for its object a Schwin germs and an associated process for mechan to create vibrations that one step  loose adjustment of impact power, vibration frequency and Vibration amplitude with simple mechanical construction enable.

The characteristics of the To serve to solve this task Proverbs 1, 8 and 11 respectively.

The solution advantageously sees a hydraulic one actuated drive piston, its working stroke with the help of a control valve is variably adjustable. The pathogens mass is rigid with the hydraulically operated drive piston coupled to the piston-cylinder unit, causing the Excitation mass induces the vibrations in the housing. Only then is the vibration exciter universal and can be used for a vibration plate, for example.

The solution enables the decoupling of the Relationship between frequency and amplitude of the Schwin and thus enables a more independent variation  of frequency and amplitude. The structure of the vibration exciter is simplified and the number of components significantly reduced.

The path of vibration of the excitation mass is z. B. at a hydraulic piston-cylinder unit using a 4/3 Directional control valve, the working pressure on the Excitation force exerted by the excitation mass is determined.

The spring and damping means preferably consist of a pneumatic piston-cylinder unit. The pneumati The working pressure determines the spring and damping characteristic of the spring means, the pressure medium in the reversal points of the excitation mass an energy storage forms. Frequency and amplitude characteristic and the The pneumat working pressure.

The excitation mass can be used as a piston in the piston-cylinder Unit of the spring means can be used. The pathogens mass in the form of a piston is then double-sided with the pneumatic working pressure of the spring means and compresses with increasing distance from the middle layer between the two reversal points of its vibration movement the pneumatic pressure medium.

Alternatively, it can be provided that several are in motion direction of the excitation mass pneuma table piston-cylinder units as spring and damping attack medium on the pathogen mass and between pathogen mass and housing are arranged.

It is preferably provided that the direction of vibration the excitation mass is adjustable in at least one level  is. The adjustability of the direction of vibration enables light due to a deviation from the vertical Force component the generation of a propulsive force on the Vibration exciter housing.

The housing with the excitation mass can preferably be in Swivel extension of the axis of motion of the excitation mass bar be articulated on a vibration plate. Such a ger vibration exciter can, for example, for soil ver seal can be used.

A control can depend on the vibration charac Frequency, amplitude and impact characteristics the vibration path of the excitation mass, the hydraulic pressure the drive of the excitation mass and the pneumatic pressure control the spring and damping means.

The following is a reference to the drawings Embodiment of the invention explained in more detail.

Show it:

Fig. 1 is a hydraulic pneumatic schematic diagram of the vibration exciter, and the

Fig. 2, 3 and 4 show different operating states of the swing ungserregers.

Fig. 1 shows a hydraulic-pneumatic circuit diagram of an embodiment with a linearly reciprocating in a Ge 1 excitation mass 2nd The exciter mass 2 is designed in the form of a piston 12 and is reciprocated within a cylinder 14 of a piston-cylinder unit 12 , 14 , which forms a spring and damping means. The piston-shaped exciter mass 2 is rigidly connected via a piston rod 3 to a piston 8 , a hydraulic drive unit 4 for the exciter mass 2 . The piston rod 3 is guided in the housing 1 and sealed with a seal 5 . The cylinder 10 of the hydrau metallic piston-cylinder unit 8, 10 encloses a pressure chamber 9, the piston 8 is acted upon schem with hydrauli pressure on both sides, while the pressure-tight against the Pressure kkammer 9 pressure chamber 13 of the piston-cylinder unit 12, 14 is pneumatically struck on both sides of the piston 12 .

The movement of the driving piston is controlled by means of a 4/3-way valve 7 are switched by means of which is guided to the upper or lower part of the pressure chamber 9, 18 of the working pressure via pressure lines 17, or both portions of Pressure kkammer 9 depressurized. With the help of the 4/3-way valve 7 , the vibration amplitude can be set by limiting the vibration path of the excitation mass 2 .

The hydraulic working pressure is generated with the aid of a hydraulic pump 22 , which is driven by a motor 20 . On the pressure side of the hydraulic pump 22 , a pressure accumulator 24 is also provided to compensate for pressure fluctuations during the switching operations of the 4/3-way valve 7 . Between the suction line 26 and the pressure line 28 of the hydraulic pump 22 , a pressure limiting valve 30 is connected. The suction line 26 and the return line 32 from the 4/3-way valve 7 end in a storage and collecting container 34 for the hydraulic oil. The working pressure can be varied by changing the setting of the pressure relief valve 30 .

The pneumatic circuit for setting the spring and damping characteristics of the spring means 6 consisting of the piston-cylinder unit 12 , 14 has a compressor 36 and an adjustable pressure control valve 38 which is connected in parallel to the compressor 36 . Pneumatic pressure lines 40 , 42 each conduct an equal pressure in the upper or lower part of the pressure chamber 13 , so that the exciter mass 2 used as piston 12 is acted upon on both sides with the same pneumatic pressure, which is desired with the help of the pressure control valve 38 depending on the ge Vibration characteristics can be set differently.

Below the piston-cylinder unit 12 , 14 is indicated that deviating from a vertical up and down movement of the excitation mass 2 by tilting the piston-cylinder units 8 , 10 ; 12 , 14 the application of force to a swivel joint 44 can also take place at an angle deviating from the vertical in order to obtain a propulsion movement in the horizontal and orthogonal to the swivel plane.

Illustrate the Fig. 2, 3 and 4 show different operating states of the vibrator at a coupling to a vibration plate 16 for compacting soil.

The vibration exciter is pivotable by means of a swivel joint 44 on the vibrating plate 16 BEFE, whereby according to the swivel position a different propulsive force forward or backward can be achieved bar.

The following table explains different types positions for such a soil compactor and explains the possible solutions according to the state of the Technology or according to the linear Schwin described here germs.  

Fig. 2 shows the operating state of the vibration exciter in the case where a high amplitude at low frequency and high impact power is required. In this case, the pressure chamber 13 is only pressurized with a small pneumatic pressure, while with the help of the 4/3-way valve 7 a large stroke of the drive piston 8 and thus also the exciter mass 2 is set. The wide ren can be adjusted with the help of the 4/3-way valve 7 in connection with the working pressure in the pressure lines 17 , 18, the frequency of the vibration. Due to the low pneumatic back pressure in the pressure chamber 13 , there are high peak values for the impact force in the reversal points of the movement of the excitation mass 2 .

In the embodiment of FIG. 3, a medium vibration amplitude with a higher frequency and a lower impact force is desired. In this case, the pneumatic pressure in the pressure chamber 13 is increased, so that the suspension and damping against the movement of the exciter mass 2 in the piston-cylinder unit 12 , 14 is increased. In connection with the control of the 4/3-way valve 7 , amplitude and frequency of the vibration can be adapted accordingly to the task posed. Additional adjustment possibilities result from the setting of a certain working pressure.

Finally, in the exemplary embodiment in FIG. 4, a small amplitude at the highest frequency and relatively low impact force is desired. In this case, the pneumatic pressure in the pressure chamber 13 is further increased, whereby it is easier to maintain a short vibration path. The compression of the pneumatic Druckme medium acts in the manner of an energy store and it facilitates the control of the reverse movement of the exciter mass 2 .

The operating states shown in FIGS . 2, 3 and 4 according to the application cases given in the table can be in the linear vibration exciter by the continuously adjustable spring and damping characteristics of the spring means, the continuously variable frequency and amplitude of the vibration and the adjustability of the working pressure with a single device.

A control, not shown in detail, coordinates the setting of the pressure relief valve 30 for controlling the working pressure, the control of the 4/3-way valve 7 for setting the vibration frequency and the vibration path and the setting of the pneumatic pressure in the pressure chamber 13 in accordance with the vibration characteristic to be set the pressure control valve 38 .

In the working principle of the rotating unbalance according to the State of the art are adjustable unbalanced masses hardly feasible. Separate soil compactors as Special devices for the respective specified in the table NEN requirements are not known, so far only Universal soil compactor with a medium vibration Frequency and mean amplitude were adjustable.

Claims (11)

1. vibration exciter with a housing ( 1 ) in which a movably mounted exciter mass ( 2 ) for the vibration generation and a piston-cylinder unit ( 8 , 10 ) existing drive ( 4 ) for the exciter mass ( 2 ) are arranged, characterized in that the excitation mass ( 2 ) with a hydraulically driven drive piston ( 8 ) of the piston cylinder unit ( 8 , 10 ) is rigidly coupled, that the excitation mass se ( 2 ) against the action of spring adjustable in the spring detection - And damping means ( 6 ) can be moved back and forth linearly and that the oscillation frequency and the oscillation amplitude of the vibrations induced in the housing ( 1 ) are variable. 2. Vibration exciter according to claim 1, characterized in that the spring and damping means ( 6 ) on the exciter mass ( 2 ) acting pneumatic pressures. 3. Vibration exciter according to claim 2, characterized in that the spring and damping means ( 6 ) consist of at least one pneumatic piston-cylinder unit ( 12 , 14 ) and that the excitation mass ( 2 ) as a piston ( 12 ) in the Piston-cylinder unit ( 12 , 14 ) is used. 4. Vibration exciter according to one of claims 2 or 3, characterized in that several in the direction of movement of the excitation mass ( 2 ) acting in opposite directions pneumatic piston-cylinder units ( 12 , 14 ) as spring and damping means ( 6 ) between the housing ( 1 ) and the excitation mass ( 2 ) are arranged. 5. Vibration exciter according to one of claims 1 to 4, characterized in that the direction of vibration of the excitation mass ( 2 ) is adjustable in at least one vertical plane. 6. Vibration exciter according to one of claims 1 to 5, characterized in that the housing ( 1 ) with the excitation mass ( 2 ) preferably in an extension of the axis of movement of the excitation mass ( 2 ) is pivotally articulated on a vibration plate ( 16 ). 7. Vibration exciter according to one of claims 1 to 6, characterized in that a control in dependency of the vibration characteristics with regard to frequency, amplitude and impact force of the vibration, the length of the vibration path of the excitation mass ( 2 ), the hydraulic pressure of the drive ( 4 ) of the excitation mass ( 2 ) and controls the pneumatic pressure of the spring and damping means ( 6 ). 8. A method for mechanical vibration generation for vibration generator, by movably mounting an excitation mass ( 2 ) in a housing ( 1 ) and by driving the excitation mass ( 2 ) with a predetermined oscillation frequency and oscillation amplitude, characterized by the linear reciprocation of the excitation mass ( 2 ) against the effect of spring and damping means ( 6 ) which can be variably adjusted in the spring detection and by rigid coupling of the exciter mass ( 2 ) to a drive piston ( 8 ) which can be acted upon alternately with hydraulic pressure, whereby vibrations with variable oscillation frequency and oscillation amplitude in the housing ( 1 ) are induced. 9. The method according to claim 8, characterized in that a pneumatic pressure is used as the spring and damping means ( 6 ) for the germs mass ( 2 ). 10. The method according to claim 9, characterized in that at least one piston-cylinder unit ( 12 , 14 ) is used as spring and damping means ( 6 ), the excitation mass ( 2 ) being used as a piston ( 12 ). 11. Vibration plate with a vibration exciter after one of claims 1 to 7.