EP1967291A1 - Oscillation exciter - Google Patents

Abstract

The vibration generator has two axles that are arranged parallel to each other, two unbalanced masses, and a unit for the adjustment of the relative turning position of the unbalanced masses. The unit has a rotary wing oscillating motor (6) with a rotor shaft (61) and a stator housing (62). The rotary wing oscillating motor has a unit for interlocking the stator housing with the rotor shaft. An independent claim is also included for an oscillating motor for use in vibration generator.

Description

The invention relates to a vibration generator according to the preamble of claim 1. The invention further relates to a pivot motor for use in a vibration exciter according to the preamble of claim 9.

In construction, vibration generators such as vibrators, vibrators or vibratory bears are used to bring profiles into the soil or to pull or to compact soil material. The soil is stimulated by vibration and thus reaches a "pseudo-liquid" state. By static load the pile can then be pressed into the ground. The vibration is characterized by a linear movement and is generated by pairwise counter-rotating imbalances within a Vibratorgetriebes. Vibration generators are characterized by the installed unbalance (referred to in the art as "static torque") and the maximum speed.

In order to achieve optimum propulsion or compaction depending on the pile material and soil properties, it is desirable to have amplitude, To regulate frequency or force direction of the vibrator. The adjustment of the vibration is expediently via a change of the static torque or the phase position of the imbalances. When starting the vibration exciter the natural frequency range of the soil is traversed. If the ground is excited in the resonance range, the amplitude of the floor vibration becomes very large, which can lead to damage to adjacent buildings. Therefore, it is necessary that act when starting the vibrator no imbalance.

Known solutions such as planetary or pivoting gear trains require a lot of space, are not very suitable for high speeds and generate due to additional gears a high noise level.

The invention aims to remedy this situation. The invention is based on the object to provide a vibration exciter, in which the effective unbalance and thus the vibration is adjustable and, moreover, has a compact design. According to the invention, this object is solved by the features of the characterizing part of patent claim 1.

With the invention, a vibration exciter is provided, in which the effective unbalance and thus the vibration is adjustable and, moreover, has a compact design. The use of the rotary vane type motor allows relative displacement of the imbalance masses without requiring conversion of linear motion into rotary motion, thereby achieving a compact design. By the means for locking the stator housing with the rotor shaft, a change in position due to internal leakage is avoided. Since in the locked state of the stator housing, the hydraulic pressure can be reduced, the seals are significantly less stressed, which has a lower wear of the seals result, since in the unpressurized state, the contact forces are significantly lower. Furthermore, an energy saving is effected because over the period of operation of the vibrator no Adjustment or adjustment of the swing motor is required. Furthermore, the required control of the swing motor is simplified.

In an embodiment of the invention, at least one shaft seal is arranged between the rotor shaft and the stator housing, which shaft is provided with a support element. As a result, external leaks are avoided at the shaft seals under a low operating pressure operating condition. By the support member lifting of the sealing edge of the shaft seal is mechanically prevented at high speeds or vibrations. Preferably, the shaft seal is hydraulically biased.

In a further embodiment of the invention, the stator housing has at least one closure lid, which is at least partially cast inextricably with a sliding alloy for radial and axial mounting of the stator housing relative to the rotor shaft at least partially. As a result, a thin-walled coating is achieved, which is resistant to vibration against pressed-sliding bearings that tend to release under strong vibrations. Alternatively, to achieve this advantage, the rotor shaft may be at least partially encapsulated inextricably with a sliding alloy. Advantageously, the sliding alloy is a lead-bronze alloy.

In a further development of the invention, the stator of the stator is formed on the rotor shaft side facing the gear. As a result, a more effective use of space is achieved. Furthermore, by utilizing the gear body at the same axial distance, the torque of the swing motor can be increased. A vibration-loaded separation point is avoided, reduces the number of items.

In an advantageous embodiment, the means for locking the stator housing with the rotor shaft is hydraulically actuated. As a result, the brake system can be connected to the existing hydraulics.

Preferably, the means for locking the stator housing to the rotor shaft is formed by a spring pressure multi-disc brake. Such multi-disc brakes require only a small space.

The invention is further based on the object to provide a swivel motor for use in a vibration exciter, which allows a constant position of the imbalances while relieving the hydraulic system during operation of the vibrator. According to the invention this object is achieved by the characterizing part of claim 9.

With the invention, a swivel motor for use in a vibration exciter is created, which allows a constant position of the imbalances while relieving the hydraulic system during operation of the vibration exciter.

Advantageously, the means for locking is hydraulically actuated. This allows the connection of the brake system to the existing hydraulics.

Preferably, the locking means is formed by a spring-loaded multi-disc brake. This allows a compact design.

In a further development of the invention, at least one shaft seal, which is provided with a support element, is arranged between the rotor shaft and the stator housing. As a result, external leaks are avoided at the shaft seals under a low operating pressure operating condition. By the support member lifting of the sealing edge of the shaft seal is mechanically prevented at high speeds or vibrations.

In an embodiment of the invention, a gear is arranged on the stator housing, which is formed on its inner side facing the rotor shaft as a stator with stator blades. As a result, effective utilization of the installation space is effected. In addition, taking advantage of the gear body at the same axial distance, the torque of the swing motor can be increased. A possibly vibration-loaded separation point is avoided and the number of items is reduced.

In a further embodiment of the invention, the stator housing has at least one closure lid, which is at least partially cast inextricably with a sliding alloy for radial and axial mounting of the stator housing relative to the rotor shaft at least partially. As a result, a thin-walled coating is achieved, which is resistant to vibration against pressed-sliding bearings that tend to release under strong vibrations. In addition, the thin-walled coating is suitable to absorb the resulting from shaft deflection and inertia loads due to the high strength of the base material of the lid with good sliding properties. The machinability of the bearing allows to be pressed against bearings a very small clearance, which in turn ensures a small relative movement between the shaft with rotor and housing with stator. The low bearing clearance results in lower mass forces acting between shaft with rotor and housing with stator. Alternatively, to achieve this advantage, the rotor shaft may be at least partially encapsulated inextricably with a sliding alloy.

Fig. 1

die Darstellung eines Vibratorgetriebes im Längsschnitt;

Fig. 2

eine Prinzipdarstellung einer schwenkmotorindizierten Unwuchtverstellung mit einer unwuchtbelasteten Achse;

Fig. 3

eine Prinzipdarstellung einer schwenkmotorindizierten Unwuchtverstellung mit zwei unwuchtbelasteten Achsen zur Einstellung der Kraftrichtung;

Fig. 4

die Prinzipdarstellung einer schwenkmotorindizierten Unwuchtverstellung mit paarweise angeordneten unwuchtbelasteten Wellen;

Fig. 5

die Darstellung eines Drehflügelschwenkmotors mit Federdruck-Lamellenbremse im Längsschnitt;

Fig. 6

die Darstellung des Schwenkmotors aus Figur 5 im Querschnitt entlang der Linie VI-VI und

Fig. 7

die Detailansicht des Ausschnitts VII aus Figur 5.

Other developments and refinements of the invention are specified in the remaining subclaims. An embodiment of the invention is illustrated in the drawings and will be described in detail below. Show it:

Fig. 1

the representation of a vibrator in longitudinal section;

Fig. 2

a schematic diagram of a Schwenkmotorindizierten imbalance adjustment with a unbalanced load axis;

Fig. 3

a schematic diagram of a Schwenkmotorindizierten imbalance adjustment with two unbalanced loaded axes for adjusting the direction of force;

Fig. 4

the schematic diagram of a Schwenkmotorindizierten imbalance adjustment with paired unbalanced waves loaded;

Fig. 5

the representation of a rotary vane with spring-loaded multi-disc brake in longitudinal section;

Fig. 6

the representation of the swing motor FIG. 5 in cross section along the line VI-VI and

Fig. 7

the detailed view of section VII off FIG. 5 ,

The vibration generator chosen as the embodiment is designed as a vibrator gear (see. FIG. 1 ). It consists essentially of a housing 1, in which two with gears 31, 32, 33 and 51, 52, 53 provided shafts 3, 5 are rotatably mounted, and a pivot motor 6, the rotor shaft 61 with gears 613, 614 and its Stator housing 62 is provided with a gear 621.

The shaft 3 is rotatably mounted in bearings 11 of the housing 1. On the shaft 3, an outer gear 31 is rotatably mounted, the opposite outer gear 33 is rotatably connected to the shaft 3. The gears 31, 33 are each provided with imbalance masses 311, 331. Centered between the gears 31, 33, a gear 32 is further arranged rotatably mounted on the shaft 3. Also, the gear 32 is provided with an imbalance mass 321. In the exemplary embodiment, the shaft 3 is connected to a drive 2.

The shaft 3 opposite a shaft 5 is further rotatably supported by bearings 12 in the housing 1. The shaft 5 is provided in the same way as the shaft 3 with three gears 51, 52, 53, to which imbalance masses 511, 521, 531 are attached. In contrast to the shaft 3, however, the outer gears 51, 53 are rotatably connected to the shaft 5 on the shaft 5; the toothed wheel 51, 53 arranged gear 52 is rotatably mounted on the shaft 5. In the exemplary embodiment, the shaft 5 is connected to a drive 4.

Between the shafts 3, 5, a shaft 61 is rotatably supported by bearings 13 in the housing 1. The shaft 61 is like the rotor shaft of a centrally arranged on this pivot motor 6. On both sides of the swing motor 6 61 gears 613, 614 are rotatably mounted on the shaft. The gears 613, 614 are positioned on the shaft 61 so as to be engaged with the gears 31, 51, 33, 53 of the shafts 3, 5, respectively. Furthermore, a gear 621 is rotatably mounted on the stator housing 62 of the pivot motor 6. The gear 621 is positioned on the stator housing 62 so as to be engaged with the gears 32, 52 of the shafts 3, 5. The shaft 61 is further connected to a rotary feedthrough 615, which protrudes from the housing 1.

The pivoting motor 6 is essentially formed by the rotor shaft 61 and a surrounding stator housing 62, and two on both sides of the stator housing closure cap 63. Between the rotor shaft 61 and the stator housing 62, a gap formed by a integrally formed on the rotor shaft 61 rotor blade 611 and is divided by a molded on the stator housing 62 stator vanes 622, so that two working spaces 64a, 64b are formed. In the exemplary embodiment, the stator vane 622 is formed directly on the inside of the toothed wheel 621, so that the stator housing 62 with the toothed wheel 621 and the stator vane 622 are integrally formed. In order to realize a pressure-dependent prestressing force of the inner seals 631 of the swivel motor 6, a shuttle valve 623 is arranged in the stator vanes 622 whose control channels open into the working spaces 64a, 64b on both sides of the stator vanes (cf. FIG. 6 ). Furthermore, 61 channels 612 for media supply of the working chambers and the multi-disc brake 65 are introduced longitudinally in the shaft through the hydraulic system.

In the embodiment according to FIG. 5 the swivel motor is provided with a multi-disc brake 65. The multi-disc brake 65 consists of a housing 630 fastened to the cover 63 of the stator housing 62, a hub 616 fixed to the shaft 61 and a clutch disk package 65. The clutch disks meshing with the housing 630 are mechanically released by spring force (or alternatively hydraulically) pressed against the hub connected to the rotor shaft 61 meshing clutch discs, so locking of the stator housing 62 is effected with the rotor shaft 61.

The stator housing 62 is sealed relative to the rotor shaft 61 by means of seals 631. The seals 631 are mechanically biased with elastic elements and are pressed by the swivel motor integrated shuttle valve 623 only upon pressurization of the working chambers 64a, 64b additionally with pressure to the corresponding mating surfaces. Thus, over the period of adjustment, that is in the pressurized state, a high density and thus a high volumetric efficiency is achieved. In the pressureless state, the hydraulic contact pressure completely eliminated with the advantage of a reduction in wear.

To avoid external leaks at the shaft seals 631 under an operating condition with low operating pressure, these are additionally provided with a support element 632. The support member 632 prevents lifting of the sealing edge at high speeds. To support the sealing effect of the seals 631 63 hydraulic channels 634 are introduced in the lid.

For axial and radial mounting of the rotor shaft in the covers 63 of the stator housing 62, a sliding alloy 633 is attached to the covers 63, which is cast permanently with the covers 63. As a result, a thin-walled, vibration-resistant coating is formed which is suitable for absorbing the loads resulting from shaft deflection and inertial forces while at the same time providing good sliding properties. In the exemplary embodiment, the sliding alloy 633 is a lead-bronze alloy, which due to the thin-walled design combines the high mechanical properties of the base material of the cover 63 with the excellent lubricity of the alloy components.

In the start-up phase of the vibrator, the imbalance masses 311 and 331 are aligned with respect to the imbalance mass 321 such that the resulting imbalance is equal to zero. The gear 33 is driven via the shaft 3, which is in communication with the drive 2, and drives the gear 614 of the shaft 61, whereby the pivot motor 6 connected to the shaft 61 is rotated. Via the shaft 61, the gear 613 and likewise the gear 31 is driven.

About the - synchronous controlled - drive 4, the shaft 5 is set with the rotatably mounted on this gear 52 in rotation, which in turn is in engagement with the gear 621 of the stator housing 62. About the gear 621 of the stator housing 62, the gear 32 of the shaft 3 is rotated, which is rotatably mounted on the shaft 3. At the end of the start-up phase, one of the working chambers 64a, 64b is subjected to overpressure via the hydraulic channels 612, controlled by an external directional control valve, so that the toothed wheel 621 rotates relative to the rotor shaft 61 and thus also to the toothed wheels 613, 614 connected in a rotationally fixed manner to the rotor shaft 61 becomes.

Likewise, the gears 32, 52 engaged with the gear 621 of the stator housing 62 are changed in their rotational position so that the unbalanced masses 321, 521 are brought out of equilibrium with the unbalanced masses 311, 331, 511, 531, thereby causing a resulting imbalance , By the degree of rotation of the gear 621 relative to the gears 613, 614 of the rotor shaft 61, the degree of vibration is infinitely adjustable.

Once the desired degree of vibration is achieved, the multi-disc brake 65 is mechanically activated by spring force when hydraulic pressure is released, whereby the stator housing 62 is locked to the rotor shaft 61. After locking, the further regulation of the position of the swivel motor via the hydraulic is no longer necessary, so that the pressurization can now be switched off, whereby the seals are relieved. Subsequently, the actual piling process can be performed.

Since the pivot motor 6 is now operated only in the load-free state of the vibrator and is relieved by the locking means of the multi-disc brake 65 during the ramming process, a significantly smaller size of the swing motor is possible.

To illustrate the unbalance control by means of rotary vane pivot motor according to the present invention are in the FIGS. 2 to 4 different wave and unbalance mass arrangements shown schematically. Of course, the present invention is not limited to the exemplified arrangement.

FIG. 3 shows a possibility of adjusting the direction of force. In soil compactors, such as vibrating plates, a direction of movement can be achieved in this way. In this case, the pivot motor 6 via the gears 613 and 621, the angular position of the imbalances to each other.

Claims (15)

Vibration generator, in particular for a vibration ram, comprising at least two axes arranged parallel to one another and at least two imbalance masses which are mounted on one or more of the axes, wherein means for adjusting the relative rotational position of the imbalance masses are provided to one another, characterized in that the means at least one rotary vane (6) with a rotor shaft (61) and a stator housing (62), wherein the rotor shaft (61) is part of one of the axes and the rotational position of the stator housing (62) relative to the rotor shaft (61) is variable and wherein Rotary vane pivot motor (6) has means (65) for locking the stator housing (62) with the rotor shaft (61). Vibration generator according to claim 1, characterized in that between the rotor shaft (61) and stator housing (62) at least one shaft seal (631) is arranged, which is provided with a support member. Vibration generator according to claim 2, characterized in that the shaft seal (631) is hydraulically biased. Vibration generator according to one of claims 1 to 3, characterized in that the stator housing (62) has at least one closure cover (63), which is at least partially permanently coated for the radial and axial mounting of the rotor shaft (61) with a sliding alloy (633). Vibration generator according to one of claims 1 to 3, characterized in that the rotor shaft (61) is at least partially non-detachably coated with a sliding alloy (633). Vibration generator according to one of the preceding claims, characterized in that on the stator housing 62, a gear 621 is arranged, which on its the rotor shaft (61) facing the inside as a stator with at least one stator (622) is formed. Vibration generator according to one of the preceding claims, characterized in that the means (65) for locking the stator housing (62) with the rotor shaft (61) is hydraulically actuated. Vibration generator according to one of the preceding claims, characterized in that the means for locking the stator housing (62) with the rotor shaft (61) by a spring-loaded multi-disc brake (65, 616, 630) is formed. Pivoting motor suitable for use in a vibration generator according to one of the preceding claims, comprising a rotor shaft (61) and a stator housing (62), between which working chambers (64a, 64b) are formed, the stator housing (62) being wound around the rotor axis (61). is rotatable, characterized in that means (65) for locking the stator housing (62) relative to the rotor shaft (61) are provided. Pivoting motor according to claim 9, characterized in that the means for locking is hydraulically actuated. Swivel motor according to claim 9 or 10, characterized in that the means for locking by a spring-loaded multi-disc brake (65, 616, 630) is formed. Pivoting motor according to one of claims 9 to 11, characterized in that between the rotor shaft (61) and the stator housing (62) at least one shaft seal (631) is arranged, which is provided with a support element (632). Pivoting motor according to one of claims 9 to 12, characterized in that on the stator housing (62) a gear (621) is arranged, which on its the rotor shaft (61) facing the inside as a stator with stator vanes (622) is formed. Pivoting motor according to one of claims 9 to 13, characterized in that the stator housing (62) has at least one closure cover (63) which is at least partially provided with a sliding alloy (633.) For the radial and axial mounting of the stator housing (62) relative to the rotor shaft (61) ) is indissolubly shed. Pivoting motor according to one of claims 9 to 13, characterized in that the rotor shaft (61) for the radial and axial mounting of the stator housing (62) relative to the rotor shaft (61) at least partially with a sliding alloy (633) is cast permanently.

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