DE112017002233T5 - Rig-mountable add-on compactor - Google Patents

Abstract

It is created a rig-mountable add-on compactor (1). The rig-mountable attachment compactor (1) comprises: a shaft (3) rotatably arranged to vibrate the rig-mountable attachment compactor (1) at a first amplitude by means of a first weight (5) and a second weight (7) and a second amplitude, and a hydraulic motor (9) adapted to drive the shaft (3). The hydraulic motor (9) is adapted to drive the shaft (3) in a direction (d). The rig-mountable add-on compactor (1) further comprises: the first weight (5) eccentrically fixed to the shaft (3) and the second weight (7) eccentrically arranged on the shaft (3), the second weight (7) between an idling mode when driven in the direction (d) and a turning mode when driven in the direction (d) is detachable. The second weight (7) is adapted to idle in the idle mode with respect to the shaft (3), the shaft (3) being adapted to increase the first amplitude of vibration by the first weight (5) in the idle mode and wherein the second weight (7) is adapted to rotate in the turning mode in synchronism with the shaft (3) to cause the second amplitude of the vibration.

Description

TECHNICAL AREA

The embodiments relate here to a rig-mounted attachment compactor.

BACKGROUND

Compressors are intended to different floors, such. As soil, gravel or the like, to compact. A known compressor includes a weight disposed on a rotatable shaft driven by a motor, which may be an electric motor, a hydraulic motor, or an internal combustion engine. The rotation of the shaft and the weight arranged on the shaft generates centrifugal forces that cause vibrations. The vibrations are used to compact the soil or gravel through the compressor. The compressor vibrates at an amplitude that depends on the eccentricity of the weight relative to the shaft and the mass of the weight and the speed of the shaft.

The rig-mounted cultivation compressor, which usually z. B. hydraulically driven by an excavator, are provided both for compacting soil, ditches and dams as well as for driving in and pulling out piles and formwork. A rig-mountable add-on compactor provides improved safety in use because there is no need for a user to stand directly in a work area of the compactor. The areas that are difficult to access for the user can be more easily achieved using the rig-mountable attached compactors.

A known rig-mountable attachment compactor is usually designed to operate at different amplitudes, typically two amplitudes. The rig-mountable crop compactor typically includes two eccentric weights attached to a shaft, the amplitudes being changed by changing the direction of rotation of the shaft. In a first direction, the eccentric weights are arranged to rotate in-phase to cause a first amplitude of vibration, while in a second direction opposite to the first direction, the weights are arranged to rotate out of phase thereby to cause a second oscillation amplitude. The first amplitude is then higher than the second amplitude. The shaft is normally driven by a bidirectional hydraulic motor that can be driven such that the weights rotate in the first or second direction.

The engine is connected to a complex flow control system, the z. B. on the above-mentioned excavator is arranged to control the flow in a hydraulic system that controls the engine.

In the known rig-mountable cultivation compressors, which are designed to work with two amplitudes, there is the problem that the rig-mountable attached compactor only with a limited number of machine types, such as. B. the above excavator, are compatible.

SUMMARY

An object of the embodiments herein is to provide a rig-mountable on-farm compactor that is compatible with multiple types of machines.

According to one aspect of the present disclosure, the object is achieved by a rig-mounted attachment compactor comprising: a shaft rotatably arranged to vibrate the rig-mountable attachment compactor at a first amplitude and weight by a first weight and a second weight causing a second amplitude, a hydraulic motor configured to drive the shaft, the hydraulic motor configured to drive the shaft in one direction. The rig-mountable attachment compactor further comprises: the first weight eccentrically attached to the shaft and the second weight eccentrically disposed on the shaft, the second weight being between an idle mode when driven in the direction and a rotational mode when it is driven in the direction is detachable. The second weight is adapted to idle with respect to the shaft in the idle mode, the shaft being configured to cause the first amplitude of vibration by the first weight in the idle mode, and wherein the second weight is configured to to rotate synchronously with the shaft in the rotational mode to cause the second amplitude of the vibration.

Since the hydraulic motor is designed to drive the shaft in the direction in which the rig-mountable attachment compressor is operated at both the first and second amplitudes, a device hydraulic motor for driving the shaft can be used. The equipment hydraulic motor is designed to work or run only in the same direction, which is referred to herein as the direction. Accordingly, the rig-mounted attachment compactor with a machine such. As an excavator, connected, which is a simple flow control system for controlling the flow in a hydraulic system, the Hydraulic motor controls includes. The rig-mounted attachment compactor is therefore with several types of machines, such. A machine with a simple flow control system. As a result, the above-mentioned object is achieved.

The first weight is eccentrically attached to the shaft. In other words, the first weight is rigidly attached to the shaft to rotate at the same speed as the shaft to the shaft. Consequently, the rotation of the shaft always causes the rotation of the first weight. Because the first weight is eccentrically attached to the shaft, the rotation of the first weight causes centrifugal forces acting on the first weight and on the shaft, the centrifugal forces causing vibration of the rig-mountable attachment compactor.

The second weight is also arranged eccentrically on the shaft. Consequently, the rotation of the second weight also causes centrifugal forces acting on the second weight and the shaft, the centrifugal forces causing vibration of the rig-mountable attached compactor. Further, because the second weight between the idle mode when driven in the direction and the turning mode when driven in the direction is detachable, the second weight can be switched between the idle mode and the turning mode. Advantageously, the second weight is switched between the idle mode and the turning mode when the shaft is at a shaft position that allows shifting. Preferably, the switching is performed when the shaft is not rotating.

In the idle mode, the second weight is designed to idle with respect to the shaft. This means that the second weight is designed to rotate freely on the shaft in a passive manner. The passive way is that the second weight in the idle mode does not contribute to the vibration of the rig-mountable attachment compactor. Thereby, in the idling mode of the second weight, the vibration of the rig-mountable attachment compressor is mainly caused by the first weight eccentrically attached to the shaft. Consequently, in the idle mode of the second weight, the first oscillation amplitude is generated.

In the turning mode, the second weight is coupled to the shaft, i. that is, the second weight is connected to the shaft to rotate synchronously with the shaft at the same speed as the shaft. Consequently, in the turning mode, the second weight rotates with the shaft and with the first weight eccentrically attached to the shaft. Thereby, in the rotation mode, the vibration is caused by both the first weight and the second weight. As a result, the second oscillation amplitude is generated.

Further, because the hydraulic motor is configured to drive the shaft in the direction and the second weight between the idle mode when driven in the direction and the turning mode when driven in the direction can be coupled, both the first amplitude and the second amplitude generated when the shaft rotates in the direction.

The weight for causing the vibration may consist of the first weight and the second weight. Thereby, the rig-mountable crop compactor can include only the first weight and the second weight in terms of the weight that rotates to cause the vibration. Consequently, the rig-mounted cultivation compactor, which has only a few rotatable weights, robust.

Optionally, the first weight and the second weight are configured to cause a second amplitude of the vibration that is twice the first amplitude of the vibration. As a result, the first oscillation amplitude can be substantially half the size of the second oscillation amplitude. This can be achieved by adjusting the masses or the eccentricities of the first weight, which is arranged on the shaft, or the second weight, which is arranged on the shaft. As a result, in the rig-mountable attachment compactor, it is easy to achieve a doubled or halved amplitude of the vibration.

The second weight may be configured to rotate in phase with the first weight in the rotational mode. In fact, the second weight together with the first weight may rotate around the shaft without a time and positional delay between the first weight and the second weight during rotation of the first weight and the second weight about the shaft. This makes the turning mode robust.

In some embodiments, the second weight may be detachable by means of a clutch assembly, wherein the rig-mountable attachment compressor includes the clutch assembly configured to connect the second weight to the shaft in the rotational mode and configured to, in the idle mode separate second weight from the shaft. As a result, the clutch assembly connects and disconnects the second weight to / from the shaft by allowing a user to engage the clutch assembly, e.g. B. by means of a lever, a handle or the like easy to couple.

In these embodiments, the coupling assembly comprises: a sleeve having a through hole for receiving the shaft and freely rotatably mounted on the shaft, the sleeve being fixedly secured to the second weight, a connecting member provided in an opening provided in the sleeve slidably disposed, and a control adapted to move the connecting element between a separating position and a connecting position. In this way, the position of the connecting element can be changed, for. B. simply using the control, such. As the lever, the handle or the like, as mentioned above, are moved.

In addition, in these embodiments, the second weight is in the idle mode when the connector is at the disconnected position, and the second weight is in the rotational mode when the connector is in the connecting position. As a result, the second weight can be changed, switched, coupled or the like simply by shifting the connecting member between the separating position and the connecting position by the control between the idling mode and the turning mode.

Moreover, in these embodiments, the shaft includes a cavity disposed on an outer side of the shaft, wherein in the connecting position, the connecting element is received through the cavity and wherein the connecting element is pulled out of the cavity in the separating position.

Thus, the rotational movement of the shaft can be easily transmitted by receiving the connecting element in the arranged on the outside of the shaft cavity at the connecting position to the second weight. Further, a transmission of the rotational movement of the shaft to the second weight can be stopped simply by the extraction of the connecting element from the cavity in the separating position.

Accordingly, the clutch assembly may be robust because the clutch assembly is configured to disconnect the second weight in a straightforward manner from the shaft in the idle mode, as explained above.

As a result, the rig-mountable attachment compactor is also more robust because the second weight can be coupled in a simple manner.

Furthermore, in some embodiments, the sleeve is provided with at least three openings including the opening. The at least three openings are arranged along a first cross-section of the sleeve. Further, the shaft comprises at least three cavities including the cavity, wherein the at least three cavities are arranged along a second cross section of the shaft. The at least three openings are unevenly spaced along the first cross-section of the sleeve, the at least three cavities being unevenly spaced along the second cross-section of the shaft. In other words, the at least three openings are spaced apart at different angles therebetween with respect to a center or axis of the sleeve. In a similar manner, the at least three cavities are spaced at different angles therebetween with respect to a center or axis of the shaft. The at least three openings comprise a first, a second and a third opening, while the at least three cavities comprise a first cavity, a second cavity and a third cavity. An angle between the first opening and the second opening is substantially equal to a further angle between the first cavity and the second cavity. Further, the angle between the second opening and the third opening is substantially equal to the angle between the second cavity and the third cavity. In fact, at only one position of the shaft with respect to the sleeve, it is such that each of the at least three cavities coincides with a corresponding aperture of the at least three apertures. Thereby, the positioning of the shaft with respect to the sleeve at a desired position is unambiguous because, if there were an equal gap between the cavities and the apertures, it would be possible to apply the second weight and the sleeve at three different positions on the shaft lock, which produces a corresponding amplitude of the vibration. Because the position where the second weight is locked to the shaft is not visible or distinguishable to the user, it would be doubtful to the user what amplitude will be generated should the cavities / openings be evenly spaced.

The coupling assembly comprises at least three connecting elements including the connecting element, wherein each of the at least three connecting elements is received at a respective connecting position by a respective cavity of the at least three cavities and wherein each of the at least three connecting elements at a respective separating position pulled out of a respective cavity of the at least three cavities is. Consequently, the second weight is connected to the shaft in a safer manner than when only one connecting element is used. Furthermore, the at least three connecting elements make a reliable and robust transmission reaches the torque from the shaft to the second weight.

In a constructive embodiment, the at least three apertures are spaced 110 degrees and 150 degrees apart, and the at least three apertures are spaced 110 degrees and 150 degrees apart. Thereby a uniform transmission of the torque from the shaft to the second weight is achieved, while at the same time only one and unambiguous position, at which the second weight can be locked to the shaft, is obtained.

Other features and advantages of the embodiments will become apparent upon studying the appended claims and the following detailed description. Those skilled in the art will recognize that the described various features may be combined to create other embodiments than those described below without departing from the scope of the embodiments as defined by the appended claims.

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• 1 eine perspektivische Ansicht, die einen Rigg-montierbaren Anbauverdichter, der an einem Bagger angeordnet ist, veranschaulicht,
• 2 eine Draufsicht, die den Rigg-montierbaren Anbauverdichter, der in 1 veranschaulicht ist, veranschaulicht,
• 3 eine weitere Draufsicht ist, die eine Welle, ein erstes Gewicht und ein zweites Gewicht des Verdichters, der in 1 und 2 veranschaulicht ist, veranschaulicht, und
• 4 eine weitere Draufsicht ist, die die Welle, das erste Gewicht und das zweite Gewicht, die in 3 veranschaulicht sind, veranschaulicht.

The various aspects of the embodiments, including their specific features and advantages, will be readily understood from the following detailed description and the accompanying drawings; show it:

• 1 FIG. 3 is a perspective view illustrating a rig-mountable attached compactor disposed on an excavator; FIG.
• 2 a plan view of the rig-mounted attachment compactor, the in 1 illustrates, illustrates
• 3 Another plan view is a shaft, a first weight and a second weight of the compressor, which in 1 and 2 is illustrated, illustrated, and
• 4 Another plan view is the shaft, the first weight and the second weight, which in 3 are illustrated.

DETAILED DESCRIPTION

The embodiments will now be described more fully hereinafter with reference to the accompanying drawings, in which exemplary embodiments are shown. The disclosed features of the exemplary embodiments may be combined. Like reference numerals refer to like elements throughout. Well-known functions or constructions are not necessarily described in detail for brevity and / or clarity.

1 illustrates a compressor 1 that is attached to a boom 4 an excavator 2 is appropriate. The boom 4 can also be called a rig. That's why the compressor 1 sometimes referred to as a rig-mountable add-on compactor. The rig-mounted add-on compactor 1 is by fasteners 6 removable on the boom 4 appropriate. Both the excavator 2 , the boom 4 as well as the fasteners 6 are well-known constructions in the field of excavators. Consequently, these constructions are not described in detail here. The rig-mounted add-on compactor 1 can also be used on other machines such. B. on a backhoe, be attached.

2 illustrates the rig-mountable attached compactor 1 in 1 , The rig-mounted add-on compactor 1 includes a wave 3 which is rotatably mounted to the vibration of the rig-mountable attached compactor 1 with a first amplitude and a second amplitude by means of a first weight 5 and a second weight 7 to cause. The rig-mounted add-on compactor 1 includes shaft bearings, which are at each end of the shaft 3 are arranged to rotate the shaft 3 within the rig-mounted attachment compactor 1 to enable. Each of the shaft bearings may be any suitable type of bearing, such as a bearing. B. a ball bearing, a needle bearing or the like. It can z. B. spherical bearings are used for vibration applications. The wave 3 is with a hydraulic motor 9 connected, which is designed to the shaft 3 drive. The hydraulic motor 9 is by means of hydraulic hoses 8th connected to a hydraulic block (not shown) of a machine.

3 shows the wave 3 , the first weight 5 and the second weight 7 of in 1 and 2 illustrated compressor. In 3 is the second weight 7 illustrated in an idle mode. The wave 3 includes a seat 10 that is designed for the wave 3 with the in 2 illustrated hydraulic motor 9 connect to. The hydraulic motor 9 is designed for the wave 3 to drive in a direction d, which in 3 is illustrated as clockwise. The direction d may be counterclockwise in other examples.

The first weight 5 is eccentric on the shaft 3 attached. The term "eccentric" refers to the first weight 5 on the shaft 3 is arranged so that a first center of mass 12 of the first weight 5 a first distance r1 from a rotation axis Ar of the shaft 3 having. The first distance r1 may be in a range of 30 to 50 mm, e.g. B. about 46 mm, z. B. 46.5 mm, are located. The first distance r1 depends on a size of the compressor 1 and of the desired vibrational forces passing through the compressor 1 to reach. According to the in 3 illustrated embodiment is the first weight 5 formed as a semicircle comprising a first hole, wherein a center point 16 of the hole is located on the axis of rotation Ar when the first weight 5 on the shaft 3 is appropriate. The first weight 5 may be made of steel or the like. The mass of the first weight 5 depends on a size of the compressor 1 and of the desired vibrational forces passing through the compressor 1 to reach. The mass of the first weight 5 can z. B. about 7 kg, z. B. 6.94 kg, amount. The first weight 5 is z. B. by a heat-sounding process on the shaft 3 attached to the first weight 5 rigid on the shaft 3 to install. Consequently, before heating the first weight 5 to get it on the shaft 3 To attach, a diameter of the first hole is slightly smaller than a diameter d1 of the shaft 3 in an area of the wave 3 be where the first weight 5 should be attached. If the first weight 5 is cold, the diameter of the first hole is, compared to when heat-sealed, explicitly smaller than the diameter of the shaft 3 ,

The second weight 7 is also eccentric on the shaft 3 arranged, which means that the second weight 7 like that on the wave 3 is arranged that a second center of mass 14 of the second weight 7 a second distance r2 from the axis of rotation Ar of the shaft 3 is spaced. The second distance r2 can be in a range of 30 to 65 mm, z. B. about 45 mm, z. B. 45.2 mm. Similar to the first distance r1 depends the second distance r2 of a size of the compressor 1 and of the desired vibrational forces passing through the compressor 1 to reach. According to the in 3 illustrated embodiment has the second weight 7 one to the first weight 5 similar shape, ie, the shape of a semicircle, the second hole with the same hole center 16 which is located on the rotation axis Ar when the second weight 7 on the shaft 3 is appropriate. The first weight 5 and the second weight 7 can z. B. made of steel or the like. Similar to the mass of the first weight 5 depends on the mass of the second weight 7 of a size of the compressor 1 and of the desired vibrational forces passing through the compressor 1 to reach. The mass of the second weight 7 can z. B. about 7 kg, z. B. 6.56 kg.

According to the in 3 illustrated embodiment is a bearing 18 between the wave 3 and the second weight 7 arranged. The warehouse 18 is between the shaft 3 and the second weight 7 attached to allow it, that the second weight 7 on the shaft 3 idling. The warehouse 18 , this in 3 shown is a ball bearing. The warehouse 18 However, another type of warehouse, z. B. a needle bearing or the like.

The second weight 7 is detachable between the idling mode when driven in the direction d and a turning mode when driven in the direction d. In idle mode, the second weight is 7 designed to be with respect to the shaft 3 to run idle. The idle of the second weight 7 can by freely rotating the second weight 7 in the warehouse 18 be achieved. Furthermore, the second weight 7 designed to be in the in 4 shown turning mode synchronous with the shaft 3 to rotate.

Because the first weight 5 eccentric to the shaft 3 is attached and the second weight 7 eccentric to the shaft 3 is arranged causes a rotation of the first weight 7 and the second weight 7 Centrifugal forces acting on the first weight 5 and the second weight 7 and on the wave 3 act, wherein the centrifugal forces cause a vibration of the rig-mountable attachment compressor.

If the second weight 7 in idle mode, as in 3 is illustrated is the wave 3 designed to cause the first amplitude of the vibration. The first amplitude of the vibration is correspondingly caused by the fact that the shaft 3 the first weight 5 turns that eccentric to the shaft 3 is attached.

The wave 3 is at the aforementioned shaft bearings 28 arranged at each end of the shaft 3 are arranged to rotate the shaft 3 within the rig-mounted attachment compactor.

The second weight 7 is by means of a coupling arrangement 11 coupled. The rig-mounted add-on compactor 1 includes the clutch assembly 11 which is designed to be the second weight in turning mode 7 with the wave 3 and designed to be the second weight in idle mode 7 from the wave 3 to separate.

According to the in 3 illustrated embodiment includes the clutch assembly 11 a sleeve 13 that is a through hole 15 for picking up the shaft 3 having. The sleeve 13 is freely rotatable on the shaft 3 arranged and fixed to the second weight 7 arranged.

Furthermore, the clutch arrangement comprises 11 three fasteners 17 , which are slidable in a respective opening 19 the three openings in the sleeve 13 are provided, are arranged, and a control 21 which is designed for the fasteners 17 between one separating position p1 and a connection position p2 to move. The separation position p1 and the connection position p2 are different positions of the connecting element 17 along a radial direction with respect to the axis Ar. In 3 are the fasteners 17 at the separation position p1 illustrated. When the fasteners 17 at the separation position p1 There is the second weight 7 in the idle mode. For simplicity, suitable reference numerals are only for a connector 17 and an opening 19 been provided.

The connecting elements 17 can be made of steel balls, such. As spherical balls, be. The connecting element 17 may have other shapes and other materials necessary for the purpose of the fasteners 17 are suitable, such. As graphite include.

The control 21 is designed to move between an open position z1 and a closed position z2 to be moved, with the fasteners 17 at the opening position z1 of the control 21 at the separation position p1 are located while the fasteners 17 at the closed position z2 of the control 21 at the connection position p2 are located. The opening position z1 and the closed position z2 are different positions of the control along an axial direction with respect to the axis Ar.

The control 21 is z. B. by a lever or a handle (which are not shown) in 3 postponed. The lever or handle may be connected to a connecting portion 20 of the control 21 be connected. The control 21 can between the open position z1 and the closed position z2 be displaced by human effort by an operator or by mechanical power from a motor acting on the lever or handle.

The wave 3 in 3 and 4 includes three cavities 23 on an outside 26 the wave 3 are arranged. During the rotation of the shaft 3 is each of the three fasteners 17 through a respective cavity of the three cavities 23 at a respective connection position p2 is included and is each of the three fasteners 17 from a respective cavity of the three cavities 23 to a respective separation position p1 pulled out. In 3 are the three fasteners 17 from a respective cavity of the three cavities 23 pulled out.

Each of the three cavities 23 includes a first edge 22 and a second edge 24 , The first edge 22 points with respect to the outer surface 26 the wave 3 a higher slope than the second edge 24 on. Consequently, at the connection position p2 each of the three fasteners 17 in a respective cavity 23 through the control 21 held, which is at the closed position z2 in particular, during the rotation of the shaft 3 in the direction d, which in the rotational mode of the second weight, the rotation of the sleeve 13 and the rotation of the second weight 7 caused, to the first edge 22 abuts.

When the control 21 at the opening position z1 is located, is each of the three fasteners 17 during rotation of the shaft in the direction d from a respective cavity of the three cavities 23 to a respective separation position p1 pulled out. This can be achieved by the forces passing through the edge 22 caused during the rotation of the shaft 3 in the direction d on the connecting element 17 Act. In this way, each of the three connecting elements 17 during the rotation of the shaft 3 in the direction d to the separating position p1 moved when the second weight 7 in idle mode.

The sleeve 13 is also with three openings 19 provided, as in 3 and 4 is illustrated, wherein the three openings 19 along a first cross-section of the sleeve 13 are arranged. The wave 3 includes three cavities 23 where the three cavities 23 along a second cross section of the shaft 3 are arranged, with the three openings 19 along the first cross-section of the sleeve 13 are unevenly spaced and wherein the three cavities 23 along the second cross section of the shaft 3 are unevenly spaced. The first cross section of the sleeve 13 and the second cross section of the shaft 13 agree with each other when the sleeve 13 on the shaft 3 is appropriate. 3 and 4 They illustrated that on the shaft 3 attached sleeve 13 ,

In other words, the three openings 19 are at different angles α and β therebetween with respect to the center 16 the sleeve spaced from each other. In a similar way, the three cavities 23 also with the angles α and β therebetween with respect to a center of the shaft 3 spaced apart.

This is the positioning of the shaft 3 in relation to the sleeve 13 at a target position unambiguous, as explained above. The wave 3 and the sleeve 13 can then be positioned to rotate in the second weight mode 7 the rotation of the second weight in phase with the first weight 5 to enable.

The angle α can be in a range of 100-120 degrees, z. 110 degrees, while the angle β is within a range of 140-160 degrees, e.g. B. 150 degrees, can be located.

4 shows the wave 3 , the first weight 5 and the second weight 7 , in the 3 are illustrated when the second weight 7 is in the turning mode. As can be seen from the figure, the connecting element 17 through that to the closed position z2 moved control 21 to the connection position p2 postponed.

In the turning mode of the second weight 7 are the first weight 5 and the second weight 7 arranged to cause the second amplitude of the vibration. The second oscillation amplitude is determined by the simultaneous rotation of the first weight 5 and the second weight 7 achieved in the rotary mode. The first weight 5 and the second weight 7 are designed to cause the second amplitude in the spin mode, wherein the second amplitude is twice or twice the first amplitude. This can be done by adjusting the masses and the distances r1 and r2 of the first and second weights 5 . 7 be achieved.

Accordingly, the rig-mounted attachment compactor 1 with a machine, such. As an excavator, which includes a simple flow control system for controlling the flow in a hydraulic system that controls the hydraulic motor comprises. The simple flow control system can, for. As a drain line is missing, which is otherwise often needed to drive the existing rig-mountable attached compressor and operate.

Claims (8)

Rigg-mountable attached compactor (1), comprising: a shaft (3) rotatably arranged to cause vibration of the rig-mountable add-on compactor (1) having a first amplitude and a second amplitude by means of a first weight (5) and a second weight (7), a hydraulic motor (9) adapted to drive the shaft (3), the hydraulic motor (9) being adapted to drive the shaft (3) in a direction (d), the rig-mounted attachment compactor (1) includes: the first weight (5) eccentrically fixed to the shaft (3), and the second weight (7) eccentrically disposed on the shaft (3), the second weight (7) being between an idling mode when driven in the direction (d) and a turning mode when in the direction (FIG. d) is driven, the second weight (7) is adapted to idle in the idle mode with respect to the shaft (3), wherein the shaft (3) is adapted to the first amplitude of the vibration to cause the first weight (5) in the idle mode, and wherein the second weight (7) is adapted to rotate in synchronism with the shaft (3) in the turning mode to cause the second amplitude of the vibration. Rigg-mountable add-on compactor (1) according to Claim 1 wherein the weight for causing the vibration consists of the first weight (5) and the second weight (7). Rigg-mountable add-on compactor (1) according to Claim 1 or 2 wherein the first weight (5) and the second weight (7) are adapted to cause the second amplitude of the vibration, which is twice the first amplitude of the vibration. A rig-mountable add-on compactor (1) according to any one of the preceding claims, wherein the second weight (7) is adapted to rotate in phase with the first weight (5) in the rotational mode. A rig-mountable add-on compactor (1) according to any one of the preceding claims, wherein the second weight (7) is coupleable by means of a coupling assembly (11), the rig-mounted attachable compactor (1) comprising the coupling assembly (11) adapted to in the turning mode, connecting the second weight (7) to the shaft (3) and adapted to disconnect the second weight (7) from the shaft (3) in the idle mode. Rigg-mountable add-on compactor (1) according to Claim 5 wherein the coupling assembly (11) comprises: a sleeve (13) having a through hole (15) for receiving the shaft (3) and freely rotatably mounted on the shaft (3), the sleeve (13) fixedly engaging the second weight (7), a connecting element (17) slidably disposed in an opening (19) provided in the sleeve (13), and a control element (21) adapted to move the connecting element (17 ) between a separating position (p1) and a connecting position (p2), wherein the second weight (7) is in the idling mode when the connecting member (17) is in the separating position (p1), and wherein the second weight (7) is in the turning mode when the connecting member (17) is in the connecting position (p2), the shaft (3) having a cavity (23) disposed on an outer side of the shaft (3) the connecting element (17) through the cavity (23) to de r connecting position (p2) is received and wherein the connecting element (17) in the Separation position (p1) is pulled out of the cavity (23). Rigg-mountable add-on compactor (1) according to Claim 6 wherein the sleeve (13) is provided with at least three openings (19) including the opening (19), the at least three openings (19) being arranged along a first cross-section of the sleeve (13), and the shaft (3) at least three cavities (23) including the cavity (23), wherein the at least three cavities (23) are arranged along a second cross section of the shaft (3), and wherein the at least three openings (19) along the first cross section of the sleeve (23) 13) are unevenly spaced and wherein the at least three cavities (23) are unevenly spaced along the second cross section of the shaft (3) and wherein the coupling assembly (11) comprises at least three connecting elements (17) including the connecting element (17) and wherein each of at least three connecting elements (17) are received at a respective connecting position (p2) through a respective cavity of the at least three cavities (23) and wob ei each of the at least three connecting elements (17) is pulled out at a respective separating position (p1) of a respective cavity of the at least three cavities (23). Rigg-mountable add-on compactor (1) according to Claim 7 wherein the at least three openings (19) are spaced 110 degrees and 150 degrees apart and the at least three cavities (23) are spaced 110 degrees and 150 degrees apart.

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