DE2935090A1 - Vibrator with infinitely and accurately adjustable imbalanced mass - has simple spur gear between fixed and rotatable masses - Google Patents

Abstract

The imbalance for the vibration exciter is produced by a first imbalanced mass (3) set secure against rotation on a driven exciter shaft. There is a second imbalanced mass (4) set on the shaft so that it can be rotated and adjusted. The second mass (4) which can be locked in any adjusted position is provided with a spur gear (7) set concentric with the exciter shaft (1) whereupon an adjustment pawl (18) which is fixed to the first mass (3) can be moved to and fro tangential to the gear so as to engage in it. This simple mechanical spur gear and pawl allows a compact mass production whilst providing a simple remote control of the exciter force.

Description

DESCRIPTION :

The invention relates to a vibration exciter with adjustable Imbalance, with a drivable exciter shaft, on which at least one first is non-rotatable Imbalance mass and a second unbalanced mass arranged to be rotatable in an adjustable manner are.

Vibration exciters designed in this way can be found, for example, in conveyor technology or piling technology as well as for sorting, distributing, dosing, Compacting, loosening, mixing or the like as ramming, vibrating conveyors, vibrating screens, Vibrating tables, etc. use. In the various applications it is necessary to the oscillation frequency, the oscillation amplitude and, in particular, the excitation force to be able to adapt to the respective requirements. For this purpose, the appropriate Setting the oscillation frequency, the speed of the unbalances can be changed. The oscillation amplitude can be influenced by the static moment of the imbalances, and it can reduce the excitation force by changing the centrifugal force accordingly rotating imbalances can be brought to the desired value, for example by Adjusting the eccentricity or by adjusting the relative phase position of the non-rotatable with respect to the exciter shaft and the adjustable unbalance mass. Will the individual parameters for adapting the device to the respective operating state set to the required value only at standstill, this leads to economical adverse business interruptions.

An exact, economically justifiable setting of the device can also be achieved in most cases only be carried out during operation, as a result the quadratic dependence of the excitation force on the number of vibrations is greater Number of readjustments at standstill would be necessary with uneconomical business interruptions.

It is known for vibration exciters with several unbalance waves To twist pairs of these unbalance shafts in their relative phase position against each other in such a way that that the oscillation quantities can be changed accordingly through vector addition or superaction enlarge or reduce. The phase position is adjusted with the aid of Gears, for example planetary, bevel, differential or screw gears, which are associated with considerable costs and mostly not a compact structure enable a machine. Such complicated gear mechanisms can be found according to the state of the art, even in the case of vibrations with a single unbalanced shaft, the unbalanced parts that are non-rotatable and adjustable or rotatable with respect to the shaft Contains, the relative angle of the two untruthful parts with mostly the same eccentricity can be changed by this gear, so that the resulting vibration magnitude from the excitation force zero (compensation of the unbalanced parts with respect to the axis of rotation diametrically opposite arrangement) up to a Maxis, .4m can (axial alignment of the unbalanced parts).

In particular with the known vibration generators with a single Take unbalanced shafts for which a compact and handy operation is desired the means necessary for adjusting the unbalanced parts, namely the aforementioned Transmission, in the level with economically justifiable construction effort room. For the purpose of reducing the gear expenditure for setting the relative angle between the unbalanced masses which can be adjusted with respect to one another, it is known that The excitation force of the vibration exciter is speed-dependent using the centrifugal force to adjust the imbalances during operation. (DE-OS 25 53 800). The exciter wave has in this known embodiment an eccentric to the shaft axis Paragraph on which the rotatable unbalance mass is qelag-ert, with between non-rotatable Unbalance mass and rotatable unbalanced mass, a spring element acting in the circumferential direction is used is whose restoring force against the centrifugal force of the rotatable unbalanced mass acts during a run with non-locking and consequently when changing the Operating speed an angle adjustment between the unbalanced masses is made possible. After setting an angle, locking means are used to lock the rotatable Unbalance mass actuated on the exciter shaft. Although this known vibration device in terms of their robust, compact design and operational safety and their simple and quick adjustability are significant advantages over others Has known embodiments, the speed-dependent setting of the Exciting force that is only possible during operation, in many Cases perceived as annoying.

The object of the invention is to create a vibration exciter with adjustable unbalance of the type mentioned at the beginning, with a simple structure an exact and reliable adjustment of the imbalance drerichtungs- and in particular speed-independent is made possible.

The object on which the invention is based is achieved by a concentric to the exciter shaft1 on the second, which can be locked in any adjustment position Imbalance mass formed ring gear in which one attached to the first unbalance mass, tangential to the ring gear movable, actuatable adjusting pawl in engagement can be brought. By using the simplest mechanical means in the form of a gear rim and adjusting pawl is not only a compact structure and inexpensive manufacture achieved, but it is the excitation force of a vibration system in a simple way externally practically arbitrarily and reliably adjustable. Ring gear and adjusting pawl can easily be manufactured as separate components and mounted in unbalance machines will. Is particularly advantageous the easy interchangeability of the ring gear and adjusting pawl, which cause increased wear during operation subject. Known unbalance devices can also be used in a simple manner the means according to the invention are converted. The unbalance adjustment according to Invention takes place independently of the direction of rotation and speed, for example via a simple method of digital pressure medium supply.

According to an advantageous development of the invention, it is provided the second unbalanced mass against a concentric stop surface on the first unbalanced mass pretensioning by means of a spring. In particular, a friction lining can be placed on the stop surface be trained. The spring is advantageously formed by a set of disc springs, which is arranged concentrically around the exciter shaft and supported on it. the The force-travel characteristic of the disc spring set runs in the selected preload travel range - practically without a slope. In this simple and compact way one becomes one in every adjustment position lockable second unbalanced mass created, the disc spring set with a defined Contact pressure is pressed against the friction surface of the first unbalanced mass. Through the quasi constant pretensioning force remains even with settlement, e.g.

as a result of friction lining wear, the desired contact pressure obtained, through The defined frictional engagement is an unwanted change in position or angle adjustment two masses excluded from each other due to inertial forces.

The force-displacement characteristics of known disc springs generally run proportionally increasing with a slightly depressive character. Be opposed to this In the invention, special disc springs are used in which the clamping force is up to to a certain spring travel increases, the increase ultimately becomes smaller and smaller finally, even with further compression, a slight decrease in the resilience takes place. This area is used as a preload travel area, with one quasi constant acting spring force is obtained in a certain path tolerance range.

The second unbalanced mass is in a further advantageous embodiment the invention is supported by needle bearings on the exciter shaft.

In a further expedient embodiment of the invention, it is provided daPJ for two axially aligned and non-rotatably connected on the exciter shaft located at a distance first unbalanced masses a single adjustable second unbalanced mass is provided, which lies between the first unbalanced masses, wherein the disc springs are supported on the first non-mass that is not the Has stop surface.

In particular, the ring gear is on that of the stop surface of the first Formed unbalanced mass facing end face of the second unbalanced mass.

The ring gear can be used for easy assembly or disassembly on the second unbalance mass be flanged by means of bolts or screw connections.

It is particularly advantageous if the meshing with the ring gear Versteliklinke is designed to be hydraulically operated.

In particular, the adjusting pawl is by one on the the stop surface having the first unbalanced mass attached, actuatable piston-cylinder arrangement movable back and forth.

Here, the pawl can be received in a transverse bore in the piston and be displaceably guided therein over the predetermined length, and it can Engaging part of the adjustment pawl laterally through an elongated hole in the cylinder wall protrude, the length of the elongated hole corresponding to the maximum stroke length of the piston. In a particularly simple embodiment, the piston is the piston-cylinder arrangement Can be acted upon hydraulically on one side against a return spring. The provision of the piston can be done by a gas spring, which is attached by a gas chamber the end face of the cylinder of the piston-cylinder arrangement that is not hydraulically acted upon is determined, wherein the piston is sealed against the gas chamber by a membrane There is in particular an axial adjusting screw in the free end face of the gas chamber arranged, which creates an adjustable stop for the hydraulic piston.

Instead of the gas spring, however, a compression spring can also be used find the one on the non-hydraulically actuated face of the cylinder of the Piston-cylinder arrangement and the corresponding piston face is supported.

A particularly expedient and compact design characterizes by the fact that the adjusting pawl in the piston-cylinder arrangement itself as hydraulically operated further piston and the transverse bore of the roller as another The same hydraulic system is advantageous here used by making the adjustment pawl hydraulic with the piston- $ cylinder assembly connected is.

The piston of the Ixolben cylinder arrangement can be hydraulically actable side be hollow, and it can be in the bottom wall of the flea formation a hydraulic supply to the adjusting pawl run.

The transverse bore of the piston has a shoulder that acts as a stop serves for the adjustment pawl.

The adjustment pawl in the transverse bore of the piston is special on one expedient configuration in the direction of the ring gear biased by a compression spring. As a result, the adjusting pawl remains in engagement with the ring gear even if no hydraulic force is applied. Does the adjustment pawl fully engage the ring gear, then there is an additional detent or locking device in addition to the frictional connection created between the floating and the rotating unbalance mass.

In a further embodiment of the invention, the ring gear has a saw tooth or pawl profile on, the profile of the engagement part of the-Verstell'linke is configured accordingly and has a bevel that the reverse stroke of piston can be used as a ramp together with the adjustment pawl is, namely when the adjusting pawl is in the transverse bore by means of a compression spring is biased. The ring gear and adjusting pawl then have a functional effect Ratchet.

A vibration exciter that is adjustable in both circumferential directions Having second unbalanced mass is expediently designed so that on the second unbalanced mass another ring gear with a saw tooth or pawl profile arranged and a belonging to this ring gear further adjusting pawl is provided is, wherein the sawtooth profile with respect to the first ring gear and the first adjusting pawl is arranged reversed. Are as in an aforementioned advantageous embodiment two non-rotatable first unbalanced masses are provided, so the further adjusting pawl is preferred attached to the rotationally fixed first unbalance mass, which is not in a frictional engagement with the adjustable unbalance mass. Both adjustment devices can be operated can be actuated optionally, with one actuation of the adjusting pawl the other does not engage in the associated ring gear.

In another alternative embodiment, one in both directions adjustable vibration exciter, the ring gear Evolvtenprofil, and it the piston-cylinder arrangement can be acted upon hydraulically on both sides. In particular a separate control piston can be provided for the adjusting pawl through which pressure medium can only be supplied from the pressurized piston side.

The connection to a hydraulic source is advantageously made in such a way that that the hydraulic side of the cylinder of the piston cylinder arrangement through a bore system in the exciter shaft and the unbalanced mass to a hydraulic motor and X or an external one Pressurized oil source connected.

In particular, the bore system has an axial bore in the drivable Exciter shaft connected to the hollow bored output shaft of the stationary hydraulic motor or the external stationary pressure oil source is substantially aligned, and the outermost end of the axial bore merges into a larger axial bore, in which a plug nipple with a circumferential seal is used, which in turn Via a flexible piece of hose with the hollow-drilled output shaft of the hydraulic motor or it is connected to an external pressure oil source. The hollow bored output shaft is here of the hydraulic motor in connection with the leakage oil chamber of the motor, and it can be through corresponding Pressure pre-tensioning of the leakage oil drain or by applying an external pressure oil source the intermittent loading of the adjustment device on this leakage oil drain can be made in a simple manner.

An advantageous development is characterized in that the Adjusting pawls can be swiveled on the one-sided hydraulically activated piston to Ko piston-cylinder arrangement is arranged in such a way that during a means Compression spring caused the piston to move backward through an associated pawl Tooth back of a tooth of the ring gear tiltable and engageable in the adjacent tooth is.

The adjusting pawl, which is articulated eccentrically on the piston, can be used is due to the centrifugal force occurring during operation in the adjacent Tooth of the ring gear are engaged.

In principle, the invention thus relates to a rotating two-mass excitation system, in which one mass is non-rotatably connected to the exciter shaft and the second mass is rotatably coupled to the first mass by means of a defined frictional engagement, an adjusting device for changing the angle of rotation position both masses is used to each other and a locking of the rotatable mass in every adjustment position takes place by means of a defined frictional engagement. The adjustment takes place Independent of the direction of rotation and speed, using a simple digital method Pressure medium supply, namely single-acting, i.e. in a circumferential direction, albeit even in advantageous embodiments double-acting, i.e. in both circumferential directions.

The invention is described below using an exemplary embodiment Referring to the drawing explained in more detail; It shows: Fig. 1 an axial section a vibration exciter constructed according to the invention with an adjusting device, Fig. 2 shows a cross section along the line A-B in Fig. 1, Fig. 3 shows a detail of one Adjusting pawl according to Fig.

1 and with the associated hydraulic connection on an enlarged scale 4 shows another embodiment according to the invention with a further toothed ring and an associated adjusting pawl for the purpose of adjustability in both circumferential directions, 5 shows another embodiment of a reversible adjustment system with a single one Gear rim with involute profile and double-acting hydraulic piston as well as a separate one Control piston, FIG. 6 shows the detail according to FIG. 5 in the area of the separate control piston, 7 shows a further embodiment similar to FIG. 4 with two adjusting pawls, and Fig. 8 shows another particularly simple embodiment of the invention with a tiltable one Adjustment latch.

9 shows another particularly functionally reliable embodiment of the Invention with a tiltable pre-tensioned adjusting pawl.

The schematic representation according to FIG. 1 shows a vibration exciter with unbalanced masses adjustable according to the invention in a longitudinal or axial section.

The exciter shaft 1 of the vibration exciter is the vibration excitation on one transmitting frame 33 mounted axially fixed via roller bearings 2, 2 '. On the wave section three unbalanced masses 3, 3 'and 4 are arranged between the bearings, wherein the first two unbalanced masses 3, 3 'in a rotationally fixed manner with respect to the shaft 1 at a distance are fastened axially aligned from each other, while the unbalance mass 4 is relatively to the exciter shaft 1 rotatably supported on needle bearings 35 and between the two first rotationally fixed unbalance masses 3,3 'is arranged. The rotatable second The unbalanced mass 4 is in the axial direction of the one rotationally fixed (in Fig. 1) unbalanced mass 3 'a concentric stop surface 30 is formed with a friction lining 5, the one with a corresponding Effective area of the second unbalanced mass 4 is engaged.

The disc spring set 6 is arranged concentrically around the exciter shaft 1 and is supported on this or on the other rotationally fixed unbalance mass 3 .ab, the does not have the stop surface 30. The defined contact pressure on the friction lining 5 is achieved in particular by disc springs, whose eraft-path characteristic in one certain area runs almost without a slope, so that even with subsidence, e.g. as a result of friction lining wear, the desired contact pressure is retained and an unwanted one Change in position of the two relatively movable outlet parts as a result is excluded from inertial forces. It can be seen that due to the Frictional engagement between the two unbalanced masses that can be twisted relative to one another a position fixation or locking is possible in every adjustment position.

The second rotatable unbalanced mass 4 is in the area of the effective surface for the frictional connection with the non-rotatable unbalanced mass 3'- a ring gear 7 flanged, which has a sawtooth profile or a Serr ratchet toothing is provided (see. Fig. 2). In the ring gear 7 engages Adjusting pawl 18, which, when actuated accordingly, i.e. one cycle-wise Back and forth movement in tangential direction with respect to the ring gear in the area of the point of engagement, the ring gear 7 together with the rotatable unbalanced mass 4 under overcoming of the frictional torque between the rotatable unbalanced mass 4 and the non-rotatable Unbalanced mass 3 'by an angular amount corresponding to the stroke of the adjusting pawl 18 moves further and thus the rotatable unbalanced mass 4 with respect to the other two first unbalanced masses 3, 3 'adjusted. In the case of a single adjustment step, the ring gear 7 is advanced by a single fence.

The adjusting pawl 18 can be actuated hydraulically and is in an adjusting device in the form of a piston-cylinder arrangement 8 movably attached, namely in a Transverse bore 28 of the piston 16 of the piston-cylinder arrangement 8, the piston 16 is in turn movable to and fro in the piston-cylinder arrangement 8.

The structure of the piston-cylinder assembly 8, which in turn is based on the rotationally fixed according to FIG. 1 right unbalanced mass 3 'via screw connections 37 is shown in greater detail in FIG. The arrangement has a cylinder housing 14, in which the piston 16 containing the transverse bore 28 is displaceable. Of the Piston 16 can be acted upon hydraulically on one side, namely via a hydraulic one Passage 23 in the cylinder housing 14 (on the right in FIG. 3), and it becomes the cylinder housing 14 on its one end face, which is on the hydraulic side of the piston 16, closed by a closure 15 in a fluid-sealing manner.

On the other, non-hydraulically actuated piston face a return spring in the form of a gas spring is provided. This is supported by a Gas spring chamber 17 is determined as a cap 22 on the corresponding front end of the cylinder housing 14 is connected gas-tight. The gas chamber 17, in which preferably Nitrogen is filled in as a resilient medium, is opposite to the piston face facing sealed by means of an elastic membrane 21 in the free end face of the gas chamber 17 an axial adjusting screw 36 is arranged, which has a defined stop for creates the hydraulic piston 16, so that the maximum stroke of the piston and thus the maximum back and forth mobility of the adjusting pawl 18 is adjustable in an alternative Embodiment can instead of the gas chamber 17 as a return spring 34 also a mechanical one Spring, e.g. a compression spring, to reset the single-acting, hydraulic actuatable piston may be provided.

The in the transverse bore 28 in the vertical direction for reciprocating movement of the piston 16 on the other hand reciprocating adjusting pawl 18 is through a Long hole 25 in the cylinder wall 14 from the piston-cylinder arrangement laterally in front, to im Operation to intervene in the associated ring gear 7. the The axial length of the elongated hole 25 is determined by the stroke of the piston 16.

The adjusting pawl 18 according to the embodiment shown in Fig. 3 is biased by means of a compression spring in the direction of the ring gear 7, wherein in the maximum engagement position of the adjusting pawl 18 this at a concentric Paragraph 40 in the transverse bore 28 of the piston 16 abuts.

The piston 16 is hollow at both of its front ends and has a hydraulic feed for in the bottom wall 38 on the hydraulic side the adjusting pawl 18, which in turn functionally as a piston with corresponding Sealing parts is formed, while the transverse bore 28 of the piston 16 as Another cylinder acts and through the hydraulic supply 24 with the help of the same Hydraulic medium can be acted upon hydraulically, which is also used for actuation of the piston 16 is provided. A terminating piece 20 closes the transverse bore LU on their front side from hydraulically, which is not for the passage of the adjustment pawl 18 is provided for engagement with the ring gear 7.

The pressurization of the adjusting device 18 with the help of the same -Kydraulikmediums, with which the piston 16 is actuated, has the advantage that the Adjustment process can also be carried out with a circulating excitation system and the adjusting pawl 18 is held in Lingriff against the centrifugal force in each case. By pretensioning the adjusting pawl 18 by means of compression spring 19 in the direction of the ring gear is when the engagement part of the adjusting pawl 18 is extended to the maximum, an additional detent or locking device for the rotatable unbalanced mass 4 is created, di supports the already existing frictional engagement. This rest is effective even when the hydraulic system is relieved. Consequently becomes an additional Locking system created, even if the first locking system fails (Frictional connection) due to a friction lining still flawless for a fixed adjustment ensures.

The pressurization of the KolMen-zylinde-Anord-nuno 8 takes place preferably through a bore system 9, 9 ', 9 ", in the exciter shaft 1 and in the first non-rotatable Unbalance mass 3 ', the bore system 9, 91, 9 "on the piston side with the Hydraulic connection 23 in the cylinder wall 14 of the piston-cylinder arrangement 8 is connected is, while the external pressure medium supply takes place via a plug nipple 11, the in the axial bore widened with respect to the axial bore 9 of the bore system 9, 9 ', 9 " 10 is inserted in a circumferentially sealing manner and by means of a flexible hose piece 12 is connected to the hollow bored output shaft of a hydraulic motor 17, wherein the high-bore output shaft of the hydraulic motor in connection with the engine leakage oil chamber and by means of appropriate pressure pre-tensioning of the leakage oil drain an interval Acting on the adjusting device can be made in a simple manner.

The hydraulically operated adjusting pawl described above 18 is single-acting, i.e. it enables the rotatable unbalance mass to be adjusted 4 in a circumferential direction. When the pressure is released, the return spring 34 of the piston 16, the adjusting pawl 18 from the maxinalnubstellung (left in Fig. 3) moved back to the starting position, the engagement part of the adjusting pawl 18 with the bevel 26 in a subsequent tooth of the ring gear due to the Bias of the adjusting pawl 18 engages by means of compression spring 19, so that if necessary a new adjustment step can be carried out.

In preferred embodiments of the invention is a double acting Adjustment provided, i.e. adjustment of the rotatable unbalance mass 4 in both circumferential directions. In such an embodiment (see Sig. 4) is in addition to the aforementioned saw toothed ring 7 including the associated locking pawl 18 a further ring gear 7 'with reversely arranged ratchet teeth and associated second adjusting cylinder 8 'is provided, which analogously to the first rotationally fixed Unbalance mass 3 is attached. The second necessary for the second adjusting cylinder Pressure medium is supplied from the free shaft end via a normal rotary feedthrough from a separately controlled pressure source, i.e. it is on the motor side facing away from the free shaft end 46 a rotary leadthrough 47 according to FIG. 4 rotatably movable warehouse. The supply takes place here from a not shown in the figure external pressure source via the supply line 48 and through the rotating union via the Bore system 49, 49 ', 49 "for Eolben cylinder arrangement 8'.

In Fig. 5 is a further embodiment of a reversible adjustment with a ring gear with an involute profile and a double-acting piston-cylinder arrangement shown. A single ring gear 50 acts here with the piston-cylinder arrangement 51 together in operation, the adjusting pawl 52 in its engaging part is adapted to the involute profile of the ring gear, in a tooth gap of the ring gear 50 can intervene. The adjusting pawl 52 has a piston 53 at its base, which slides in the transverse bore of the hydraulic piston 54 and of both rare des Piston 54 can be acted upon optionally via a separate small control piston 60 is, the functioning of which will be explained in connection with FIG. 6.

The piston 54 slides in the cylinder housing 55 and is pretensioned by means of the Compression springs 56 and 55 'centered. The piston 54 is acted upon depending on the desired direction of adjustment either through the hole 57 or 57 ', the pressure medium supply type being analogous to the preceding explanations is to be viewed. If, for example, the ring gear is to be rotated clockwise, then through the bore 571 hydraulic fluid passed to the right side of the piston 54 and at the same time also via the control piston 60 under the piston 53 of the adjusting pawl 52, This extends, the piston 54 moves to the right to the stop and the ring gear is rotated by one tooth, the pawl in the recess 58 of the cylinder slides. The pressure medium is in the left cylinder chamber as shown in the drawing displaced through the bore 57 without pressure. After the adjustment process there is also a drilling 57 'depressurized, the adjustment pawl moves as a result of the centrifugal force acting on it with displacement of the pressure medium from the tooth engagement and the centering spring 56 brings the piston 54 back into the rest position.

For the opposite adjustment, the process is reversed.

Tn Fig. 6 is an enlarged section of the piston 54 below the transverse bore is shown, which receives the pawl piston 53. In the bottom of the A small control piston 60 can be displaced in a cylindrical space 61 through the transverse bore mounted and centered on the compression springs 62 and 62 '. Is now used by the Drawing on the right side of the piston 54, the pressure P1 is applied, the pressure medium migrates, e.g. a hydraulic fluid, through the bore 63 'via the face of the control piston 60 and pushes it to the left against the pressure of the spring 62 to the stop. Through this causes the connection of the bores 64 and 65 from the central shell part of the piston leg 60 is interrupted, while through the bore 64 ', the annular channel 66 'and the bore 65' the pressure medium for extending the left under the piston 53 can stream. After the adjustment has taken place, the spring 62 brings the control piston 60 again in the middle position, and the volume under the ratchet piston 53 can escape without pressure via both bore systems.

When P2 is applied, the reverse is done analogously Sequence.

Fig. 7 shows a further embodiment similar to that of FIG. 5 by the piston-cylinder arrangement is equipped with two adjusting pawls 52 and 52 '. One pawl piston each is via the bore 59 or 59 'of the associated piston side pressurized so that the right pawl when turning the The ring gear is extended clockwise, while the left pawl for the other direction of rotation functions. The pawl is returned after the adjustment here, for example, by compression springs 70 and 70 ', which are attached to extension bolts 71 and 71 'attack, which penetrate the wall of the piston 54.

Of course, in the embodiment according to FIG. 5, a Spring return of the adjusting pawl 52 according to FIG. 7 in combination with the tax con) 0n 60 take place.

FIG. 8 shows a particularly simple embodiment of the invention shown with a pivotable adjusting pawl 79. According to this embodiment the piston 76 which can be acted upon by hydraulic pressure on one side and which is movable to and fro becomes by means of a spring 77 in the unpressurized state at the right stop of a cylinder 75 held, the shaft of the open piston 76 at its upper part a Bolt bearing 78 carries which the adjusting pawl 79 rotatably fixed.

The bolt bearing 78 slides laterally in a recess 80 of the Cylinder.

The pawl 79 is designed so that its center of gravity "S" to the right the bearing pin 81 comes to rest. This will ensure that the latch in the case of a revolving device with the help of centrifugal force always in the one shown upright position is maintained. Now the piston is pressurized through the bore ~~ 82, the piston 76 moves against the spring tension, and the pawl 79 rotates the ring gear 83 according to the piston stroke one tooth position Further. When the pressure is released, the tensioned spring 77 presses the piston 76 into its Starting position back. The pawl 79 is thereby running against the back of the tooth 84 tilted, disengaged and moved back behind the next tooth, where it snaps into place again.

According to a further development, a resilient one shown in FIG Element 85 may be provided which is attached to the outer wall of the cylinder 75 and is biased with its resilient end against the rear of the pawl 79 and it rests at a point on the back of the pawl 79, in which the through the bias on the pawl 79 force exerted the latter in the winrückstellung moved or held in the engagement position. If such a resilient element 85 is provided is, then a training and storage of the pawl 79, in which the focus the pawl 79 returns this to the engagement position, as shown in FIG. 8, not necessary anymore. The resilient element 85 thus ensures that the pawl 79 is in the engagement position when the adjusting device is at a standstill, as is is shown in FIG.

In Fig. 8 is another functionally reliable Elusfiihrungsform of the invention with a pivotable adjusting pawl 91 shown. Even with this one Embodiment is just as in Fig. 8 a reciprocating, one-sided hydraulically acted upon piston 87 by means of a compression spring 89 in the unpressurized State held at the right stop of a cylinder 86. A piston rod 88 is fixed to the bottom of the piston 87 and extends through the compression spring 89 and a slide guide opening in the opposite of the right stop Side of the cylinder 86 through to the outside. At the free end of the piston rod 88 is a head piece 90 attached, on the side associated with the ring gear 97 the Adjusting pawl 91 is pivotably arranged by means of a bolt mounting 92. A designed as a helical spring 93 resilient element is with one end in a Recess of the head piece 90 and with the other end on a support extension of the Adjusting pawl 91 is supported and biases the adjusting pawl 91 into the engagement position before; In addition, the head piece 90 is on the opposite of the adjusting pawl 91 Side provided with a prism-shaped extension 94, which is designed as a guide part is and yleitet in a guide rail 95, which is attached to the cylinder 86 Die The piston 87 is pressurized through a bore 96.

The mode of operation of the embodiment in FIG. 9 is similar to that in FIG Fig. 8 illustrated embodiment. When the piston moves back to its starting position the adjusting pawl is also made by running against the back of an adjusting tooth tilted, disengaged, and then behind the next tooth in the engaged position returned in the embodiment according to FIG. 9 by the resilient element 93 in the same way as in the embodiment in Fig. 8 with resilient Element 85 happens.

Claims (33)

"VIBRATION GENERATOR WITH ADJUSTABLE IMBALANCE" PATENT CLAIMS: 1. Vibration exciter with adjustable unbalance, with a drivable exciter shaft, on the non-rotatably at least one first unbalanced mass and rotatable in an adjustable manner a second unbalanced mass are arranged, characterized by one for the exciter shaft (1) concentric, on the second unbalanced mass which can be locked in every adjustment position (4) formed toothed ring (7), in which one on the first unbalanced mass (3, 3 ') fixed, tangential to the ring gear (7) movable back and forth, actuatable adjustment pawl 418) (79) can be brought into engagement. 2. Vibration exciter according to claim 1, characterized in that the second unbalanced mass (4) against a concentric stop surface (30) on the first unbalance mass (3 ') is spring-loaded. 3. Vibration exciter according to claim 2, characterized in that a friction lining (5) is formed on the stop surface (30). 4. Vibration exciter according to claim 2 or 3, characterized in that that the second unbalanced mass (4) is pretensioned by a plate spring set (6), which is arranged concentrically around the exciter shaft (1) and supported on it. 5. Vibration exciter according to claim 4, characterized in that the force-displacement racing line of the disc springs (6) in the relevant preload area is essentially constant. 6. Vibration exciter according to claim 1 to 5, characterized in that that the second unbalanced mass (4) via needle bearings (35) on the exciter shaft (1) is supported. 7. Vibration exciter according to claim 4 to 6, characterized in that that with two axially aligned rotatably connected on the exciter shaft (1) and the first unbalanced masses (3, 3 ') located at a distance are a single one adjustable second unbalanced mass (4) is provided between the first unbalanced masses (3, 3 '), the disc springs (6) being supported on the first unfavorable mass (3) are that does not have the stop surface (30). 8. Vibration exciter according to claim 1 to 7, characterized in that that the ring gear (7) on the stop surface (30) of the first unbalanced mass (3 ') facing end face of the second unbalanced mass (4) is formed. 9. Vibration exciter according to claim 8, characterized in that the ring gear (7) is flanged to the second unbalanced mass (4) by means of bolts (32) is. 10. Vibration exciter according to claim 1 to 9, characterized in that that the adjusting pawl (18) engaging in the toothed ring (7) can be actuated hydraulically is. 11. Vibration exciter according to claim 10, characterized in that the adjusting pawl (18) in a first on the stop surface (30) having Unbalanced mass (3 ') attached, actuatable piston-cylinder arrangement (8) supported and is movable back and forth. 12. Vibration exciter according to claim 11, characterized in that the adjusting pawl (18) in a transverse bore (28) of the piston (16) of the piston-cylinder arrangement (8) is received and is guided therein displaceably over a predetermined length, and that the engagement steeply of the adjustment line through an elongated hole (25) in the cylinder wall protrudes laterally, the length of the elongated hole (25) being the maximum stroke length of the Piston (16) corresponds. 13. Vibration exciter according to claim 11 or 12, characterized in that that the piston (16) can be acted upon hydraulically on one side against a return spring (34) is. 14. Vibration exciter according to claim 13, characterized in that the return spring (34) is a gas spring, which is through a gas chamber (17) on the not hydraulically acted upon end face of the cylinder (14) of the piston-cylinder arrangement (8) is determined, the piston (16) opposite the Gaskamm.er (17) by a Membrane (21) is sealed. 15. Vibration exciter according to claim 13 or 14, characterized in that that in the free end of the gas chamber (17) an axial adjusting screw (36) is arranged, which creates a defined stop for the hydraulic piston (16). 16. Vibration exciter according to claim 13, characterized in that the return spring (34) is a compression spring that is not hydraulically applied to the Front side of the cylinder (14) of the piston-cylinder arrangement (8) and on the corresponding Piston face is supported. 17. Vibration exciter according to claim 11 to 16, characterized in that that the adjusting pawl (18) in the piston-cylinder arrangement (8) itself as hydraulic actuatable further piston and the transverse bore (28) of the piston (16) as another Cylinder space are formed. 18. Vibration exciter according to claim 17, characterized in that the adjusting pawl (18) is hydraulically connected to the molben cylinder arrangement (8) is. 19. Vibration exciter according to claim 18, characterized in that the piston (16) is hollow on its hydraulically actuatable side and In the bottom wall (38) there is a hollow construction with a hydraulic feed (24) for the locking latch (18) are provided. 20. Vibration exciter according to claim 12 to 19, characterized in that that the transverse bore (28) of the piston (16) acts as a stop for the adjusting pawl (18) serving paragraph (40). 21. Vibration exciter according to claim 12 to 20, characterized in that that the adjusting pawl (18) in the transverse bore (28) of the piston (16) in the direction The ring gear (7) is biased by a compression spring (19). 22. Vibration exciter according to one of the preceding claims, characterized characterized in that the ring gear (7) has a sawtooth or ratchet profile, being the profile of the engagement part of the adjusting pawl (18) accordingly is configured and has a chamfer (26) which on the return stroke of the piston (1õ) can be used together with the adjusting pawl (18) as a ramp. 23. Vibration exciter according to claim 22, characterized in that on the second unbalanced mass (4) another ring gear with a sawtooth or Arranged pawl profile and a further adjustment pawl belonging to this ring gear is provided, the sawtooth profile with respect to that of the first toothed ring and the first adjustment pawl is reversed. 24. Vibration exciter according to claim 1 to 21, characterized in that that the ring gear has an involute profile, and that the piston-cylinder arrangement can be acted upon hydraulically on both sides. 25. Vibration exciter according to claim 24, characterized in that a separate control piston (Go) is provided for the adjustment pawl through which pressure medium can only be supplied from the pressurized piston side. 26. Vibration exciter according to claim 11 to 25, characterized in that that the hydraulic side of the cylinder (14) of the piston-cylinder arrangement (8) through a bore system (9, 9 ', 9 ") in the exciter shaft (1) and the unbalanced mass (3') is connected to a hydraulic motor (15) and / or an external pressure oil source. 27. Vibration exciter according to claim 26, characterized in that the bore system (9, 9 ', 9 ") has an axial bore (9) in the drivable exciter shaft (1) has, the one with the hollow-drilled descent shaft of the stationary one Hydraulic motor (13) or the external stationary pressure oil source essentially axially is aligned, and that the extreme end of the axial bore (9) in a larger Axial bore (10) merges, in which a plug-in nipple (11) with a circumferential seal (42) is used, which in turn via a flexible hose piece (12) with the hollow bored output shaft of the hydraulic motor (13) or the external pressure oil source is connected. 28. Vibration exciter according to claim 1 to 11, 13 to 16, 23, 26 and 27, characterized in that the adjusting pawl (79) is pivotable on one side arranged hydraulically actuatable piston (76) of a piston-cylinder arrangement (75) is such that during a return stroke effected by means of a compression spring (77) of the piston (76) the adjusting pawl (79) by an associated tooth back (84) of a tooth of the ring gear is tiltable and can be engaged in the adjacent tooth. 29. Vibration exciter according to claim 28, characterized in that the eccentric -v.ch on the piston (76) tgelente adjusting pawl (79) by the during centrifugal force occurring during an operation can be engaged. 30. Vibration exciter according to claim 28, characterized in that the adjusting pawl (79) into the engagement position by means of a resilient element (85) is kept biased. 31. Vibration exciter according to one of claims 28 to 30 characterized in that the adjusting pawl (91) is pivotably arranged on an outside of the cylinder (86) Head piece (90) of a piston rod (88) is attached by the compression spring (89) passed through and hydraulically with the one-sided chargeable Piston (87) is firmly connected 32. Vibration exciter according to claim 31, characterized characterized in that the adjusting pawl (91) in the engagement position by means of a resilient element (93) is biased, which is supported on the head piece (90). 33. Vibration exciter according to claim 32, characterized in that the head piece (90) has a prism-like guide extension (94) which is in a with the cylinder (86) connected guide rail (95) slides.