DE3431639A1 - Merry-go-round having a plurality of passenger cars - Google Patents

Abstract

The merry-go-round possesses a plurality of passenger cars 18 which are suspended from flexurally stiff car arms 17. The car arms are pivotable relative to a merry-go-round crown formed by booms 15, tensioning struts 14 and transverse struts 16. By means of power units 21 to be triggered individually by the passenger, each car 18 can be swung out beyond the position determined by the centrifugal force. Short pivot levers 19 pointing outwards and downwards at an acute angle to the car arms 17 are attached to the car arms 17, their free ends being connected via a flexible tension member 20 to the assigned power unit. In the lower position of rest of the cars, the tension member is therefore folded on the transverse struts 16. The radius of roll on the tension strut is selected, in combination with the length and the angle of the pivot lever, to be such that the free end of the pivot lever 19 emerges behind the radius of roll only at a predetermined outward-pivoting position of the cars, and the tension member is thus no longer folded at that time. From the lower position of rest of the cars to this position, the effective lever arm for applying a torque to swing the cars outwards is small and constant. From this point, the lever arm increases continuously to its maximum value, which is reached in a predetermined upper limit position 26 of the cars. <IMAGE>

Description

Carousel with several passenger gondolas

Description: The invention relates to a carousel according to the preamble of claim 1. Such a carousel is from DE-PS 19 20 ol8 or DE-OS 32 34 279 known.

In the carousel of DE-PS 19 20 ol8 there are power transmitters that by automatic control devices or controlled from a central control panel be operated in such a way that they hang on the long swing arms passenger gondolas briefly give a force impulse at the beginning of the swing out and / or swing in, while the rest of the rocking process of the passenger gondolas remains unaffected.

The power transmitter act on short swivel arms, which essentially an extension of the gondola or

Represent rocking arms on the pivot bearing of the same addition. the Power transmitters can do this - depending on whether there is a swing in or out below or above the centrifugal force position is desired - a push or a pull on the swivel arms exercise. The effective lever arm of the pivot lever is then at its maximum when the Gondolas are in their "centrifugal position". This is unfavorable when there is an oscillation the gondola arms should be raised above the horizontal.

Accordingly, DE-OS 32 34 279 also suggests the articulation the power transmitter to the nacelle poor so that the effective lever arm to Pivoting up the gondolas increases further with increasing pivoting upwards towards an upper limit. For this, however, there are two complex torque gears provided, which are constantly in engagement with each other and their effective rolling radius changed in opposite directions. Two piston-cylinder arrangements are also provided for this purpose. In contrast, these piston-cylinder arrangements can be operated remotely by the passenger to the power generators of DE-PS 19 20 o18. Disadvantageous in the construction of the DE-OS 32 34 279, however, is the complex and therefore failure-prone construction.

Based on DE-OS 32 34 279, it is therefore the task of the present Invention to improve the known carousel so that it is simpler Structure has the desired torque curve for swiveling out the gondolas. Farther of course, optimal safety should be given in all possible operating locations This object is given by in the characterizing part of claim 1 Features solved. Before- partial refinements and further training the invention can be found in the subclaims.

With the features of claim 1 is a particularly simple, safe and easy to assemble carousel created. Once the gondola has swung out so far that the pulling element is no longer on the rolling radius of the Pivot bearing rests, the effective lever arm increases continuously up to to a maximum value. Before that, the lever arm remains relatively small, i.e. H. he corresponds to the rolling radius of the swivel bearing, and remains up to the point at which the tension organ is no longer kinked, constant.

The is in the area of the upper limit of the swinging out of the gondola Maximum lever arm. A relatively long travel of the force transmitter is then required (with little force) to swivel the gondola arm further. This occurs automatically a dampening of the movement.

With the features of claim 3 it is achieved that even when Swinging out the gondola arm, the pulling element cannot sag loosely and others Linkage is avoided.

With the features of claim 4 it is achieved that a single Hoist pump is sufficient to raise both the yoke of the carousel and the To operate the rocking cylinder. The individual cylinders are dimensioned in this way or the control for this is coordinated so that an actuation of the rocking cylinder is only possible when the yoke is fully raised. One special cheap construction of the lifting cylinders, which the common supply of lifting cylinders and rocking cylinders favored by a hoist pump is in the claims 7 and 8 indicated.

With the features of claim 9 is in a particularly simple manner the preload pressure built up to avoid the linkage slack.

With the features of claim lo it is achieved that even when shutting down Maintain the preload pressure on the lift cylinder to avoid slack in the linkage remain. A specific implementation for this is given in claim 11.

With the features of claims 12 to 26, a simple, reliable and safe control of the rocking cylinder is achieved.

The features of claim 27 ensure damping of the stroke movement the lifting cylinder and form a further safety factor. more details and advantages of the invention are the following description of an embodiment refer to.

In the following the invention is based on an exemplary embodiment explained in more detail in connection with the drawing. It shows: Fig. 1 a schematic side view of the carousel according to the invention, the passenger gondolas are shown in different operating positions; Fig. 2 is a schematic, partially cut-away view of the carousel to explain the lifting and rocking mechanism; 3 shows a schematic detailed side view to explain the rocking mechanism; Fig. 4 A + B a schematic side view and a corresponding top view of the suspension the passenger gondola and the rocking mechanism; 5 shows a schematic detailed view the lifting mechanism; 6 shows a detailed view of a lifting cylinder; 7 shows an enlarged, Sectional detailed view of a detail of the lifting cylinder according to a further development the invention; 8 is a schematic view of an oil guide tube; Fig. 9 a schematic diagram of the entire hydraulics of the carousel according to the invention; Fig. Lo is a basic circuit diagram of the hydraulic system for the control or actuation of the rocking cylinder; and FIGS. 11A-C are basic sketches of the inlet and outlet valves for actuating the rocking cylinder in various operating positions.

The same reference characters in the individual figures denote the same or corresponding parts.

Reference is first made to FIG. 1. On a base frame lo, which stands on the ground with a usual underpalling is a vertical one Central mast 11 attached. This is via a rotary drive, which is a pumping station here 12 for a hydraulic pump is rotatable about its longitudinal axis. At its upper end wearing the central mast has a yoke 13 displaceable in the axial direction, on which laterally slightly downwardly inclined tension struts 14 and laterally slightly upwardly inclined boom 15 are attached. The free ends of the tension struts 14 and the boom 15 are connected to each other. Adjacent connection points of Tension struts and arms are still connected to one another via cross struts 16, these cross struts have pivot bearings for gondola arms 17. The cross braces 16 form a closed polygon that is formed by the tension struts 14 and the arms 15 is held.

All around this polygon there are several each via a gondola arm 17 (Passenger) gondolas 18 attached.

These gondolas 18 can around the longitudinal axis of the associated cross strut 16 can be pivoted. For this purpose, at the upper end of the gondola arms 17 is an outward at a predetermined angle protruding pivot lever 19 rigidly attached. more details are explained in connection with FIGS.

At the outwardly protruding end of the pivot lever 19 is a pulling member 20 attached, for example a wire rope or a chain. The other end of the Zugorganes 20 is attached to a rocking cylinder 21, which in turn on the yoke 13 is anchored.

In the starting position of the carousel, the yoke 13 is in its lower, lowered position; the gondolas 18 are located in the with the reference numerals 22 designated position for changing passengers.

When starting the carousel, the yoke 13 is raised and at the same time the central mast 11 is set in rotation.

The gondolas then pass through the take-off or landing curve 23, with the gondolas are pivoted outwards by centrifugal force. Depending on the speed of the middle mast 11 reach the gondolas when fully extended Yoke 13 has a stationary position, which is denoted by the reference numeral 25. From this Out of position, the gondolas can then be pivoted by actuating the rocking cylinder 21 which is indicated by a rocking curve 24. Will the rocking cylinder 21 acted upon with pressure medium, the pulling element 20 pulls over the pivot lever 19 the gondola arm 17 with the gondola 18 up to an upper limit position, which is denoted by the reference numeral 26. By releasing the pressure from the rocking cylinder 21 the gondola returns due to its own weight (gravity) and can Swing under point 25 or, more precisely, circle (25). Of the possible angle at which the gondola swings upwards from the vertically hanging position can, is around 135 ".

The rocking cylinder 21 is actuated during normal operation remotely controlled by the passengers. In every gondola there is therefore a control lever for the respective gondola is available. With this control lever, solenoid valves (Fig. lo and 11) operated. The height of the swiveling out of the gondola thus depends on the duration the actuation of this lever and can be freely selected by the passenger. For safety reasons it is provided that the rocking cylinder 21 can only be actuated when the yoke 13 is fully raised, so the gondola has reached point 25 Has. Safety precautions have also been taken to prevent it from swinging out over the top or to prevent the lower limit position.

As an alternative to actuation by the passenger, rocking can be used can also be controlled from a central control panel for the carousel. So is it is also possible for test runs or a "TÜV acceptance", all of them Driving states, including rocking, to bring about when the gondolas are unoccupied.

Fig. 2 shows in more detail the lifting mechanism for the yoke 13 and the rocking mechanism. The yoke 13 is designed here as a cylindrical tube, which is mounted axially displaceably on the central mast 11 via sliding guides 27. The displacement of the yoke 13 along the central mast 11 takes place via two lifting cylinders 28 and 29, on the one hand non-rotatably on the central mast by means of consoles 30 and 31, respectively 11 and on the other hand are attached to the yoke 13, there in the space between the central mast 11 and the side wall of the yoke 13 protruding arms.

Furthermore, cylinders are parallel to the central mast 11 and thus to the lift 28 and 29 a telescopic return pipe 32 is present, the function of which is more detailed in connection with FIGS. 8 and 9 will be explained. This return pipe is also non-rotatably connected to the central mast 11 and the console 13.

For the rotary drive of the carousel and thus the central mast 11 is a slewing ring 33 is provided as well as a slewing gear 34, which is a hydraulic motor here, which cooperates via a pinion 36 with a ring gear 35 which is fixed to the Central mast 11 is connected. The slewing ring 33 is screwed to a foundation frame 37, which, in turn, with underlying cladding 38 on the ground 39 rests.

At the upper and lower ends of the yoke 13 are short cantilevers 40 and 41 is provided to which the tension struts 14 and the boom 15 are attached. In addition, there is an abutment 42 for the rocking cylinder in the area of the lower cantilever arm 41 21 attached, which is roughly parallel to the associated boom 15 is, in the abutment 42, however, pivotable by a predetermined angular amount is. If the rocking cylinder 21 is acted upon with pressure medium, for example hydraulic oil, so its piston rod pulls on the pulling element 20, which via the pivot lever 19 pulls the gondola arm 17 and thus the gondola upwards along the rocking curve 24. A control block 43 is shown here on the rocking cylinder 21, which controls the individual Contains control valves as well as various safety devices that are related are explained in more detail with FIGS. 9 and 10.

3 and 4 illustrate the rocking mechanism.

As already mentioned, on the gondola arm 17 is the one that protrudes outward Swivel lever 19 rigidly attached. In the shown with solid lines In the "rest position" of the gondola 18, the pivot lever 19 points obliquely downwards. The pulling organ 20 therefore rests on the cross strut 16 and is thus kinked. The effective starting lever arm 44 thus corresponds to the rolling radius 45 of the cross strut 16. To pivot the Gondola from this rest position is due to the small initial lever arm 44 a very great force is required.

The articulation point occurs from a certain swing-out position of the nacelle of the pulling element 20 on the pivot lever 19 behind the rolling radius 45. Of the effective lever arm increases from this swing-out position, creating a desirable There is an increase in torque (with the desired decrease in the angular velocity of the Gondola arm). The angle between the gondola arm 17 and the pivot lever 19 as well the rolling radius 45 can be chosen so that the point from which the effective lever arm enlarged, especially during the swing position the nacelle is reached, in which this is due to the centrifugal force at operating speed of the carousel is pivoted into its stationary position (point 25 in Fig. 1).

The upper limit position of the nacelle is shown in Fig. 3 with dashed lines shown. In this position the maximum lever arm 46 is effective. From this dashed Position can also be seen that the rocking cylinder 21 on its mast-side Must be pivoted at the end, you want to ensure that only tensile forces (and no torques) occur on the rocking cylinder. Fig. 4B shows the more clearly Storage of the cross strut 16 between two adjacent tension struts 14, the cross strut 16 is pivotably mounted on the tension struts 14 and the gondola arm 17 in turn is firmly connected to the cross strut 16.

Fig. 5 shows in more detail the lifting mechanism for the yoke 13. During In Fig. 2 the yoke is almost completely raised, it is in Fig. 4 still in a lower position. In addition to those in connection with FIG Features described can be seen more clearly from Fig. 5 that the yoke 13 in In the lowered position, the lifting cylinders 28 and 29 are covered and also the consoles 30 and 31. Furthermore, an additional sliding guide 49 can be seen with the the yoke 13 on the lifting cylinders 28 and 29 and thus also in the lower area of the Central mast 11 is guided.

The lifting cylinders 28 and 29 are via a common pressure line So pressurized with pressure medium, in particular hydraulic oil. This becomes a lower one Cylinder chamber 51 supplied. A special feature here is the piston rod 52 with a through hole provided through the piston 53 through into the cylinder chamber 51 opens. The effective piston area is thus the cross-sectional area of this Bore reduced.

As described in more detail in connection with FIGS. 6 and 9 is used so that the lifting cylinders 28 and 29 not only to lift the yoke 13, but also for forwarding the pressure medium to the rocking cylinder. At the top An opening is provided at the end of the piston rod, to which a pressure medium line is provided 56, hereinafter referred to as "rocking pressure line", connected is. Through the piston top surface, the outside of the piston rod 52, and a cylinder seal 54 an upper cylinder chamber 55 is formed, which in the area of the cylinder seal 54 or the console 30 or 31 has an outlet opening to which also a Pressure medium line 57 is connected, which is hereinafter referred to as "preload pressure line" referred to as. That is, if the piston rod 52 is moved upwards, then the pressure medium located in the upper cylinder chamber 55 displaces and builds in the preload pressure line 57 to a pressure. Finally, 13 still leads to the yoke a return line 58, which will be explained in more detail in connection with FIG will.

Of course, the yoke 13 has corresponding lateral openings for the passage of lines 56, 57 and 58.

Fig. 6 shows the construction of the lifting cylinder in more detail.

The piston rod 52 and the piston 53 have a continuous central one Bore 59, which opens into a lateral opening at the upper end of the piston rod, to which the rocking pressure line 56 is connected.

Of course, the piston 53 is opposite the inner wall of the cylinder sealed in the usual way with a seal 53 '. Neglecting the The area of this seal is the effective piston area and thus the cross-sectional area of the piston 53 minus the cross-sectional area of the bore 59. This effective piston area is acted upon by the pressure medium and generates the power to Raising the yoke 13. Part of the pressure medium passes through the bore 59 in the rocking pressure line 56 for acting on the rocking cylinder 21. The upper one Cylinder chamber 55 is also filled with pressure medium, here hydraulic oil.

The effective piston area is the cross-sectional area of the piston 53 minus the cross-sectional area of the piston rod 52. It is therefore smaller than the effective piston area in the cylinder chamber 51.

In the exemplary embodiment in FIG. 6, the cylinder seal 54 has a laterally offset opening 54 'to which the preload pressure line 57 is connected is.

This line is for refilling the upper cylinder chamber 55 to a Tank 61 connected, with the interposition of a check valve 62.

This ensures that only when the piston 53 is lowered that is, when the volume of the upper cylinder chamber 55 increases, hydraulic oil is sucked up.

If, on the other hand, the piston is moved upwards, i. H. the volume of upper cylinder chamber 55 is reduced, so that is located in this chamber Hydraulic oil is pressed into the preload pressure line 57 and passes from there via a check valve 63 switched in the forward direction to a further section 64 of the swing pressure line. This check valve 63 also prevents that when Lowering the piston 53 pressure medium flows back from the line 64.

An eye 60 is attached to the upper end of the piston rod 52, with which the piston rod is attached to the yoke by means of a bolt.

Fig. 7 shows a somewhat modified form of the lifting cylinder. In order to should dampen the upward movement shortly before reaching the upper end position can be effected.

In particular, the lower end of the piston rod 52 is adjacent the piston 53 is provided with a circumferential collar 65, so that there is a thickening the piston rod occurs. This collar 65 is at its cylinder seal 54 the facing end is provided with a bevel 66. The cylinder seal 54 has a central recess 67, the dimensions of which are chosen so that the collar 65 moves upwards the piston rod 52 can enter there. At the upper end of this recess 67 a preload pressure channel 68 is connected, which in the preload pressure line 57 flows out. Above the recess 67 is then the usual seal 69, for example in the form of a packing or an O-ring.

In addition, the cylinder seal 54 has a measuring pressure channel 70, which leads from the upper cylinder chamber 55 to the outside. On this channel 70 is a Control line 71 connected, which leads to an adjusting device 72, the a hoist pump 73, which generates the working pressure, adjusted.

The mode of operation of this arrangement is as follows: Will the piston rod 52 raised so far that the collar 65 enters the recess 66, so forms First a throttle point 74 through the bevel 66. The hydraulic oil slows down conveyed away from the upper cylinder chamber 55; so a counterpressure gradually builds up on, which slows down further upward movement of piston rod 52 and piston 53. As soon as the collar 65 has entered the recess 61, the connection between the preload pressure channel 68 and the cylinder chamber 55 shut off. The pressure medium from the upper cylinder chamber 55 can no longer continue in the Preload pressure line 57 arrive. The pressure in the cylinder chamber 55 builds up continues on and is via the measuring pressure channel 70 and the control line 71 to the adjusting device 72 forwarded, which then swings back the hoist pump 73, d. H. in your The delivery rate is reduced. The piston 53 and the piston rod 52 thus move smoothly in its upper limit position, the delivery rate of the hoist pump then so it is regulated that the pressure is sufficient, the piston 53 in its upper position to hold and thus also the yoke 13 and the rocking cylinder via the bore 59 to supply with sufficient pressure.

In a specific exemplary embodiment, the rocking pressure is 250 bar, while the pressure for lifting and holding is around 130 bar, depending on the load.

Fig. 8 shows in more detail the arrangement of the return pipe. This The tube is designed as a telescopic tube and is therefore basically similar to the lifting cylinders, the piston, of course, being omitted. In detail there is the return pipe 32 from a lower cylinder 75, in which a pipe 77 axially via a seal 76 is movable. The cylinder 75 has an opening at its lower end which is connected to a return line 78 leading to the (not shown) Ö1 tank leads. The lower end of the cylinder 75 is attached to a bracket 79, which in turn is firmly connected to the central mast 11. The top of the tube 77 is attached to a bracket 80 which is attached to the inside of the yoke 13 is. In the area of the upper end of the tube 77 there is also an opening, to which the return line 58 is connected. For the sake of completeness are also here the rocking pressure line 56 and the preload pressure line 57 which are connected to the lifting cylinders 28 and 29.

9 shows a basic circuit diagram of the entire hydraulic system. A motor 81 (e.g.

Electric or internal combustion engine), the two hydraulic pumps 73 and 82 drives. The pump 73 is here the lifting gear pump for the lifting cylinders 28 and 29 and at the same time also the pump, which supplies the oil pressure for the rocking cylinder 21 generated. The pump 82 is the slewing gear pump that drives the slewing gear 34. The slewing gear pump 82 can be accessed from a control stand by means of a remote adjustment device 84 from controllable. Two hydraulic lines 86 and 87 are connected via a valve block 85 passed through a rotary leadthrough 83 on the central mast to the slewing gear 34 (oil motor).

The hoist pump 73 is also by an electrical remote adjustment device 88 controllable from a control stand. In addition, the hoist pump 73 is also hydraulic controllable by a hydraulic remote adjustment device 89, which for example the adjusting device 72 according to FIG. 7 also contains. The working pressure line 50 becomes the two lifting cylinders 28 and 29 through the rotary feedthrough 83 directed. In addition, a control pressure line branches off from the working pressure line 50 9o, which leads to the hydraulic remote adjustment device 89, whereby a pressure control can be carried out. The inlet side of the elevator pump 73 is connected to the tank 61 connected, in which a return or tank line 105 opens, which is also passed through the rotary leadthrough 83 and to the return line 78 from the return pipe 32 is connected.

The rocking pressure line 56 is the lifting cylinder on both piston rods 52 28 and 29 connected and opens in a pressurized oil ring line 91, to which several control blocks 92 are connected, one for each Swing cylinder 21 or per gondola. For the sake of simplicity, there is only one control block here 92 and a rocking cylinder 21 are shown. The pressure oil ring line 91 is - like is explained in more detail in connection with Fig. lo - with the "rocking pressure" applied. Pressure medium is fed to the rocking cylinder 21 via the control block 92 and discharged from this, via a line 93. As soon as the line 93 with Pressure is applied, the piston of the rocking cylinder 21 is drawn in, so that the gondola is pivoted out via the pulling element 20 (FIG. 1). The other side the rocking cylinder 21 is subjected to atmospheric pressure here. Is concrete the corresponding cylinder chamber is connected to an air manifold 94, which replenished with dried air from an air dryer 95 and a check valve 96 will. For blowing off the air when the piston of the rocking cylinder 21 is retracted Another check valve 97 is provided, which provides the air path to a blow-off pipe 98 releases. This ensures that the one cylinder chamber of the rocking cylinder 21 is always filled with fresh, dry air and there is no. Precipitate condensation can.

The working chamber of the rocking cylinder 21 is now constantly rocking filled with hydraulic oil and emptied again. Both take place via line 93. The control block 92 - shown in greater detail in FIG. 10 - directs the return oil Via an output line 99 to a return oil ring line loo, which is constantly with a Preload pressure of, for example, 30 bar is applied.

This return oil ring line loo is via a preload line lol and the check valve 63 to the preload pressure line 57 and thus to the upper cylinder chamber 55 of the lifting cylinders 28 and 29 are connected. Farther is the Return oil ring line connected to a reservoir 103, which also acts as a pressure accumulator serves.

Finally, the return oil ring line is loo via a pressure relief valve 104 connected to the return line 58, which is attached to the upper pipe 77 of the return pipe 32 is connected. As already in connection with Fig.

6, the preload pressure line 57 is via the check valve 62 still connected to the tank 61, via a line section 102 and the tank line 105.

The operation of the hydraulic system according to FIG. 9 is described below. The slewing gear pump 82 is actuated via the motor 81, which drives the slewing gear 34 and thus the entire carousel is set in rotation. The control takes place via the remote adjustment device 84 and valve block 85.

At the same time, the lifting mechanism pump 73 is driven by the motor 81. The pressure medium at 130 bar, for example, causes the lifting cylinders 28 and 29 raise the yoke 13. The control block 92 locks during this upward movement Pressure medium supply to the rocking cylinders 21 still from, so that the full delivery rate the hoist pump 73 is available for lifting the yoke.

During rocking, the pressure fluctuations in the oil pressure Via the control line 9o and the hydraulic adjusting device 89, the delivery flow the pump is adjusted to the consumption due to the rocking according to the pump characteristic. As soon as the lifting cylinders 28 and 29 are fully extended, the return pipe 32 corresponding valve 63 and the line lol also the return oil ring line preload pressure of, for example, 30 bar is applied. This pressure will also stored in the reservoir 103, and it is through the pressure relief valve 104 monitored. Should the preload pressure exceed the pressure relief valve 104 set pressure rise, the valve 104 opens and allows excess Pressurized oil through line 58, return pipe 32, return line 78 and finally the tank line 105 into the tank 61 from.

During this mode of operation, the control block 92 leaves the established Preload pressure of the ring line loo to the working chamber of the rocking cylinder 21. The rocking cylinders 21 are thus biased with the bias pressure, whereby any The linkage is eliminated. However, the preload pressure is set so that it is not enough to swing out the gondolas. Also contributes to this in the Fig. 2 to 4 described articulation of the gondola arms 17 with the changing lever arm at.

As soon as the upper limit position of the lifting cylinders 28 and 29 is reached is, the control block 92 is released for actuation of the rocking cylinder. To retract the rocking cylinder, i. H. to swing out the gondolas, arrives then the pressure medium from the hoist pump 73 via the path 50, 83, 28, 29, 52, 56, 91, 92, 93 in the working chamber of the rocking cylinder.

On the other hand, when the rocking cylinder is pivoted down, the pressure oil arrives from the working chamber of the same via line 93 and control block 92 as well the line 99 in the ring line loo and the reservoir 103, where the first Preload pressure is maintained until valve 104 responds and any excess Releases pressure medium.

If the yoke is to be shut down again, then the Lifting gear pump swiveled out negatively. The yoke then presses under its own weight the lifting cylinders 28, 29 together. The pressure oil in the working chamber of the lifting cylinder 28, 29 flows back into the tank via line 50 and hoist pump 73. the Hoist pump 73 thus becomes an oil motor and drives the electric motor, which is in the frame its characteristic runs oversynchronously and feeds energy back into the electrical network. the upper chambers of the lifting cylinders 28, 29, i.e. the chambers generating the preload pressure, must be refilled during this lowering movement. To even with this operating condition To be able to maintain the preload pressure, this make-up does not take place the ring line loo, but from the tank 61. The check valve takes care of this 63, which prevents a make-up from the loop loo in cooperation with the check valve 62, which is a make-up from the line 102 and connected to it connected line 105 allows. Finally it should be mentioned that the lines 102 and 78 are connected to one another here in front of the rotary leadthrough 83.

Fig. Lo shows the structure of the control block 92 in more detail. The control block 92 is connected on the input side to the pressure oil ring line 91 and thus to the Swing pressure line 56. The pressure medium arrives from there via an orifice plate or Throttle 106 to an input valve 107, which is a solenoid valve, which can be electrically controlled remotely by the passenger. Depending on the switch position of the Inlet valve 107, the pressure medium reaches a line 108 in which a Parallel connection of a throttle lo9 and a check valve 11o lies. That Check valve llo is switched so that the pressure medium from the ring line 91 can flow in the direction of the rocking cylinder 21. The pressure medium arrives from there to a rectifier plate 111 containing an adjustable control valve 112, which due to the rectifying effect of four check valves always in one Direction is flowed through and the flow rate of the Pressure medium limited to an adjustable, predetermined amount. Got from there the pressure medium via a line 113 to a valve 114, which is a check valve 115 and a throttle 116 are connected in parallel as a "bypass". The check valve 115 is switched so that the pressure medium from the ring line 91 to the rocking cylinder 21 can flow.

From there, the pressure medium passes through a further valve 117, the a check valve 118 is connected in antiparallel to the line 93 and thus into the working chamber 121 of the rocking cylinder 21. The check valve 118 is switched so that pressure medium flowing back out of the working chamber, the valve 117 can handle. The valves 114 and 117 are controlled via scenes 119, namely by the working position of the rocking cylinder 21. The valve 114 limits the lower position of the swing arm, d. H.

the extended position of the rocking cylinder 21. Here, the Valve 114 switched to "hold down" so that it blocks an oil flow. That Valve 117 accordingly limits the upper, swiveled-out limit position of the rocking arm, d. H. the fully retracted position of the rocking cylinder 21. So it becomes in this case switched from passage to blocking and defines a "stop above".

The rocking cylinder 21 is in a working chamber through its piston 120 121 and an air chamber 122 divided. The air chamber is - as described above - Connected to the air dryer 95 or the blow-off pipe 98. On the piston rod of the rocking cylinder 21, an eye 123 is attached to which the pulling element 20 is connected is.

A branch line is located between the rectifier plate 111 and the valve 114 124 is provided, which via an orifice or throttle 125 to a pressure relief valve 126 leads to which a check valve 127 is connected anti-parallel. The starting page of the pressure limiting valve 126 and the inlet side of the check valve 127 are jointly connected to a line 128, which in turn is connected to the output line 99 and are thus connected to the return oil ring line loo.

Between the rectifier plate 111 and the parallel connection Throttle 1o9 and check valve llo, a return and make-up line is connected, which leads to an outlet valve 13o and from there via a line 131 to the Output line 99 or the ring line loo. The exit valve 130 is also a Solenoid valve that can be operated electrically by the passenger.

Finally there is another return line (for slow lowering the gondolas) from the inlet valve 107 to the outlet line 99 and thus to the Loop loo. In Fig. Lo the two valves 107 and 130 are in the idle state, d. H. in the de-energized state, shown.

The following describes the operation of the control for the rocking cylinder in connection with FIGS. lo and 11, FIG. 11 showing the possible Switching combinations of valves 107 and 130 shows.

In the nacelle there is a control lever that has three positions can, namely a position for "lifting" (Fig. 11A), a neutral or central position (Fig. 11B) and a position for rapid lowering (Fig. 11C). First of all, be of it assumed that the two valves 114 and 117 open for the limit positions are. As soon as the electrical remote control of the two valves 107 and 130 is released the passenger can operate the two valves using the control lever.

First, the raising of the lifting cylinders 28, 29 and the assembly of the preload pressure. The two valves 107 and 130 are de-energized and thus in the in Fig.

rest position shown lo. The loo building up on the ring line The preload pressure reaches the working chamber 121 of the rocking cylinder via the following path 21: Output line 99, line 128, check valve 127, line 124, parallel connection from open valve 114 and check valve 115, open valve 117, line 93; In addition, the pre-tensioning pressure also reaches the following to the one described above parallel path to valve 114 and check valve 115: line 99, outlet valve 130, line 129, rectifier plate 112, line 113. Since at least at the beginning of the When the yoke is raised, the gondola can still have its lower limit position Valve 114 can also be blocked by the gate control 115, so that alone the check valve 115 allows the preload pressure to reach the working chamber 121. However, as soon as the gondolas swivel out due to centrifugal force, the valve 114 opened so that the parallel connection of valve 114 and check valve 115 is effective is. The effect of the throttle 116 is negligible here. The one when starting up The pre-tensioning pressure that builds up is sufficient for the one that arises when the nacelle arm is swiveled up To compensate for the linkage-free, so that the pulling element 20 is constantly under a pretension remain.

While the yoke is running up, the inlet valve 107 is in FIG Rest position shown in Fig. lo and thus for the working pressure on the ring line 91 still blocked. So flows through the piston rod of the two lifting cylinders 28, 29 no pressure medium through yet, so that the full pump output for lifting of the yoke is available. Once the yoke is fully up, will the two valves 107 and 130 released. It is now the operating status of the The end- pivoting of the gondolas described. The passenger pushes the Control lever in the "lift" position; the solenoid valves 107 and 130 are energized and brought into the operating position shown in Fig. 11A. The inlet valve 107 is open while the outlet valve 130 is closed. Pressure medium now flows from the ring line 91 through the valve 107 on the path described to the rocking cylinder 21, whereby the latter is retracted and the gondola swings out. The air chamber 122 is emptied via the check valve 97 and the blow-off pipe 98. The two valves 114 and 117 are in the illustrated open position, to when the gondola reaches the upper swiveling position through the gate control 119 the valve 117 is closed. Further pressure can no longer be in the Flow to working chamber 121. Since on both sides of the check valve 118 in essentially the same pressure prevails, possibly at the outlet of valve 114. even a higher pressure builds up, the check valve 118 is still blocked, so that with energized valves 107 and 130, but closed valve 117, the rocking cylinder 21 remains in the end position reached. So the gondola is in the highest position held stationary.

If the passenger brings the control lever into the "neutral" position, so the input valve 107 is de-energized and switches over, while the output valve 130 still remains excited. The inlet valve 107 thus blocks a further make-up of hydraulic oil. The line that is still at full working pressure at this moment 108 is connected to line 132 and thus ultimately to the preload pressure in the loop loo. The pressure in the lines of the control block 92 drops, the check valve 118 opens and pressure medium can flow from the chamber 121 via the Check valve 118, valve 114, line 113, rectifier plate 111 through the throttle 1o9 drain through. The throttle 1o9 determines here the lowering speed of the gondola. There is a slow lowering. The cross section of the throttle lo9 is of course smaller than that of the adjustable control valve 112, so that the throttle 1o9 the maximum possible Determined flow velocity. The gondola descends down to a stationary one Swivel position caused by the rotating speed of the carousel (centrifugal force) is determined. As already described above, the pressure medium initially only arrives on the pre-tensioned ring line loo and only when the pressure relief valve responds 104 also ultimately back into the tank 61.

During this slow lowering, the carousel is at normal speed the lower limit position of the nacelle is not reached, the valve 114 thus remains in the in Fig. Lo shown open position.

Next, the rapid descent mode will be described. By operating the lever in the nacelle, both valves 107 and 130 are de-energized and get into the position of FIG. 11C, which is also shown in FIG. This position is also assumed in the event of a sudden power failure. The inlet valve 107 is still blocked for a replenishment of pressure medium from the ring line 91; the outlet valve 130 is now open in the direction from the line 129 to the line 131. The possible oil return paths, namely the path via the throttle lo9, the valve 107 and the line 132 on the one hand and the path via the line 129, the outlet valve 130 and the line 131 are thus parallel. The choke 1o9 is therefore ineffective, since the path through the outlet valve 130 offers less flow resistance. The pressure medium thus flows off very quickly, with the flow velocity determined by the adjustable control valve 112 in the rectifier plate 111 will.

With this rapid lowering, it may well happen that the The gondola swings down under the stationary swiveling position caused by the centrifugal force. If the lower limit position is reached, the gate control closes 119 the valve 114, so that then the return path from the rocking cylinder 21 to Ring line loo limited by the throttle 116 and is thus strongly attenuated.

Various safety functions are explained below. For example, if the nacelle is overloaded or is due to a control error the hoist pump reaches a dangerously high pressure, the pressure relief valve speaks 126 and lets pressure medium from line 113 and thus the entire system the line 128 to the ring line loo. The pressure relief valve 126 is here set to the "rocking pressure" plus a safety margin and lies thus, for example, a little over 200 - 220 bar. In this case, builds up in the preload pressure ring line loo initially a higher pressure, which is then generated via the pressure control valve 104 (Fig. 9) is drained. To avoid pressure fluctuations, is on the inlet side of the pressure limiting valve 126, the aperture or throttle 125 should also be provided If some of the valves get stuck due to malfunction, the following occurs: Stays the inlet valve 107 hang in the rest position, so the rocking cylinder 21 is only preloaded by the preload pressure. Otherwise there will be no incorrect reaction on. If the solenoid valve 107 remains in the excited position, the valve will 117 close when the upper pivoted position is reached and then possibly open. Pressure that builds up further is released through the pressure limiting valve part 126.

If the outlet valve gets stuck in the rest position, then flows when the valve is energized Inlet valve 107 the pressure medium in the circuit through line 129, the open Outlet valve 130 and line 131 back. If the outlet valve remains in the hang in the excited position, the return flow takes place through the throttle lo9. The gondola slowly descends.

In the worst case, both valves 107 and 130 remain energized Hanging position, the hoist pump must be switched off. The oil can then via the throttle lo9, the ring line 91, the line 56 etc.

flow through the hoist pump 73 back into the tank 61.

In the event of a line break, the oil flow through the orifice 106 limited.

LIST OF REFERENCE SYMBOLS: lo base frame 11 central mast 12 pumping station 13 Yoke 14 tension strut 15 boom 16 cross strut 17 gondola arm 18 gondola 19 pivot lever 20 Pulling element (chain) 21 Rocking cylinder 22 Pos. For changing passengers 23 Take-off curve / landing curve 24 swing curve 25 swing start 26 upper swing limit 27 sliding guide 28 Lifting cylinder 29 Lifting cylinder 30 Console 31 Console 32 Return pipe 33 Slewing ring 34 Slewing gear (pump) 35 Cross teeth 36 Pinion 37 Foundation frame 38 Underpalling 39 Soil 40 Cantilever arm 41 Cantilever arm 42 Swing cylinder bearing 43 Control block 44 Start lever arm 45 rolling radius 46 end position lever arm 47 max.swivel angle 49 sliding guide 50 Pressure line 51 Cylinder chamber 52 Piston rod 53 Piston 53 'Seal 54 Cylinder seal 54 'opening 55 upper cylinder chamber 56 swing pressure line 57 preload pressure line 58 Return line 59 Bore 60 Bolt eye 61 Tank 62 Check valve 63 Check valve 64 Line 65 Collar 66 Chamfer 67 Recess 68 Preload pressure channel 69 Piston rod seal 70 measuring pressure channel 71 Control line 72 Adjustment device 73 Hoist pump 74 Throttle point 75 Cylinder 76 Gasket 77 Pipe 78 Return line 79 Bracket 80 Console 81 Motor 82 Swing pump 83 Rotary feed-through 84 Remote adjustment device 85 valve block 86 line 87 line 88 el. Remote adjustment device 89 hydr. Remote adjustment device 9o control pressure line 91 pressure oil ring line 92 control block 93 line 94 air collecting line 95 air dryer 96 check valve 97 check valve 98 blow-off pipe 99 exit line loo return oil ring line lol preload line 102 suction line 103 reservoir 104 pressure relief valve loS tank line 106 throttle 107 inlet valve 108 line lo9 throttle llo check valve 111 rectifier plate 112 adjustable Control valve 113 Line 114 Delay valve "Stop down" 115 Check valve 116 Throttle 117 Delay valve "Stop up" 118 Check valve 119 Link control 120 Piston 121 Working chamber 122 Air chamber 123 Bolt eye 124 Line 125 Orifice / throttle 126 Pressure relief valve 127 Check valve 128 Return and make-up line 129 Return line 130 outlet valve 131 line 132 line - Blank page -

Claims (27)

Carousel with several passenger gondolas Claims: 1. Carousel with several passenger gondolas attached to ~ brackets or tension struts via freely pivoting, Rigid gondola arms are suspended and depending on the centrifugal force when Rotating the carousel outwards and upwards can be moved with between the booms or a central mast and the gondola arms arranged power transmitters (rocking cylinders), which swivel the gondolas beyond a centrifugal force position, and with devices, the torque acting on the rocking arm (rocking moment) as a function of change from the pivot position, including a rigid pivot lever on each of the gondola arms is attached, the free end of which is coupled to the assigned force transmitter, through this characterized in that for coupling between the force transmitter (rocking cylinder 21) and associated Swivel lever (19) a flexible pulling element (chain, wire rope or the like 20) is provided is that the pivot lever (19) at such an angle on the gondola arm (18) is attached that the pulling element (20) in the rest position (22) of the gondola (18) on the pivot bearing (Cross strut 16) of the gondola arm (18) is angled and that, in addition, the rolling radius (45) is selected on the pivot bearing so that the tension member (20) only from a predetermined The pivoting position of the gondola (18) runs in a straight line. 2. Carousel according to claim 1, characterized in that the angle between the gondola arm (18) and pivot lever (19) is also selected so that in a predetermined, maximum upper pivoting position (26) of the gondola (18) of the effective lever arm (46) of the pivot lever (19) has its maximum value. 3. Carousel according to claim 1 or 2, characterized in that the Pulling element (20) by the force transmitter (rocking cylinder 21) is constantly under tension is held. 4. Carousel according to one of claims 1 to 3, characterized in that that - as known per se - a yoke (13) of the carousel axially opposite the central mast (11) is displaceable and that a single hoist pump (73) for supplying pressure medium of lifting cylinders (28, 29) and the rocking cylinder (21) is provided. 5. carousel according to one or more of claims 1 to 4, characterized characterized in that the rocking cylinder (21) of each gondola (18) individually from the nacelle can be controlled remotely. 6. Carousel according to claim 4 or 5, characterized in that the Rocking cylinder (21) only after the yoke has reached an upper limit position (13) can be acted upon with working pressure. 7. Carousel according to one or more of claims 3 to 6, characterized characterized in that the pressure medium supply of the rocking cylinder (21) with working pressure takes place through the lifting cylinder (28, 29). 8. carousel according to claim 7, characterized in that the lifting cylinder (28, 29) have a bore passing through their pistons (53) and piston rods (52) (59) and that a pressure medium line (56, 91) for supplying the rocking cylinder (21) with working pressure on this bore (59) in the upper area of the piston rods (52) is connected. 9. Carousel according to claim 7 in conjunction with claim 3, characterized characterized in that a chamber (55) of the lifting cylinder (28, 29) which does not have working pressure is acted upon, when the lifting cylinder (28, 29) is raised with a working chamber (121) the rocking cylinder (21) is connected. lo. Carousel according to Claim 9, characterized in that the chamber (55) separated from the rocking cylinders (21) when the lifting cylinders (28, 29) are lowered and is connected to a (pressureless) pressure medium tank (61). 11. carousel according to claim 9 or lo, characterized in that the chamber (55) via check valves (62, 63) with the rocking cylinders (21) or the pressure medium tank (61) is connected. 12. Carousel according to one or more of claims 3 to 11, characterized characterized in that all rocking cylinders (21) each have their own control block (92) and that all control blocks are connected to a common pressure oil ring line (91) and a common return oil ring line (loo) are connected, the pressure oil ring line (91) to the pressure medium outlets of the lifting cylinders (28, 29) and the return oil ring line (loo) connected to the preload pressure outputs (chamber 55) of the lifting cylinders (28, 29) are. 13. Carousel according to claim 12, characterized in that the return oil ring line (loo) to a storage tank (1o3), which also functions as a pre-tensioning pressure tank serves, is connected and at the same time via a pressure relief valve (104), the is set to a predetermined pressure, and return lines (58, loS) with the (pressureless) tank (61) is connected. 14. Carousel according to claim 13, characterized in that in the Return line (58, 105) a telescopically extendable and synchronous with the lifting cylinders (28, 29) running return pipe (32) is switched on. 15. Carousel according to one or more of claims 1 to 14, characterized characterized in that the sides of the rocking cylinder which are not acted upon by pressure medium (21) via a common air collecting line (94) with an air blow-off pipe (98) and an air dryer (95) are connected. 16. Carousel according to claim 15, characterized in that the air dryer (95) and the air blow-off pipe (98) via check valves (96, 97) with the air collecting line (94) are connected, these Check valves (96, 97) switched in this way are that an air supply to the rocking cylinder (21) only via the air dryer (95) and blowing off air from the rocking cylinders (21) only via the blow-off pipe (98) takes place. 17. Carousel according to one or more of claims 12 to 16, characterized characterized in that the control block (92) is an electromagnetically actuated inlet valve (107) and an electromagnetically operable outlet valve (130), wherein the inlet valve (107) is connected to the pressure oil ring line (91) and one Connection between the pressure oil ring line (91) and the rocking cylinder (21) is optional releases or blocks and wherein the output valve (130) a connection between the rocking cylinder (21) and the return oil ring main (loo) optionally releases or locks. 18. Carousel according to claim 17, characterized in that the pressure medium path between the valves (107, 130) and the rocking cylinder (21) an adjustable Control valve (112) is provided, which controls the flow rate of the pressure medium limited to an adjustable value. 19. Carousel according to claim 17 or 18, characterized in that in the pressure medium path to and from the rocking cylinder (21) two gate-controlled (scenes 119) shut-off valves (114, 117) are present, one of which in each case Limit positions of the rocking cylinder (21) is blocked. 20. Carousel according to claim 19, characterized in that the two Valves (114, 117) are bridged by check valves (115, 118), wherein the Check valve (115) that shuts off in the lower limit position of the gondolas Valve (114) bridged, pressure medium from the pressure oil ring line (91) to the rocking cylinder (21) and locks in the opposite direction while the check valve (118), which bypasses the valve (117) that shuts off the gondolas in the upper limit position, is switched so that it flows away the pressure medium from the rocking cylinder (21) leaves, but blocks in the opposite direction. 21. Carousel according to claim 20, characterized in that parallel a throttle point to the check valve (115) and the slide-controlled valve (114) (116) lies. 22. Carousel according to one or more of claims 17 to 21, characterized characterized in that between the inlet valve (107) and the rocking cylinder (21) a parallel connection of a throttle point (1o9) and a check valve (llo) is, the check valve (llo) is switched so that there is pressure medium from the pressure oil ring line (91) to the rocking cylinder (21) can flow, in reverse Direction blocks, however, and that in the reflux direction, d. H. from the rocking cylinder (21) to the inlet valve (107), a return line (129) to the outlet valve (130) branches off, which through the outlet valve (130) to the return oil ring line (loo) can be connected or is separated from it. 23. Carousel according to one or more of claims 17 to 22, characterized characterized in that in the direction of flow from the pressure oil ring line (91) to the Rocking cylinder (21) behind the control valve (112) is an adjustable pressure relief valve (126) is connected, the output of which is connected to the return oil ring line (loo) is. 24. Carousel according to claim 23, characterized in that the pressure limiting valve (126) is bridged by a check valve (127), which a pressure medium flow from the return oil ring line (loo) (preload pressure) to the rocking cylinder (21). 25. Carousel according to claim 23 or 24, characterized in that an orifice plate or throttle (125) in front of the inlet of the pressure relief valve (126) is upstream. 26. Carousel according to one or more of claims 17 to 25, characterized characterized in that the pressure medium inlet of the inlet valve (107) has an orifice or throttle (106) is connected upstream. 27. Carousel according to one or more of claims 4 to 26, characterized characterized in that the piston rod (52) of the lifting cylinder (28, 29) at its lower End has a collar (65) that the cylinder cover or the cylinder seal (54) has a corresponding recess (67), this recess in a Channel (68) opens, which opens into the preload pressure line (57) and that the cylinder seal (54) has an additional control pressure channel (70) which is connected to an adjusting device (72) for a hoist pump (73) is connected.