EP1886967A2 - Raised platform - Google Patents

Abstract

The working platform comprises a chassis upon which is arranged a telescopic support device (3) which is formed by support segments (7,8) which are at least partially nested one inside the other, and at least one adjusting device (25) in the form of a lift cylinder arrangement (26) is associated with a movable support segment. The support device is formed by three support segments, and the adjusting device is associated with the center segment (7).

Description

The invention relates to a work platform with a chassis according to the preamble of claim 1.

From the prior art such as the US 4,930,598 Working platforms are known in which a joint construction is used as a support means for the working platform, which is similar to a safety gate. By operating individual joint elements, it is possible to adjust the working platform in height. A disadvantage of such work platforms is the relatively high cost of materials and the fact that in the retracted state remains a relatively large residual height, since the scissors are supported in the transport position usually one above the other on a chassis frame.

These known disadvantages also work platforms are known, the suspension means telescopically off and can be retracted. Exemplary here on the DE 103 35 687 referenced, in which a working platform is disclosed, the working platform is connected via three telescopic suspension means with the chassis of the chassis. The telescopic support means are arranged crossing each other between the work platform and chassis, wherein at least two support means are positioned parallel to each other and the further support means is arranged between them. For extending and retracting the telescopic segments lifting cylinder arrangements are described, which are assigned to the respective support means in the region of its base tube. Since the base tube of the support means is in each case connected to the chassis of the chassis, such designs have the particular disadvantage that the piston rods of the lifting cylinder arrangements must cover very long ways to move the work platform from a transport position to a desired working position. A major disadvantage of such Hubmechanismen designed is that the lifting cylinder require a relatively large space and because of the long distance traveled by the piston rods paths small positional deviations in the bearings of the lifting cylinder can lead to significant tension in extended piston rod. The latter remedy, suggests the DE 103 35 687 among other things, to realize the extension and retraction movement of the support means segments at least partially via chain drives. Such drive but are structurally complex and also have the disadvantage that high-precision positioning of the work platform in the vertical direction can be realized only limited. In the in the DE 103 35 687 described embodiment, the precise positioning of the work platform is limited solely to the movement of the platform on the ground, since the landing gear of the platform so-called "Mecanum wheels" which are generally in accordance with the DE 38 41 971 are executed. Characteristic of such running wheels is that they comprise a wheel formed by mutually adjacent support members, the support members rotatably accommodate a plurality of rolling bodies between them and on a circumferential circle and the rolling bodies protrude at least partially over the circumference of the support members and their axes of rotation obliquely to Are aligned axis of rotation of the wheel body. By now such an impeller about its impeller axis and the rolling bodies are rotatable about their longitudinal axes, a chassis designed in this way can perform very precise changes in direction and allow in extreme cases, a turn on the spot or precise 90 ° change of direction of movement.

It is therefore an object of the invention to avoid the disadvantages of the prior art described and in particular to propose a working platform, which allows a precise positioning of the working platform in addition to a compact design.

This object is achieved by the characterizing features of claim 1.

By the working platform of adjusting means activatable, telescopic suspension means for the vertical deflection of a working platform relative to the chassis of the Includes working platform and the support means are formed by at least partially nested suspension element segments and the at least one adjustment is associated with a movable support means segment ensures that the platform has a space-saving compact design and also a very precise positioning of the working platform can be reached. The latter is particularly possible because now shorter adjustment can be used, the shorter adjustment also lead to shorter tolerance-related positional deviations, which ultimately significantly reduces constraints in the system or completely avoids.

A structurally simple implementation of the invention results in particular when the support means of three at least partially nested suspension element segments is formed and the at least one adjusting means is associated with the central support element segment.

In an advantageous embodiment of the invention, the adjusting means is designed as a lifting cylinder assembly comprising at least one coupled to the chassis of the chassis and a working platform with a piston rod, so that when pressurizing the Hubzylinderanordnung the working platform can be moved continuously relative to the chassis in the vertical direction, the vertical position change can be done very sensitively due to the running as a lifting cylinder adjustment.

A speedy and uniform operation of the work platform can be achieved if the lifting cylinder assembly is designed as a synchronous cylinder arrangement in such a way that the lifting cylinder assembly comprises a first lifting cylinder and another lifting cylinder, with one and the same movable support means segment and with each other via a conduit system in the manner are coupled, that the piston rod side pressure chambers and the piston surface side pressure chambers of the lifting cylinders are each connected to each other. This effect will be greatest when, according to an advantageous embodiment of the invention, all the piston rod side pressure chambers and all piston surface side Pressure chambers of the respective support means associated lifting cylinder are interconnected.

In order to avoid overloads and associated disturbances in the process of the work platform is provided in an advantageous embodiment of the invention that the line system of the lifting cylinder comprises at least a check valve and a pressure storage unit.

An optimal utilization of the limited available installation space also results when, according to an advantageous development of the invention, the pressure storage medium is guided within the piston rods of the adjusting means designed as a lifting cylinder.

To avoid coercive forces during the movement of the work platform, which would also have negative effects on a sensitive positioning of the work platform, it is further proposed that the lifting cylinder and / or connected to the chassis of the chassis and the working platform support means segments by means of pivot joints, preferably by means of ball joints the chassis and the work platform are connected. In this way, the lifting cylinder and the support means segments can move with a variety of degrees of freedom about their pivot points.

In a further advantageous embodiment of the invention, at least one pivot joint of a support means and / or a lifting cylinder is designed as a cross slide joint. This has the particular advantage that to compensate for tolerance-related positional deviations to avoid coercive forces, the various points of articulation of the lifting cylinder and the support means in addition to the pivotal movements and thrusting transverse to the longitudinal direction of the work platform can perform.

A space-saving and the work platform securely in the working position holding arrangement of the support means results in an advantageous embodiment of the invention then, if between chassis and work platform at least three Supporting means are provided, which intersect the work platform with the chassis, at least two suspension elements being arranged parallel to one another and at least one further suspension element being arranged between the suspension elements arranged in parallel.

So that the position of the work platform can be set very precisely and inclinations of the work platform can be approached precisely, is provided in a further advantageous embodiment that each support means is associated with a cable pull sensor in such a way that the guide cable detects the change in length of the respective support means. The positioning accuracy of the work platform is also improved by the fact that when moving the work platform and the inclination of the platform due to unevenness is taken into account. This can be achieved, for example, by assigning an inclination sensor for determining the working platform inclination to at least the chassis and / or the suspension elements and / or the work platform.

An effective, efficient and easily implementable processing of the detected change in length signals in a precise positioning of the working platform is achieved when the change in length of the respective support means is encoded in actual length signals and compared the actual length signals in a control unit with desired length signals and upon coincidence of the detected actual length signals with the predetermined setpoint length signals, stop signals for stopping the movement of the suspension element segments are generated by the control and regulation unit.

In an analogous manner, the precise positioning is also supported if, in an advantageous embodiment of the invention, the change in length of the respective support means is encoded in actual length signals and the actual length signals are compared in a control and regulation unit with nominal length signals and wherein the Comparison takes into account the inclination of the platform by tilt signals generated by the inclination sensors and wherein the control and regulation unit in accordance with the detected actual length signals with the predetermined target length signals Stop signals for stopping the movement of Tragmittelsegmente generated.

A high-precision positioning of the platform as such on the ground is achieved in an advantageous embodiment of the invention in that the chassis comprises a plurality of wheels and the wheels comprise a wheel formed by adjacent support members, the support elements lying between them and on a peripheral circle a Rotatably accommodate a plurality of rolling elements and the rolling bodies protrude at least partially over the circumference of the support elements and their axes of rotation are aligned obliquely to the impeller axis of the wheel body.

A precise positioning and safe driving of the work platform on a substrate is also supported if, in an advantageous embodiment of the invention, the outer contour of at least one rolling body has an elliptical shape and wherein the geometry of this ellipse to the geometry of the rolling bodies of the impeller at its Rotation is adapted to the wheel axis described cylindrical envelope.

The covering of precise driving paths on a substrate can also be optimized in that each impeller of the chassis is assigned at least one hydraulic motor to the active drive of the respective impeller and wherein the pressure oil medium is provided by an electrical control circuit, as hydraulic motors in addition to very slow speeds and very small rotation angle the wheels can implement.

In an advantageous embodiment of the invention, the chassis has paired wheels, wherein at least one of the paired wheels is associated with a wheel motor, so that the chassis on the one hand can support larger loads on the ground, but on the other hand remain the cost of the wheel drive system justifiable. In this context, it is also conceivable that each wheel is associated with a wheel motor, so that in addition to the rising production costs transfer significantly higher drive power and Consequently, larger masses can be moved from the work platform. A very energy-efficient drive structure is achieved when, in an advantageous development of the invention, a wheel motor is assigned to each paired impeller and the drive of at least one of the wheel motors of the paired impellers is limited to overcoming the rolling friction between the respective impeller and the ground, so that this impeller has no active drive function for the working platform.

By operating the electric control circuit operated by battery and a battery associated with the battery regulator provides only so much electrical energy that the delivery volume of the pressure oil medium just the power requirements of the driven wheels, it ensures that on the one hand, the storage capacity of the battery is optimally used and on the other hand, the wheels Almost ideal for implementing the required movements can be controlled.

To avoid rolling movements of the support means in the positioning of the work platform is provided in a further advantageous embodiment that the at least partially telescopically nested support means segments have a prismatic cross-section.

Figur 1

eine perspektivische Ansicht der erfindungsgemäßen Arbeitsbühne

Figur 2

eine Detaildarstellung eines Tragmittels der Arbeitsbühne

Figur 3

eine Seitenansicht der erfindungsgemäßen Arbeitsbühne

Figur 4

eine Detailansicht eines Laufrades der erfindungsgemäßen Arbeitsbühne

Further advantageous embodiments are the subject of further subclaims and are described below with reference to an embodiment shown in several figures. Show it:

FIG. 1

a perspective view of the work platform according to the invention

FIG. 2

a detailed representation of a support means of the work platform

FIG. 3

a side view of the working platform according to the invention

FIG. 4

a detailed view of an impeller of the working platform according to the invention

Fig. 1 shows a perspective view of an embodiment of a working platform 1 with a chassis 2, to which three support means 3, 4, 5 are pivotally mounted. The Supporting means 3, 4, 5 are formed as from support means segments 6, 7, 8 assembled telescopic masts, at the ends of a working platform 9 is attached. The ends of the support means 3, 4, 5 are articulated hinged to the underside of the working platform 9, so that by extending or retracting the support means segments 6, 7, 8, a vertical movement of the working platform 9 is made possible.

The articulated connection of the support means 3 - 5 with the chassis 2 and the work platform 9 is realized via pivot joints 10 to be described later. In the illustrated embodiment, two support means 3, 4 are arranged parallel to each other and arranged by means of the pivot joints 10 on the chassis 2 and the work platform 9 in such a way that these support means 3, 4 approximately diagonally from one side of the chassis 2 to the opposite side of the platform. 9 extend. Between these support means 3, 4 crossing a third support means 5 is passed, which is articulated pivotably at the other end of the chassis 2 and the opposite end of the working platform 9. In the illustrated embodiment, the working platform 9 is shown in a raised position, wherein it can be seen that the arrangement of the platform-side ends of the support means 3 - 5 and symmetrical to the central axis 11 of the rectangular working platform 9, a three-point support of the working platform 9 is realized. This leads to a stable mounting of the working platform 9 both during a vertical movement and in the held state.

Further, in the illustrated embodiment, the chassis 2 is formed by individually in the chassis 12 of the chassis 2 hinged wheels 13.

According to the enlargement in Figure 1, the wheels 13 are designed as so-called Mecanum wheels. The wheel body 14 of such wheels 13 includes in addition to the only dash-dotted illustrated impeller axis 15 on both sides of the impeller width limiting, adjacent to each other arranged support members 16, 17, which are rotatably connected to the impeller axis 15. The support members 16, 17 are interspersed at regular intervals by lying on a common circumferential circle openings 18, wherein the openings 18 of not shown Bearing seats of the peripheral surface of the impeller 13 associated rolling elements 19 are penetrated. The rolling elements 19 are each freely rotatably received by the support elements 5, 6, wherein the axis of rotation 20 of each rolling body 19 is arranged at an angle to the impeller axis 15 of the respective impeller 13 and this inclination of the rolling elements 19 by the resulting angle α in the front view between said impeller axis 15th and the respective axis of rotation 20 results. By the impeller 13 on the one hand to rotate around its own impeller axis 15 in the direction of arrows 21 in the counterclockwise direction and on the other hand, each roller body 19 rotates about its axis of rotation 20 in the direction of arrow 22 also in the counterclockwise direction or, is provided with such wheels 13 vehicle, in a known manner able to perform very precise movements in different directions of movement. The wheel members 14 on both sides associated support members 16, 17 are also formed in their radially outer regions so-called shielding 23 which extend at least partially in the area between adjacent rolling elements 19 so that the resulting between successive rolling elements 19 free spaces 24 are largely shielded. This prevents in particular that lying on the run over by the impeller 13 floor obstacles can not penetrate into these spaces 24 and damage the impeller 13.

In Fig. 2, the arrangement of the retraction and extension of the support means segments 6 - 8 effecting adjusting means 25 is now described using the example of the support means 3. In Figure 2, the adjusting means 25 is designed as a double-acting lifting cylinder 26, the cylinder body 27 via one or more flange 28 is fixed to the frame but releasably connected to the middle, movable support member segment 7. The lower, with the chassis 12 of the chassis 2 hingedly connected Tragmittelsegment 6 passing piston rod 29 is connected in the simplest case also via the hinge connection 10 of the lower suspension element 6 on the chassis 12 of the chassis 2. In an analogous manner, the upper, with the working platform 9 hingedly connected Tragmittelsegment 8 passing through the piston rod 30 in the simplest case also via the hinge connection 10 of the upper support element segment 8 at the Work platform 9 attached. Further, the cylinder body 27 is associated with a divider 31 which blocks the piston surface side pressure chambers 32, 33 of the lifting cylinder 26 against each other, so that the piston rod movements do not affect each other. Because of the divider 31, all piston rod side pressure chambers 34, 35 and piston surface side pressure chambers 32, 33 each have at least one inlet nozzle 36-39 via an oil flow 40 the lifting cylinder 26 to or can be removed from this.

Depending on whether the piston rod-side pressure chambers 34, 35 or the piston surface-side pressure chambers 32, 33 are pressurized, the piston rods 29, 30 either travel into or out of the cylinder body 27. Because of the articulated connection 10 of the piston rods 29, 30 and the lower or upper Tragmittelsegment 6, 8 with the chassis 12 or the work platform 9 lead the pressurization or pressure relief for telescoping the at least partially nested support means segments 6-8 against each other. Extend the piston rods 29, 30 from the work platform 9 is moved in the vertical direction upwards, while the retraction of the piston rods 29, 30, the working platform 9 is moved from a working position to a transport position on the chassis 12 of the chassis 2.

By now each of the piston rod side pressure chambers 34, 35 and the kobenflächenseitigen pressure chambers 32, 33 of the lifting cylinder 26 are short-circuited, the interconnected pressure chambers 32-35 are each pressurized simultaneously with an oil flow 40 or depressurized, so that the lifting cylinder 26 operates as a synchronizing cylinder. With respect to one and the same support means 3-5 associated lifting cylinder 26 is thereby a nearly uniform extension or retraction of the piston rods 29, 30 of a lifting cylinder 26 causes, so that the displaceable Tragmittelsegmente 6-8 cover almost the same way. Now, if each of the piston rod-side pressure chambers 34, 35 and the kobenflächenseitigen pressure chambers 32, 33 of all the various support means 3-5 associated lifting cylinder 26 are coupled together, this has the advantage that all support means 3-5 when pressurizing or depressurizing the lifting cylinder 26 is almost the same Experience length change so that Tension due to different changes in length of the individual suspension elements 3-5 can be avoided.

To avoid or dampen load-dependent pressure peaks, the hydraulic circuit 41 supplying the lifting cylinder 26 may comprise at least one check valve 42 and / or an accumulator 43. In an analogous manner, according to the right-hand illustration in FIG. 2, the lifting cylinder 26 can also be replaced by two double-acting lifting cylinders 26a, 26b, wherein each of these lifting cylinders 26a, b is assigned to the movable supporting means segment 7 by means of a suitable number of the flange connections 28 already described. Depending on the design of the suspension element segments 7, the lifting cylinder or cylinders 26, 26a, 26b may be associated with the movable suspension element segment 6 on the inside or outside. In analogy to the one-piece lifting cylinder 26 and the paired lifting cylinders 26a, 26b may be integrated into the hydraulic circuit 41, that each of the piston rod side pressure chambers 34, 35 and the piston surface side pressure chambers 32, 33 of the respective lifting cylinder 26b, a are connected to each other, so that the respective pressure chambers 32-35 at the same time by means of an oil flow 40 pressurized or relieved of pressure by discharging an oil flow 40. It is within the scope of the invention that the lifting cylinders 26, 26a, 26b can also be arranged freely floating between the pivot joints 10, so that no matter how designed flange 28 can be dispensed with.

Because of the limited space available inside and outside the support means 6-8 can in an advantageous embodiment of the invention, the piston rods 29, 30 of the lifting cylinder 26, 26a, 26b in their interior bores 44 for guiding the oil flow 41 in the interior of the lifting cylinder 26, 26a, 26b have.

Because of the sometimes long travel paths 45 between the end positions of the working platform 9, the already described pivot joints 10 can be designed as known per se and therefore not shown ball joints 46, so that the piston rods 29, 30 and the respective Tragmittelsegmente 6, to avoid tolerance-related constraining forces, 8 with great degree of freedom in the Swivel joints 10 can be moved. The effect of compensating for positional deviations is also further increased if at least one pivot joint 10 of the suspension element segments 6-8 and the lifting cylinders 26, 26a, 26b are designed as so-called per se known and therefore unspecified cross slide joint 67. This has the particular advantage that members coupled with a cross slide joint 67 can realize a transverse displacement in addition to the pivoting movement, so that the respective support means segment 6-8 and / or the lifting cylinders 26, 26a, 26b can be displaced transversely to the longitudinal direction of the work platform 1 for position compensation.

Fig. 3 shows schematically the setting of the desired position of the working platform 9. A particularly precise vertical positioning of the working platform 9 is achieved when each support means 3-5 is associated with a so-called cable pull sensor 47. In a manner known per se cable pull sensors 47 are formed so that a guide cable 48 is used for the detection of changes in length. In the illustrated embodiment, the swivel joints 10 associated with the chassis 12 are assigned to each suspension means 3-5 pulleys 49 for storing the guide cable 48. At the other end, the guide cable 48 is connected to the working platform 9. This can, as shown, take place in that the guide cable 48 is also coupled on the work platform side with the pivot joints 10 of the suspension elements 3-5. In known manner, the rotational movement of the pulleys 49 and the winding diameter of the guide cable 48 is detected on the respective pulley 49. From this information, the actual length of the unwound guide cable 48 is determined in a control and regulating unit 50 and finally determines the position of the working platform 9 in the room because of the known geometry of the platform 1.

The control unit 50 is usually designed so that it also controls the definition of a length to be handled of the respective guide cable 48, the extension and retraction of the support means 3-5, so depending on the definition of these lengths, the working platform 9 in A variety of vertical positions is movable, wherein the working platform 9 can take in different vertical positions flat or inclined orientations. It would be possible in In this context, that the support means 3-5 and / or the chassis 12 and / or the working platform 9, preferably the chassis 12 also known per se, only symbolically shown inclination sensors 51 are assigned to the beyond of the inclination of the bottom 52nd dependent inclination of the platform 1 detected and this information in the control unit 50 in the positioning of the working platform 9 are taken into account. This has the particular advantage that regardless of the flatness of the bottom 52 is always a nearly horizontal position of the working platform 9 in the room can be reached.

A simple technical implementation of this control and regulating process would be realized in a conventional manner by when the change in length of the respective suspension 3-5 is encoded in length change signals X and the length change signals X in the control unit 50 with desired length change signals Y. are compared and in accordance with the detected change in length with the predetermined target length change stop signals Z to stop the movement of Tragmittelsegmente 6-8 are generated. In the simplest case, the stop signals Z lead to the interruption of the oil flow 40 in the hydraulic circuit 41 shown in FIG. 2. In an analogous manner, the inclination signals W generated by the inclination sensors 51 can be taken into account in the control unit 50 during the generation of the stop signals Z.

In addition to the precise positioning of the working platform 9 in the vertical direction plays at the same time the precise positioning of the platform 1 in the room a major role. This will be all the more possible, the more sensitive the chassis 12 can be moved on the ground. By now each wheel 13 is associated with a wheel motor 53, each wheel 13 can first be controlled individually, with wheel motors 53 are usually controlled so that the respective wheel motor 53 associated impeller 13 with extremely low speed and only to extremely small rotation angle is movable, so that the platform 1 can ultimately be moved very precisely even over very short distances. In the illustrated embodiment, the wheel motors 53 are designed as hydraulic motors 54, wherein the hydraulic pump 56 integrated in the hydraulic circuit 56 is controlled via an electric control circuit 57 in a manner known per se so that the individual wheels 13 can be supplied with pressure oil independently of one another. Since such work platforms 1 typically comprise a battery system 58 as an energy source, the efficient use of energy plays a significant role in minimizing time-consuming charging processes. From this point of view, the electric battery system 58 has at least one battery regulator 59 which controls the energy output of the battery 58 in such a way that only so much electrical energy is provided by the battery 58, that the delivery volume of the pressure oil medium just the power requirement of the wheel motors 53 to drive the respective impeller 13 corresponds. According to the detailed view B in Fig. 3, the chassis 2 of the work platform 1 may be designed so that the wheels 13 are arranged in pairs, each wheel 13, a wheel motor 53 a, 53 b is assigned. In this context, it is conceivable that one of the paired wheel motors 53a, 53b provides only so much drive energy for its associated impeller 13 that just the rolling friction of the impeller 13 on the bottom 52 is overcome, the impeller 13 itself but no active Drive the platform 1 causes. From the viewpoint of reducing manufacturing costs, however, it is also conceivable that only one of the paired impellers 13, a wheel motor 53 a, 53 b is assigned, so that the further impeller 13 always takes only a support function but no drive function. By all wheels 13 but are designed as so-called Mecanum wheels remains in any case, the highly flexible movement of the platform 1 is obtained.

A high rigidity of the support means 3-5 and a precise guidance of the respective support means segments 6-8 is also achieved if the support means segments 6-8 according to the detail A in Fig. 3 have a prismatic cross-section 66.

As described above, the wheels 13 are designed as so-called Mecanum wheels, because of the arranged on the circumference of each impeller 13 rolling body 19 and the associated superposition of rotational movements of the wheel body 14 and the rolling body 19 a very precise guidance of the platform 1 on the Enable soil. This high precision, coupled with a great quietness and low wear of such wheels 13 is also still promoted when the rollers 19 of the wheels 13 are designed as described in Fig. 4.

According to FIG. 4, when the impeller 13 rotates about its impeller axis 15, the rolling elements 19 assigned to the impeller 13 describe a cylindrical envelope 60. Due to the fact that the axes of rotation 20 of the rolling elements 19 and the impeller axis 15 of the respective impeller 13 are not aligned with each other, i. are aligned in the space not parallel to each other, sweeps over rotation of the impeller 13, each roller body 19, the bottom 52 in such a way that first the upstream in the direction of rotation area and then reach the downstream areas of each roller 19 in contact with the bottom 52. In this rolling movement finally results in a contact zone between the rolling body 19 and bottom 52, which is formed by a rolling track lying in space 61, wherein the points of the rolling track 61 each represent the points of contact between the bottom 52 and the running surface 62 of the respective rolling body 19.

The oblique arrangement of the rolling elements 19 to the impeller axis 15 causes a section through the envelope 60 in the orientation direction of the rotation axis 20 of a rolling body 19 causes a section line 63 with an elliptical contour. This cutting line 63 also forms the shape of the rolling track 61, which would have to be achieved so that a rolling body 19 sweeping over the floor 52 has permanent contact with the floor 52. By now the outer contour 64 of the respective rolling body 19 has an elliptical shape 65 which corresponds to the elliptical contour of the section line 63 through the envelope 60, this permanent contact of the respective rolling body 19 is made possible on the ground 52, since this section line 63 of the optimal rolling track 61st equivalent.

Reference number list:

1 platform 31 divider 2 landing gear 32 piston surface side pressure chamber 3 support means 33 piston surface side pressure chamber 4 support means 34 piston rod-side pressure comb 5 support means 35 piston rod-side pressure comb 6 Carrying means segment 36 inlet connection 7 Carrying means segment 37 inlet connection 8th Carrying means segment 38 inlet connection 9 working platform 39 inlet connection 10 pivot 40 oil flow 11 central axis 41 Hydraulic circuit 12 chassis 42 check valve 13 Wheel 43 accumulator 14 Wheel center 44 drilling 15 wheel axle 45 traverse 16 supporting member 46 ball joint 17 supporting member 47 wire sensor 18 opening 48 guide rope 19 roll body 49 pulley 20 axis of rotation 50 Control unit 21 arrow 51 tilt sensor 22 arrow 52 ground 23 shielding 53 wheel motor 24 free space 54 hydraulic motor 25 adjustment 55 Hydraulic circuit 26 lifting cylinder 56 hydraulic pump 27 cylinder body 57 electrical control circuit 28 flange 58 battery 29 piston rod 59 battery controller 30 piston rod 60 envelope 61 rolling track 62 tread 63 intersection 64 outer contour 65 elliptical shape 66 prismatic cross-section W tilt signal X Actual length signal Y Target length signal Z stop signal

Claims (21)

Platform with a chassis on which at least one telescopic suspension element is arranged with one end, wherein on the other end facing away from the suspension of the support means is arranged a working platform and wherein the support means is assigned at least one adjusting means for extending and retracting the suspension element,
characterized,
in that the suspension element (3-5) is formed by carrier element segments (6-8) which are at least partially nested in one another and the at least one adjusting means (25) is associated with a movable suspension element segment (7, 8). Work platform with a chassis according to claim 1,
characterized,
in that the suspension element (3-5) is formed by three suspension element segments (6-8) which are at least partially nested in one another and the at least one adjustment means (25) is associated with the central suspension element segment (7). Work platform with a drive according to one of the preceding claims,
characterized,
in that the adjusting means (25) is designed as a lifting cylinder arrangement (26, 26a, 26b) which comprises at least one piston rod (29, 30) coupled to the chassis (12) of the running gear (2) and to a working platform (9). Work platform with a chassis according to claim 3,
characterized,
in that the lifting cylinder arrangement (26, 26a, 26b) comprises a first lifting cylinder (26, 26a) and a further lifting cylinder (26, 26b) with one and the same movable carrying means segment (7) and with each other via a line system (41) in such a way are coupled, that in each case the piston rod side pressure chambers (34, 35) and the piston surface side pressure chambers (32, 33) of the lifting cylinder (26, 26 a, 26 b) connected to each other are. Work platform with a chassis according to claim 4,
characterized,
in that the line system (41) comprises at least one check valve (42) and a pressure storage unit (43). Work platform with a drive according to one of claims 4 and 5,
characterized,
in that the piston rod-side pressure chambers (34, 35) and the piston surface-side pressure chambers (32, 33) of the lifting cylinders (26, 26a, 26b) assigned to the respective suspension elements (3-5) are connected to one another. Work platform with a drive according to one of the preceding claims,
characterized,
in that the pressure storage medium (40) is guided within the piston rods (29, 30) of the adjusting means (25) designed as lifting cylinders (26, 26a, 26b). Work platform with a drive according to one of the preceding claims,
characterized,
in that the lifting cylinders (26, 26a, 26b) and / or the support means segments (7, 9) connected to the chassis (12) of the running gear (2) and the work platform (9) are connected to the chassis by means of pivot joints (10), in particular ball joints (12) and the working platform (9) are connected. A work platform with a drive according to claim 8,
characterized,
in that at least one pivot joint (10) of a suspension element (3-5) and / or a lifting cylinder (26, 26a, 26b) is designed as a cross slide joint (67). Work platform with a drive according to one of the preceding claims,
characterized,
that between the chassis (2) and work platform (9) at least three suspension elements (3-5) are provided, which intersect the work platform (9) with the chassis (2) connect, wherein at least two support means (3, 4) are arranged parallel to each other and at least one further support means (5) between the parallel arranged support means (3, 4) is arranged. Work platform with a drive according to one of the preceding claims,
characterized,
that each support means (3-5) a cable sensor (47) is associated in such a way that the guide cable (48) detects the change in length of the respective support means (3-5). Work platform with a drive according to one of the preceding claims,
characterized,
in that at least the chassis (2) and / or the suspension elements (3-5) and / or the work platform (9) is assigned an inclination sensor (51). Platform with a chassis according to claim 11,
characterized,
in that the change in length of the respective suspension element (3-5) is coded in actual length signals (X) and the actual length signals (X) in a control and regulation unit (50) are compared with desired length signals (Y) and, if they match detected actual length signals (X) with the predetermined desired length signals (Y) stop signals (Z) for stopping the movement of Tragmittelsegmente (6-8) are generated by the control unit (50). Work platform with a chassis according to claims 11 and 12,
characterized,
in that the change in length of the respective suspension element (3-5) is coded into actual length signals (X) and the actual length signals (X) in a control and regulation unit (50) are compared with desired length signals (Y) and wherein the comparison the inclination of the work platform (1) is taken into account by inclination signals (W) generated by the inclination sensors (51), and wherein the control unit (50) if the detected actual length signals (X) agree with the predetermined nominal length signals (Y), stop signals (Z) for stopping the movement of the suspension element segments (6-8) are generated. Work platform with a drive according to one of the preceding claims,
characterized,
in that the running gear (2) comprises a multiplicity of running wheels (13) and the running wheels (13) comprise a wheel body (14) formed by mutually adjacent supporting elements (16, 17), wherein the supporting elements (16, 17) between them and on one Peripheral circle lying a variety of rolling bodies (19) rotatably receive and the rolling bodies (19) at least partially beyond the circumference of the support members (16, 17) protrude and their axes of rotation (20) obliquely to the impeller axis (15) of the wheel body (14) are aligned. A work platform with a chassis according to claim 15,
characterized,
in that the outer contour (64) of at least one rolling body (19) has an elliptical shape (65) and the geometry of this ellipse (65) matches the geometry of the rolling bodies (19) of the running wheel (13) as it rotates about the running wheel axis ( 15) described cylindrical envelope (60) is adapted. Work platform with a drive according to one of the preceding claims,
characterized,
in that each impeller (13) of the chassis (2) is assigned at least one hydraulic motor (54) for actively driving the respective impeller (13) and wherein the pressurized oil medium is provided by an electrical control circuit (57) Work platform with a drive according to one of the preceding claims,
characterized,
that the running gear (2) arranged in pairs running wheels (13) and at least one of the pairs of wheels (13), a wheel motor (53) assigned. A work platform with a chassis according to claim 18,
characterized,
in that a wheel motor (53a, 53b) is associated with each of the paired running wheels (13), and wherein the drive of at least one of the wheel motors (53a, 53b) of the paired running wheels (13) is aimed at overcoming the rolling friction between the respective running wheel (13). and the floor (52) is limited. Platform with a chassis according to claim 17,
characterized,
in that the electrical control circuit (57) operates by means of battery (58) and a battery regulator (59) assigned to the battery (58) provides only enough electrical energy so that the delivery volume of the pressurized oil medium corresponds precisely to the power requirement of the driven running wheels (13). Work platform with a drive according to one of the preceding claims,
characterized,
that the at least partially telescopically nested support means segments (6-8) has a prismatic cross-section (66).

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