DE29700496U1 - Scissor lift system for work platforms - Google Patents

Abstract

Each stack (5) of scissors consists of an outer pair of scissors arms (7), intersected by a scissors arm joined to the intersection point (13) by an axle crosswise to the lifting direction. The underneath ends (9) of the scissors arms of the scissors stack above it are attached to the top ends (10) of the scissors arms (8) of the scissors stack underneath. At least one lifting cylinder (14) has an effective axis touching the inner scissors arm at an acute angle, near the lowest scissors stack. At least one auxiliary cylinder (17,21) is positioned in the lifting direction between two link points (18,19,23,24) which are splayed apart during lifting.

Description

Scissor lifting system for work platforms

The invention relates to a scissor lifting system for work platforms with a plurality of identical scissor packs arranged one above the other, each of which consists of an outer pair of scissor arms and a scissor arm arranged in between, which is articulated at the intersection point with the pair of scissor arms via an axis lying transversely to the lifting direction, wherein the lower ends of the scissor arms of the scissor pack above them are articulated to the upper ends of the scissor arms of the lower scissor pack in each case and there is at least one lifting cylinder which, in the area of the lowermost scissor pack, engages the inner scissor arm with its effective axis at an acute angle and is mounted against it in a frame-mounted manner.

With scissor lifting systems of this type, the aim is to achieve ever greater working heights, which means that the number of scissor packages arranged one above the other must be increased accordingly. However, the number of scissor packages also increases the forces required.

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which must be applied by the lifting cylinder in order to erect the scissor frame. Furthermore, due to the increasing weight of the scissor frame, this means that when lifting in the lowered position, the individual scissor packages are not erected synchronously. Rather, the lower scissor packages deform first, and primarily the scissor package at the bottom, because in the usual steel design, their scissor arms bend elastically. Since the lifting forces transferred from one scissor package to the next upper one become smaller as the frame is raised, a spring-elastic erection of the scissor frame takes place within certain limits, which cannot be precisely controlled, which is why certain working heights cannot be reached precisely in the lower erection area. This is particularly noticeable in scissor lift frames that have more than four scissor packages.

For this reason, in the case of scissor scaffolds for work platforms, which also have pairs of scissor arms on the inside, whose scissor arms are arranged at a distance from one another, it has already been decided to provide an additional lifting cylinder between the inner scissor arms above the lower lifting cylinder. However, this is not possible with a scissor lifting system of the generic type, because this is a so-called three-part system, in which a scissor package consists of an outer pair of scissor arms and a single scissor arm crossing between them, with these three scissor arms being arranged close together when viewed in the projection of the lifting direction.

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are arranged. Consequently, there is no usable space between the external scissor arms in such a three-part system, and the lifting cylinder required for erecting the scissor frame can only be installed under the single scissor arm located at the bottom. For reasons of space, this lifting cylinder forms a very acute angle with the scissor arm to which it is attached, which is only a few degrees in the lowered end position of the scissor lifting frame, which is why the high erecting forces are required for the initial lifting movement.

The invention is based on the object of creating a scissor lifting system for work platforms of the type mentioned at the beginning, in which the lifting cylinder and the lower scissor packages are relieved during the initial erection and at low erection heights.

This object is achieved in a scissor lifting system for work platforms of the generic type according to the invention in that at least one auxiliary cylinder is arranged in the lifting direction between two articulation points which spread apart from one another during the lifting.

It is essential for the invention that, when the scissor lift is in the usual vertical position, the auxiliary cylinder also acts in this vertical direction, in which, especially when the position is low, far less lifting force is required than with the inclined lifting cylinder. This means that even with relatively low auxiliary forces,

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forces on both the lifting cylinder and the lower scissor arms of the scissor lift frame are effectively relieved, which also means that the size of the lifting cylinder can be reduced. It goes without saying that the lifting cylinder and the auxiliary cylinder are controlled synchronously, which is particularly important for the first use of force when lifting the scissor lift frame from its lower end position. The new scissor lift frame can therefore easily be designed with six or more scissor packages arranged one above the other.

Such a lifting cylinder can be arranged under the lowest scissor package; instead of this or in addition, auxiliary cylinders can also be provided on the outside of the scissor lift frame, in particular between the scissor packages located further up. The auxiliary cylinders arranged on the upper, external scissor arms of the scissor packages relieve the load on the scissor packages located further down, especially when the scissor lift frame is initially or only slightly raised, which can significantly reduce the elastic deformation of the scissor lift frame. This means that low erection heights can be reached precisely with the new scissor lift system.

In principle, it is not necessary to use auxiliary cylinders to support the erection of the scissor lift over the entire erection path. This is because the forces to be applied by the lifting cylinder decrease with increasing erection, and from a certain erection height onwards, the lifting cylinder is able to apply the forces for further erection of the scissor lift alone. Instead of using

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Telescopic cylinders allow the auxiliary cylinders to be designed for a stroke less than the maximum between the articulation points on the scissor lift frame, whereby the cylinder tube or the piston rod of the relevant auxiliary cylinder is loosely connected to one of its two articulation points in the direction of the stroke. Once the maximum extension of the auxiliary cylinder has been reached, the scissor lift frame can be further raised using the lifting cylinder, whereby the articulation point at which there is only a loose connection to the auxiliary cylinder is then moved away from its articulation device. In order for this articulation point to be able to reconnect with the relevant auxiliary cylinder when lowering, a safety device is provided on it or on the auxiliary cylinder itself, which automatically establishes engagement between the articulation point and the auxiliary cylinder when the scissor lift frame is lowered.

Further advantageous features of the invention emerge from the subclaims.

The invention is explained in more detail below with reference to an embodiment example and the drawing.

Fig. 1 shows the side view of a scissor lift system carrying a work platform and

Fig. 2 shows the front view of the scissor lifting system according to Figure 1.

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Fig. 1 shows in detail a chassis 1 with a support frame 2 on which a scissor lift 3 is arranged. At the upper end, the scissor lift 3 carries a work platform 4, which can be moved in height between the lower end position and the upper, erected end position of the scissor lift 3.

The scissor lifting frame 3 consists of identical scissor packs 5 arranged one above the other, each of which consists of scissor arm pairs 6 with external scissor arms 7 and internal scissor arms 8. The scissor arms 7 of each scissor arm pair 6 are congruent with one another when viewed in the transverse direction and are spaced just such that the internal scissor arms 8 are arranged between them with sufficient play. This results in a so-called three-part system for the scissor lifting frame 3, as can be seen in particular in the front view of Fig. 2. The lower ends 9 of the external scissor arms 7 of the scissor arm pairs 6 are each connected in an articulated manner to the upper ends 10 of the internal scissor arms 8, and the lower ends 12 of the internal scissor arms 8 are also articulated between the upper ends 11 of the external scissor arms 7. The outer scissor arms 7 of the scissor arm pairs 6 and the inner scissor arms 8 of a scissor package 5 are coupled together in an articulated manner at intersection points 13 by means of a through-passed axle or the like, each halfway along their length. As can be seen from the number of these intersection points 13, among other things, the scissor lifting frame 3 is one that is equipped with a total of six scissor packages 5.

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The main drive for raising and lowering the scissor lift frame 3 is carried out by a lifting cylinder 14, which is arranged on the chassis 1 or support frame 2 at a pivot point 15 in the middle of the scissor lift frame 3 in the transverse direction and which engages with its piston rod at a bearing point 16 on the underside of the lowest scissor arm 8. The effective axis of the lifting cylinder 14 takes up a very acute angle to this lower, inner scissor arm 8, which on the one hand saves construction height, but on the other hand requires increased lifting forces when raising the scissor lift frame 3 from the lower end position.

An auxiliary cylinder 17 is arranged centrally under the scissor lift frame 3 on the support frame 2, which is suspended there in a pendulum manner at a pivot point 18. The auxiliary cylinder 17's piston rod engages an upper pivot point 19, which is located on the underside of the lowest, inner scissor arm 8. The direction of action of the auxiliary cylinder 17 is in the lifting direction of the scissor lift frame 3, usually in the vertical direction. The direction of action of the auxiliary cylinder 17 is therefore arranged exactly in the vertical plane in which the crossing points 13, which spread apart from one another when the scissor lift frame 3 is lifted, are located. Unlike the lifting cylinder 14, which only acts on the scissor lift frame 3 with its smaller force component in the lower starting position, the full force of the auxiliary cylinder 17 acts in the vertical lifting direction. In particular, the auxiliary cylinder 17 supports the initial lift of the scissor lift mast 3 from its lowered position, and since with increasing erection angle of the

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Scissor arms 7, 8, the vertical force component of the lifting cylinder 14 increases, from a certain erection height of the scissor lift mast 3, this alone can generate the further lifting forces up to the upper end position of the erected scissor lift mast 3. It is therefore sufficient if the auxiliary cylinder 17 is only effective over the initial lifting path of the scissor lift mast 3, which means that the auxiliary cylinder 17 can save on overall length. Thus, from a certain erection height, the piston rod of the auxiliary cylinder 17 at the articulation point 19 comes out of engagement with the scissor arm 8 located at the bottom, and so that when the scissor lift frame 3 is lowered, the end of the piston rod of the auxiliary cylinder 17 safely engages again at the articulation point 19, there is a suitable catch device 20 on the underside of the inner swivel arm 8, which ensures an exact adjustment of the auxiliary cylinder 17 when engaging the articulation point 19.

Further up on the scissor lift frame 3, between the second and third scissor packs 5, there are two further auxiliary cylinders 21, which are arranged on the outside of the external scissor arms 7 of the relevant scissor arm pairs 6. These auxiliary cylinders 21 have the same vertical direction of action as the auxiliary cylinder 17, their lower articulation points 24 are at the level of the crossing points 13 of the lower scissor pack 5, while the upper articulation points 23 of the auxiliary cylinders 21 are in the area of the crossing points of the upper scissor pack 5. The piston rods 22 of these auxiliary cylinders 21 also have a
Safety gear 25 so that the loose linkage 23

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from a certain height during further lifting. In the opposite direction of movement, it is also ensured that the articulation point 23 again safely engages with the respective piston rod 22 of the relevant auxiliary cylinder 21.

In the embodiment, the two auxiliary cylinders 21 are arranged mirror-symmetrically to one another at the same height of the scissor lift frame 3, which is not absolutely necessary. In principle, both the upper auxiliary cylinders 21 and the lower auxiliary cylinder 17 can be arranged offset from the transverse center plane running in the vertical direction; the only decisive factor is that the articulation points 18 and 19 for the lower auxiliary cylinder 17 and the articulation points 23 and 24 for the upper auxiliary cylinders 21 move away from one another in the vertical direction when the scissor lift frame 3 is erected. In particular, the upper auxiliary cylinders 21 arranged in pairs can also be provided at the ends of the scissor arms 7, 8, because there are also articulation points with an axis running through the scissor arm ends, which can be used to link the auxiliary cylinders 21 if extended appropriately beyond the outsides of the outer scissor arms 7.

Instead of the auxiliary cylinders 17, 21, as shown in the drawing, cylinders can also be used that cover the entire stroke between the two articulation points. Telescopic cylinders are then used for this.

Claims (12)

PATENT ATTORNEYS · · · saddeSBauwer.strasse 20 DlPL- ING. BODO THIELKING phone: (0521) 6O621 DIPL.- ING. OTTO ELBERTZHAGEN fax: (0521) 173725 TELEX: 932059 attorney d POSTAL ACCOUNT HANNOVER
(Bank code 25010030) 3091 93-302 ATTORNEY FILE: O 2 U -5 date: 13.01.1997/HÜ Protection claims : 1. Scissor lifting system for work platforms with a plurality of identical scissor packs arranged one above the other, each consisting of an outer pair of scissor arms and a scissor arm arranged in between, which is connected in an articulated manner to the scissor arm pair at the intersection point via an axis lying transversely to the lifting direction, whereby the lower ends of the scissor arms of the scissor pack above are articulated to the upper ends of the scissor arms of the lower scissor pack and at least one lifting cylinder is present, which in the area of the lowermost scissor pack engages with its effective axis at an acute angle on the inner scissor arm and is fixed to the frame, characterized, that at least one auxiliary cylinder (17, 21) is arranged in the stroke direction between two articulation points (18, 19; 23, 24) which spread apart from one another during the stroke. 2. Scissor lifting system according to claim 1,
characterized, that the at least one auxiliary cylinder (17, 21) in the respective 5203 is arranged in a transverse plane running in the vertical direction or close to this transverse plane in which the crossing points (13) of the scissor arms (7, 8) are located. 3. Scissor lifting system according to claim 1,
characterized, that the auxiliary cylinder (17) is arranged between the support frame (2) and the intersection point (13) of the swivel arms (7, 8) of the lowest scissor package (5). 4. Scissor lifting system according to claim 3,
characterized, that the auxiliary cylinder (17) is arranged centrally under the scissor arm (8) located between the outer scissor arm pair (6). 5. Scissor lifting system according to one of claims 1 to 4, characterized in that two auxiliary cylinders (21) are arranged on the outsides of the external scissor arm pairs (6) of two scissor arm packages (5). 6. Scissor lifting system according to claim 5,
characterized, that the auxiliary cylinders (21) are arranged on the scissor arm pairs (6) of two adjacent scissor packages (5). 7. Scissor lifting system according to claim 5 or 6, characterized in that the auxiliary cylinders (21) are arranged on the scissor arm pairs (6) of the two uppermost scissor packages (5). —3— 8. Scissor lifting system according to one of claims 5 to 7, characterized in that the auxiliary cylinders (21) are arranged at least in one of the transverse planes running in the vertical direction or close to at least one of these transverse planes which pass through the joints at the ends of the scissor arms (7, 8). 9. Scissor lifting system according to one of claims 1 to 8, characterized in that the auxiliary cylinders (21) are arranged in the area of the outlet end for the piston rod (22) in a pendulum manner on the relevant pair of scissor arms (6). 10. Scissor lifting system according to one of claims 1 to 9, characterized in that the auxiliary cylinders (17, 21) are designed for a stroke less than the maximum between the mutually spreading articulation points (18, 19; 23, 24) and are loosely connected to one of the two articulation points (19, 23) in the stroke direction. 11. Scissor lifting system according to claim 8,
characterized, that a safety device (20, 25) is arranged on the loose articulation point (19, 23) on the relevant scissor arm pair (6) and/or on the relevant lifting cylinder (17, 21) to ensure safe connection during the lowering process. 12. Scissor lifting system according to one of claims 1 to 9, characterized in that the auxiliary cylinders (17, 21) are telescopic cylinders.