EP3476792A1 - Scissors lift - Google Patents

Abstract

A scissor lift, in particular Riemenhubtisch or Spindelhubtisch (5), with two each of interconnected and mutually parallel scissor blades formed Scherenblattanordnungen (6), which are pivotally connected to each other via a scissors axis (9) and a subframe (16) with a top frame ( 15) so that the upper frame (15) can be raised or lowered relative to the lower frame (16) by reciprocal pivoting of the scissors blade assemblies (6). The scissor lift has for raising and lowering a drive (8) and a lifting and lowering mechanism, which is actuated by the drive, wherein the two scissor blade assemblies (6) are respectively coupled via push rockers (2) articulated to the raising and lowering mechanism and wherein at least two to a scissor blade assembly (6) belonging push rockers (2) are interconnected via a crossmember (1). The push rockers (2) are connected to the associated traverse (1) via a screw (12, 4).

Description

The invention relates to a scissor lift according to the preamble of claim 1.

Corresponding scissor lift tables are for example off EP 1454873 B1 known.

Usually, pairs of scissors formed from scissor blades are connected to each other and are pivotable relative to each other about a scissors axis. Usually there is an upper platform on which the object to be assumed, above the scissor assembly, a base platform is located on the ground. The possibilities of opening or closing the scissors vary according to the design of the scissor lift. As a rule, a lifting and lowering mechanism is always used, which is coupled to a drive, usually an electric motor. For certain tables, as well as the generic table according to the cited document, the force of the drive is introduced via so-called push rockers in the scissors. These pushrods are coupled to the raising and lowering mechanism and therefore represent a critical component in the design of such scissor lift tables.

The push rockers belonging to a scissor blade arrangement formed by scissor blades are generally connected to one another via a crossbeam. According to the current state of the art, the push rockers are welded to the traverse.

Welding, however, has serious disadvantages. First of all, the parts to be welded have to be aligned and fixed in exact position relative to one another before the actual joining process. This in turn requires a considerable effort in the assembly and especially for this purpose specially trained personnel.

The present invention has for its object to provide a scissor lift of the type mentioned, in which the disadvantages described do not occur and in particular for the assembly and manufacture of such a scissor lift no special training is required.

This object is achieved by a scissor lift with the features of claim 1. Advantageous embodiments can be found in the dependent claims.

In the scissor lift according to the invention, which may be designed in particular as a belt lift or Spindelhubtisch, two are each connected to each other and Scherenblattanordnungen formed formed parallel to each other shear blades. These in turn are pivotally connected to each other via a scissors axis and thereby couple a subframe with a top frame so that the top frame relative to the subframe can be raised or lowered by mutual pivoting of the scissor blade assemblies. For this purpose, the scissor lift according to the invention for lifting and lowering a drive and a lifting and lowering mechanism. The latter is actuated by the drive. For this purpose, the two Scherenblattanordnungen are each coupled via thrust arms articulated with the lifting and lowering mechanism. At least two push rockers belonging to a scissor blade arrangement are connected to one another via a crossbeam. According to the invention, thrust rockers are connected to the associated traverse via a screw connection.

The present invention offers a whole series of advantages by screwing together the traverse and the push rocker. First of all, the effort that is required when connecting the push rocker and traverse in the conventional welding process, significantly lower because the parts to be joined must not previously aligned precisely with each other and fixed. Furthermore, a screw can also be made by untrained personnel, so it requires no fitter with training in welding technology.

In addition, it is of course also possible in this way to reduce maintenance and repair costs, since in the event of a defect, only the screw connection can be loosened and a push rocker can be exchanged. So it must not be disposed of a complete composite component of traverse and push rockers, which makes the cost of replacing much lower. Of course, due to the fact that no welding is required, the replacement parts are much easier to manufacture.

It is preferably provided that the traverse comprises at its ends at least one form-locking region which engages positively when merging the traverse with the push rockers with at least one correspondingly designed form-fitting region of the respective push rocker. In this way, the connection of Traverse and push rockers is much easier to perform, the installer simply puts the end of the crosshead through a corresponding opening of the push rocker and can attach a screw from the other side. For this purpose, the end of the traverse preferably has a thread onto which a securing element, such as a screw ring, can be screwed. Preferably, a locking plate can still be provided between push rocker and screw ring. The locking plate preferably has an annular shape and may additionally project radially outward Have projections which are formed as spring projections. Preferably, these spring projections are bent in the direction of the free end of the traverse, ie in the direction of the screw ring.

Preferably, each end of the traverse is passed through a recess of a push rocker. In the form of recesses, the form-fitting regions can be made particularly simple and particularly safe to handle, so that in particular each end of the traverse is positively connected to a push rocker.

In particular, it can be provided that the scissor lift according to the invention is designed as Spindelhubtisch. Here, the lifting and lowering mechanism comprises at least one spindle nut which is coupled or connected to a spindle nut plate. The spindle nut plate, in turn, is hingedly connected to the pushrods of the scissor blade assemblies.

In this embodiment, the scissor lifting table according to the invention preferably further comprises a spindle driven by the drive, by means of which the spindle nut can be driven. The spindle nut plate, on which the spindle nut is arranged, is then in particular articulated to the thrust rocker according to the invention at the other end (ie, the opposite end connected to the traverse).

By turning the spindle over the drive, the spindle nut - and thus the spindle nut plate hinged to the push rods - moves linearly along the spindle, thereby deflecting the push rods.

In another embodiment, the scissor lift according to the invention is designed as a belt lift, wherein the drive with the lifting and lowering mechanism via at least one traction means, in particular a pull belt, is coupled. Other traction means are of course also conceivable, for example ropes or chains. In that regard, the term Riemenhubtisch is not limited to the use of belts as traction means.

Finally, according to a preferred embodiment, the scissor lift according to the invention can have a lifting and lowering mechanism which has a hydraulically or pneumatically operated component.

Figur 1A

- zeigt einen erfindungsgemäßen Scherenhubtisch in perspektivischer Darstellung.

Figur 1B

- zeigt den Scherenhubtisch aus Figur 1A in seitlicher Ansicht.

Figur 2A

- zeigt eine perspektivische Darstellung der mit den Schubschwingen erfindungsgemäß gekoppelten Traverse.

Figur 2B

- zeigt die Verbindung zwischen den Schubschwingen und der Traverse in Explosionsdarstellung.

Figur 2C

- zeigt einen Schnitt entlang der Linie A-A aus Figur 2A.

Figur 2D

- zeigt schließlich einen Schnitt entlang der Linie B-B aus Figur 2A.

The invention will be described below with reference to FIGS. 1A to 2D explained in more detail. The explanations are based on the example of a spindle lifting table, but can also be transferred 1 to 1 to other lifting tables, where shear rockers are used. The embodiment shown has thrust rockers only on one side of the scissors axis. Of course, in the context of the present invention, it is equally possible for the scissor lift table to have push rockers on both sides of the scissor middle axis.

Figure 1A

- Shows a Scherenhubtisch invention in perspective view.

FIG. 1B

- shows the scissor lift table Figure 1A in lateral view.

FIG. 2A

- Shows a perspective view of the present invention coupled to the push arm traverse.

FIG. 2B

- Shows the connection between the push rockers and the traverse in exploded view.

Figure 2C

- shows a section along the line AA FIG. 2A ,

FIG. 2D

finally shows a section along the line BB FIG. 2A ,

In the Figures 1A and 1B is exemplified for the genus scissor lift 5 a Spindelhubtisch shown. This has a top frame 15 and a bottom frame 16. The two frames 15, 16 are coupled together via a scissors gear. The scissors gear is composed of mutually parallel arrangements of scissor blades 6. The respective scissors blade arrangements are pivotally connected to each other via a scissors axis 9.

Via a drive mechanism, which in the example shown comprises a motor 8, a lifting and lowering mechanism is actuated, which in the example shown comprises a drive spindle 7 and a spindle nut 14 seated thereon.

By the drive 8, the spindle nut 14 is moved along the spindle 7. The spindle nut 14 is connected or coupled to a spindle nut plate 14a. With the spindle nut plate 14a thrust links 2 are in turn coupled, one end 17 of which is articulated on the spindle nut plate 14a and whose respective other ends are articulated on an associated scissor blade 6. The push rods 2 themselves are connected to each other with a cross member 1.

By moving the spindle 7, the spindle nut plate 14a is moved over the spindle nut 14 along the spindle axis, so that the push rockers 2 are deflected, whereby the scissor blades 6 coupled thrust rockers 2, the scissors depending on the drive direction open or close, with the scissor blades 6 to the Swing scissors central axis 9 against each other.

The installation of such a table is expensive according to conventional design, because a whole series of components must be very complicated welded together.

This means that essentially the complete table has to be pre-assembled and precisely aligned and then subsequently corresponding parts have to be joined together by welding.

According to the invention, this is achieved differently in the area of the push rockers. FIG. 2A shows an arrangement of two push rockers 2 and one of these two interconnecting Traverse 1. In FIG. 2B is shown in more detail in exploded view, as the cross member 1 is connected to the push rocker 2.

The push rocker 2 has for this purpose a recess 21 in the form of an opening, the inner edge 22 has straight and curved portions. It is a form-fitting opening, which can be joined together with a corresponding form-fitting part on the traverse 1. This form-fitting part is formed by the straight surface 11 and the rounded surface 13 at the connecting end of the traverse 1. If the end 10 is inserted through the opening 21, so are the sections 11 and 13 at the inner edge 22 of the opening 21 of the push rocker 2. The relative position between the push rocker 2 and Traverse 1 is thus already fixed before the final assembly and can be designed so accurate. After passing through the end 10 of the traverse 1 through the opening 21, a locking plate 3 is preferably pushed over the end 10.

The locking plate 3 has in the example shown an annular shape, which has continued at the outer edge opposite the surface of the ring 3 and slightly bent to the ring spring projections. For fixing a trained as a screw ring fixing ring 4 is then pushed over the end 10. This has an internal thread which fits to the external thread 12 at the end 10 of the traverse 1 and can be screwed thereto. As a result, the push rocker 2 is screwed to the crossbeam 1. The arrangement is on average also in Figure 2C to see.

In order to position the trained as a locking plate ring 3 positionally accurate, at the end 10 in the longitudinal direction of the cross member 1 extending groove 18 may be inserted. The locking plate 3 has a matching projection 15 in the groove 3 a, which allows easy guidance and thus a simplified sliding of the locking plate 3 on the end 10. This situation is shown again in FIG. 2D. The projection 3a engages in the groove 18 a.

In this way, the push rocker 2 can be attached by screwing in a simple and reliable way to the crossbeam 1, without the need for a welded joint and without specially trained personnel must make this installation. On the other hand, this can also simplify replacement work and maintenance and can be particularly easy to disassemble the lift table at this point.

Claims (8)

Scissor lift, in particular Riemenhubtisch or Spindelhubtisch (5), with two each formed from interconnected and mutually parallel scissor blades Scherenblattanordnungen (6), which are pivotally connected to each other via a scissors axis (9) and a subframe (16) with an upper frame (15) so coupling, that the upper frame (15) relative to the lower frame (16) can be raised or lowered by mutual pivoting of the scissor blade assemblies (6), the scissor lift table for raising and lowering comprises a drive (8) and a lifting and lowering mechanism which by the drive is actuated, wherein the two scissors blade assemblies (6) are each articulated via push rockers (2) coupled with the raising and lowering mechanism, wherein at least two push rockers (2) belonging to a scissor blade assembly (6) are interconnected via a crossbeam (1) are,
characterized,
that the connecting links (2) with the associated cross-member (1) via a screw connection (12, 4) are connected. Scissor lift (5) according to claim 1,
characterized,
that the crossmember (1) at their ends (10) at least one form-fitting region (11, 13) which when merging the crossmember (1) with the thrust wings (2) with at least one correspondingly formed positive-locking portion (22, 23) of the respective push rocker (2) engages positively. Scissor lift (5) according to one of the preceding claims,
characterized,
in that each end (10) of the crossbeam (1) is guided through a recess (21) of a push rocker (2). Scissor lift (5) according to claim 3,
characterized,
that each end (10) of the traverse (1) is positively connected to a push rocker (2). Scissor lift (5) according to one of the preceding claims,
characterized,
in that it is designed as a spindle lifting table, wherein the raising and lowering mechanism comprises at least one spindle nut (14) which is coupled or connected to a spindle nut plate (14a), which in turn is hingedly connected to the push rockers (2) of the scissors blade assemblies (6). Scissor lift (5) according to claim 5,
characterized,
in that it further comprises a spindle (7) driven by the drive (8), by means of which the spindle nut (14) can be touched. Scissor lift (5) according to claim 1 to 4,
characterized,
in that it is designed as a belt lifting table, wherein the drive (8) is coupled to the lifting and lowering mechanism via at least one traction means, in particular a pull belt. Scissor lift according to one of the preceding claims,
characterized,
in that the lifting and lowering mechanism has a hydraulically or pneumatically operated component.

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