WO2023118391A1 - Drive mount for receiving and supporting a drive unit of an escalator or a moving walkway, mounting kit, method and use - Google Patents

Abstract

The present invention relates to a drive mount for receiving and supporting a drive unit of an escalator or a moving walkway, in particular in an arrangement on a drive train of the escalator, having at least one plate or base with fastening means for supporting and fastening the drive unit. The invention also relates to an escalator or a moving walkway having such a drive mount and to a mounting kit for such a drive mount. In addition, the present invention also relates to a method for providing and at least partially installing a drive mount for receiving and supporting such a drive unit. Finally, the present invention also relates to the use of at least one plate or base for providing and at least partially installing such a drive mount.

Description

Drive mount for receiving and supporting a drive unit of an escalator or a moving walk, assembly kit and method and use

technical field

The present invention relates to a drive socket for receiving and supporting a drive unit of an escalator or a moving walk, in particular in an arrangement on a drive train of the escalator or moving walk, with two plates with fastening means for supporting and fastening the drive unit. The invention also relates to an escalator or a moving walkway with such a drive mount and an assembly kit for such a drive mount. Furthermore, the present invention also relates to a method for providing and at least partially installing a drive receptacle for receiving and supporting such a drive unit. Last but not least, the present invention also relates to the use of two plates for providing and at least partially installing such a drive mount.

Background of the Invention

In many escalators, the support structures, in particular with regard to the drive unit and possibly also other drive components, are comparatively strictly predefined, in particular with regard to their relative position, arrangement, alignment and purpose. However, in the event that, for example, a new type of drive or a drive unit with a new/different type of base (or contact area) is to be installed or drive components to be replaced are to be changed, the engineers have to do a lot of work, what the (constructive , Structural) redesign of the respective escalator and its supporting structures and struts and beams or, for example, adjustments to a gear housing. In particular in the case of drive units with a different type of base or support or base area than is usual, the type of support must be on the supporting structure of the escalator or, for example, on another component of the escalator Drive sstrangs, such as a gearbox (size, relative arrangement or the like), are redesigned, which can bring comparatively high effort and high costs. In some cases it seems almost impossible or at least not sensible to renew a drive concept, especially if, for example, no welding work is permitted on the structure of the escalator. You can also put it this way: A change or a renewal of the type of drive unit is frustrated in very many escalators or is judged to be unfeasible simply because the associated constructive conversion of the escalator support structure and/or the necessary redesigns of other affected people components would be too complex or would not be permitted. In this respect, hitherto only the same drive units have usually been exchanged (in particular identical configuration, 1:1 correspondence); other options are not yet available, at least not with reasonable effort.

Standardized drive foundations or base support structures are known to date, which allow the use or assembly of standardized drive components, but are comparatively inflexible and, for example, make it very difficult or even impossible to install new components that may deviate from the previous standard.

The publications DE 102017 218 291 A1 and JP 2010-6 542 A describe arrangements for accommodating a drive unit of an escalator, which allow a translatory variation of the support position by means of guide rails or elongated holes.

Description of the invention

Based on this situation, it is an object of the present invention to provide a device and a method with which implementation of a different or new type of drive unit in an existing escalator or a moving walk can be simplified, in particular for the purpose of replacing an already installed drive unit. The task consists in particular in Drive unit and optionally also related drive components in/on the drive train of an escalator (or a moving walk) to be able to be installed in the escalator in such a way that the drive unit can be easily exchanged or replaced by a different type of drive unit.

The object of the invention is solved by the features of the independent main claims. Advantageous configurations are specified in the dependent claims. If technically possible, the teaching of the respective subclaims can be combined as desired with the teaching of the other main and subclaims.

In particular, the object is therefore achieved by a drive mount for receiving and supporting a drive unit of an escalator or a moving walk, in particular in an arrangement on a drive train of the escalator (or the moving walk), with two plates with fastening means for supporting and fastening the drive unit; wherein the drive receptacle has at least one crossbeam that can be supported on at least one support of a support structure of the escalator (or the moving walk), which is set up and arranged/can be arranged for connection to the plates, in particular to the plates and the crossbeam in a predetermined relative position to one another, the Plates have at least one position-variable fastening means, in particular at least one slot, by means of which the fastening position of the drive unit relative to the plates and/or its fastening points on the plates can be variably predefined. This provides new options related to the installation, replacement, maintenance and/or upgrade of drive components, particularly the drive unit of escalators. Several measures can be implemented in parallel or alternatively, in particular the strengthening or supplementing of individual supports (especially in connection with the use of connection adapters), and/or providing a partially pre-assembled assembly including the drive unit and installing this assembly in the escalator. In particular, the following advantages can also be mentioned: high flexibility and variability in the selection and replacement of drive units; minimized in-house developments or design changes by the manufacturer/operator of escalators; flexibility in Maintenance matters, especially thanks to the comparatively large number of replacement options; Potential cost savings, in particular thanks to the omission of just one predefined type of drive mount.

Advantageous aspects of the claimed invention are explained below and preferred modified exemplary embodiments of the invention are further described below. Explanations, in particular on advantages and definitions of features, are basically descriptive and preferred, but not limiting, examples. The term "escalator" also refers analogously to an application for moving walks, unless this is explicitly negated (to avoid redundancy, only the term "escalator" is used in the following); in this respect, the present invention analogously relates to both applications. If an explanation is to be understood as limiting, this is expressly mentioned.

In other words, it is provided in particular that the drive receptacle can provide a kind of adapter function for attaching different drive units, wherein the drive receptacle can be connected to the supporting structure in such a way that the drive unit can be advantageously integrated/installed in the escalator.

The respective plate can in particular also form a support for the drive unit. In particular, all forces acting on the drive unit can be transmitted to the supporting structure of the escalator solely via the two plates, in particular in such a way that a power flow from the drive train is transmitted via these plates into the supporting structure.

The drive socket has two plates which can be/are connected to one another in a variable position/size, in particular variable in size in the longitudinal direction (x), by means of at least one size adjustment means, in particular by means of at least one angle profile. This provides even better variability and also advantageous accessibility. According to one exemplary embodiment, the drive receptacle has two plates which can be/are connected to one another in variable positions/sizes by means of at least one angle profile, in particular variable sizes in the longitudinal direction (x).

According to one embodiment, the plates can/are indirectly connected to the at least one cross member, in particular by interposing at least one (longitudinal) reinforcement element, in particular by the plates being mounted on the at least one (longitudinal) reinforcement element and by the at least one (longitudinal) -) Reinforcement element is connected to the cross member. Last but not least, this makes it possible to provide a support without having to carry out major/complicated interventions on the supporting structure, with the connections of the individual components advantageously being designed to be reversible/removable. The approach also consists of strengthening or expanding the existing support structure using comparatively simple measures, in particular in combination with corresponding (positive/positive locking) connection adapters, and then installing the drive unit in the reinforced area. This approach also provides advantages in terms of the comparatively small amount of material required, simple handling and manageable logistical effort.

According to one embodiment, one of the plates can be connected/connected directly to the at least one cross member, in particular by the corresponding plate being arranged in a plan view in an arrangement that overlaps the cross member or at least in an arrangement directly adjacent to the cross member (i.e. without a longitudinal offset), in particular with the panels structurally supported by means of at least one (longitudinal) support element. Last but not least, this also makes it possible to provide a pre-assembled or pre-welded subassembly, which can optionally also already include a/the pre-assembled drive unit. The approach also consists in first preassembling the preassembled or welded assembly together with the drive unit in order to then attach the entire assembly to the support structure. This approach can also prove to be preferable, for example, if handling advantages can be achieved by installing the drive unit externally, and if the assembly is designed in this way that the mounting on the support structure can be realized at a few comparatively fixed/stable attachment points/interfaces.

At least one of the plates can be mounted in different height positions on the supporting structure, in particular by the corresponding plate being mountable/fastenable on a (third) carrier of the supporting structure of the escalator extending in the height direction. Last but not least, this also promotes an optimization of the height position of the drive unit without having to make complex design changes.

According to one exemplary embodiment, at least one of the panels can be mounted in different height positions on the support structure, namely by the at least one panel being mountable/fastenable to a (third) carrier of the support structure of the escalator extending in the height direction.

The plates define an access area via which the drive unit remains accessible at least from below when it is mounted on the plates, in particular an access area defined between the two plates, the access area being preferably larger in the longitudinal direction than the area covered by at least one of the plates . This further increases the variability and practicality.

According to one embodiment, the plates define an access area via which the drive unit remains accessible at least from below when it is mounted on the plates, the drive receptacle having an access area defined between the two plates, the access area being longer in the longitudinal extent than that of at least one of the plates covered area.

According to one exemplary embodiment, the assembly kit set up for a drive unit according to the present disclosure has plates that can be connected to one another in variable positions/sizes by means of at least one size adjustment means, with the assembly kit also having at least: the components of a cross member and at least one (longitudinal) reinforcement element that can be connected to the plates. This favors in particular the reversible assembly, in particular according to a first embodiment, in particular with the assembly of the drive unit as the last assembly step.

The assembly kit has plates that can be connected to one another in a variable position/size by means of at least one size adjustment means, the assembly kit also having at least: the components that can be connected to the plates in each case at least one (transverse) reinforcement plate and at least one (longitudinal) support element and optionally also fastening means between the corresponding plate and the corresponding cross member, in particular plastic fixing wedges. This favors in particular the provision of an already pre-assembled sub-assembly, in particular according to a second exemplary embodiment.

The object defined above is also achieved by an escalator or a moving walk with a drive mount described above, wherein a drive unit of the escalator is supported on a supporting structure of the escalator by means of the drive mount. This provides advantages previously described, particularly in connection with maintenance and/or replacement of drive components.

According to one exemplary embodiment, in the installed state, an access area or a cavity is formed between the two plates of the drive receptacle below the drive unit. This provides further advantages with regard to access and the installation situation and independence from the individual structural or size/shape design of the drive unit.

The object defined above is also achieved by a method for providing and at least partially installing a drive mount according to the present disclosure for receiving and supporting a drive unit of an escalator or a moving walk, in particular a drive mount described above, wherein at least two plates with fastening means are provided for supporting and fastening the drive unit, at least one of the plates being connected to at least one cross member that can be supported on at least one carrier of a supporting structure of the escalator, the drive unit being connected by means of of the plates and by means of at least one position-variable fastening means relative to the plates at one or more fastening points on the plates and thereby also on the supporting structure. This provides the advantages previously described, particularly in connection with the replacement or redesign of drive units.

The drive receptacle has two plates which are connected to one another in a variable position/size, in particular variable in size in the longitudinal direction x, by means of at least one size adjustment means, in particular by means of at least one angle profile. This increases variability and can also provide an advantageous cavity between the plates. The correspondingly arranged drive components are therefore even more easily accessible and easier to maintain and/or to (dis)assemble.

At least one of the panels can be mounted at variable heights in different height positions on the supporting structure of the escalator, the panels being installed in such a way that the panels define an access area via which the drive unit remains accessible at least from below when it is mounted on the panels.

According to one exemplary embodiment, at least one of the plates is indirectly connected to the at least one cross member by connecting the at least one plate to at least one (longitudinal) reinforcement element, in particular by resting on it, which is/is connected to the cross member, in particular on both sides two opposite cross members or with a cross member and a transverse frame part of the supporting structure. Last but not least, this favors a procedure in which only individual reinforcement elements have to be provided on the supporting structure in order to be able to advantageously flexibly/variably connect the drive receptacle to the supporting structure.

According to one embodiment, one of the plates is directly connected directly to the at least one cross member by arranging the corresponding plate in plan view in an arrangement overlapping the cross member or at least in an arrangement directly adjacent to the cross member and on the cross member is overlyingly connected to the crossbeam, in particular to the panels being structurally supported by at least one (longitudinal) beam element. Last but not least, this also makes it possible to provide a preassembled and/or partially welded subassembly. This subassembly can then optionally be installed first with the drive unit before the entire arrangement is connected to the support structure.

The plates define an access area via which the drive unit remains accessible at least from below when it is mounted on the plates, with the access area preferably being defined by the two plates by a free space spanned between the plates, with the access area in Longitudinal extension x is preferably greater than the area covered by the plates. This not only provides an adapter function for different types of drive units, but can also ensure further advantages in terms of accessibility of the individual/respective installed drive unit, i.e. provides advantages for handling in practice over the entire service life of the system.

The object defined above is also achieved by using two plates for providing and at least partially installing a drive receptacle for receiving and supporting a drive unit of an escalator or a moving walk, with the plates providing an adapter function for the reversible, detachable attachment of different types of drive units by providing fastening means that can be positioned in at least one spatial direction for supporting and fastening the drive unit on the plates, at least one of the plates being connected to at least one cross member that can be supported on at least one carrier of a supporting structure of the escalator, the drive unit being secured by means of the plates and by means of at least one fastening means variable in position relative to the panels at one or more fastening points on the panels and thereby also on the supporting structure, the two panels being connected to one another in a variable position/size by means of at least one size adjustment means, with at least one of the panels being height-variable mountable in different height positions on the supporting structure of the escalator, wherein the plates are installed in such a way that the plates define an access area via which the drive unit remains accessible at least from below when it is mounted on the plates. This provides advantages previously described.

Brief description of the drawings

The invention is explained in more detail below with reference to the accompanying drawings using preferred exemplary embodiments. The wording figure is abbreviated to figure in the drawings. Show it

1 in a partially schematic representation in a perspective view from above, a drive recording according to an embodiment of the invention;

2 in a partially schematic illustration in a perspective view from above, a drive receptacle according to a further exemplary embodiment of the invention;

3 in a partially schematic illustration in a perspective view from the side, components of an escalator and optional arrangement points for a drive mount according to exemplary embodiments of the invention;

Detailed description of the exemplary embodiments

The exemplary embodiments described are merely examples that can be modified and/or supplemented in a variety of ways within the scope of the claims. Each feature described for a particular embodiment can be used on its own or in combination with other features in any other embodiment. Each feature that is described for an embodiment of a certain category of claims can also be used in a corresponding manner in an embodiment of another category of claims. The reference numbers will first be described generally; an individual reference is made in connection with the respective description of the figures. An escalator 1 has at least one drive unit 3, which is supported on a carrying/supporting structure 5 of the escalator (in particular on a supporting structure with supporting structure/supporting elements). The support structure 5 forms, for example, a frame structure 5a arranged in particular in an xy plane that runs at least approximately horizontally. The support structure 5 comprises, for example, at least one first support 5.1 (in particular parallel supports below the drive unit), at least one second support 5.2 (in particular transverse support below the drive unit) and at least one third support 5.3 (in particular extending in the vertical direction).

A drive receptacle 10, 10a comprises two plates, namely a first and a second plate 12a, 12b, on which/which variable-position fastening means 12.1 (for example in the form of elongated holes, with corresponding connection adapters being able to be provided for this purpose) are provided. The corresponding plate 12a, 12b is attached to at least one cross member 16 (in particular cross member made of sheet metal) by means of adjustment means 16.1 (e.g. in the form of elongated holes, through holes, slots, notches or the like, with corresponding connection s adapters being provided for this purpose), the at least one crossbeam 16 rests on the at least one first beam 5.1 or is attached to it. The two plate parts 12a, 12b can be mounted in the desired relative position relative to each other and also relative to the drive unit by means of size adjustment means 14 (in particular at least one angle profile) with fastening means 14.1 (e.g. in the form of elongated holes with corresponding screws provided for this purpose or other connection adapters). Depending on the installation situation and the type of drive, it can be advantageous to provide a (transverse) reinforcement plate 15 at one of the free ends of the plate(s), in particular in the transverse orientation y transverse to the longitudinal extension x. It can also be advantageous to provide at least one (longitudinal) support element 19 or an equivalent (longitudinal) support unit for better support of the panels on one another, in particular in an orientation at least approximately orthogonal to the cross member. The components 15, 19 can optionally be reversibly mounted or welded. Optionally, the components 15, 19 can also be omitted, especially if the Plate (s) on at least one (longitudinal) reinforcement element 17 (in particular angle profile) with adjustment means 17.1 (for example in the form of a slot) can be supported.

If two plate parts 12a, 12b are used, they are preferably arranged at a longitudinal distance from one another, so that a cavity V12 (in particular recess, access area, open section) is formed between them.

The coordinate axes x, y, z indicate the longitudinal, transverse and vertical directions.

Figure 1 shows a drive mount 10 according to a first embodiment, in which two plates 12a, 12b are connected to one another with an angle 14, and the plates rest on two (longitudinal) reinforcement elements 17, which are designed as a U-profile (alternatively, e.g. L - Or Z-profile) are designed and are connected to cross members 5.2, 16, for example, can also be welded. In this configuration, a size variation in the longitudinal direction x is possible without any problems, because the reinforcing elements 17 are longer than the maximum longitudinal area covered by the plates 12a, 12b. Bolts with a T-shaped head can optionally be installed at the connection points provided in particular for screw connections (in particular at points 14.1, 17.1). Form-fitting adapters or connection partners that interact with one another in a form-fitting manner (so-called poka-yoke connection/fastening means) can be provided at the individual connection points. Optionally, additional (underlay) plates can be provided, in particular to be able to compensate for an inclination or an incline of a base plate/base (e.g. 80x40x6mm).

Figure 2 shows an at least partially welded drive mount 10a according to a second embodiment, which also has two plates 12a, 12b connected to one another at an angle 14, with a (transverse) reinforcing plate 15 being provided at one of the free ends of the plate(s), and at least one (longitudinal) support member 19 for better supporting the panels together is provided under the panels. At the interface between at least one of the plates 12a, 12b and the corresponding cross member 16, positive/non-positive connection adapters such as wedges, Expansion dowels or the like can be provided. Optionally, the reinforcement plate 15 is screwed directly to the support structure 5 of the escalator 1 . Thanks to the comparatively high rigidity of the assembly described in Fig. 2, the assembly can also be preassembled together with a drive unit and only installed afterwards, and installation can also take place in a height position that can be decoupled from the plane in which the components shown in Fig 1 can be provided (which are not required in the present exemplary embodiment according to FIG. 2). FIG. 3 shows the escalator 1, the supporting structure 5 and a frame structure 5a formed thereby being indicated schematically. The relative position of the drive unit and the individual carriers of the support structure 5 can of course be/are predefined individually and specifically for each type of system.

Reference character list

1 escalator (or alternatively moving walk)

3 drive unit

5 Load-bearing/support structure, in particular load-bearing structure with load-bearing structure/support element(s)

5a Frame structure, especially in the xy plane

5.1 first carrier, in particular parallel carrier below the drive unit

5.2 second carrier, in particular cross member below the drive unit

5.3 third carrier, in particular with an extension in the height direction

10 drive mount

10a drive mount, welded

12 plate

12a, 12b first and second plates

12.1 variable position fastener for drive unit

14 size adjustment means, in particular angle profile with fasteners

14.1 Fasteners

15 (transverse) reinforcing plate, especially in the transverse orientation

16 Cross member/strut with adjustment means, in particular cross member made of sheet metal

16.1 Means of adjustment

17 (Longitudinal) reinforcement element, in particular angle profile with adjustment means

17.1 Means of adjustment

19 (longitudinal) support element or (longitudinal) support unit, in particular orthogonal to the cross member

V 12 Cavity, in particular recess, access area, open section x, y, z longitudinal, transverse and vertical direction

Claims

patent claims

1. Drive mount (10, 10a) for receiving and supporting a drive unit (3) of an escalator (1) or a moving walk, with two plates (12a, 12b) with fastening means (12.1) for supporting and fastening the drive unit (3); characterized in that the drive receptacle (10, 10a) has at least one crossbeam (16) which can be supported on at least one support (5.1) of a support structure (5) of the escalator (1) and which is set up and arranged/can be arranged for connection to the plates (12a, 12b), wherein the plates (12a, 12b) have at least one variable-position fastening means (12.1), by means of which the fastening position of the drive unit relative to the plates and/or its fastening points on the plates (12a, 12b) can be variably predefined, wherein the two plates (12a, 12b) can be connected to one another in a variable position/size by means of at least one size adjustment means (14), wherein at least one of the plates (12a, 12b) can be mounted in different height positions on the support structure (5) of the escalator (1). wherein the plates (12a, 12b) define an access area (V12) via which the drive unit (3) remains accessible at least from below when it is mounted on the plates (12a, 12b).

2. Drive mount (10, 10a) according to claim 1, wherein the two plates (12a, 12b) of the drive mount (10, 10a) are connected to one another in a variable position/size by means of at least one size adjustment means (14), namely by means of at least one angle profile, in particular variable in size in the longitudinal direction (x).

3. Drive mount (10, 10a) according to at least one of claims 1 or 2, wherein the plates (12a, 12b) are indirectly connected to the at least one cross member (16), in particular by interposing at least one (longitudinal) reinforcing element (17 ), in particular in that the plates (12a, 12b) are mounted on the at least one (longitudinal) reinforcement element (17) and in that the at least one (longitudinal) reinforcement element (17) is connected to the cross member (16).

4. Drive mount (10, 10a) according to at least one of the preceding claims, wherein one of the plates (12a, 12b) is directly connected to the at least one cross member (16), in particular by the corresponding plate (12b) in a plan view arrangement overlapping the cross member (16) or at least in an arrangement directly adjacent to the cross member (16), in particular with the panels (12a, 12b) structurally supported by at least one (longitudinal) support member (19).

5. Drive receptacle (10, 10a) according to at least one of the preceding claims, wherein at least one of the plates (12a, 12b) is variable in height in different height positions on the supporting structure (5) of the escalator (1) can be mounted, namely by the at least one plate ( 12) can be mounted/attached to a carrier (5.3) of the support structure (5) extending in the vertical direction.

6. Drive receptacle (10, 10a) according to at least one of the preceding claims, wherein the plates (12a, 12b) define an access area (V12) via which the drive unit (3) in a state mounted on the plates (12a, 12b) at least remains accessible from below, the drive receptacle having an access area (V12) defined between the two plates (12a, 12b), the access area (V12) being larger in the longitudinal extent (x) than that of at least one of the plates (12a, 12b) covered area.

7. Assembly kit for a drive mount (10, 10a) according to at least one of the preceding claims, wherein the assembly kit has plates (12a, 12b) that can be connected to one another in variable positions/sizes by means of at least one size adjustment means (14), wherein the assembly kit further comprises at least: either the components cross member (16) and at least one (longitudinal) reinforcement element (17) connectable to the plates, or the components connectable to the plates at least one (transverse) reinforcement plate and at least one (longitudinal) carrier element (19) and optionally also fasteners between plate and cross member, in particular fastening wedges made of plastic. 17

8. Escalator (1) or moving walk with a drive mount (10, 10a) according to at least one of claims 1 to 6, wherein a drive unit (3) of the escalator (1) is attached to a supporting structure (5) of the escalator or of the escalator by means of the drive mount moving walk is supported.

9. Escalator or moving walkway according to the preceding claim, wherein in the installed state an access area or a cavity (V12) is formed between the two plates (12a, 12b) of the drive receptacle (10, 10a) below the drive unit (3).

10. A method for providing and at least partially installing a drive mount (10, 10a) according to one of claims 1 to 6 for receiving and supporting a drive unit (3) of an escalator (1) or a moving walk, characterized in that two plates (12a, 12b) are provided with fastening means (12.1) for supporting and fastening the drive unit (3), at least one of the plates (12a, 12b) having at least one support structure (5) on at least one carrier (5.1) of the escalator (1) or of the moving walk, the drive unit (3) being connected by means of the plates (12a, 12b) and by means of at least one fastening means (12.1) which can be positioned relative to the plates at one or more fastening points on the plates (12a, 12b) and thereby also fastened to the support structure (5), the two panels (12a, 12b) being connected to one another in a variable position/size by means of at least one size adjustment means (14), with at least one of the panels (12a, 12b) being height-variably mountable in different Height positions on the support structure (5) of the escalator (1), the plates (12a, 12b) being installed in such a way that the plates define an access area (V12) via which the drive unit (3) is mounted in a manner on the plates (12a, 12b) remains accessible at least from below in the assembled state.

11. The method according to the aforementioned method claim, wherein the two plates (12a, 12b) are connected to one another in a variable position/size by means of at least one size adjustment means (14), namely by means of at least one angle profile, namely variable in size in the longitudinal direction (x). 18

12. The method according to at least one of the above method claims, wherein at least one of the plates (12a, 12b) is indirectly connected to the at least one cross member (16) by connecting the at least one plate to at least one (longitudinal) reinforcement element (17). is, in particular, supported on it, which is/is connected to the crossbeam (16), in particular on both sides with two opposite crossbeams or with a crossbeam and a frame part of the supporting structure running transversely.

13. The method according to at least one of the above method claims, wherein one of the plates (12a, 12b) is connected directly to the at least one cross member (16) by the corresponding plate (12b) overlapping the cross member (16) in a plan view arrangement or at least in an arrangement directly adjacent to the cross member (16) and resting on the cross member (16) is connected to the cross member (16), in particular to the plates (12a, 12b) structurally supported by means of at least one (longitudinal )carrier element (19).

14. The method according to at least one of the aforementioned method claims, wherein the plates (12a, 12b) define an access area (V12) via which the drive unit (3) is accessible at least from below when it is mounted on the plates (12a, 12b). remains, the access area (V12) being defined by the two plates (12a, 12b) by a/the free space spanned between the plates, the access area (V12) being larger in the longitudinal extent (x) than that of the plates (12, 12a, 12b) covered area.

15. Use of two plates (12a, 12b) for providing and at least partially installing a drive mount (10, 10a) for receiving and supporting a drive unit (3) of an escalator (1) or a moving walk, with the plates (12a, 12b ) an adapter function for the reversible, detachable fastening of different types of drive units is provided by providing fastening means (12.1) that can be positioned in at least one spatial direction for supporting and fastening the drive unit (3) on the plates, with at least one of the plates (12a, 12b) having at least one crossbeam (16) that can be supported on at least one beam (5.1) of a support structure (5) of the escalator (1) or the moving walk 19, the drive unit (3) being connected by means of the plates (12a, 12b) and by means of at least one position-variable fastening means (12.1) relative to the plates at one or more fastening points on the plates (12a, 12b) and thereby also on the supporting structure (5), the two panels (12a, 12b) being connected to one another in variable positions/sizes by means of at least one size adjustment means (14), with at least one of the panels (12a, 12b) being mountable in variable heights in different height positions on the supporting structure (5 ) of the escalator (1), wherein the plates (12a, 12b) are installed in such a way that the plates define an access area (V12) over which the drive unit (3) in a state mounted on the plates (12a, 12b) at least from remains accessible below.