EP4253298A1 - Foundation frame and method for retrofitting a building with an elevator system - Google Patents

Abstract

The invention relates to a method for retrofitting a multi-story building 1 with an elevator system 41, the building having a staircase 5 with main platforms 6, 6.1, 6.2... and intermediate platforms 12, 12.1, 12.2... for a two-flight staircase, comprising the Process steps: a) attaching a foundation 15 for a prefabricated elevator system 41, b) opening the front of the building, c) removing the intermediate landings and at least parts of the two-flight staircase, d) installing webs 32 in the stairwell, which are away from the main landings extend horizontally to the front of the building, e) installation of single-flight stairs 31, f) installation of a prefabricated elevator system 41 provided with elevator platforms 42 on the foundation 15, and / or f) installation or attachment of elevator platforms 42, which are attached to the webs 32 are attached or connected to these, and g ') setting up the prefabricated elevator system 41 on the foundation 15 and attaching the elevator system to the elevator platforms 42, whereby) before step (a) the geometric dimensions of the staircase 5 are measured, i) before Method step (a) a foundation frame 16, which contains mounting points or receptacles for the prefabricated elevator system 41, is prefabricated according to the dimensions of the stairwell, andj) the prefabricated foundation frame 16 is used in method step (a) at least as part of the foundation 15.

Description

The invention relates to a method for retrofitting a building with an elevator system according to the preamble of patent claim 1 and to a foundation frame for use in such a method.

This process is used to retrofit a building that has multiple floors. These each have at least one floor door, with the floor doors being accessible via a common staircase. The stairwell lies within the building shell and borders on a front side of the building, so that that section of the building shell front side that coincides with the front side of the stairwell forms a stairwell facade. Each floor of the building has a main landing for the floor doors in the stairwell. Between each floor there is an intermediate landing arranged on the stairwell facade for a two-flight staircase, which connects the intermediate landings and the main landings.

Elevator systems for attachment to a building or for retrofitting a building are usually used in older buildings where barrier-free access has not yet been taken into account. In particular, older residential buildings with a number of residential units spread over several floors, but also administrative buildings and commercial buildings, are often built in the construction method mentioned at the beginning; They have a plurality of floors, which are divided in particular into several residential units or other self-contained units and have corresponding floor doors that are accessible via a common staircase. This design integrates the staircase at the front of the building, with an entrance door at ground level and a two-flight staircase that provides access to all floor doors via intermediate landings and main landings on each floor.

It is obvious that people with walking difficulties in such buildings have little chance of getting to the floor doors on their own. The transport of heavy objects usually has to be carried out via the stairwell and therefore often cannot be made easier with appropriate aids. It is therefore often desirable to retrofit such a multi-story building with an elevator system, in particular with a prefabricated elevator system, such as those from EP 3 315 448 A2 of the applicant has become known. By prefabrication of the elevator system, which essentially only needs to be set up and connected on site, the construction time for retrofitting can be limited to a level that is tolerable for residents or users of the building, which is often a key decision criterion for or against retrofitting the elevator system Building with an elevator system.

From the DE 196 33 636 A1 a method for retrofitting a building with a modular, prefabricated elevator system is known. From this state of the art it is clear that retrofitting the building with an elevator system without further renovation work only partially solves the problem of unhindered access for people with walking disabilities. Because if the retrofitted elevator system is placed on the front of the building in front of the stairwell and the transitions between the elevator shaft and corresponding building openings in the stairwell facade are made, a person who leaves the elevator car only reaches one intermediate landing in the stairwell, so that for access to the floor doors must be overcome half a floor up or down using a section of the double staircase.

If a corresponding building is to be modernized to be largely barrier-free by retrofitting an elevator system, the method of choice is still to gut the stairwell and completely rebuild it with an elevator system. Since access to the floor doors is generally not possible during the corresponding construction period, retrofitting a corresponding building with an elevator system is often not done, at least from the point of view of maximum accessibility.

Alternatively, in the DE 203 00 662 U1 a method for retrofitting a building with an elevator system is proposed, in which a prefabricated elevator system is placed on a foundation in front of the stairwell facade. Beforehand, the front of the building is opened by removing the stairwell facade and a one-piece or multi-part frame is placed on the stairwell facade, the frame being equipped with one elevator platform that is essentially the width of the stairwell on each floor at the height of the main platform of the stairwell. This frame is an assembled outer platform element, each of which is designed floor-high as a table-shaped prefabricated element with a plate-shaped outer platform and several table leg-like supports. After opening the front of the building and attaching the frame consisting of external platform elements, the intermediate platforms of the stairwell are removed and the two-flight staircase is dismantled. Bridges are then installed in the stairwell, which extend horizontally from the main landings to the elevator landings and only partially cover the floor plan of the stairwell in projection in order to leave clear space for a single-flight staircase that connects the main landings and the elevator landings. The prefabricated elevator system is then placed on the staircase prepared in this way, which is now provided with a single flight of stairs, aligned and connected to the elevator platforms or the external platform elements. The result is a stairwell in which the doors of the elevator system are connected to the floor doors via the elevator platforms, the walkways and the main platforms and are therefore barrier-free. From the EP 3 712 355 A1 The applicant has disclosed a similar method for retrofitting a building with an elevator system. According to this state of the art, however, after removing the stairwell facade and taking out the intermediate landings and the two-flight stairs, a prefabricated stairwell module with horizontally running webs to connect the main landings with floor openings of the elevator system and with single-flight stairs to connect webs of adjacent floors is pushed into the gutted stairwell , which greatly reduces the time required for construction work on site. The prefabricated elevator system is then placed on the foundation, aligned and connected to the installed stairwell module.

The present invention is based on this prior art, and it has been found that it is difficult and therefore time-consuming to detach the stairwell facade from the building, which is usually done with concrete saws, in particular for the further process steps To ensure the dimensional accuracy required for inserting the stairwell module. The stairwell module also first has to be aligned, which is a time-consuming process, so that it can be pushed into the gutted stairwell. Finally, aligning the prefabricated elevator system on the foundation is quite complex and not optimal in terms of time.

The present invention is therefore based on the object of simplifying a method of the type described above and of providing a prefabricated foundation frame for use in such a method.

A first part of the problem is solved by a method with the features of claim 1, with advantageous developments of the method according to the invention being set out in claims 2 to 10.

The second part of the task is solved by a foundation frame with the features of claim 11. Appropriate configurations of this foundation frame can be found in claims 12 to 15.

1. a) Anbringen eines Fundaments für die vorgefertigte Aufzugsanlage vor der Treppenhausfassade,
2. b) Öffnen der Frontseite des Gebäudes durch Entfernen der Treppenhausfassade,
3. c) Entfernen der Zwischenpodeste,
4. d) Entfernen zumindest von Teilen der zweiläufigen Treppe,
5. e) Einbau von Stegen in das Treppenhaus, die sich von den Hauptpodesten waagrecht bis zur Frontseite des Gebäudes erstrecken und in Projektion die Grundfläche des Treppenhauses nur zum Teil überdecken, um lichten Raum für eine einläufige Treppe zu lassen,
6. f) Einbau von einläufigen Treppen, die jeweils ein Hauptpodest oder einen diesem zugeordneten Steg mit jeweils einen Aufzugspodest oder Steg einer benachbarten Etage verbinden, je nachdem, ob die jeweiligen Treppenabschnitte gerade Antritte oder Austritte oder beispielsweise viertelgewendelte Antritte und Austritte aufweisen, gegebenenfalls auch teilweise,
7. g) Aufstellen einer mit Aufzugspodesten für die einzelnen Etagen versehenen, vorgefertigten Aufzugsanlage auf das Fundament an der Frontseite des Gebäudes und Ansetzen der Aufzugspodeste an die Stege.

With the method according to the invention, a building of the type mentioned, the stairwell of which is provided with main landings and intermediate landings as well as two-flight stairs connecting these, is retrofitted with a prefabricated elevator system. The process steps are the following:

1. a) Attaching a foundation for the prefabricated elevator system in front of the stairwell facade,
2. b) opening the front of the building by removing the staircase facade,
3. c) removing the intermediate platforms,
4. d) removing at least parts of the two-flight staircase,
5. e) Installation of walkways in the stairwell, which extend horizontally from the main landings to the front of the building and, in projection, only partially cover the base area of the stairwell in order to leave clear space for a single-flight staircase,
6. f) Installation of single-flight stairs, each of which connects a main landing or a walkway assigned to it with an elevator landing or walkway on an adjacent floor, depending on whether the respective stair sections have straight entrances or exits or, for example, quarter-turn entrances and exits, if necessary also partially,
7. g) Setting up a prefabricated elevator system equipped with elevator platforms for the individual floors on the foundation at the front of the building and attaching the elevator platforms to the walkways.

As an alternative to process step (g), the elevator platforms in process steps (g`) and (h`) are not prefabricated together with the elevator system and are placed together with it on the front of the building and on the walkways connected, but installed separately in the stairwell or, if necessary, as for example in the prior art according to DE 203 00 662 U1 described, with frames, or, modifying the state of the art in this respect, a single frame, placed on the foundation and attached to the webs. In this case, the prefabricated elevator system is then placed on the foundation and attached to the elevator platforms.

Furthermore, as an alternative, the elevator platforms can be installed together with the webs, as is the case, for example, in the prior art EP 3 712 355 A1 was proposed. All of these alternatives are within the scope of the present invention and some are already known.

The essential novelty of the method according to the invention lies in the method steps (i), (j) and (k), after which the geometric dimensions of the staircase are measured before method step (a), and also before method step (a) a foundation frame, which Contains attachment points or receptacles for the prefabricated elevator system, is prefabricated according to the dimensions of the stairwell, in particular from at least one steel material, and finally the prefabricated foundation frame is used in method step (a) at least as a significant part of the foundation.

The prefabricated foundation frame according to the invention makes it possible to dispense with complex alignment of the elevator system, particularly when setting up the prefabricated elevator system on the foundation. The elevator system simply needs to be placed on the intended mounting points or holders in the foundation frame in order to be precisely aligned with the building and the specific conditions of the stairwell. Because these specific conditions have already been taken into account when the foundation frame was created by measuring the stairwell in advance, it is sufficient to carefully place the foundation frame in relation to the building when creating the foundation to align. In contrast, a much more complex alignment of the prefabricated elevator system can then be eliminated.

The stairwell is preferably measured with reference to at least two reference points, so that a coordinate system related to these reference points can be used for all further work, in particular when producing the foundation frame and when prefabrication of the elevator system. The foundation frame then only needs to be aligned on site with the help of these reference points on the stairwell facade in order to be able to precisely align the elevator system in particular, but also other preferred, prefabricated elements of the new stairwell and devices for carrying out the process with the help of the foundation frame.

Two points on the front of the building in the area of the ground are preferably chosen as such reference points, i.e. near the ground, or on the ground, or below the ground surface. Particularly preferably, the foundation frame is then attached directly or indirectly to these reference points, whereby on the one hand it is precisely aligned and on the other hand it can no longer slip.

The foundation frame according to the invention is preferably anchored in the ground by means of a pile foundation, with particular advantages if the foundation frame is used as a template for inserting bored piles into the ground. A pile foundation offers the advantage that further concreting work is unnecessary, as the foundation frame distributes the weight it absorbs to the bored piles and transfers them into the ground.

A further advantage can arise if the building that is to be retrofitted with an elevator is, as usual, equipped with supply lines that run directly in front of the stairwell at a depth of around 1.50 m, i.e. exactly at the point where the Foundation must be provided for the elevator system. The insertion of bored piles for a pile foundation can be done before Especially when the foundation frame, which is preferably made of steel, distributes the load to be transferred, can easily be done next to the supply lines, while conventional excavation for a conventional concrete foundation carries the risk of damaging supply lines.

It is particularly preferred if the foundation frame is prefabricated with a pivot bearing, and for process steps (e) and (f), or for process steps (e), (f) and (g`), a prefabricated staircase module is created with the help of this pivot bearing is pivoted into the stairwell with walkways and single-flight stairs. Such a prefabricated staircase module has bearing points with which it can be pivoted in the pivot bearings of the foundation frame. It can first be brought to the construction site lying on a truck and placed on the foundation frame in such a way that the bearing points come to rest on the pivot bearings and the stairwell module can be pivotably attached to the pivot bearings. The stairwell module can then easily be swung into the previously gutted stairwell by attaching its upper end to a crane around a pivot axis that runs through the pivot bearings. The new staircase with continuous webs from a main landing to an elevator landing and a single-flight staircase or single-flight staircase sections can be installed in the gutted staircase in a very short time.

Since the foundation frame and the pivot bearings arranged on it are already aligned exactly with the building, the prefabricated staircase module is also aligned precisely with the building after it has been attached to the pivot bearings and can then simply be pivoted in without having to align or fit it on site.

According to a further development of the method according to the invention, the foundation frame is prefabricated with supports or attachment points for an auxiliary scaffolding, which is placed on the foundation frame, attached to the front of the building and used for method steps (b) and/or (c) and/or (d). becomes. Such an auxiliary scaffolding, which is in turn aligned exactly with the building from the outset by being placed on the foundation frame, can be used, for example, to guide at least one saw for method step (b), in particular by means of a saw template provided on the auxiliary scaffolding.

It is particularly advantageous if a climbing platform is attached to this auxiliary scaffolding, which is used for method step (b), i.e. opening the front of the building, and/or method step (c) and/or method step (d) and/or Process step (e) can be used.

The auxiliary scaffolding according to this development of the method according to the invention can finally also be attached to the stairwell facade to be removed and removed piece by piece together with it.

The foundation frame, which is provided according to the present invention and is intended for use in the method according to the invention, has mounting points or receptacles for the prefabricated elevator system. As already mentioned, it is preferably designed as a prefabricated steel part and is more preferably provided with a pivot bearing for a prefabricated stairwell module, which in particular consists of two individual pivot bearings, which together define a pivot axis for pivoting in a stairwell module.

The foundation frame according to the invention can also be provided with a support or with one or more attachment points for an auxiliary scaffolding.

Finally, it is particularly preferred if the foundation frame is intended for a pile foundation and forms the foundation together with bored piles. For this purpose, the foundation frame can be provided with connection points for attachment to a number of bored piles. The foundation frame is preferably equipped with templates for inserting bored piles into the ground, so that it is no longer necessary to install the corresponding ones on site Select locations for the bored piles or implement corresponding plans by measuring on site. This also significantly reduces the likelihood of errors when inserting the bored piles.

Figur 1

ein Gebäude, das mit einer Aufzugsanlage nachgerüstet werden soll, in schematischer Schnittdarstellung, im Verfahrensschritt (b);

Figur 2

eine teilgeschnittene Draufsicht auf das Treppenhaus des Gebäudes aus Figur 1;

Figur 3

einen Teil der Frontansicht des Gebäudes aus Figur 1;

Figur 4

das Gebäude aus den vorangehenden Figuren, beim Einbau eines vorgefertigten Treppenhausmoduls mit Stegen und einläufigen Treppen;

Figur 5

eine teilgeschnittene Draufsicht auf das Treppenhaus des Gebäudes aus Figur 4;

Figur 6

das Gebäude aus den vorangehenden Figuren beim Ansetzen einer vorgefertigten Aufzugsanlage;

Figur 7

das Gebäude aus den vorangehenden Figuren, mit fertig nachgerüsteter Aufzugsanlage.

An exemplary embodiment for the application of the method according to the invention in a multi-story building of the type described above and for a foundation frame according to the invention is described and explained in more detail with reference to the accompanying drawings. Show it:

Figure 1

a building that is to be retrofitted with an elevator system, in a schematic sectional view, in method step (b);

Figure 2

a partially sectioned top view of the building's stairwell Figure 1 ;

Figure 3

part of the front view of the building Figure 1 ;

Figure 4

the building from the previous figures, with the installation of a prefabricated staircase module with walkways and single-flight stairs;

Figure 5

a partially sectioned top view of the building's stairwell Figure 4 ;

Figure 6

the building from the previous figures when a prefabricated elevator system is installed;

Figure 7

the building from the previous figures, with a fully retrofitted elevator system.

In the Figures 1 to 7 are schematically different stages of the process, leaving out parts of the building that are not of interest but are actually present shown in the exemplary implementation of a method according to the invention on an apartment building with four floors, an attic and a basement.

Figure 1 shows building 1 still in its original position: Building 1 includes a basement 2 and four floors 3, 3.1, 3.2, 3.3 as well as an attic 3.4. There are apartments on each floor, which are accessible via floor doors 4, 4.1, 4.2, 4.3, 4.4. A stairwell 5, each with a main landing 6, 6.1, 6.2, 6.3, 6.4 in front of the floor doors, borders on a front side 7 of the building, whereby, in the width of the stairwell 5, part of the front side 7 of the building 1 becomes a stairwell facade 8 . In the stairwell facade 8 there are windows 9 for illuminating the stairwell 5 and a front door 10. The stairwell 5 is bounded at the top by a roof 11.

Inside the stairwell 5, the front door 10 leads to a first intermediate landing 12, from which the main landing 6 for the first floor 3, which forms the ground floor, can be reached via a first stair section 13 of a two-flight staircase. A second stair section 14 of the two-flight staircase leads from the intermediate landing 12 to the basement 2. In a corresponding manner, the two-flight staircase of the stairwell 5 connects with its first half of the staircase, which consists of the first staircase sections 13.1, 13.2..., and its second half of the staircase, which is formed from the second stair sections 14.1, 14.2..., the main landings 6, 6.1, 6.2..., each via intermediate landings 12, 12.1, 12.2... between the floors. The intermediate landings 12, 12.1, 12.2... adjoin the stairwell facade 8 from the inside.

Based on this illustration of a multi-story building to be retrofitted with an elevator system, the fundamental problem is easily recognizable that when an elevator system is connected to the stairwell facade 8 from the outside and the individual door openings of the elevator system lead to the intermediate platforms 12..., accessibility of the Staircase 5 not yet available is. Because from each intermediate landing 12... you have to climb either up via a first stair section 13... or down via a second stair section 14... of the two-flight staircase in order to get to one of the main landings 6... and thus a floor door 4... to be able to achieve.

In the in Figure 1 In the process section shown, a foundation 15 has already been made in front of the stairwell facade 8. This foundation 15 consists of a prefabricated foundation frame 16 made of steel, which transfers its load into the ground via bored piles 17 in the form of a pile foundation. These drilled piles 17 were inserted into the ground in a manner known per se, after placing and aligning the foundation frame 16, using appropriate drilling templates that are present in the foundation frame 16.

Figure 2 shows this in a top view from above: The foundation frame specifies the places in which the bored piles 17 are placed in the ground. In particular, this can also be done in such a way that the bored piles 17 are placed outside the area in front of the stairwell 5 of the building 1 in which supply lines lead into the building 1. In particular, the foundation frame 16 can be made significantly wider and the bored piles 17 can be attached to locations that are to the right and left of the stairwell 5.

How Figure 2 also clarified, the foundation frame 16 is attached to two reference points 18 on the front 7 of the building 1. These reference points 18 were also the reference points for carefully measuring the stairwell 5 in order to be able to prefabricate the foundation frame 16, but also all other auxiliary devices and installations for the stairwell 5, with precise dimensions. By attaching the foundation frame 16 to the two reference points 18, the foundation frame 16 is automatically correctly aligned, then using recordings and attachment points (in Figure 2 not shown) in particular to align a prefabricated elevator system exactly towards the stairwell 5 when setting it up on the foundation frame 16.

In Figure 1 a pivot bearing 19 for a stairwell module (not shown here) can be seen, the pivot bearing 19 being produced together with the foundation frame 16 during prefabrication or being firmly connected to it. The pivot bearing 19, which in the present case has two bearing points, makes it possible to pivot the stairwell module, not shown here, into the gutted stairwell 5, exactly aligned with the two reference points 18 ( Figure 4 ).

The foundation frame 16 is also provided with support points for an auxiliary scaffolding 20, so that this auxiliary scaffolding 20 can also be positioned exactly aligned with the front side 7 of the building 1 with respect to the reference points 18. Shows more about this Figure 3 :

In Figure 3 a section of the front 7 of the building 1 is shown in a side view. The front side 7 with the roof 11 and the stairwell facade 8, which is to be removed according to the invention, are indicated.

The auxiliary scaffolding 20 consists of five sections, each of which is formed from steel rails 21 and is connected to one another with releasable hinges 22. A number of cross struts 23 ensure stabilization and complete the steel rails 21 to form the auxiliary scaffolding 20.

On the foot side, the auxiliary scaffolding 20 stands on corresponding mounting points of the foundation frame 16. The individual sections of the auxiliary scaffolding 20 have each been attached to the stairwell facade 8 using dowels 24, the dowels, as in Figure 1 can be seen, where an intermediate platform 12 is arranged behind the stairwell facade 8, extending into the intermediate platform 12. The individual, floor-high sections of the auxiliary scaffolding 20 are each firmly connected to a floor-high section of the stairwell facade 8 and the associated intermediate platform 12.

A climbing platform 25 runs on the steel rails 21 of the auxiliary scaffolding 20. How better in turn Figure 1 can be seen, two concrete saws 26 sit on this climbing platform 25 in order to separate the stairwell facade 8 from the rest of the front 7 of the building 1. The saw cut runs vertically and is guided by the climbing platform 25 and thus by the precisely aligned auxiliary scaffolding 20. The saw bar of the concrete saw 26 is chosen so long that not only the stairwell facade 8 is cut off, but also the intermediate platforms 12, which from then on are only held on the auxiliary scaffolding 20 by means of the dowels 24.

In Figure 1 is on the fourth floor 3.3 (3rd floor). shown how an already separated section of the stairwell facade 8 together with the intermediate platform 12 hanging on it has been pivoted forward, away from the front side 7 of the building 1, by means of the auxiliary scaffolding 20 which can be swung out on the hinge 22 and therefore with the help of a crane 27, after loosening of the hinge 22, can be lifted away from the building 1 and placed in a designated storage location. Meanwhile, the concrete saws 26 continue to run with a further downward movement of the climbing platform 25 in order to cut out the stairwell facade 8 in a highly time-efficient manner.

Figure 4 shows building 1 Figure 1 in a later stage of the process. After the foundation 15 has been laid by prefabrication of the foundation frame 16 and setting of bored piles 17 as well as by aligning and fastening the foundation frame 16 to the reference points 18 (see also Figure 1 ) has been manufactured, the auxiliary scaffolding 20 has been attached to the stairwell facade 8 and has been successively removed in sections together with separated pieces of the stairwell facade 8 (also Figure 1 ), and in the old staircase 5 both the intermediate landings 5 and the two-flight staircase sections 13, 14 have been removed, as in Figure 4 to see, in stairwell 5 only the main landings 6... remained; the stairwell facade 8 has been removed and the stairwell 5 is therefore open to the front.

How Figure 4 now illustrated, a prefabricated stairwell module 28, which is shown here schematically twice, i.e. at different points in time, is brought to the construction site by means of a truck (not shown here) and placed on the foundation 15.

The prefabricated staircase module 28 has two bearing points 29 with which it is pivotally fastened in the pivot bearings 19 of the foundation frame 16. With the help of the crane 27, the stairwell module 28 is then pivoted into the stairwell 5 about a pivot axis defined by the pivot bearings 19, as indicated by an arrow for the pivoting direction 30. Since the pivot bearings 19 are aligned in a defined manner with respect to the reference points 18 and the stairwell 5 had been measured in advance with respect to these reference points 18, the stairwell module 28 could be prefabricated in a coordinate system adapted to the specific conditions of the building 1, with the pivot bearings being precisely aligned in advance 19 ensure an exact alignment of the stairwell module 28 to the specific stairwell 5, so that no on-site adjustment measures are necessary when the stairwell module 28 is swiveled in.

How Figure 4 along with Figure 5 , a partially cut top view of the stairwell 5, also illustrates, the stairwell module 28 with single-flight stair sections 31, webs 32 and a support structure designed as a railing 37 is prefabricated so that it can be transported with a conventional truck, i.e. in particular not together with the truck higher than 4 m. This is made possible by the fact that both the single-flight stair sections 31 and the webs 32 are provided with hinges, whereby the single-flight stair sections 31 are divided into a fixed stair section 33 and a foldable stair section 34. The webs 32 are accordingly also divided into a fixed web section 35 and a foldable web section 36. For transport, both the foldable stair sections 34 and the foldable web sections 36 are folded down, as shown in Figure 4 is shown. At the same time the railing 37 is also divided by means of hinges into a fixed railing section 38 and a foldable railing section 39, the folding railing section 39, as shown in Figure 5 is best visible, is also folded down for transport in order to minimize the overall height of the stairwell module 28.

As indicated by arrows 40, after the stairwell module 28 has been pivoted into the stairwell 5, the folded-down stair sections 34, the folded-down web sections 36 ( Figure 4 ), as well as the folded down railing section 39 ( Figure 5 ) pivoted in such a way that straight, single-flight stair sections 31 and straight webs 32 as well as a straight railing 37 result, which each run from the front 7 of the building 1 to the main platforms 6 and connect there or are attached there (cf. Figure 7 for this final state).

In order to complete the retrofitting of Building 1 with an elevator system, as in Figure 6 shown, a fully functional, prefabricated elevator system 41, which is already equipped with elevator platforms 42 and an elevator car 44, is driven to the construction site with a truck 43 and, with the help of the crane 27, is placed on the foundation 15, more precisely: on defined and reference points 18 precisely aligned contact points of the foundation frame 16 are set up. Since everything has been measured in advance in relation to the two reference points 18 and the prefabrication was also carried out in this coordinate system, the elevator platforms 42 now rest on the webs 32 and single-flight stair sections 31 of the stairwell module 28 without further alignment and can be connected to them.

Figure 7 shows a view of building 1 as in Figure 1 , wherein the method according to the invention for retrofitting the building 1 with the elevator system 41 is completed. People who travel in the elevator car 44 to a specific floor 3.3, in this case the 1st floor, can access the elevator system 41 barrier-free via the associated elevator platform 42 and the associated Walkway 32 to the main landing 6 on the 1st floor. Without using the elevator system 41, the individual floors can be reached on foot via single-flight stair sections 31, each of which runs from a main landing 6 to an elevator landing 42 on the adjacent floor.

Due to the high degree of prefabrication, there are only a few days between the in the process according to the invention Figure 1 shown initial state of the building, in which it can still be used, and the final state shown in Figure 7 of the building with a retrofitted elevator system, in which the building can be used again. Time-consuming adjustment work can be eliminated, and time-consuming work on site, such as removing the stairwell facade in particular, is time-optimized.

Claims (15)

Method for retrofitting a building (1) with an elevator system (41), which building (1) has a plurality of floors (3, 3.1, 3.2...) each with at least one floor door (4, 4.1, 4.2...). , which are accessible via a common staircase (5), the staircase (5), forming a staircase facade (8), adjoining a front side (7) of the building (1) and one on each floor (3,...). Main platform (6, 6.1, 6.2...) for the floor doors (4...) as well as an intermediate platform (12, 12.1, 12.2...) arranged on the stairwell facade (8) between the floors (3...) for a two-flight staircase (13, 14), comprising the method steps: a) attaching a foundation (15) for a prefabricated elevator system (41) in front of the stairwell facade (8), b) opening the front (7) of the building (1) by removing the staircase facade (8), c) Removing the intermediate platforms (12...), d) removing the two-flight staircase (13, 14), e) Installation of webs (32) in the stairwell (5), which extend horizontally from the main platforms (6) to the front (7) of the building (1) and only partially cover the base area of the stairwell (5) in projection to leave clear space for a single flight of stairs, f) installation of single-flight stair sections (31), each of which connects a main landing (6) or a web (32) assigned to it with an elevator landing (42) or web (32) on an adjacent floor, g) setting up a prefabricated elevator system (41) provided with elevator platforms (42) for the individual floors on the foundation (15) on the front (7) of the building (1) and attaching the elevator platforms (42) to the webs,
and or g`) Installation or attachment of elevator platforms (42), which are attached to the webs (32) or are connected to them, and h`) setting up the prefabricated elevator system (41) on the foundation (15) and attaching the elevator system (41) to the elevator platforms (42),
characterized in that i) before step (a) the geometric dimensions of the staircase (5) are measured, j) before method step (a), a foundation frame (16), which contains mounting points or receptacles for the prefabricated elevator system (41), is prefabricated according to the dimensions of the stairwell (5), in particular made of at least one steel material, and k) the prefabricated foundation frame (16) is used in method step (a) at least as part of the foundation (15). Method according to claim 1,
wherein the staircase (5) is measured with reference to at least two reference points (18) and the foundation frame (16) is aligned on site on the staircase facade (8) using these reference points (18). Method according to claim 2,
wherein two points on the front (7) of the building (1) in the area of the floor are selected as reference points (18), and the foundation frame (16) is attached directly or indirectly to these reference points (18). Method according to at least one of claims 1 to 3,
wherein the foundation frame (16) is anchored in the ground using pile foundations. Method according to claim 4,
wherein the foundation frame (16) is used as a template for inserting bored piles (17) into the ground. Method according to at least one of claims 1 to 5,
wherein the foundation frame (16) is prefabricated with a pivot bearing (19), and for method steps (e) and (f), or for method steps (e), (f) and (g`), using this pivot bearing (19) a prefabricated staircase module (28) with webs (32) and single-flight staircase sections (31) is pivoted into the staircase (5). Method according to at least one of claims 1 to 6,
wherein the foundation frame (16) is prefabricated with supports or attachment points for an auxiliary scaffolding (20), which is placed on the foundation frame (16), attached to the front (7) of the building (1) and used for method steps (b) and/or (c) and/or (d) is used. Method according to claim 7,
wherein the auxiliary frame (20) is used to guide at least one saw (26) for method step (b), in particular by means of a saw template provided on the auxiliary frame (20). Method according to one of claims 7 or 8,
wherein a climbing platform (25) attached to the auxiliary scaffolding (20) is used for method step (b) and/or method step (c) and/or method step (d). Method according to at least one of claims 7 to 9,
wherein the auxiliary scaffolding (20) is attached to the stairwell facade (8) to be removed and is removed piece by piece together with it. Foundation frame for use in a method according to at least one of claims 1 to 10,
characterized,
that the foundation frame (16) has attachment points or receptacles for a prefabricated elevator system (41) and is in particular designed as a prefabricated steel part. Foundation frame according to claim 12,
characterized,
that the foundation frame (16) is provided with a pivot bearing (19) for a prefabricated staircase module (28). Foundation frame according to one of claims 11 or 12,
characterized,
that the foundation frame (16) is provided with a support or with one or more placement points for an auxiliary scaffolding (20). Foundation frame according to at least one of claims 11 to 13,
characterized,
that the foundation frame (16) is provided with connection points for attaching the foundation frame (16) to a number of bored piles (17) for a pile foundation. Foundation frame according to at least one of claims 11 to 14,
characterized,
that the foundation frame (16) is provided with templates for inserting bored piles (17) into the ground.

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