EP3134587A1

EP3134587A1 - Mobile hall construction

Info

Publication number: EP3134587A1
Application number: EP15745421.6A
Authority: EP
Inventors: Dietmar Linke
Original assignee: Siemens AG
Current assignee: Siemens Energy Global GmbH and Co KG
Priority date: 2014-07-28
Filing date: 2015-07-21
Publication date: 2017-03-01
Also published as: WO2016016047A1; RU2656257C1; AU2015295620A1; DE102014214756A1; AU2015295620B2

Abstract

The invention relates to a mobile hall construction (1), in particular for carrying out maintenance and/or repair work on a turbine rotor (24), comprising at least one base frame (2), a plurality of support pillars (4) which are held on the at least one base frame (2), and a roof structure (6) which can be mounted on the support pillars (4), wherein the support pillars (4) are provided with at least one drive (5) and are articulatedly mounted on the at least one base frame (2) in such a way that, with the use of the at least one drive (5), they can be pivoted between a transport position and a straightened-up position relative to the at least one base frame (2).

Description

description

Mobile hall construction

The present invention relates to a mobile Hallenkon ^¬ constructive tion, in particular for carrying out maintenance and / or repair work on a turbine rotor, comprising at least a base frame, a plurality of support pillars which at least one base frame are supported on the, and a mountable to the support posts the roof structure.

Maintenance and / or repair work on a turbine runner are advantageously carried out while it is in a vertical position. In particular, the de-stacking a turbine rotor is greatly simplified ^¬ in this manner. For erecting runners with a high own weight runner systems are used in the prior art. These include a turning jack with arranged thereon

Swiveling device and at least one bearing block. In a first step, the turning block and the bearing block are set up on an industrial hall floor and aligned with each other, whereby at least the turning block is anchored to the hall floor with suitable fastening means. In a further step, the runner to be processed is placed using a crane on the turning block and the bearing block and then attached to the pivoting device provided on the turning block. Now, the runner can be transferred using the pivoting device and using a crane in the vertical position and locked in this to perform the upcoming maintenance and / or repair work on the upright runner. A problem with maintenance and / or repair work on turbine rotors is that their use requires an industrial periphery in the form of a hall with industrially manufactured base, on which the turning block and the enclosed least one bearing block arranged and in which the forces can be introduced when erecting the runner on the turning block. However, industrial halls with suitable subsoil are not available in many places, which is why these extra must be erected, which entails very high costs. Alternatively, mobile hall constructions of the type mentioned above can be used, which are set up before carrying out the work on an industrial base and dismantled after work. A problem in this context is that the mobile hall constructions must have very high altitudes for very long turbine rotors for their maintenance and / or repair, which makes the use of high cranes in the construction and dismantling of mobile Hallenkonstrukti ^¬ on the same in many places not available.

Starting from this prior art, it is an object of the present invention to provide a mobile hall construction of the type mentioned, which can be built up and dismantled despite using a large height using conventional small cranes.

To achieve this object, the present invention provides a mobile hall construction of the type mentioned above, which is characterized in that the pillars are provided with we ^¬ least one drive and are hinged to the at least one base frame that they using the at least one drive between one

Transport position and an erect position relative to the at least one base frame are pivotable. Thanks to this configuration, the pillars of the mobile hall construction according to the invention can be erected independently, which is why it is possible to dispense with the use of high cranes.

Preferably, each buttress is held on a separate base frame. This results in a modular design aims, in which the individual base racks can be easily transported and handled.

The dimensions of the base frames are advantageously chosen such that they can be transported in containers of standardized dimensions. Accordingly, the transport of the mobile hall construction to air, water and land is not a problem. Preferably, the base racks and / or the container with the base racks arranged therein are connected to each other connectable, so that the rigidity of the construction he ^¬ height, if necessary is. The at least one drive is advantageous as Hydraulikan ^¬ drive provided, in particular as at least one both with the at least one base frame and one of the

Support pillars of articulated hydraulic cylinder. This leads to a simple technical implementation of the automatic erectability of the abutments.

According to one embodiment of the present invention, each buttress is provided with its own drive, wherein the drives can advantageously be moved simultaneously using a suitable software.

The roof structure is preferably hingedly connected to the support pillars. This is to the advantage that the roof ^{¬ construction} in the state in which the pillars are in their transport position, mounted and then can be pivoted together with the pillars. Accordingly, the installation of the roof structure can be carried out at low altitude, which time, cost and risk potential for staff can be reduced.

The roof structure preferably has at least one load crane. In other words, at least one load crane is integrated in the roof structure, so that no separate load crane in the shark must be constructed to handle loads within the hall.

According to one embodiment of the present invention, the hall construction has a height of at least 12 m.

The length of the hall construction is preferably at least 17 m. The width of the hall construction advantageously has at least 11 m.

Other features and advantages of the present invention will become apparent from the following description of a hall structure according to an embodiment of the present invention with reference to the accompanying drawings. This is / are

1 shows a schematic representation of a mobile hall construction according to an embodiment of the present invention;

Figures 2 to 11 are schematic diagrams showing successive steps during assembly of the hall structure shown in Figure 1;

FIGS. 12 to 14 are schematic representations showing the use of the mobile hall construction shown in FIG. 1 in carrying out maintenance and / or repair work on a turbine runner; and

Figure 15 is a schematic representation of a mobile hall construction according to another embodiment of the present invention.

The mobile hall construction 1 comprises as main components six identically constructed base frames 2, which are arranged on an industrial base 3, six likewise identical support pillars 4, each of which is articulated to one of the base racks 2 and pivotable relative to the base frame 2 by means of a drive 5, and a roof structure 6, which is mounted on the pillars 4.

Each base frame 2 comprises a substantially rectangular base frame 7. The one free end of the base frame 7 is provided with an upwardly projecting bearing means 8, on which the associated supporting pillar 4 is pivotally supported between a horizontal transport position and a vertically erected position. At the other free end of the base frame 7, two support ^¬ post 9 are provided, on which the buttress 4 is supported in its horizontal transport position. The drive 5 comprises two hydraulic cylinders which are articulated both to the base frame 7 of the base frame 2 and to the support pillar 4. Accordingly, the support pillar 4 can be pivoted by appropriate extension and retraction of the hydraulic cylinder between its transport position and the erected position. The dimensions of each Basisge ^¬ stells 2 are selected such that this can be transported with standardized dimensions in a con tainer ^¬ 10th The roof structure 6 comprises vertical beams 11, which articulates at its lower free end with the support pillars 4

are connectable. The vertical supports 11 are connected to one another via two horizontal supports 12, the horizontal supports 12 simultaneously serving as guide rails for crane bridges 13 of two cranes 14, along which a trolley 15 can be moved in a known manner. A roof strut construction 17 of the roof structure 6 is fixed to outriggers 16 extending outwards from the vertical supports 11 and covered with a tarpaulin 18. The sidewalls of the hall construction 1 are also provided with a corresponding tarpaulin 19. With reference to FIGS. 2 to 11, the assembly of the hall construction 1 shown in FIG. 1 will be explained below. In a first step, the industrial substrate 3 for the hall construction 1 is manufactured, as shown in FIG. In the present case, the industrial sub ^{¬ base} 3 consists of a plurality of bottom plates 20 which are fastened together. Alternatively, however, the industrial substrate 3 may be constructed in a conventional manner using concrete. On the industrial substrate 3, a turning block 21 with integrated pivoting device and a bearing block 22 are also mounted, which are needed for erecting a turbine rotor for the purpose of performing maintenance and / or repair work.

In a further step, the base racks 2 with the support pillars 4 received thereon are removed from the containers 10 and placed on the industrial base 3, as shown in FIG. The base frames 2 can be fixed to the industrial substrate 3 and / or to each other in order to increase the rigidity of the arrangement. Alternatively, however, the hall construction 1 can also be designed in such a way that the base racks 2 remain in the containers 10, the containers 10 being aligned with each other after removal of the container covers and attached to one another and / or to the base 3. In this case, the finished hall construction 1 is then bordered at the bottom by the side of the containers 4, as shown in FIG. Incidentally, the construction shown in Fig. 15 corresponds to the construction shown in Fig. 1, and thus the same or similar components are given the same reference numerals. Subsequently, the vertical beams 11 are attached with the arms 16 arranged thereon articulated to the free ends of the pillars 4, as shown in Figure 4. Thereafter, the vertical beams 11 are interconnected using the horizontal beams 12 of FIG. In a further step, the crane bridges 13 of the cranes 14 are mounted with the trolleys 15 arranged thereon between the horizontal supports 12, whereby the rigidity of the roof construction is increased. Should it be necessary, in order to further increase the rigidity, it is additionally possible to provide these cross members which interconnect these in the region of the free ends of the horizontal supports 12, even if this is not shown here.

According to Figure 7, the roof strut construction 17 of the roof structure 6 is then attached to the arms 16 of the vertical support 11.

Then the tarpaulin 18 can be attached to the roof strut construction 17 according to FIG.

Referring now to Figures 9 and 10, the pillars 4 are now transferred from their horizontal transport position to their vertical erected position using the drives 5. Thanks to the fact that the vertical supports 11 of the roof structure 6 hingedly attached to the pillars 4, the roof structure remains 6 during the on ^¬ straightening process in the horizontal position.

To reinforce the hall construction 1, the support pillars 4 are connected to one another in a further step according to FIG. 11 using stiffening struts 23.

In a final step, as shown in Figure 1, the tarpaulin 19 is mounted.

In reverse order, the hall construction 1 can also be dismantled again. A significant advantage associated with the previously described mobile hall construction 1 is that this can be thanks to the automatically by means of the drive 5 on ^¬ directional support pillars 4 without the use of a high crane to assemble and disassemble.

It should be noted that, in particular the number of base frames 2, the pillar 4 and the actuators 5 in constructive tion from ^¬ dependence on the desired dimensions of the Hallenkon- 1 is variable. Furthermore, it is possible for the supporting pillars 4 and / or the vertical supports 12 to be dependent on the desired height of the hall construction 1

telescopically to ensure that the individual components and modules of the hall structure 1 can be transported in containers 10 with standardized dimensions.

FIGS. 12 to 14 show, by way of example, the erection of a turbine rotor 24 using the turning block 21, the bearing block 22 and a crane 14. In a first step, the turbine rotor 24 to be machined is laid on the turning block 21 and the bearing block 22 using the crane 14 and then attached to the provided on the turn block 21 pivoting device. Now, the turbine runner 24 can be transferred using the pivoting device and using the crane 14 in the vertical position and locked in this to perform the upcoming maintenance and / or repair work on the upright turbine runner 24. In particular, the turbine rotor 24 can be unstacked easily in this position.

Although the invention has been further illustrated and described in detail by the preferred embodiment, the invention is not limited to the disclosed examples, and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

Claims

claims

1. Mobile hall structure (1), in particular for imple ^¬ tion of maintenance and / or repair work on a turbine rotor (24) comprising at least a base frame (2), a plurality of support pillars (4) attached to the at least one Basisge ^¬ alternate ( 2), and a roof structure (6) which can be mounted on the supporting pillars (4), characterized in that the supporting pillars (4) are provided with at least one drive (5) and are articulated to the at least one base frame (2), in that they can be pivoted relative to the at least one base frame (2) by using the at least one drive (5) between a transport position and an upright position.

2. hall construction (1) according to claim 1, characterized in that each supporting pillar (4) on a separate base frame (2) is held.

3. hall construction (1) according to claim 2, characterized in that the dimensions of the base racks (2) are selected such that they can be transported in containers (10) with standardized dimensions.

4. hall construction (1) according to claim 2 or 3, characterized in that the base racks (2) and / or the Contai ^¬ ner (10) with the base racks (2) arranged therein are designed to be connected to each other mitein-.

5. hall construction (1) according to one of the preceding claims, characterized in that the at least one on ^¬ drive (5) is provided as a hydraulic drive, in particular as at least one with both the at least one Basisge ^¬ stell (2) and with one of Support pillars (4) articulated hydraulic cylinder.

6. hall construction (1) according to one of the preceding claims, characterized in that each supporting pillar (4) is provided with its own drive (5).

7. hall construction (1) according to one of the preceding claims, characterized in that the roof structure (6) ge ^¬ lenkig with the support pillars (4) is connected.

8. hall construction (1) according to any one of the preceding claims, characterized in that the roof structure (6) to ^{¬ at} least one load crane (14).

9. hall construction (1) according to one of the preceding claims, characterized in that it has a height of at least 12 m.

10. hall construction (1) according to one of the preceding claims, characterized in that it has a length of at least 17 m.

11. hall construction (1) according to one of the preceding claims, characterized in that it has a width of at least 11 m.