DE2451134A1 - High rise concrete skeleton building sliding formwork erection - with verticals to storey height, and ceiling formwork retained until load bearing - Google Patents

Abstract

The process, for the erection of storeyed buildings, on the reinforced-concrete skeleton structural system, involves the use of the sliding-formwork method. Columns and walls, and other vertical parts of the building are erected to storey height on the sliding system and the formwork for the ceiling of the storey is advanced together with the sliding formwork, by means of commonly shaped hoist devices (3). When storey height is attained, the storey ceiling is erected, the sliding formwork being retained in place while this operation is in progress, until the storey ceiling has attained its own load bearing capacity. There may be a pause in concreting before commencement of the erection of the vertical elements for the next storey.

Description

Method for the production of multi-storey buildings The invention relates to a process for the production of multi-storey buildings in reinforced concrete frame construction below Use of slipform construction.

There have been repeated high-rise buildings with the help of slipform construction been erected. The creation of the individual floor slabs poses a major problem represent.

In a known embodiment, the entire vertical Part of the building erected and then the floor slabs with the help of slab formwork created, which is lowered from the top floor ceiling.

This construction requires a strong oversizing of all vertical ones Parts of the building, as these are initially not stiffened by any ceilings or beams. The high concreting performance achieved with the slipform can be translated into in this case even have a detrimental effect. Another problem is the connection of the storey ceilings with the vertical parts of the building. For this purpose Openings are provided in the walls at short intervals at the level of each floor ceiling, which can only be created with a considerable amount of work, since the Reinforcement in the openings must be exposed.

In other known embodiments, the floor slabs created from prefabricated parts. Here too, a satisfactory stiffening of the vertical components not reached. The ceiling supports are only possible with great effort and expense to create and to close the joints at the connection points of the prefabricated parts.

The scope of the vertical reinforced concrete components is in the case of those mentioned Embodiments always very large. This also requires extensive slipform equipment, whose economic use is to be improved in that without interruption and is concreted in several work shifts. This uninterrupted sequence of work is only possible with high labor costs and a great deal of work on machines and equipment feasible. It would also be difficult to find appropriate staff for such To have tasks ready. With this uninterrupted way of working, it becomes impossible to take full advantage of all the additional advantages of the slipform construction in particular through the precise installation and setting in concrete of finished components, Facade cladding, installation devices, brackets, etc. result.

The object of the invention is to provide a particularly economical process for the production of buildings with single storeys to create which the application the slipform construction.

This object is achieved with the method characterized in claim 1 solved.

Further advantageous embodiments of this method and according to the invention Devices for carrying out the method are listed in the subclaims.

A major advantage of the invention is that it is monolithic Construction method for the entire StiSbetonskelettbau, whereby each floor ceiling directly concrete is poured onto the walls and supports. All reinforced concrete components are made without Consideration for the sliding formwork construction only according to the statically required Designed from a point of view. The savings in building material that can be achieved in this way and the slipform equipment is beneficial to the cost of construction of Shell from.

Another advantage of the invention is that it is continuous Construction process for normal gag shifts and in the relatively small proportion on slipform equipment compared to the cross-sectional dimensions of the structure. The construction process for the creation of a storey begins with the concreting of the Walls and columns up to the lower edge of the next floor ceiling.

All components, installations, etc., which are set in concrete, are to be attached to the appropriate places beforehand. The steady start-up the sliding formwork is interrupted as soon as the slab formwork has completed the corresponding Has reached height and is aligned by means of the lifting devices. In the next The work section is carried out after the slab reinforcement has been put in place and the Components etc. concreted the floor slab. The length of the pause in concreting that now follows is determined by the length of time until the self-supporting capacity of the floor slab, from the scope of the preparatory work for the next floor and the scope the elaborations of the last floor. The self-supporting capacity of the floor slab depends on many factors and can be timed by appropriate devices to be influenced.

Another advantage of the invention is the high dimensional accuracy all vertical and horizontal reinforced concrete components made with this slipform process be achieved. The approximately 1.20 m high formwork panels of the sliding formwork are on sliding frames attached. The distance is determined by means of suitable reinforcements between the sliding frames of the sliding formwork to each other during the entire construction process. The alignment of the formwork for the storey ceiling is made by adjusting the lifting devices performed on the climbing poles. This setting and the horizontal alignment the sliding frame and thus also the sliding formwork and the slab formwork is easy to implement and is well known in slipform technology.

Another advantage of the invention is the design of the Slab formwork. The weight of the floor slabs is up to their own load-bearing capacity Transferred to the carrier via the tie rods. This arrangement enables it to be used of large-area and light formwork panels, which make handling them much easier will. According to a special feature of the invention, the ceiling formwork consists of predominantly narrow formwork panels that are attached to the tie rods and are made of large-area Formwork panels that are placed between the narrow formwork panels and by means of suitable Brackets are attached to these. This arrangement allows for early repositioning of the large formwork panels, as the weight of the floor slab continues to exceed the Tie rods is transferred to the carrier. When using a second sentence of narrow formwork panels, the next slab formwork is placed before the start of concreting of the next floor completed.

Embodiments of the invention are shown in the drawing and are described in more detail below. They show: FIG. 1 a sectional view of the device according to the invention FIG. 2 is a sectional view of the device according to the invention Device after the completion of a complete floor Fig. 3 is a sectional view View of the device according to the invention during the erection of the vertical Components of a storey Fig. 4 is a plan view of the ceiling formwork.

The sliding formwork consists of the formwork 1, which is attached to the sliding frame 2 is attached, from the lifting device 3 and from the climbing pole 4. Means the lifting device is the sliding frame with the cladding on the climbing pole pulled up. The sliding frames are connected to one another by carriers 6 and to one another stiffened. Tie rods 7 projecting beyond the lower chord are arranged on the girders. At the ends of the tie rods is a certain distance from the lower edge of the beam the ceiling formwork 5 attached.

In Fig. 1 are two sliding frames with the formwork, a carrier and the slab formwork shown in section.

In Fig. 2, the same casing is shown in section according to the completion of a floor.

This position is used by the formwork during the pauses in concreting adhered to. The external finishing work is carried out from the suspended scaffolding 8.

In Fig. 3 the casing is shown in section and shows the concreting process during the creation of the vertical building sections of one storey.

In Fig. 4, the division of the ceiling formwork is in plan view shown in narrow formwork panels 11 and in large formwork panels 12.

Claims (12)

Patent claims: ~ t 1., Process for the production of multi-storey buildings in steel ~ 'concrete skeleton construction using the slipform construction method, which means that it is not shown, that, a) the vertical parts of the building, such as columns and walls, up to floor level in B) the formwork for the floor slab when erecting of the vertical parts of the building together with the sliding formwork by means of shared lifting devices is raised, c) after reaching the storey height, the storey ceiling is made is, the sliding formwork during this Hertstellvorgangs in its position pauses until the floor slab has reached its own load-bearing capacity. 2. The method according to claim 1, characterized in that g e k e n n -z e i c h n e t that a pause in concreting is planned after the completion of a floor slab, before starting to erect the vertical building sections on the next floor will. 3. The method according to claim 2, characterized in that g e k e n n -z e i c h n e t that the slab formwork for the next floor slab is put together during the concreting break is prepared with the slab reinforcement. 4. The method according to claim 2, characterized in that g e k e n n -z e i c h n e t that during the concreting break the arrangement and alignment of the vertical parts of the building Components, brackets, installation devices to be set in concrete on the next floor and the like takes place. 5. The method according to claim 2, characterized in that g e k e n n -z e i c h n e t that during the concreting break with the help of suspended scaffolding attached to the sliding formwork the expansion of the produced storey takes place. 6. Apparatus for performing the method according to claim 1, characterized it is not noted that girders connected to the frame of a sliding formwork it is provided that the girders have tie rods protruding beyond the lower chord, and that at the ends of the tie rods at a certain distance from the lower edge of the carrier Formwork panels are attached to shuttering a floor slab. 7. Apparatus according to claim 6, characterized in that g e k e n n -z e i c h n e t that the lifting device for lifting the sliding formwork and the carrier from hoists consists of climbing poles arranged in the vertical parts of the building er. 8. Apparatus according to claim 6, characterized in that g e k e n n -z e i c h n e t that the length of the tie rods protruding beyond the lower edge of the girder is greater, than twice the height of the ceilings to be produced. 9. Apparatus according to claim 6, characterized in that g e k e n n -z e i c h n e t that the ceiling formwork consists of predominantly narrow formwork panels attached to the Tie rods are attached and made of large formwork panels between the denalen Formwork panels are arranged and attached to them by suitable brackets are. 1o. Apparatus according to claim 6, characterized in that it is n -z e i c h n e t that the formwork panels are open at their edges for receiving of the tie rods. 11. The device according to claim 6, characterized in that g e k e n n -z e i c h n e t that the lower chord of the girder serves as a measuring basis for the ceiling surface to be produced serves. 12. The device according to claim 11, characterized in that g e k e n n -z e i c h n e t that auxiliary devices for processing the ceiling surface are arranged on the supports and are guided.