EP0340599A1 - Adjustable bottom slab for high buildings and method for its production - Google Patents

Abstract

In the case of an adjustable bottom slab for high buildings on soils susceptible to settlement, in particular over-consolidated clays which form laminations, at least one adjustable space is provided under the bottom slab in the soil. So that an accurate adjustment can be made within a wide adjusting range even after completion of the carcass, fixed chamber walls (4 - 9) are connected to the bottom slab (18), which chamber walls (4 - 9) extend essentially vertically below the bottom slab (18) into the soil (11, 12) and laterally define chambers (2, 3) open at the bottom. Extending into each of the chambers is at least one injection tube (15, 16) into which an injection material can be injected. <IMAGE>

Description

The invention relates to a controllable floor slab of high-rise buildings on settlement-sensitive floors according to the preamble of claim 1. Another aspect of the invention relates to a method for producing such a controllable floor slab and for controlling this floor slab.

Foundations of high-rise buildings in subsidence-sensitive floors experience partially different settlements, which thus cause skewing of the building. These misalignments become problematic with increasing building height, e.g. because they can cause faults in installations in buildings, such as elevators. Attempts have therefore already been made to create foundations with controllable floor slabs of high-rise buildings, with which such uneven settlement can be avoided or, if they have occurred, compensated for.

The invention relates in particular to those foundations which take place in the tertiary, namely in over-consolidated tones, or in younger layers immediately above, such as quaternary or young fillings. These overconsolidated clays represent relatively solid soils that are characterized by - almost horizontal - lamella formation or leathering. An example of such an over-consolidated tone is the so-called Frankfurt tone.

According to the prior art, non-controllable shallow foundations are usually carried out in the form of a floor slab, which is designed according to the center of gravity of the building to be erected above it and under the geology. The foundation takes place in the tertiary or younger layers immediately above. Any necessary adjustments to the structure must be made by applying dead loads above the foundation, ie the floor slab, or by inserting presses into the body-in-white. - The disadvantage is that a targeted, permanent intervention in the adjustment of the building is difficult because the dead loads applied above the foundation plate only have an indirect effect and deformations can only be tracked over a long period of time and insufficiently corrected. The adjustment options in the shell above the foundation slabs are limited in time and must be abandoned in the final state. Adjustment in the shell leads to an undesirable polygon in the structure; Compensation levels and drag plates are inevitable.

In a case in which different settlements were to be expected under the high-rise foundation due to the geology, a controllable base plate according to the preamble of claim 1 with an adjustment option under the base plate has been provided. For this purpose, water cushions made of a plastic, which is known under the trade name "neoprene", have been arranged as an adjustable volume under the foundation. The skyscraper could be adjusted by draining water from individual water cushions in the raw state of the skyscraper. After the settling, which had been temporarily balanced, had subsided, the water was replaced by cement milk, which then hardened to cement stone. - This adjustment option between the foundation plate and the floor by means of water cushions, which are characterized by flexible walls, has various disadvantages: Generally, the water cushions made of plastic are poorly suited for use on construction sites and often leak before the final installation, which endangers the entire adjustment system. The adjustment itself can only be carried out to a limited extent and downwards because the maximum height of the water cushions is limited by their geometry and the cushions can only be adjusted to be flatter by draining off adjustment liquid or water. Since the ratio of the height of the cushion to its width is not fixed due to the flexible walls, the drained liquid volume is not always a linear measure of the lowering. In addition, the control of the base plate with water cushion is not suitable for subsequent adjustment after replacement of the Adjustment fluid through cement milk and its hardening.

In order to subsequently adjust a skyscraper that has already been misaligned, it is already known to provide fan-like bores from the side under the skyscraper, into which injection lances are introduced. Injection material is then pumped through the injection lances into the ground, which is to be lifted in a controlled manner. - The disadvantage of this control is the high outlay for the large number of necessary bores and injection lances, which are to be arranged in a fan shape. Nevertheless, according to this method, which is also referred to as soil fracturing method, a partial lifting of the structure is difficult to control, including because the injection spaces are not limited. Since the injection material can spread indefinitely, the injection material consumption is high and the floor is heavily stressed by the spreading of the injection material. Due to the imprecise metering and lifting, the structure can be overstressed.

In order to avoid partial subsidence from the outset, so-called mixed foundations are also known, in which large bored piles are arranged below a base plate. As a result, part of the loads are placed over the slab surface and part of the loads are placed over the piles derived to bridge ground inhomogeneities. - However, the necessary bored pile work under the foundation bed is costly and can extend the overall construction time. Settlements are reduced, the higher the load-bearing part of the piles, however, there is no possibility of adjustment under the plate, since the piles claw in the ground and counteract a setting of the foundation plate that is desired for adjustment.

The invention has for its object to develop a controllable base plate according to the preamble of claim 1 with the associated control measures so that a particularly accurate, targeted adjustment can be done with a large adjustment range, even after completion of the shell. This is intended to enable extensive, even retrospective, compensation of partial subsidence, so there are possibilities for readjustment.

This object is achieved by the further development of the controllable base plate and by the design of the adjustable volumes provided between the base plate and the base.

The essence of the invention is that under the base plate defined by the laterally firmly delimited chambers to that extent partial volumes in which injected material essentially only results in a corresponding variable change in height of the partial volume, the height being practically unlimited due to the chambers open at the bottom for adjustment purposes is. The solid chamber walls delimiting the chambers adjoin the floor, in particular over-consolidated clay, both outside and inside the chambers. The bottom plate is therefore carried directly from the ground before adjustment, without the need for additional measures. The manufacture of the chamber walls, which will be described further below, is not cost-intensive and can take place immediately after the formation of the cleanliness layer - a sub-concrete slab. During the adjustment process by pumping injection material, it cannot spread beyond the chamber walls, so that the injection material consumption is low. The combination of the sub-chambering of the base plate in over-consolidated clays, which also form lamellae within the chambers, is advantageous. These lamellae can be supplied with injection material one after the other through the inserted injection tubes, so that adjustment processes at different times without mutual interference are possible in a low-cost manner, for which purpose the lamella layer connected to an adjustment tube is first cracked by a pressure surge.

It is advantageous in the sub-chambering of the floor slab according to the invention that the floor slab has contact with the subsurface like in a normal shallow foundation without the possibility of adjustment. By injecting injection material, a laterally defined cavity can be created within each chamber, which is filled with grout. It is essential that the pressing volume in each individual chamber can be set individually and that each individual chamber can be acted on with a different pressure and / or a different material to be pressed, so that the adjustment in the form of a partial elevation can be adjusted locally to the background conditions can. Inadmissible stresses on the base plate are avoided. The amount of the correction is unlimited. The adjustment options with regard to the expected partial settlements can already be arranged and The formation of the chambers should be taken into account by not necessarily distributing the chambers evenly under the entire base plate and forming them with the same partial volumes, but rather at the points at which the need for lifting is to be expected. The chamber arrangement can also be adapted to the statically necessary requirements. The embodiment according to claim 8 is suitable, for example, in cases in which a pivot point is formed in the area of the base plate that is not sub-chambered.

The geometry of the chambers can be flexibly adapted to the different geological and static conditions. The base areas of the individual chambers can e.g. be round, oval or angular. - No exceptional requirements are imposed on the injection material, here hardening liquids can be selected from emulsions, solutions, suspensions, pastes and mortars made of solids or synthetic resins according to DIN 4093 and DIN 18309 depending on the requirements. A mixture of bentonite and cement is preferred which obtains clay-like properties when solidifying, which can be cracked for further adjustments if necessary. Clay materials that remain plastic are particularly suitable for chambers that lie below the building's pivot points. If, on the other hand, it is only a question of partially filling the volumes of the chambers with hardening material for adjustment, cement milk can be used. A special hardness, which is suitable for sandy soils, can be achieved with silicates as injection material.

In a preferred arrangement, the chamber walls can extend into the floor under a layer of cleanliness, which can consist of sub-concrete or another separating layer and which is slotted at the position of the chamber walls. The chamber walls can, if consisting of concrete, thereby advantageously be produced at the same time as the cleanliness layer. In this case, the base plate lies over the cleanliness layer on the chamber volumes. - However, other embodiments are also conceivable in which the chamber walls extend above the cleanliness layer.

The injection tubes are preferably introduced into the chambers from above through the base plate and, if appropriate, the cleanliness layer. - In an alternative, which generally requires longer injection tubes, but does not require an opening in the base plate and possibly the cleanliness layer, the injection tubes can also be inserted laterally into the chambers from below.

The arrangement according to claim 5 is advantageous, according to which it is provided that a plurality of injection tubes extend into each chamber, the openings of which are at different heights. The openings are therefore staggered in different layers in the floor in the chamber. This arrangement is particularly suitable for several successive adjustment processes, the material injected for adjustment in the meantime becoming hard in the meantime. With each adjustment process, a cavity is formed in a different layer or lamella of the floor, which, if necessary, can be cracked beforehand.

Subsequent adjustment can be carried out with little effort if a layer of material to be injected previously into a chamber is drilled through from an injection tube located above it, so that further material to be injected can be introduced into a deeper layer.

For the purpose of specifying cavity layers, the casings for the material to be injected can be inserted into these casings during the manufacture of the chambers, into each of which an injection tube opens. As a result, cracking processes can largely be dispensed with.

The chamber walls can be flexibly selected according to claims 9-12, depending on the special requirements of the building, its foundation and the geological conditions. However, it is important that the chamber walls are firm enough to withstand the injection pressure and also any cracking process that may take place before the injection, so that the chamber volume is limited laterally and the advantageous effects of the adjustment can occur.

The lifting of the chambers occurring during the adjustment can be facilitated by a sliding layer on the chamber walls, so that correspondingly lower injection pressures are sufficient.

A particularly advantageous method for producing the controllable base plate and for controlling the base plate and the chambers used for this purpose is according to claim 15 according to a further aspect of the invention is that after excavating an excavation pit and producing a separating layer between the floor and the subsequent base plate is provided, from the level of the separating layer from solid, essentially vertical chamber walls laterally limited, downwardly open chambers are produced, which close up close to the base plate, that ends of injection tubes are inserted into the chambers and that after the base plate and Erection of the high-rise building in the shell, depending on the differences, predetermined quantities of hardening grout are injected into selected chambers.

In this manufacturing process, the normal foundation work and construction progress are minimally hampered; the construction time is short. Normally, no injection needs to be carried out, only when differences occur, are these controlled by predetermined quantities of injection material in the individual chambers different pressures balanced. The necessary pressing volume is known from the subdivision with chamber walls, so that time-consuming tests and adjustment processes can be omitted here. The injections can also be carried out several times if necessary. Correction processes are also possible after the end of the shell construction phase without major expenditure. The system for controlling the base plate produced in this way is particularly robust.

The injection tubes forming part of the adjustment system can consist of metals or plastics and can be designed as hoses.

They are preferably straight, laid from above into the chambers, so that a hardened injection material layer can be drilled through them so that the injection material introduced for the next adjustment reaches a deeper layer.

Regarding the multiple injection in different layers in the chamber, it is pointed out that here too there is an advantageous interaction with overconsolidated clays, which form lamellae, since largely independent cavities are formed for receiving the injection material.

• Fig. 1a einen vertikalen Schnitt durch eine Ausführungs­form der steuerbaren Bodenplatte mit den zur Steuerung vorgesehenen Kammern,
• Fig. 1b ein zugehöriges Bodenprofil als Beispiel,
• Fig. 2 eine Unteransicht auf die Kammern (Grundriß) und
• Fig. 3 einen senkrechten Schnitt durch eine alternative Ausführungsform einer Kammer.

The invention is explained below with reference to a drawing with four figures. Show it:

• 1a is a vertical section through an embodiment of the controllable base plate with the chambers provided for control,
• 1b an associated floor profile as an example,
• Fig. 2 is a bottom view of the chambers (floor plan) and
• Fig. 3 shows a vertical section through an alternative embodiment of a chamber.

In Fig. 1, a cleanliness layer initially made of sub-concrete or as a separating layer is designated by 1. Chambers, for example 2, 3, with a rectangular plan are arranged under the cleanliness layer. They are laterally delimited by essentially perpendicular solid walls which extend through slots 13, 14 in the cleanliness layer and merge tightly into a base plate arranged on the cleanliness layer. The base plate supports the building. Continuous walls on the outer circumference of the entire chamber arrangement are designated by 4-7, further walls for internal division by 8 and 9. For example, chamber 2 is laterally delimited by walls 4, 7, 8 and 9. As can be seen in particular from FIG. 1 a, the chambers are open at the bottom and include bottom 10. As can be seen from FIG. 1b, the chambers lie in the tertiary 11, while a quaternary layer 12 is located in the region above the chambers.

Injection tubes extend into the chamber walls from above, e.g. 15, 16, 17. The injection tubes are guided downwards through the base plate 18 and the cleanliness layer 1.

In Fig. 3 it is shown how individual injection tubes 19-21 through a base plate 22 and a separating layer 29 as injection material guides into different injection bladders 23, 24, 25, which are formed by shells for injection material, in a side bounded by walls 26, 27 Pass chamber 28 open downwards.

Claims (22)

1. Controllable floor slab of high-rise buildings on settlement-sensitive floors, in particular overconsolidated clays, which form lamellas, at least one adjustable volume being provided in the floor under the floor slab,
characterized,
that with the bottom plate (18) below this in the bottom (11, 12) substantially vertically extending, fixed chamber walls (4-9) are connected, the downwardly open chambers (2, 3) laterally, and that in each the chambers have at least one injection tube (15, 16) into which an injection or grout can be injected. 2. Controllable base plate according to claim 1,
characterized,
that the chamber walls extend into the floor under a cleanliness layer (1) on which the base plate lies and which is slotted at the position (13, 14) of the chamber walls. 3. Controllable base plate according to claim 1 or 2,
characterized,
that the injection tubes (15, 16) from above through the base plate (18) and optionally the cleanliness layer (1) are introduced into the chambers (2,3). 4. Controllable base plate according to claim 1 or 2,
characterized,
that the injection tubes are inserted laterally into the chambers from below. 5. Controllable base plate according to claim 3 or 4,
characterized,
that in each chamber several injection tubes (19, 20 21) reach, the openings of which are at different heights. 6. Controllable base plate according to one of the preceding claims,
characterized,
that shells for the injection material are inserted within the chamber, into each of which an injection tube opens. 7. Controllable base plate according to one of the preceding claims,
characterized,
that the entire floor plan of the base plate is sub-chambered with a large number of chambers (for example 2, 3) which directly adjoin one another. 8. Controllable base plate according to one of claims 1-6,
characterized,
that the floor plan of the floor slab, with the exception of a predetermined area, is sub-chambered with a plurality of chambers. 9. Controllable base plate according to one of the preceding claims,
characterized,
that the chamber walls consist of in-situ concrete. 10. Controllable base plate according to one of claims 1-8,
characterized,
that the chamber walls are made of precast concrete. 11. Controllable base plate according to one of claims 1-8,
characterized,
that the chamber walls are designed as a diaphragm wall. 12. Controllable base plate according to one of claims 1-8,
characterized,
that the chamber walls are designed as an overcut bored pile wall. 13. Controllable base plate according to one of claims 1-8,
characterized,
that the chamber walls are made of sheet steel. 14. Controllable base plate according to one of claims 1-8,
characterized,
that the chamber walls are composed of steel profiles. 15. Controllable base plate according to one of claims 1-8,
characterized,
that the chamber walls are made of wood. 16. Controllable base plate according to one of the preceding claims,
characterized,
that the chamber walls are provided with a sliding layer. 17. Process for the production of a controllable floor slab of high-rise buildings on soils sensitive to settlement, in particular over-consolidated clays that form lamellas, and for controlling the floor slab,
characterized,
that after excavating an excavation pit and making a separating layer between the ground and the later Bottom plate is provided, from the level of the separation layer with solid, essentially vertical chamber walls laterally limited, downwardly open chambers are made, which are sealed off at the top by the bottom plate, that ends of injection tubes are inserted into the chambers and that after the creation of the Base plate and erection of the high-rise building in the shell are injected into selected chambers depending on the differences in predetermined amounts of hardening grout. 18. The method according to claim 17,
characterized,
that the injections in the individual chambers are controlled at different pressures. 19. The method according to claim 17,
characterized,
that the injection is repeated. 20. The method according to claim 19,
characterized,
that the multiple injection takes place in different layers in the chamber. 21. The method according to claim 20,
characterized,
that deeper layers are drilled through an injection tube and the hardened grout through for multiple injection under hardened grout. 22. The method according to any one of claims 17-29,
characterized,
that each injection process is preceded by a cracking process in which a bottom layer is broken up in the chamber.

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