DE3626169A1 - Foundation with pile support - Google Patents

Abstract

The invention relates to a foundation, with pile support, for buildings without a cellar, especially for prefabricated houses of skeleton construction with vertical supports which are supported on the piles and, for their part, form, with horizontal beams supported by them, prefabricated subassemblies. The object on which the invention is based is to create a foundation which can be constructed in an economical manner, i.e. rapidly and without great expense, in a dimensionally accurate manner and with reliable anchoring of the piles in the ground. This object is achieved by virtue of the fact that the pile support consists of steel-reinforced concrete piles with a boring tip made of steel and an armoured steel-reinforced concrete shank with a socket for the foot of a vertical support, and of stiffening plates, each pile passing through an aperture in a stiffening plate.

Description

The invention relates to a foundation according to the Preamble of claim 1.

Foundations of a known type consist of piles that are in are driven into the ground. The associated verti Cold supports are provided directly by the piles or by one carried on this applied base. The base is in known cases largely massive on the spot made on the piles. Such a foundation is complex to manufacture and use of materials. Around it takes strong piles into the ground not only heavy ramming machines, but often too difficult preparation of the surface. The exact one Placement of the piles and their exact vertical alignment tion require great care and therefore considerable Time expenditure. The same goes for making one Base on which, for example, a prefabricated house is put up to be judged.

The object of the invention is to establish a foundation in The preamble of claim 1 described genus create in an economical way, i.e. quickly and with little effort, accurate to size and with secure anchoring of the piles in the sod.

According to the invention, especially for Ske Lathe construction with slim vertical supports through which  Features of claim 1 solved. Reinforced concrete piles with A steel drill bit can be done with little effort Time and with simpler devices in the ground be brought. The same applies to the exact plazie and the vertical alignment of the pile. The ge exact placement is also determined by the respective Ab rigid plate, which can be angular or annular additionally relieved. The bracing plate can be there it is easy to use, especially good in front of it bring seen place. In turn, it serves as Guide for the pile to be screwed in. Also enlarge the stiffening plates advantageous to the ground pressure area Soil. A lean concrete can be used for better laying be applied. The best made of reinforced concrete shank of each pile allows a safe, and at exactly inserted pile very precise support of the proper vertical support. This is especially true then essential advantage if very slim vertical supports Find use. In addition, the great dimensional accuracy essential for the use of component sets that come from already connected vertical supports and Ho horizontal girders exist. With an exactly placed Foundation is the subsequent erection of the Bauske letts quickly, safely and with little helpers and / or -means possible.

The secure connection of every pile with its bracing plate and thus the exact placement is ensured by the Characteristic of claim 2 achieved.

Another improvement in the anchorage of the pile is guaranteed by the feature of claim 3.

An advantageous further development of the foundation gives itself through the feature of claim 4. A hat Miger base is quickly made from prefabricated elements  deliver. Its exact placement and also the hori Central alignment is without additional effort for Measurements and the like by the exact placement of the Piles secured. In this way, the base forms a good condition for a future ground floor floor it for beams or lightweight concrete slabs. An under concrete layer, for example on a ballast roller not mandatory.

A particularly easy way to get into the ground The shape of the pile is characterized by the characteristic of Claim 5 addressed.

The feature of claim 6 speaks an advantageous Further development of the foundation. The design too in the vertical direction, i.e. the exact altitude of each top of the pile and thus the base can be Already fix exactly when laying the bracing plates. This way handling and alignment is repeated simplified.

A foundation with piles according to the characteristic of the An saying 8 allows a particularly quick and exact ar at times. Strength and durability of the foundation is increased while dimensions are reduced.

That addressed by the feature of claim 11 The embodiment of the piles also offers good ones Anchoring options for the vertical supports. This is particularly important for slim supports Advantage.

An embodiment of a fundie according to the invention tion is described below using the drawings ben. Show it:  

Fig. 1 schematically parts of a frame construction started building with a foundation,

Fig. 2 shows a reinforced concrete pile,

Fig. 3 is a section corresponding to the section III-III in Fig. 2, and

Fig. 4 shows an enlarged detail in FIG. 1.

In Fig. 1, a building designated as a whole by 1 is schematically indicated by a base 2 , a skeleton of vertical supports 3 and horizontal base supports 4 erected thereon, and a schematic roof 5 . On the base 2 , bars 6 are also indicated for a floor not shown. This can also lie on lightweight concrete slabs.

Building 1 is supported by a pile foundation designated as a whole by 7 . It consists of individual reinforced concrete piles 8 , each of which supports a vertical support 3 . Each reinforced concrete pile 8 passes through a rigid plate from 9th This is based on a lean concrete layer 19 .

Fig. 2 shows an enlarged reinforced concrete pile 8 with egg ner reinforcing plate 9th The pile has a conical shaft 10 made of reinforced concrete with a basket-shaped reinforcement 17 made of non-stainless steel and a drill tip 11 arranged in the use position at the lower end of the shaft made of stainless steel. The shaft 10 also contains a receptacle 12 for a foot 3 a of a vertical support 3 . The receptacle 12 extends approximately over half the length of the shaft 10 and is open up to the end remote from the drill tip. The end portion 10 a of the shaft in this area, in contrast to the circular cross section of the rest of the shaft, has a polygonal cross section. This is indicated in Fig. 3 with ge dashed lines.

On the shaft are also four steel brackets 16 made of non-ro steel most protruding from the circumference so that they are plate 9 above the stiffener when the pile is inserted. An in-situ concrete cap 18 , after turning the pile 8 applied at this point, ver binds the reinforced concrete pile with the reinforcing plate. The steel brackets 16 serve for additional anchoring.

The bracing plate 9 has a central recess 13 .

When creating the pile foundation, the space for each pile, and thus the subsequent vertical support, is precisely marked by laying out a reinforcing plate 9 . For the stiffening plates, a support surface is cleared under the level of the humus layer and provided with a lean concrete layer. The level of the contact surface determines the later height of the pile or the vertical support foot. The reinforced concrete pile is screwed vertically with its drill tip into the dimensionally placed reinforcement plates. The diameter of the recess 13 determines, in cooperation with the outer diameter of the shaft cone, the insertion depth of the pile. This end position can be seen in Fig. 2. This explains that in Fig. 3 the recess 13 from the rigid plate 9 is not recognizable. After the exact placement of the piles in the stiffening plates and bringing on the in-situ concrete cap 18 , the soil 14 can be refilled to the desired level, as indicated in the top left of FIG. 2.

In the receptacle 12 of each pile 8 , the foot 3 a of a vertical support indicated only schematically here can be guided. There is so much free space in the receptacle 12 by appropriate dimensions that by pouring in-situ concrete - indicated in Fig. 3 the foot 3 a is firmly anchored in the pile.

Fig. 4 shows schematically how an L-shaped Sockelab section 2 a with a leg on the reinforced concrete pile 8 is supported. A recess 15 releases the receptacle 12 for the vertical support 3 . In this way, the base 2 is composed of base sections 2 a . The beams 6 or lightweight concrete slabs for a floor to be applied later can be supported on both sides of the base sections. They then span the entire free space between two opposite sides of the building. In the skeleton indicated, component sets are thought of in which one or two vertical supports and, if appropriate, cross members are articulated to a horizontal girder. Such a component set can be transported as a whole with the supports or supports pivoted to one another and set up easily at the construction site.

The foundation according to the invention from the three-part construction: pile - stiffening plate - base - thus represents a logical continuation of a complete prefabricated structure made of reinforced concrete for non-lower-limbed buildings.

Claims (13)

1.Foundation for non-basement buildings with a pile foundation, in particular for prefabricated houses in skeleton construction with vertical supports, which are supported on the piles and in turn form prefabricated component sets with the horizontal girders they support, as characterized in that the pile foundation ( 7 ) made of reinforced concrete piles ( 8 ) with a drill tip ( 11 ) made of steel and a reinforced reinforced concrete shaft ( 10 ) with a receptacle ( 12 ) for the foot ( 3 a ), a vertical support ( 3 ), and reinforcing plates ( 9 ), whereby each pile ( 8 ) has a recess ( 13 ) in a stiffening plate ( 9 ). 2. Foundation according to claim 1, characterized in that the pile ( 8 ) with the top of the reinforcing plate ( 9 ) by means of an in-situ concrete cap ( 18 ) is positively and positively connected. 3. Foundation according to claim 2, characterized in that on the reinforced concrete shaft ( 10 ) at least two, preferably four and more, over its circumference perpendicular to its axis steel bracket ( 16 ) are angeord net that they are in the in-situ concrete cap ( 18th ) he stretch. 4. Foundation according to at least one of claims 2 and 3, characterized in that prefabricated hat-shaped base elements ( 2 a ) are supported on the piles ( 8 ). 5. Foundation according to one of claims 1 to 4, characterized in that the shaft ( 10 ) of the pile ( 8 ) is formed ko nically. 6. foundation according to claim 5, characterized in that the shaft (10) in the recess (13) of the working plate is applied such that to together by the diameter of the cone of the pile shaft (10) height, the jacking of the vertical support (3) is determined. 7. Foundation according to at least one of claims 1 to 6, characterized in that the reinforced concrete shaft ( 10 ) has a basket-shaped, with the drill tip ( 11 ) welded reinforcement ( 17 ). 8. Foundation according to claim 1 to 7, characterized in that the drill tips ( 11 ) of the piles ( 8 ) consist of stainless steel. 9. Foundation according to claim 8, characterized in that the reinforcement ( 17 ) of the reinforced concrete shaft ( 10 ) consists of stainless steel and is welded to the drill tip ( 11 ). 10. Foundation according to at least one of claims 2 to 9, characterized in that the steel bracket ( 16 ) consist of stainless steel. 11. Foundation according to one of claims 1 to 10, characterized in that the receptacle ( 12 ) in the shaft ( 10 ) for the vertical support ( 3 ) has an at least sectionally from a cross section of the vertical support ( 3 ) cross-section for pouring the Vertical support ( 3 ) anchoring in-situ concrete. 12. Foundation according to one of claims 1 to 11, characterized in that the shaft ( 10 ) in the boring point most distant section ( 10 a ) has a polygonal cross section. 13. Foundation at least according to claim 4, characterized in that the base elements ( 2 a ) have recesses ( 15 ) for the vertical supports ( 3 ) and form the stock for floor beams ( 6 ) or lightweight concrete slabs.