SK500462015U1 - Base of overground construction element, in particular column and/or mast, method of creating the base and tools for creating the base - Google Patents

Abstract

The foundation (1) has a steel supporting hollow tube (2) adapted to be hammered into the ground. The pipe (2) has a closed circular or polygonal, or elliptical cross-section, and the length of the pipe (2) is at least twice its diameter. The pipe (2) can be made as a weld of two bent halves which are joined by two longitudinal welds. The base (1) may have at least one lamella (3) attached to the tube housing (2). The connecting element has a ring (4) with holes and stiffeners (5) attached to the pipe surface (2). The rim (4) is intended to attach a flange of an above-ground structural element (8). The attachment element may have an adjustment mechanism to achieve a different angular position of the base axis (1) to the above-ground structural element (8). A steel base (1) is placed vertically on the base at the base (1) and the pipe (2) is pressed into the substrate by repeated strokes. The ram rests on the foundation directly or through the spacer (13). At the start of the hammering, the base (1) can be held upright by the support arms (12) of the support (10).

Description

Foundation of an above-ground building element, in particular a mast and / or mast, method of foundation foundation and foundation foundation aid

Technical field

The technical solution relates to a foundation of an above-ground element, in particular a column and / or a mast, in which the foundation is formed in a dry way without concreting and without excavation work. The technical solution also describes a new method of loading columns and / or masts by means of vibrational hammering and describes aids that facilitate the implementation of this method.

BACKGROUND OF THE INVENTION

In the most common way of laying poles or masts in the field, a pit with sufficient depth is excavated, the bottom of the mast or mast is inserted and the pit is poured with concrete, the top of the mast or mast is temporarily fixed in a vertical position.

The concrete bed usually has a bottom surface designed to transmit the compressive load to the load bearing substrate. A procedure is also used in which only the foot is first concreted and the mast or mast itself is later attached to the foot. Such foundation solutions require excavation work, laying down of the topsoil layer, removal of excavated material, transport of concrete and are time-consuming, the concrete needs several weeks to obtain guaranteed strength. The wet foundation process is also limited by climatic conditions, concreting into frozen soil is problematic. In the case of temporary constructions, such as temporary by-pass lines for repairing high-voltage distribution systems, the use of concrete foundations is slow, inefficient and overpriced. The use of concrete beds is also unecological, as their removal and restoration of the site is difficult to achieve.

If necessary, build columns, respectively. pylons for temporary power lines are also used to place the mast or pole on a ground support and stabilize with at least three ropes anchored away from the support. This solution is characterized by high soil engagement, anchoring ropes define a large area. The anchoring is lengthy and unusable in confined conditions, for example at a mast next to a public road.

and

DE4230776A1 discloses a coating base for small rod-shaped articles. The base has conical outer surfaces with grooves. This solution cannot be used for multi-meter columns and the desired effects cannot be achieved even by proportional enlargement of the base. DE3145882A1 discloses the possibility of creating a foundation using a tube vibrated into the substrate. However, in order to obtain sufficient strength, this disclosure uses concrete at the top of the pipe or wing reinforcements on the surface of the column surroundings. This again leads to technological constraints and the publication does not solve the problems of achieving the exact vertical position of the column.

A simple technical solution is required which makes it possible to create a solid and load-bearing foundation, especially for a pole or mast, to be used in a short time and using available equipment, and to allow for rapid dismantling and possible relocation if necessary.

The essence of the technical solution

The drawbacks of the prior art substantially eliminate the foundation of an above-ground building element, in particular a column and / or mast, where the foundation has a steel support element provided on the upper side with a connecting element for detachably attaching the above-ground building element. wherein the support element is a hollow pipe adapted to be hammered into the ground, the pipe having a closed circular or polygonal or elliptical cross-section and the length of the pipe being at least twice its diameter. In a preferred embodiment, the length of the pipe, i.e. the length of the base support element, will be four to ten times the diameter of the pipe, particularly preferably six to seven times the diameter of the pipe.

Steel support elements in the form of feet with a connecting element are known in the art, wherein the feet are concreted into the bed in exactly horizontal position. Later he put on the heel and fastened the column. The support element at such a foot does not have the shape of a pipe suitable for hammering but has a shape suitable for a firm connection to the concrete.

In the hammering, for example in the shoring of pits, steel profiles are used which hammer into the substrate and form a wall with a trapezoidal surface. The exact vertical position is not important in the sheeting, as the sheeting itself is only an auxiliary operation for carrying out other construction activities.

In our technical solution, a hollow support pipe is used, in particular of circular or bent polygonal cross-section, which is adapted for hammering into the ground. Hammering in this description expresses any force pushing of an object into the substrate using repeated impacts. It can also be named as hammering, vibration hammering, ramming, vibration ramming, ramming, driving and the like. The essence is that in this process, a solid steel support pipe is pushed into the ground without creating a trench, while the material near the pipe is compacted, not loosening as in a trench. The tube is adapted to be hammered in particular by being hollow and its cross-section substantially does not change along the embedded height, and the printed material remains inside the support tube. This material contributes, by its weight and adhesion forces, to the rigidity of the base. The pipe is designed to withstand impact loads when hammering, strut loading and, later, column or mast loads. The pipe diameter of the support element will usually correspond to the diameter of the column to be fixed on the base.

The rigidity of the connection of the support tube to the substrate is ensured by high friction between the surface of the support tube and the compacted material. At a given diameter of the support pipe, the available friction surface can be increased by means of at least one lamella, which is attached to the outer casing of the pipe and extends to the lower half of the height of the pipe. It is preferred that a plurality of lamellae are used, which are regularly arranged on the outer casing of the pipe, are radially oriented and extend substantially along the entire insertion height of the pipe. This increases the friction surface at a given diameter without the need to increase the length of the pipe, which would otherwise necessitate the use of a higher ram crane and also reinforce the pipe for strut support.

The slats can also be placed on the inner surface of the pipe, especially in the case of larger pipe diameters.

The connection element for detachably attaching the above-ground building element is in a preferred embodiment part of the above-ground head having a ring with openings and stiffeners. An overhead building element, for example a post, is mounted on the head with the protruding edge of the support tube, and the post is screwed to the foundation through the openings in the rim. In view of the transmission of forces from the rim to the support tube, it is desirable if the rim has spacers on the circumferential side. These can be connected to a second outer rim from which the slats continue down. This results in an advantageous force transmission. In order to increase the rigidity of the support tube in the region of the head, the tube in this zone may be provided with reinforcements on the inside, similarly as on the outside. The individual elements of the base will usually be joined by welding, but no forms of joining are excluded.

In order to be able to adjust the exact vertical position of the above-ground building element, it will be advantageous if the connecting element is adjustable to achieve a different angular position of the pipe axis relative to the above-ground building element. This will allow a pillar or mast to be erected vertically even on a slightly crooked foundation. This is not only a purely aesthetic effect, but a precise vertical bearing is important to achieve efficient power transmission, for example from the weight of the power lines. The range of adjustment of the angles of the relative position will take into account commonly achievable accuracy, resp. deviations of the foundation from the vertical position.

In a simple embodiment, the angular adjustability of the connecting element can be achieved by using longer bolts or screws to connect the foundation to the above-ground building element. threaded rods with nuts, where the flange, the rim of the above-ground building element is clamped between the pairs of nuts, the height of the pair of nuts being adjustable.

Another solution may be to use a lockable joint in the oven head. The hinge can also be used by attaching the above-ground structural element to the foundation in a horizontal position and subsequently erecting it by lifting to a vertical position. When the correct position is reached, the joint locks.

It will be appreciated that a pair of inclined washers are used to adjust the correct angular position of the overhead building element. By rotating the relative positions of the washers, different angles can be achieved between the lower and upper surfaces of the pair of washers. If both washers have an angle of inclination of X degrees, the resulting angle can be adjusted to 0 to 2X degrees by turning them. The washer may have an annular shape that abuts the rim with openings and also has a plurality of apertures or multiple groups of apertures spaced apart from the apertures on the rim. The upper part of the pipe protruding above the rim may form a shaft for rotating the annulus to a suitable position. Both slanted annular rings may have a number scale on the circumference. After measuring the deviation of the actual angular position of the pushed-on carrier tube from the vertical, the tables can quickly determine to which relative positions the annular rings are to be rotated and what the position of the entire pair of annular ring is to the head.

The drawbacks mentioned in the prior art are also substantially eliminated by the method of foundation of an above-ground building element, in particular a column and / or a mast, which is attached to it after the foundation has been created. in that a steel foundation comprising a support tube is positioned substantially vertically on the base at the base, and the support tube is pushed repeatedly from above into the substrate to a depth of at least twice the diameter of the tube. Usually, but not exclusively, a crane is used to set the foundation upright and to support the ram. It will also be advantageous if an intermediate piece is inserted between the base and the pile, which transmits the forces from the pile to the head of the base, thereby transferring forces to a larger surface so as not to damage, push the contact surfaces on the head. The spacer also makes it possible to use pile drivers which are designed to drive trapezoidal sheeting profiles. The solution does not therefore require a new ram construction. In the most common embodiment, the spacer will have on the underside a connecting flange intended to be connected to the base connection element, and on the upper side will have a profile to be inserted into the pile mouth.

A further aid for carrying out the method according to the present invention is a support which serves for stable positioning of the foundation in the initial stages of hammering. The support has a perimeter frame designed to be laid on the ground at the point of hammering. The free space of the frame allows the crane to erect the foundation inside the frame. At least three adjustable length arms extend from the peripheral frame. The upper ends of the arms form a support for the base body. It is preferred that the ends of the arms are provided with sliding guides into which the base with the support tube is supported. The guides may have grooves for inserting the edge of the slats. The perimeter frame may be detachable for easier removal from the hammering area. The individual arms can have laterally adjustable struts, by adjusting them to achieve appropriate positioning of the foundation even when the device is laid on an uneven foundation.

The new foundation method can be advantageously used in the construction of a temporary overhead power line, in which foundations are formed in the route of the line by hammering, after the foundation has been hammered, columns and / or masts are attached thereto and the power line is suspended. After performing the temporary power line function, the power line is hung up, the poles or masts are disconnected from the foundation and the foundation is pulled out of the ground. The crane and pile driver are again used to pull out the foundations. The ram strikes the foundation, the high-span wide-spectrum vibration causes the effect that the material behaves as a fluid in the boundary layer touching the steel body of the foundation. When removing the foundation, the crane lifts the pile driver and thus the entire foundation until it is completely removed from the base.

The technical solution is applicable not only for the construction of poles and poles for power lines, but can also be used for other constructions, permanent or temporary, preferably also in emergency situations, after natural disasters and the like. The hammered foundation can be used in the construction of billboards and other advertising equipment, in the construction of bridge structures and footbridges, in the construction of wind power plants and the like. Where several foundations need to be installed on a given structure, such as a river bridge construction, the deviation of the distances between the arrested foundations compared to the project can be compensated by inserts that are operatively cut by plasma according to the dimensions measured on site after the arrest.

If the base according to this invention is used for the construction of a wind power mast, the steel body can also be used as an earth-leakage heat sink, which is used in some control modes.

The interior of the steel tube of the foundation can also be used as a well casing in a preferred arrangement. After the foundation is hammered, the soil is removed from the inside of the steel pipe, creating a well or shaft to observe the groundwater level. Soil removal can be simplified by the liner that is adhered to the inner circumference of the steel pipe, and when the liner is pulled out by crane, the soil pressed inside is also pulled out. After the well has been formed, an above-ground building element, for example a wind power station mast, can be mounted on the foundation, which can also draw water from the well.

The device according to this technical solution enables to create the foundation of the above-ground element very quickly and without excavation and concrete work. The new founding method is environmentally friendly, allows the site to be restored to its original state, avoids soil contamination, and reduces soil take-up.

Overview of the drawings

The technical solution is explained in more detail by means of Figures 1 and 16. The display scale used and the size ratio of the foundation and above ground element may not be true or are intentionally adjusted for clarity.

Fig. 1 is a perspective view of a foundation formed by a support tube with slats and a head of a connecting element.

Figure 2 shows a detail of the foundation head where the internal reinforcements are also visible.

Figure 3 shows a top view of the rim foundation, then Figure 4 is a cross-sectional view from above through the reinforcement zone.

Fig. 5 is a view of a spacer without a later welded profile which is selected and welded to the upper surface of the spacer according to the type of pile jaws.

Figure 6 shows the attachment of the spacer to the head of the foundation.

Figure 7 is a top view of the spacer where openings for adjacent placement to the rim are visible.

Fig. 8 shows a support with the arms adjusted without an inserted foundation.

Figure 9 is an axonometric view of the support with the arms adjusted.

Figure 10 is a detail of a corner of the perimeter frame where the arm is attached to the joint.

Figure 11 is a detail of the arm end with a guide.

Fig. 12 shows an example of using a base for the installation of a wind power pole.

Figure 14 is an axonometric view of the spacer without a later welded profile.

Figures 15 and 16 show a pair of inclined washers, with only every second tube shown for clarity. In Figure 15, the inclined washers are rotated relative to each other so as not to change the resulting angle, in Figure 16 they are rotated to achieve a 6 degree angular change in axes.

Examples of technical solution

Example 1

When repairing high-voltage power lines, a replacement line should be provided to create a temporary bypass. Substantial repairs and replacement of the wires can then be carried out on the original line. Points for temporary pylons shall be measured next to the power line. Steel sheet poles have a bent cylindrical shape. 1 to 11, 13, 14, a steel base 1 with a support tube 2 is used to form the foundations for these poles. In this example, the support tube 2 has an outer diameter of 845 mm, which corresponds approximately to the inner diameter of the tower. The support tube 2 in this example has a total length of approximately 5.6 m.

The tube 2 has in the upper part a head 7 comprising a collar 4, stiffeners 5 and inner stiffeners 6. These parts are also made of sheet steel and are welded to the support tube 2. The rim 4 has openings at regular angular spacing.

The annular ring 4 is welded to the pipe 2 below the upper edge of the pipe 2, the edge of the pipe 2 protruding from the head 7 by this arrangement and allows easier mast guidance and deployment. The underside of the rim 4 is supported by radially spaced stiffeners 5 that are welded to the pipe 2. The stiffeners 5 extend from the ring 4 to the annulus below which the zone of the pipe 2 for embedding in the substrate is located.

The inner reinforcements 6 are welded inside the pipe 2 between two circumferential reinforcement elements similar to the arrangement of the reinforcements 5 on the outer surface of the pipe 2.

Below the level of the head 7, six slats 3 are welded on the outer surface of the pipe 2, which extend from the head 7 down to the bottom of the pipe 2. The slats 3 are spaced at a regular angular spacing.

After the base has been welded, the entire weldment is hot-dip galvanized. With regard to its length, diameter and relatively low weight (in this example less than three tons), the base 8 is brought by a conventional truck to the installation site.

At first, a support 60 having a triangular circumferential frame 11 with three arms 64 is unfolded. The peripheral frame 11 is detachable and has corners in the corners with pin holes. The arms 12 are telescopically adjustable by means of a series of holes. The arms 12 extend from the corners of the frame 11 and each arm 12 is supported by two struts that rest on the sides of the frame 16. The struts are also adjustable, allowing to adjust the desired position of the end of the arm 12 in the space. At the end of the arms 12 there is a guide with a groove for inserting the edge of the slat 3.

A spacer 13 is placed and screwed on the rim 4. At the upper end of the spacer 13, a short sheeting profile is welded on to which the pile driver is designed. The profile is clamped by the ram and by means of a crane, the intermediate piece 3 with the base 8 is raised and inserted into the interior of the support 10. Now the vertical position of the base 8 is set and anchored by the arms £ 2. Subsequently, with the pile, the entire base 4 is driven into the substrate, whereby the tube 2 with the slats 3 is gradually immersed in the substrate. After a brief hammering, the vertical position of the pipe 2 is stabilized and the legs 12 of the support 10 can be released and tipped to the ground outwardly from the peripheral frame 11 so as not to interfere.

The foundation 1 is driven to the required depth, where only the head 7 protrudes above ground level. By compacting the substrate around the foundation 1, soil may drop in the vicinity of the foundation 1, but this is not a technical or environmental problem. After insertion of the foundation 1, the spacer 13 is removed from the head 7, the rim 4 is checked and the mast is lifted by the mast above the base 1. The mast flange is placed on the rim 4 and screwed with screws so as to eliminate the angular deviation of position.

After the masts are installed and the overhead lines are suspended, the temporary high-voltage bypass is switched on. After repairs have been made, the temporary wiring and masts are removed again. Subsequently, an intermediate piece 13 is attached to the base 1 and is fastened to the ram jaws. The crane lifts the lowered ram, thanks to which the foundation is gradually pulled out of the terrain. After the base 1 has been completely pulled out, it can be used for loading elsewhere.

Example 2

In this example of Figures 15 and 16, the base 1 of Example 1 is supplemented by a pair of obliquely placed washers 9. The washer 9 has a circular plan view and is made by welding two annulus. The annulus forming the inclined surface has a slightly elliptical shape, which is determined by a plane section of the cylinder. In this example, the washer 9 has a series of 42 holes corresponding to twice the number of holes on the rim 4. Each hole in the washer 9 continues through the interior of the support tube, which is welded between the lower and upper annular rings. The individual pipes are numbered from 1 to 42, the number 1 denotes the longest pipe, the pipes on the periphery to the number 21 are gradually shortened, to 22 to 42 they grow. The taper of the washer 9 in this example is 3 degrees. One pair of washers 9 can eliminate the deflection of the base 1 from the vertical to 6 degrees, the indentation technology having an angular accuracy of up to 5 degrees.

In place, after the base J has been completely knocked, its angular deviation from the vertical is measured and also the orientation of this deviation relative to the zero angular mark on the head 7 is determined. Then, according to the setting tables, it is found that to eliminate the deviation, e.g. 1.5 degrees with orientation directly in the plane of the zero angle line, the bottom washer 9 is rotated so that the number 39 is placed against the zero angle line, the upper washer 9 is rotated to position 3 with respect to the zero angle line on the head 7. This achieves elimination of a coaxiality of 1.7 degrees in the zero-angle plane. Adjusting the positions with numbers 1 and 21 achieves an angle of 6 degrees.

Subsequent assembly of the mast or mast is similar to Example 1.

Example 3

The base 7 is applied to a pole which carries a billboard on a road. The billboard is temporary and can later be moved to another suitable location with the foundation.

In order to achieve good hammering properties, the tube 2 is made of sheet metal by folding. By bending, two troughs are produced, half of the pipe 2, which are then welded into the pipe 2 by two longitudinal welds. The vibration from the pile driver propagates better in such a weld than if a conventional spiral weld tube is used, which is produced when the pipe is skewed from the belt.

Example 4

The two bases 1 are pushed along the sides of the river, spanning the length of the footbridge to be fixed above the river. After the hammering, the actual distance of the heads 7 is measured and the bolts are made to measure according to the deviation. Foundations 1 can be permanent or temporary.

Example 5

The base 1 is used for fitting a mast with a wind power plant according to the figure

Example 6

The foundation 1 carries a column with a wind pump which draws water from the well inside the oven 2.

Industrial usability

Industrial applicability is obvious. According to this technical solution, it is possible to industrially manufacture and install the foundations of columns, masts, bridges, wind power plants and the like. At the same time, it is possible to use a spacer and support device.

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Claims (20)

Claims ΝΑ PROTECTION A foundation for an above-ground building element, in particular a column and / or a mast, the foundation having a steel support element provided at the end with a connecting element for detachably attaching the above-ground building element (8), characterized in that the support element is a hollow tube (2) hammering into the ground, the pipe (2) has a closed circular or polygonal or elliptical cross-section and the length of the pipe (2) is at least twice its diameter. Foundation of an aboveground building element, in particular a column and / or a mast according to claim 1, characterized in that the length of the pipe (2) is four to ten times its diameter, preferably six to seven times its diameter. Foundation of an above-ground building element, in particular a column and / or a mast according to claim 1 or 2, characterized in that the pipe (2) is rounded or bent from a sheet which is joined by a longitudinal weld. Foundation of an aboveground building element, in particular a column and / or a mast according to claim 3, characterized in that the pipe (2) is a weldment of two edge halves which are connected by two longitudinal welds. Foundation of an above-ground building element, in particular a column and / or a mast according to any one of claims 1 to 4, characterized in that it has at least one slat (3) attached to the casing of the pipe (2), the slat (3) going into the lower half oven height (2). Foundation of an above-ground building element, in particular a column and / or a mast according to claim 5, characterized in that it has at least three slats (3) evenly and spaced apart on the outer casing of the pipe (2). Foundation of an above-ground building element, in particular a column and / or a mast according to any one of claims 1 to 6, characterized in that the connecting element for detachably attaching the above-ground building element (8) has a rim (4) with openings and braces (5) attached. to the surface of the pipe (2), preferably also has internal reinforcements (6) inside the pipe (2). Foundation of an above-ground building element, in particular a column and / or a mast according to any one of claims 1 to 7, characterized in that the connecting element has an adjusting mechanism for achieving a different angular position of the axis of the foundation (1) relative to above-ground building element (8). Foundation of an above-ground building element, in particular a column and / or a mast according to claim 8, characterized in that the adjusting mechanism comprises a pair of inclined, mutually placed washers (9). Foundation of an above-ground building element, in particular a column and / or a mast according to claim 8, characterized in that the adjusting mechanism comprises a plurality of threaded joints with a positionable pair of nuts. Foundation of an above-ground building element, in particular a column and / or a mast according to any one of claims 1 to 10, characterized in that the foundation (1) is hot-dip galvanized. A method of forming a foundation for an above-ground building element, in particular for a post and / or a mast which is attached to it after the foundation has been formed, the foundation being formed without concreting, characterized in that construct a steel base (1) comprising a support tube (2) and press the tube (2) repeatedly from the top into the substrate to a depth of at least twice the diameter of the tube (2). Method for forming a foundation for an above-ground building element, in particular for a mast and / or a mast according to claim 12, characterized in that the foundation (1) is hammered by a ram supported by a crane. Method for forming a foundation for an above-ground building element, in particular for a column and / or a mast according to claim 13, characterized in that the foundation (1) is pulled out of the substrate by means of a pile driver so that the pile vibrates the base (1). 1) hoist by crane. Method for forming a foundation for an above-ground building element, in particular for a mast and / or a mast according to claim 13 or 14, characterized in that the pile driver strikes the foundation (1) by means of an intermediate piece (13) on the underside attached to the head (7) and attached to the ram at the top. Method for forming a foundation for an above-ground building element, in particular for a mast and / or a mast according to claim 12 or 13, characterized in that at the beginning of the hammering, the foundation (1) is held upright by the support arms (12) . A device for forming a foundation for an above-ground building element, in particular a mast and / or a mast according to claim 15, characterized in that the adapter (13) for transmitting the force from the pile driver to the head (7) has a flange adapted connection to the rim (4) and at the top 5 has a protruding element for connection to the ram jaws. A device for forming a foundation for an above-ground building element, in particular for a column and / or a mast according to claim 16, characterized in that the support (10) is for positioning the foundation (1), the support (10) has a peripheral frame (11), from which at least one adjustable arm (12) emerges. 10 A device for forming a foundation for an above-ground building element, in particular for a mast and / or a mast according to claim 18, characterized in that the arm (12) has laterally adjustable struts. Aid for forming a foundation for an above-ground building element, in particular for a mast and / or a mast according to claim 18 or 19, characterized in that: 15, the arm (12) has at its end a sliding guide with a groove for inserting the edge of the slat (3).