CH715591A1 - Building element and structure. - Google Patents

Abstract

The invention relates to a building element (10) comprising a base element (11), the building element (10) comprising at least two primary screw foundations (12) which can be inserted into the ground through insertion openings of the base element (11) and by means of which a non-positive connection can be created between the base element (11) and the base, and the primary screw foundations (12) can be replaced without the base element (11) having to be removed from the base. The present invention also includes a building comprising at least one such building element.

Description

Technical field of the invention

The present invention relates to a building element for the construction of buildings. In particular, the invention relates to a building element in which the foundations, which create non-positive connections between a basic element of the building element and the floor, can be replaced. The present invention also relates to a structural element in which the condition, the integrity and the stability of the foundations can be checked by means of sensors. The present invention also relates to a building which comprises at least one building element according to the present invention.

State of the art

Buildings, for example line structures such as retaining walls, walls or banquet fuses, are created in different methods and by means of different building elements. For example, in the case of a classic linear structure - be it on the plain or on a slope on the mountain or valley side - a line foundation is made of in-situ concrete after excavation and the structure, often also in in-situ concrete, is connected to it. Or prefabricated line construction elements made of concrete or other materials are connected to one or more foundations or placed on a foundation level. In the case of prefabricated linear structural elements, the connections between the foundations and linear structural elements are created in a non-positive manner, for example by casting in concrete.

Another principle for the construction of structures, in particular line structures, is based on point foundations, so-called piles, of special civil engineering. For this purpose, piles or pipes placed in the building ground are often reinforced with an internal or external potting. Then they are integrated into the line structure. The pile head is therefore no longer accessible. Accessibility is maintained if the piles lead through a cladding tube through the line structure and secure the external anchoring by means of a screwed-on plate.

An interesting alternative to foundations made of concrete or the piles described above are screw foundations, also called ground screws, usually made of steel. Their length can vary from a few tens of centimeters to several meters. Generally speaking, screw foundations have a shape comparable to a normal screw, i.e. they consist of an elongated body in the form of a cylinder with a part which comprises an external thread. In the case of extendable systems, functional elements such as plates can also be individually coupled between them. Screw foundations are often designed as a hollow body, which is closed with a flange.

The great advantage of screw foundations is that they are immediately resilient, completely removable, modular and reusable. Screw foundations are also particularly easy to install in the ground, since they can simply be screwed into the ground. In addition, no curing times have to be waited for. Screw foundations are increasingly used in a wide variety of situations, for example as foundations for noise barriers, solar panels, or for small or medium-sized houses.

The most important task of foundations is to absorb loads from the building and pass them on to the building ground without the resulting load on the soil leading to disadvantages for the building or the environment. The load-bearing capacity of the built-in foundations is therefore an important safety parameter and often has to be able to be monitored and checked for decades after construction. Ideally, before this, but at the latest after determining that the foundations or back anchorings no longer fulfill their function, this must be recognized and remedied. Otherwise the entire structure is at risk. This can be caused by changes in the material, for example corrosion or cracking, reduced load transfer due to changes in the ground, for example due to changes in drenching, or a change in the acting loads, for example due to road traffic.

In all known buildings and building elements, especially in line structures and line building elements, it is no longer possible after the completion of the building to check the foundations of the existing structure both statically and for integrity and to replace them if necessary.

Based on the prior art, the present invention is therefore based on the object to overcome the aforementioned disadvantages and to provide a building element and a structure that enable the checking of integrity and stability and the replacement of the foundations.

Summary of the invention

[0009] According to the present invention, these objects are achieved primarily by the elements of the two independent claims. Further advantageous embodiments also emerge from the dependent claims and the description.

In particular, the objectives of the present invention are achieved by a structural element comprising a base element, the structural element comprising at least two primary screw foundations, which can be inserted into the base through insertion openings of the base element and by means of which a non-positive connection between the base element and the ground can be created and the primary screw foundations can be replaced without having to remove the base element from the ground.

Thanks to the building element according to the invention, it is possible to build structures in which the primary screw foundations are accessible for checking their integrity and stability. In addition, the primary screw foundations can be replaced if necessary without having to remove the base element from the floor. In contrast to the building elements known from the prior art, in which the foundations and anchors are either integrated in the in-situ concrete or cannot be dismantled, the checking and replacement of foundations is possible with the building element according to the invention.

[0012] As a result, periodic checks of the screw foundations can be carried out, for example, and the expected service life thereof can be checked individually and continuously. This allows the aging process to be monitored and the planning and implementation of suitable measures to preserve the structure. The risk of building failure due to insufficient load transfer of the foundations during the entire life cycle of the building element is massively reduced. The simple testing options and the simple possibility of replacing the foundations mean that there are no costs or the building can be used for much longer.

In a first preferred embodiment of the present invention, the base element takes the shape of a cuboid and the screw foundations and the insertion openings are oriented such that they do not pass through the weight-bearing surface of the base element.

This proposes a structural element in which the primary screw foundations are accessible for checking their integrity and stability. The orientation of the insertion openings ensures that the screw foundations absorb tensile loads from the basic element and pass them on to the ground. In addition, the screw foundations can be replaced if necessary. The proposed building element is particularly suitable for the construction of linear structures.

In a further preferred embodiment of the building element according to the invention, the base element has contact surfaces perpendicular to the insertion openings, onto which screw-on foundation flanges of the primary screw-on foundations can be placed. As a result, the connecting force between the base element and the floor can be distributed over the support surfaces, which translates into a smaller mechanical pressure and which prevents the base element from breaking.

In another preferred embodiment of the building element according to the invention, the bearing surfaces are arranged within recesses of the base element. As a result, the primary screw foundations can be arranged completely within the volume of the basic element. The primary screw foundations are thus protected.

In a further preferred embodiment of the structural element according to the invention, the cutouts of the basic element are configured such that they can be closed by means of cover plates. This means that the primary screw foundations can be protected even better, especially against environmental influences such as rain.

In another preferred embodiment of the structural element according to the invention, support rings are arranged between support surfaces and screw-foundation flanges. For example, steel rings can be provided between the base element and screw foundation flanges to protect the base element.

In a further preferred embodiment of the building element according to the invention, the building element comprises flange screws, by means of which the distances between the primary screw foundation flanges and the contact surfaces can be adjusted. As a result, the tensile force of the primary screw foundations and therefore the amount of non-positive connection between the base element and the floor can be set precisely.

In another preferred embodiment of the building element according to the invention, the building element comprises one or more support elements, by means of which the weight-bearing surface of the base element can be received. As a result, the base element does not have to be in direct contact with the floor. This protects the basic element against soil moisture, for example, or it is not necessary to create a formation.

In a further embodiment of the building element according to the invention, the building element comprises at least two secondary screw foundations, by means of which a non-positive connection between support elements and floor can be created. This can ensure that the weight load of the structural element is sufficiently supported by the secondary screw foundations and that creep behavior of the basic element is prevented.

In another preferred embodiment of the building element according to the invention, the building element comprises through-holes in the base element, through which secondary screw foundations can be inserted into the ground, the secondary screw foundations comprising bolt holes and the base element comprising side holes, through which bolts can be inserted, with non-positive connections by means of bolts can be created between the basic element and the secondary screw foundations. This means that the secondary screw foundations, which support the weight of the building element, can also be replaced if necessary. All that is required is to remove the bolts that connect the base element and the screw foundation to be replaced. The simple possibility of replacing these foundations means that there are no additional costs or the building can be used for a much longer time.

In a further embodiment of the building element according to the invention, the secondary screw foundations have interfaces, such as flanges, to which other elements, such as security elements, line building elevations, warning signals or solar panels, can be attached. This enables, for example, crash barriers, safety elements, warning signals or solar panels to be attached directly to the interfaces of the secondary screw foundations.

In a further embodiment of the building element according to the invention, the basic element takes the form of a plate, and the primary screw foundations and the basic element are non-positively connected to one another by means of yoke connections. This proposes a building element in the form of a plate in which the screw foundations are accessible for checking their integrity and stability. In addition, the screw foundations can be replaced if necessary without having to remove the base element from the floor.

In another preferred embodiment of the structural element according to the invention, the primary screw foundations and / or the secondary screw foundations have through-holes through which sensors and / or signal sources, such as light sources, can be inserted. This enables the integrity and stability of the screw foundations to be measured and monitored.

In yet another preferred embodiment of the structural element according to the invention, the sensors are optical sensors, vibration sensors, temperature sensors, acoustic sensors, motion sensors or a combination thereof. In this way, the relevant parameters for monitoring and checking the integrity and stability of the foundations can be measured. Based on the data measured by sensors, it is possible to make an informed decision as to whether or when a foundation needs to be replaced.

In a further preferred embodiment of the structural element according to the invention, the optical sensors are cameras. This makes it possible to check whether the foundations have cracks or gaps, for example, and to assess whether the foundations therefore have to be replaced.

In a further preferred embodiment of the building element according to the invention, the building element comprises transmission means by means of which the data measured by the sensors can be transmitted to a central office. This means that the integrity and stability of the screw foundations can be monitored delocalized. In addition, it also enables automatic and / or periodic monitoring and the sending of an alarm if a sensor measures a value that exceeds a predetermined limit value.

[0029] In a further preferred embodiment of the structural element according to the invention, the transmission means and the control center communicate via mobile radio networks. As a result, the data measured by the sensors can be transmitted very easily to a remote control center.

[0030] The objectives of the invention are also achieved by a building comprising at least one building element according to the invention.

[0031] In a preferred embodiment of the building according to the invention, at least two building elements are non-positively connected to one another.

Further details of the invention will become apparent from the following description of the preferred embodiments of the invention, which are illustrated in the accompanying drawings. The description also shows the further advantages of the present invention, as well as suggestions and suggestions as to how the subject matter of the invention could be modified or further developed as part of the claimed.

Brief description of the drawings

[0033] <tb> <SEP> FIG. 1 shows a perspective view of a building element according to a first embodiment of the present invention; <tb> <SEP> FIG. 2 shows a sectional view of a building element according to the first embodiment of the present invention; <tb> <SEP> FIG. 3 shows a perspective sectional view of a building element according to the first embodiment of the present invention; <tb> <SEP> FIG. 4 shows a perspective view of a building element according to a second embodiment of the present invention; <tb> <SEP> FIG. 5 shows a perspective sectional view of a building element according to the second embodiment of the present invention; <tb> <SEP> FIG. 6 shows a sectional view of a building element according to the second embodiment of the present invention; <tb> <SEP> FIG. 7 shows a sectional view of a yoke connection between the screw foundation and base element according to a third embodiment of the present invention; and <tb> <SEP> FIG. 8 shows a perspective view of a building element according to a third embodiment of the present invention.

Preferred embodiments of the invention

Figure 1 shows a perspective view of a first embodiment of a building element 10, here a linear building element, according to the present invention. The line structure element 10 comprises a base element 11, advantageously made of concrete, at least two primary screw foundations 12, which in this embodiment are provided for absorbing tensile loads on the base element 11 and passing these loads on to the foundation.

The line structure element 10 further comprises at least two secondary screw foundations 13, which are provided for absorbing pressure loads on the base element 11. The line structure element 10 also comprises a support element 14, on which the base element 11 is placed. The line construction element 10 further comprises one or more sensors 40 and / or signal sources for monitoring the stability and integrity of the primary screw foundations 12. The sensors are provided with the transmission means 41 for the transmission of the data measured by the sensors 40 to a remote center (not here shown). Even if it is indicated in FIG. 1 that sensors 40 and transmission means 41 are connected with a wire, they could just as well be connected wirelessly, for example by means of Wi-Fi or Bluetooth. In addition, sensors and transmission means for monitoring the secondary screw foundations 13 could also be provided.

As illustrated in Figures 2 and 3, the base member 11 comprises recesses 15 and insertion openings 16 through which the primary screw foundations 12 can be inserted. The primary screw foundations 12 penetrate the base 17 and thus establish a non-positive connection between the base 17 and the base element 11. A support ring 18, for example a ring made of steel, is arranged between the flange 12a of a primary screw foundation 12 and the base element 11. The tension of the primary screw foundations 12 can be adjusted by means of flange screws 12b. Thanks to the support ring 18, this can be done without damaging the base element.

As can also be seen in FIGS. 2 and 3, the primary screw foundations 12 have through holes 12c through which sensors and / or signal sources, such as cameras and light sources, can be inserted into the hollow body of the foundations (see FIG. in the text below for more details). The secondary screw foundations 13 are connected to the support element 14 by means of screws 13b. As already mentioned above, the base element 11 can simply be placed in the support element 14. It is of course also possible to provide a non-positive connection, for example with a spout made of concrete, between base element 11 and support element 14. Even if only one support element 14 for two basic elements 11 is shown in FIG. 1, it is of course clear that a different number of support elements 14 would be possible. In addition, a direct support of the basic elements 11 on the secondary screw foundations 13 would also be possible.

The longitudinal axes X and Y of the primary screw foundations 12 and the secondary screw foundations 13, as shown in FIG. 2, form an angle α of approximately 50 °. However, the angle α can be different and can be adapted to the building ground 17 to which the linear construction element 10 is attached. The angle α can also be adjusted as a function of the forces acting locally on the base element 11. Thus, the angle α can of course be different for each primary screw foundation 12.

The base element 11 also has cover plate recesses 19 in which cover plates (not shown here) can be placed. Access to the primary screw foundations 12 can thus be blocked. This protects the primary screw foundations against environmental influences.

Thanks to the line structure element 11, it is possible to replace the primary screw foundations 12 without dismantling the structure. In addition, it is possible to carry out the replacement without having to stop operating the building. If the line structure 11 is used, for example, to secure a street banquet, it is possible to gradually replace the primary screw foundations 12 without having to stop the traffic on the street.

As mentioned above, it is possible to insert sensors 40 and signal sources into the primary screw foundations 12 through the access holes 12c. This enables the integrity and stability of the foundations to be checked. If necessary, changes can be made in good time. For example, optical cameras, infrared cameras, motion sensors, vibration sensors, acoustic sensors and / or seismic sensors can be used as sensors 40. So that images can be taken with optical cameras, signal sources, for example light sources in the form of fiber-optic illuminations, can also be introduced through the access holes 12c into the foundations 12 together with the sensors 41.

FIG. 4 shows a linear structural element 20 according to a second preferred embodiment of the present invention. Components of the line construction element 20 which have already been described above in the context of the description of the first embodiment are identified here with the same reference symbols.

As can be seen in FIGS. 4 and 5, the linear structural element 21 has a base element 21, primary screw foundations 12 and secondary screw foundations 23. In this embodiment too, the base element 21 comprises cutouts 15 and insertion openings 16, through which the primary screw foundations 12 can be inserted into the ground. The primary screw foundations 12 penetrate the base 17 and thus establish a non-positive connection between the base 17 and the base element 21. The support element 18, for example a ring made of steel, is placed between the flange 12a of a screw foundation 12 and the base element 21. The tension of the primary screw foundations 12 can thus be adjusted by means of screws 12b without the base element 21 being damaged thereby.

In addition, the primary screw foundations 12 also have holes 12c in the second embodiment, through which sensors 40 and / or light sources can be inserted. The sensors 40 are connected to the transmission means 41, which enables the integrity and stability of the screw foundations to be monitored in real time. As illustrated in this figure, sensors 42 are provided in order to also monitor the secondary screw foundations 13.

In contrast to the base element 11, the base element 21 has through holes 24 through which the secondary screw foundations 23 can be inserted into the ground, as shown in FIG. 6. The secondary screw foundations 23 have bolt holes 25 which are arranged orthogonally to the longitudinal axis of the screw foundations 23. The base element 21 in turn has side holes 22. Bolt 26 can be inserted through the bolt holes 25 of the screw foundations 23 and the side holes 22 of the base element 21 in order to non-positively connect the base element 21 to the screw foundation 23. Since the secondary screw foundations 23 penetrate into the base 17, a non-positive connection between the base 17 and the base element 21 is thus created.

As illustrated in FIGS. 5 and 6, the secondary screw foundations 23 also have a flange 23a. For example, elements 33 of a safety barrier can be attached to this flange 23a by means of a corresponding interface, for example a flange-flange connection.

The great advantage of the line structure element 21 is that not only the primary screw foundations 12 but also the secondary screw foundations 23 can be replaced without the base element 21 having to be removed from the floor. In addition, the secondary screw foundations 23 have holes 23c through which sensors and / or light sources can be inserted. This enables "live" monitoring of the integrity and stability of the secondary screw foundations 23. This can increase the safety of the line structure and also its cost-effectiveness, since the screw foundations are only replaced when this is really necessary.

As in the first embodiment of the present invention, multiple line structure elements 21 can be combined to create an entire line structure 50. Advantageously, a plurality of line construction elements 11 or 21 can be held together by means of ropes or other connecting elements 34. This increases the stability of the entire line structure 50.

As mentioned above, the stability and integrity of the primary screw foundations 12 and secondary screw foundations 13, 23 can be monitored “live” by means of sensors. For this purpose, transmission means 41 are provided in order to transmit the data measured by the sensors to a remote center (not shown). The transmission means 41 advantageously use mobile radio networks such as GMS, GPRS, UMTS or LTE for this transmission. However, it can be provided that the sensors first transmit their data to a “local” control center, for example using Wi-Fi or the like, and that this local control center sends the collected sensor data to a delocalized control center. The electrical energy required for the sensors and transmission means can be obtained, for example, by solar panels (not shown) attached to the basic elements 11, 21.

Figures 7 and 8 show a building element 60 according to a third preferred embodiment of the present invention. The structure 60 comprises a base element 61, here in the form of a plate, advantageously made of concrete or metal, and four primary screw foundations 62, which can be inserted into the floor 17 through insertion openings 64 of the base element 61, and by means of which a non-positive connection between the base element 61 and the bottom 17 is buildable.

As can be seen in FIG. 7, the plate 61 and the primary screw foundations 62 are connected to one another by means of a so-called yoke connection 63. The yoke connection 63 comprises a first connection plate 63a with a hole 63f, which is connected by means of screw 63b to the flange 62a of the screw foundation, and a second connection plate 63c between the first connection plate 63a and the flange 62a. The second connecting plate 63c is in turn connected to the base element 61 by means of a threaded rod 63d and a nut 63e. Thanks to the yoke connection 63, the screw foundations 62 secure the base element 61 both against pressure loads and against tensile loads. Nevertheless, the screw foundations 62 can be replaced, as in the two previous preferred embodiments, without the base element 61 having to be removed from the floor. In addition, an additional non-positive connection, for example with a pouring from a hardening mass, such as concrete, can be provided between the base element 61 and the yoke connection 63. This can also counteract lateral loads. A spout can advantageously be provided either between the first connecting plate 63a and the second connecting plate 63c and / or between the base element 61 and the outer wall of the screw foundations 62. It should be noted that margins can be provided in order to ensure a certain flexibility during the construction of the building element 60. In particular, the diameter of the hole 63f of the first connecting plate 63 can be selected such that the screw foundation 62 and the base element 61 can be displaced relative to one another. Similarly, the diameter of the hole 64 of the base element 61 can be selected such that a certain flexibility in the relative position of the screw foundation 62 and of the base element 61 to one another is ensured.

As shown in Figure 7, one or more sensors 40 and / or signal sources, such as light sources, can be provided with which the condition, integrity and stability of the screw foundations 62 can be measured and monitored. Here, too, the sensors can be connected to the transmission means 41 for the transmission of the data measured by the sensors 40 to a remote center (not shown here). The sensors 40 and transmission means 41 can be connected together with a wire or wirelessly. The sensors 40 can be inserted into the screw foundation 62 through a hole 62c, for example in the screw 63b.

Even if the screw foundations 62 are aligned perpendicular to the plate 61 in FIGS. 7 and 8, they could also be aligned obliquely to the plate 61. Furthermore, the base element 61 can have a different form factor and accordingly can comprise a different number of screw foundations 62. For example, the base element 61 may take the form of a bar. In this case, two screw foundations 61 may be sufficient. The basic element 61 can also take the form of a disc. In this case, the number of screw foundations required is heavily dependent on the diameter of the disc and the acting load.

Finally, it should be pointed out again that the embodiment described here by way of example represents only one possibility of realizing the ideas according to the invention and should in no way be regarded as limiting. Those skilled in the art will understand that other implementations of the invention and other elements are possible without neglecting the essential features of the invention.

Claims (19)

1. building element (10, 20, 60) comprising a base element (11, 61), characterized in that that the building element (10, 20, 60) comprises at least two primary screw foundations (12, 62) which can be inserted into the floor (17) through insertion openings (16, 64) of the base element (11, 21, 61) and by means of which one non-positive connection between the base element (11, 61) and the bottom (17) can be established, and that the primary screw foundations (12, 62) can be replaced without the base element (11, 61) having to be removed from the ground. 2. Building element (10, 20) according to claim 1, wherein the base element takes the shape of a cuboid, and wherein the insertion openings (16) are oriented such that they do not pass through the weight-bearing surface of the base element (11, 21). 3. Building element (10, 20) according to claim 2, wherein the base element (11, 21) has contact surfaces (11a) perpendicular to the insertion openings (16), onto which screw foundation flanges (12a) of the primary screw foundations (12) can be placed. 4. Building element (10, 20) according to claim 3, wherein the bearing surfaces (11a) are arranged within recesses (15) of the base element (11, 21). 5. building element (10, 20) according to claim 4, wherein the recesses (15) are configured such that they can be closed by means of cover plates (19). 6. building element (10, 20) according to one of claims 3 to 5, wherein between the support surfaces (11a) and screw foundation flanges (12a) support rings (18) are arranged. 7. Building element (10, 20) according to one of claims 3 to 6, comprising flange screws (12b), by means of which the distances between the screw foundation flanges (12a) and the contact surfaces (11a) can be adjusted. 8. Building element (10) according to one of claims 2 to 7, comprising one or more support elements (14), by means of which the weight-bearing surface of the base element (11) can be received. 9. building element (10) according to claim 8, comprising at least two secondary screw foundations (13), by means of which a non-positive connection between support elements (14) and floor can be created. 10. Building element (20) according to one of claims 2 to 7, comprising through holes (24) in the base element (21) through which secondary screw foundations (23) can be inserted into the ground, wherein the secondary screw foundations (23) bolt holes (25) and the base element (21) has side holes (22) through which bolts (26) can be inserted, wherein a non-positive connection between the base element (21) and secondary screw foundations (23) can be created by means of bolts (26). 11. Building element (20) according to claim 10, wherein the primary screw foundations (23) have interfaces, for example flanges (23a), to which other elements (33), such as security elements, line construction elevations, warning signals or solar panels can be attached. 12. Building element (60), according to claim 1, wherein the base element takes the form of a plate (61), and wherein the primary screw foundations (62) and the base element (61) are connected to one another by means of yoke connections (63). 13. Building element (10, 20, 60) according to one of the preceding claims, wherein the primary screw foundations (12, 62) and / or the secondary screw foundations (13) have through holes (12c, 13c, 62c) through which sensors (40, 42) and / or signal sources, such as light sources, can be introduced. 14. Building element (10, 20, 60) according to claim 13, wherein the sensors (40, 42) are optical sensors, vibration sensors, temperature sensors, acoustic sensors, motion sensors or a combination thereof. 15. Building element (10, 20, 60) according to claim 13, wherein the optical sensors (40, 42) are cameras. 16. Building element (10, 20, 60) according to one of claims 13 to 15, wherein the building element comprises transmission means (35), by means of which the data measured by the sensors (40, 42) can be transmitted to a control center. 17. Building element (10, 20, 60) according to claim 16, wherein transmitting means (35) and the center communicate via mobile radio networks. 18. Building comprising at least one building element (10, 20, 60) according to one of claims 1 to 17. 19. Building according to claim 17, wherein the building elements (10, 20, 60) are non-positively connected.