GR20180100038A - Building with counterweight and jetty - Google Patents

Abstract

A construction system 1 or building stable and free of foundations is presented herein which construction or building is composed of the base 3 and the jetty–extension 2. The technique consists in displacing the gravity centre 10 of the building into the base 3 via the counterweight 6 set at the end of the building which is diametrically opposite to the jetty 2; the counterweight may be a cistern, a swimming pool, sand, rock or other element of great volume and specific weight.

Description

DESCRIPTION

BUILDING WITH COUNTERWEIGHT ON CANOPY

The present invention relates to a structural system or building without a foundation, with cantilever and counterweight in stable balance. A cantilever is a structural element, such as a building section, beam or surface, which protrudes from the base or seat of the system. This element can be rigid or oscillating. The cantilever is especially used in the bridge construction process. In a building the cantilever serves either to extend the useful surface of the building beyond its base, for example to create a terrace, or simply to shade the floor below the cantilever.

A conventional cantilevered building is shown in Drawing 1. In this drawing architects Lorena Franco and Jorge Cheng present a cantilevered building that extends beyond the base of the building by about one-third of the base. The static balance of the cantilever is achieved thanks to the strong foundation of the building.

Document GB2547116, the basic shape of which is shown in Figure 2 shows a building of the tree-building type with two or more cantilevers on either side of the support base. The problem that this invention is supposed to solve is the minimization of the support base, so that the space that is under the cantilever can be used as a car park. The structure of the building according to this document follows the rules of the tree-building, in which a base with a small area supports floors with a larger area. The loads of one storey which are outside the base are carried by the floor and are balanced by loads which are on diametrically opposite surfaces. This means that the cantilever loads located for example on the right side of the building are balanced by loads located on the opposite side ie on the left side of the building.

Drawing 3 represents the front and two side views of a building which apparently has a large cantilever. But as it becomes clear from the three views, the cantilever-like phenomenon is supported by two columns which in the document in question form an angle with respect to the horizon. Therefore, only the part of the building that protrudes from the support is considered a cantilever.

And in this document this section is small.

Document EP0507623 (Figure 4) shows a building which has as its basis a column on which rests a conical base. The conical base supports cantilevers in all directions, which balance each other. And this building follows the structural rules of the tree-building. The structure of this building is particularly complex and as a result requires very precise static planning and technically complex execution of the construction.

The problem that the present invention is called to face is to support a large cantilever, so as to create a pioneering and impressive building which is very simple in design and particularly easy to construct and above all does not require a foundation.

The object of the present invention is to address the above problem by providing a structural system, such as for example an autonomous building, which consists of a single element including a cantilever and a base, which system is characterized by a counterweight resting on the base. The base, like the entire unit, simply rests on the support surface, without a foundation. The single element is generally rigid, or can oscillate.

Since the counterweight has the role of balancing large forces on the opposite side of the building, according to the basic implementation of the present invention, the area of the cantilever can be large, for example much larger than the area of the base. In this way, a second cantilever is not required on the opposite side of the building, as is required in the case of the tree-building.

Therefore, an important advantage of the present invention is that the cantilever can have a large size, in relation to the surface of the base, i.e. it can be equal to or larger than it.

The counterweight can be illustratively a tank, water stored in a tank or a pool, sand stored in special containers or in bags, soil, which can also be cultivated and create a garden, one or more rocks or other materials relatively high specific gravity.

The static study of the building is carried out by a specialized static engineer based on the dimensions of the building, the weight of the materials used, the future use and the loads that the building will receive, external factors such as the wind and the seismicity of the area, the relationship between cantilever and base, etc. This study follows the rules of statics and is not part of the present invention.

According to the basic application of the present invention the structural system is a building which consists of a single floor. Alternatively, it may have more than one floor.

According to another application of the present invention the counterweight can be another structural element, such as for example a similar structural element which is placed on the base but with its center of gravity inside the base. Also, the counterweight can be another part of the building, such as one or more floors in addition to the main floor, whose center of gravity is within the base.

Preferably, and due to the large size and limited displacement needs, the structure is constructed at the desired location. But since the static balance of the building is achieved by balancing the cantilever with a counterweight, another important advantage of the present invention is that the building does not require a foundation. The absence of a foundation reduces the cost and also the construction time of the building. Also, the entire system can be reoriented, moved or even transported to another location. Finally, the absence of a foundation reduces the disturbance to the environment, because excavations are not required, which are done by heavy earthmoving machinery.

It is understood that the designer and builder may add foundation, or support of the base to the ground in accordance with existing techniques, either to further enhance the stability of the building or simply to make the building meet the building or other regulations of the area or country in which it will be built, but without such a foundation or support being technically necessary.

In addition to this, a further advantage of the present invention is that the structure can be prefabricated in a factory and then transported to the desired location.

Also, after initial placement, the building block can be moved and placed elsewhere.

In case the single structural element has been prefabricated, then its placement at the desired point is done in three phases:

In the first phase, the single structural element is transported and placed at the desired point using known techniques, such as with a crane, and the cantilever is supported on one or more temporary support elements. The supporting elements can be metal columns or any other elements or materials suitable for carrying large loads.

Also, the crane can temporarily support the single structural element at the desired point.

Then, in the second phase, the counterweight is placed. For example, if a swimming tank is used as a counterweight, and the water that the tank can contain is used in part, then in order to strengthen the stability of the building, the tank is filled with water. If the counterweight is a rock, then it is transported and placed at the end of the unitary structural element which is opposite the cantilever.

In the third phase, the temporary support elements, or other means that may have been used, are removed and the stability of the building is achieved thanks to the combination of cantilever and

counterweight.

Also, after first being installed in one place, this structure can then be easily reoriented, moved or even transported to other places or different locations. Thus, it enables its users to live different experiences, to try different residential spots with different views, different wind exposure and different orientation in relation to natural light or to fulfill different needs.

Where the single structural element is prefabricated, a high quality of construction is achieved, quality control is easily carried out and economies of scale are realised. In addition, there is little burden on the natural environment, because the nuisance of construction activity is avoided, which in normal conditions includes the opening of additional roads, excavations, transport and storage of raw materials, dust, noise, etc.

This structural system can be used indicatively as a residence, as an office space, as an exhibition space, as a museum, as a commercial space or as a combination of these.

In the plans

Figure 1 is a section of a cantilevered building according to the prior art.

Figure 2 is a perspective view of a building with two cantilevers according to the prior art.

Figure 3 illustrates another cantilevered building according to the prior art.

Figure 4 illustrates another cantilevered building according to the prior art.

Figure 5 illustrates a section of the structural system according to the present invention

Figure 6 illustrates a perspective view of the structural system according to the present invention

Figure 7 illustrates the top view of the structural system according to the present invention

Figure 8 illustrates a section of the structural system according to another embodiment of the present invention

Figure 9 illustrates a section of the structural system according to another embodiment of the present invention

Figure 10 illustrates a section of the structural system according to another embodiment of the present invention

Referring to the drawings and specifically to Figures 5, 6 and 7 the structural system (1) of the present invention is an autonomous building which consists of a single element with a base (3) and a cantilever (2), on the base (3 ) of which a counterweight (6) is attached. As base (3) we consider the part of the unitary structural element which rests on a fixed surface (15).

In the example represented in Figure 7 the surface (2a) of the top view C-D-E-F of the cantilever (2) is greater than the surface (3a) of the top view C-D-H-G of the base (3).

In the same example the natural ground (4) has remained as it is and at the desired point a structure (5) has been erected whose upper surface (15) is a horizontal surface on which the base (3) of the building (1) will rest ). The structure (5) can be stone-built, made of reinforced concrete or of another material or combination of materials known in the art.

Alternatively, a part of the natural landscape can be leveled according to known techniques and create a horizontal surface, on a part of which is created the fixed surface (15) on which the base (3) of the building will rest.

In the above construction example it is obvious that the center of gravity of the unitary structural element is approximately in the center of the building, or on the line A-A' therefore outside the base (3) of the building, the end of which is represented by the line B-B' . Therefore, the building in this form is statically deficient or unstable. To transfer the center of gravity (10) of the building inside the base (3) we place a counterweight (6) at the end of the building which is diametrically opposite the cantilever (2). This technique allows the center of gravity (10) to shift within the base (3) thus above the fixed surface (15). The counterweight of the example construction shown in Figures 5 and 6 is a tank, for example a swimming tank which may be filled with water.

The exact dimensioning of the building, the calculation of the loads and therefore the size, exact position and size of the counterweight are the subject of a static study which is carried out by a specialized static engineer, follows the known rules of statics and is not part of the present invention.

The construction of this building is carried out following the following phases:

In the first phase the structural system (1) is constructed on site, or if it has been prefabricated, it is transported and placed at the desired point. During this phase the base (3) rests on the support surface (15) and the cantilever (2) rests on temporary support elements, such as one or more temporary columns, which are not shown in the Drawings. These columns can be made of metal, reinforced concrete or any other material suitable for carrying heavy loads. Alternatively, the cantilever is supported by cables from the crane (or cranes) which, for example, has moved the building to the desired point.

Then the counterweight (6, 16, 26) is placed so that the system is stabilized. In the example of Figures 5 and 6 where the water of a swimming tank is used as a counterweight, the tank itself can be the counterweight, but it is considered more advantageous and the static adequacy becomes complete when the tank is filled with water.

In the third phase in which the tank has been filled and the center of gravity has been transferred inside the base (3), the temporary support is removed and the staticity of the building is achieved thanks to the combination of cantilever (2) and counterweight (6). Alternatively, the wires holding the cantilever are removed.

It is obvious that instead of water, the designer and/or manufacturer can use another material or combination of materials to minimize the possibility of water leakage or evaporation, which in combination with other factors, such as wind, excessive cantilever loading, etc. .would have the effect of changing the balance of the building. Sand, gravel, stones or soil can be chosen as such material. In the latter case the soil can be cultivated with plants and/or trees.

Figure 8 shows another construction example in which a rock (16) is used as a counterweight. The rock (16) is placed at the end of the base (3) and achieves the transfer of the center of gravity (10) of the building (1) within the base (3) therefore above the fixed surface (15). In this way, its stability is achieved

building.

In Figure 9 another example of application is represented in which the structure (5) on which the base (3) of the system (1) rests is an existing building. A rock (16) is used as a counterweight. The rock (16) is placed by crane on the end of the base (3) and achieves the transfer of the center of gravity (10) inside the base (3) therefore above the fixed surface (15).

In Figure 10 another construction example is represented in which a second floor (26) is used as a counterweight, which is built on the base (3) of the building (1). The extra floor (26) can be built at the same time as the rest of the building according to known techniques, or it can be moved and added later. In this case, the construction of the building is carried out following the three phases of construction which have been analyzed elsewhere in this description.

Claims (10)

1. Structural system (1) consisting of a cantilever (2) and a base (3) in which the base (3) rests on the support surface (15) and on the base (3) rests a counterweight (6, 16, 26). 2. Structural system (1) according to claim 1, wherein the surface (2a) of the plan view of the cantilever (2) is equal to or greater than the surface (3a) of the plan view of the base (3). Structural system (1) according to claim 1, wherein the foundation has been replaced by a counterweight. Structural system (1) according to claim 1, wherein the counterweight is a tank (6). Structural system (1) according to claim 1, wherein the counterweight (16, 26) is a solid material of high specific gravity. Structural system (1) according to claim 6, wherein the counterweight (16) is a rock. Structural system (1) according to claim 6, wherein the counterweight (26) is an additional structural system. A structural system (1) according to claim 1, wherein the structural system (1) is transportable. Structural system (1) according to claim 1, wherein the structural system (1) is prefabricated. 10. Method of manufacturing a structural system (1) which includes a single structural element with a cantilever (2) and a base (3) as well as a counterweight (6, 16, 26) in which - the single structural element is placed at the desired point, the base (3) rests on the support surface (15) and the cantilever (2) rests on one or more temporary support elements - the counterweight system is placed to stabilize - the anchors (6, 16, 26) are removed so that the supporting elements.