ES2329535B2 - DEVICE AND SYSTEM TO DECREASE THE AIR PHASE IN THE BUILDING STRUCTURES. - Google Patents

Abstract

Device and system to decrease the phase Aerial in building structures.

A system for building structures of building formed by telescopic supports attached to horizontal structures such as floor slabs in each of its segments so that these are elevated by the action of some pressure equipment to its final position connected by pressure taps

Description

Device and system to decrease the phase Aerial in building structures.

Object of the invention

The present invention relates to a system for the construction of building structures based on a special device, hereinafter referred to as pilastón, linked to a constructive process to reduce the aerial phase of the work of architecture, especially referred to few buildings heights

Background of the invention

At present there are two ways mainly to solve building structures: on-site execution systems and prefabricated systems, although given the complexity of certain works we can find intermediate situations, this being the most common. The most common materials in building structures are concrete and steel, although there are many others, such as wood, stone, aluminum, etc. The bibliography in this regard is very extensive, so we will now describe the main systems that make up the market which the present invention would foreseeably affect.

Within the first group of on-site structure execution systems we find reinforced concrete structures based on uni or bidirectional pillars and slabs, in which the structural foundation consists of a grid of pillars usually tending to an orthogonal arrangement braced together by means of beams and trunks and that support a crosslinked that supports the layers that make up the floor of the building. The loads are transmitted from the ground to the interviewed, from the latter to beams and rails, and from these to the pillars that carry the loads to the foundation from where they are transmitted to the ground. It is a type of construction of wide diffusion and that raises all the problems derived from the putting in work of the concrete besides the own dangers of a structure that is constructed at all times to its definitive height, with the own risks of the transport of heavy material with heavy machinery while the operators on temporary formwork handle elements that exceed them several times in weight, with sharp end armor, and often with scarce safety measures given the precarious qualification of many of the operators in the sector. This coupled with a large volume of work and low levels of control in general of the technicians in charge implies a high level of occupational accidents in the sector (of the highest in Europe) for the case of Spain. Within this group we also find the steel structures, in which their execution requires higher levels of precision in regard to stake out, since the tolerances are millimetric, while in the case of concrete they are a centimeter. They are more expensive structures but have the advantage of solving the structure with smaller sections. Also, from certain lights, steel structures are more competitive than concrete ones, since we take advantage of their best bending behavior. They are carried out with standardized and tabulated profiles, which greatly improves the calculation and execution processes, finding numerous type details that solve the most common encounters. Mixed structures also appear in which the main difficulty is to work the steel elements in solidarity with the concrete.

In the second group, that of the structures executed with prefabricated systems, the variety is wide. We find, for example, prefabricated reinforced concrete wall systems that are carried on site and have dry joint solutions that act as load-bearing walls to support the loads of floors and roofs. These systems of limited dissemination in our country have important limitations of heights obtained and are also not very flexible systems of distribution in plan of the buildings, by restricting the possibilities of the factory measurements of the walls. We also have the systems that develop base habitable modules that include the resolution of the installation and / or enclosure systems, with possible variations on it to adapt it to different uses and that acquire higher levels of complexity due to the addition of several of these modules. They present the problems derived from the fact that the habitable module is built in a workshop and has to be transported to work, which limits its dimensions to the dimensions allowed by the transport channels. The flexibility of the system is therefore limited. Other systems are based on the construction of systems formed by different interrelated parts designed so that the joints can be solved in situ dry and in a short time. These systems are expensive and of limited applicability to the dimensions of the pieces, in addition to requiring a highly labor force
specialized.

The present invention is located halfway between the on-site and prefabricated execution systems, incorporating the flexibility of the former and adding to them the advantages of control and safety of the latter.

We also find inventions of systems of building pillars in which conformations are proposed telescopic These inventions represent an advance with respect to conventional systems without reaching the level of innovation proposed by the following invention because they do not contemplate a construction process like the present in which the structure is iza taking advantage of the characteristics and evolutions that the invention and with its consequent advantages.

Description of the invention

The invention serves in an optimal way to facilitate the execution of a building structure, especially in the case of structures for residential buildings with labor without high level of qualification and in buildings up to a number of heights not excessively high, since it exists the limitation of the weights to be lifted by the connected pilastones to the drive pumps.

The device of the invention provides the following advantages

Decreases the aerial phase of the work by 95% of its construction phase of the structure, which usually it represents a third of the total execution time of the work.

Enter a more advanced level of technology inside the building, in the same way that the elevators assume a technological evolution in the circulation systems of the building, more controlled and subjected to aptitude tests and reliability, with guarantee.

Decrease the execution times of the structure, not requiring hardening levels in pillars (at these do not exist and be replaced by prefabricated elements) or forged beyond resistance levels to withstand confined compressions.

It is expected a decrease in the levels of accident rate of the work if we stick to the study data of the Mutual Union in collaboration with Aidico (Institute Technological of Construction in the Valencian Community) that indicate that more than a third of construction deaths are due to accidents at height.

In the case that horizontal structures are reinforced concrete accelerates the hardening processes of the concrete since the heat of cement hydration generates a higher temperature in the structure that accelerates the reactions. All passing with less loss of humidity compared to the systems traditional since there is no ventilation between floors, to function all like a compact sandwich in which the elements centrals are isolated by those of the perimeter (which in turn generate hot).

For the same reason as above and counting also with horizontal reinforced concrete structures is a optimal system to build in cold places, since the volume to control hygrothermally to ensure non-freezing of the intimate concrete substrate - with the consequent loss of resistance- is much lower.

It facilitates the work of setting out especially as regards plumbing between horizontal structures.

Facilitates the transport of the execution material from the structure to the future raised floors, decreasing runtimes

Facilitate concreting, not being accurate pumps that drive the binder to high levels.

It is a versatile system in that they can offer different possible diameters and different lengths.

According to the invention, the system comprises a device formed by a telescopic support called pilastón attached to horizontal structures and a connection to a drive system that interact in a process destined to form an autonomous building structure and stable once the process has concluded. Telescopic stand It consists of as many segments as horizontal structures connect, incorporating connection elements to said horizontal structures that prevent punching both in the phase of the structure in which it acts as a mechanism as in the stabilized phase in which it acts as an isostatic structure or hyperstatic according to the specific embodiment of the invention. Sayings segments have connections to the pressure equipment that they introduce the necessary tension to induce the sliding of some segments over others and raise the horizontal structure linked to the sliding segment. Once the structure has reached the final level the device incorporates a mechanism that alters the type of union, going from acting as a mechanism to act as a fixed union and allowing the system to be removed safe drive and guaranteeing the operation as stable system Said mechanism of transformation of a state with degree of negative hyperstaticity to one with degree of zero or positive hyperstaticity may be integrated into the telescopic device or in connection to the device drive, contemplating the present invention both possibilities. In addition, the process is included as an inherent part of the invention. constructive that you need, in which the structure is built from the foundation bed dimension (either the ground or the base structure on which the affected structure is to be lifted by the present invention) that takes advantage of the advantages that this state allows previously described, with alterations in the systems for the execution of the work such as formwork (disappearing systems such as struts and giving way to elements less slender such as plots), meters, machinery transport (adapted to a non-aerial construction), systems of security (displacing the use of safety nets by systems of cushioning of less spectacular falls and prioritizing the fall of elements on the operators and the handling of the machinery), distribution of trades (in which the degree of specialization of the operators who manipulate the pilastones and make the drive of those who place the armor and concrete, steel structures, ... depending on the case), ... etc. A variant of the present invention contemplates that the pilastons do not are immobilized, the structure remains stable thanks to the discharge pressure and even free height variation by manipulating the discharge pressure with systems of frequency variation, to the way in which the height of Stop in hydraulic lifts.

Brief description of the drawings

Figure 1 shows a vertical section of a possible embodiment of the invention.

Figure 2 shows a horizontal section of a possible embodiment of the invention referenced as SECTION A-A 'to figure 1.

It is presented in Figures 3A-3E the process for horizontal reinforced concrete structures.

Figure 3A shows the time when Pilastones are presented on site.

Figure 3B shows an intermediate moment of successive formwork and concreting process of each level.

Figure 3C shows the moment in which all the levels are concreted and the structure is healing for reach the necessary resistance levels.

The 3D figure shows the moment when proceeds to raise levels 3 and 4.

Figure 3E shows the hoisted structure and set.

Figure 4 shows an image of a structure hoisted in a ground floor building plus two floor floors.

Description of a practical embodiment of the invention

For a ground floor building plus two floors of floor - in which therefore a horizontal structure is realized of foundation plus three horizontal concrete structures armed- the pilastón would consist of four segments 01-01-02-03, leaving the foundation pillar 00 embedded in the ground 04. The foundation segment 00 would be formed by a shirt lost resistant steel 06 and would have inside a second 07 steel inner shirt attached to the first ribbed to allow lubrication with lubricating oil 08 guiding the consequent sliding of the next segment 01. The segment of foundation has an increase 09 that indicates the upper level of the slab and allows to resist better the additional tensions that They could happen at this point. When the whole structure is concreted and with the level of resistance sufficient to resist their own weight the pressure taps 18 are connected to the top of the segment and curl up. At that time and before to start lifting, the plugs are connected on the opposite side 17 steel impact absorption with their corresponding Neoprene sealing washers and foam impact mattresses of polyurethane 12. Once both sides are screwed and assured, the drive pump is connected with a maximum capacity of 100 tons. At that time the upper segment 01 will begin to get up dragging everything on it, segments 02-03. The shear resistance plunger of steel (situation described in different section of the structure with the numbering 31) is currently inside the mouth of the pressure tap 18, allowing the passage of the lubricating oil into segment 00 driving the plant segment first 01. The steel bearings 10 allow the sliding of the segment 01. As the segment goes up the waiting tunnel 22 goes approaching the pressure tap until it faces the plunger, moment in which it slides inside until impact against the impact mattress 12. At that time the pressure can cease slowly so that the piston goes into charge 11. Once assured that all the plant's pilastones have reached the dimension at the same time and the plungers have reached their position it empties for which unscrew the valves of purged 20, leaving part of the oil through the drain channel 19. Said oil will be collected for reuse. At that moment one of the pressure taps 18 can be unscrewed, proceeding to the cleaning of the area and the subsequent welding 33 with maximum level of control of the piston against the head of the segment. We perform the same procedure with the opposite cap. We would continue unscrewing the remaining pressure socket and welding and we would end with the remaining impact plug. This would be done in all Pilastones at once. In this way, there are four zones of welding we make sure that the union resists against compression eccentric in both directions.

Each pilastón is attached to the structure horizontal by means of anti-puncture structures based on UPN 25 steel profiles attached to the head of the pilastón and braced to each other by steel flat 27 to secure the solidarity behavior between the metal structure and the concrete structure 24.

Describe sufficiently the nature of the invention, as well as how to perform it in practice, should be noted that the provisions indicated above and represented in the attached drawings are susceptible to modifications of detail as long as they do not alter the principle fundamental.

Claims (5)

1. Device to decrease the air phase in building structures of the permanent and non-detachable type multi-storey consisting of a telescopic stand or pilastón attached to horizontal structures and a connection to a system of impulsion that is characterized because the pilastón comprises a plurality of segments (00,01,02,03) sliding together, leaving the first foundation segment (00) embedded in the ground (04), being further formed said first segment (00) by a first shirt lost (06) and, inside, a second inner shirt (07) attached to the first ribbed shirt, to allow lubrication with the lubricating oil (08) guiding the consequent next segment slip; and where the drive system comprises a drive pump, with a plunger (11), a pressure tap (18) screwed on the top of each segment (00.01.02.03), as well as an impact absorption plug (17), washers and mattresses impact (12) such that, when the structure is concreted, the drive system is secured (12,17,18) and each segment where it is connected will begin to rise, dragging to the following segments; and where once the structure has reached the final level, means of alteration of the type of union (31.32) in the pressure tap (18), acting as fixed joint, removing the drive system. 2. Device according to claim 1 characterized in that as each segment climbs the waiting tunnel (22) it approaches the pressure tap (18) until it faces the plunger (11), at which time it it slides through it until it hits the impact mattress (12), ceasing the pressure so that the piston (11) enters into charge. 3. Device according to claims 1 and 2 characterized in that it comprises a purge valve (20) for each segment (00.01.02.03) and a drain channel through which part of the oil (08) leaves a Once the piston (11) has reached its position against the impact mattress (12). 4. Device according to the preceding claims characterized in that once without oil (08) and with the means of alteration of the type of union (31,32) in position, the opposite plug (17) is welded (33) to the pressure tap (18) unscrewed and housing the mentioned means. 5. System for decreasing the aerial phase in building structures of the permanent and non-detachable type of several plants comprising a plurality of devices according to claims 1 to 4 and characterized in that each pilaston is connected to a horizontal structure by means of anti-puncture structures based on profiles attached to the head of the pilastón and braced together.