AT14917U1 - arch house - Google Patents

Abstract

The invention relates to a bow house of semicircular prefabricated concrete elements (1), wherein each two oppositely arranged precast concrete elements (1) form an arc, wherein the precast concrete elements (1) have a tongue and groove connection at the apex of the bow. The invention further comprises a method for constructing a bow house according to the invention made of precast concrete elements (1).

Description

Description: The invention relates to a bow house made of semicircular prefabricated concrete elements.

E in bow house is a house with an arched roof, or ceiling and in the strict sense, a house whose outer surface is substantially arcuate in its entirety.

DE 3246364 A1 shows a bow house, which is formed from semi-circular uniform reinforced concrete parts. During construction, the floor slab is laid in sections on a prepared subgrade in individual slab strips and optionally provided with an abutment. Then then the elliptical side and ceiling shells are also set up in sections from the abutment to the apex and secured by supports. By placing the appropriate "counterpart", the two shells hold each other and the support can be removed and used for the next section or the next container. Thereafter, the arcuate foot in a groove created by the customer of the bottom plate and the apex or ridge line is cast to form a three-hinged frame. The disadvantage is that a support is needed to build, or that the similar arch elements only reliably support each other when the parabolic elements are arranged vertically and thus exceeds the height of the house half the width of the house, which is not effective especially for single-storey arched houses is.

The AT 13649 U2 shows a ground-level, barrier-free solid house in modular design, which is composed of several equal and interconnected, curved modules gewölbewirkend, the modules are placed on on-site prepared concrete bases and frontal Deckenabschalungen. Also, this house is formed of uniform reinforced concrete parts, which are used to build supports that support the reinforced concrete parts at the apex or ridge. Any support can only be removed if the reinforced concrete parts are connected by the introduction and curing of concrete at the crest or ridge.

The object underlying the invention is to improve the construction of a bow house so that it can be erected without the use of supports.

For solving the problem is proposed, the precast concrete elements in particular reinforced concrete precast parts of the bow house, which face each other an arched, at the ridge or apex to be provided with a tongue and groove system.

This ensures that the precast concrete elements reliably support each other, even if the width of the house significantly exceeds the height of the house, or if the arc width is more than twice the stitch of the sheet.

Preferably, the arc formed by two semi-curved precast concrete elements is an elliptical arc, basket arch or more preferably a stitch, segment or flat arch.

Particularly preferably, the precast concrete elements seen at the apex in the longitudinal direction of the house or building part on at least two different areas, wherein in the first region, the finished part is provided with a groove and / or a spring and in the second region with a recess, which for Production of the ceiling closure can be potted with concrete. Preferably, this recess is arranged at the top of the precast concrete part and thus at the top of the arch to be built and does not extend to the bottom of the sheet, so that the recess can be concreted without the attachment of a formwork, to connect the precast concrete elements together materially. Compared to the prior art is achieved so particularly advantageous that the bow house without the use of supports and formwork can be built extremely quickly.

The invention, in particular its advantageous embodiments and further inventive, over the prior art advantageous details will be on hand

Drawings are shown in: Fig. 1a: shows schematically a particularly preferred single-storey arched house formed from exemplary prefabricated concrete elements according to the invention from the front.

Fig. 1b: Shows the most preferred single-storey arch house of Fig. 1a from above.

2a shows four exemplary ready-mixed concrete elements according to the invention in exploded onsdarstellung from above.

2a shows two exemplary precast concrete elements according to the invention in exploded onsdarstellung from the front.

Fig. 3: shows schematically a two exemplary Fertigbetonele inventive elements from above.

Fig. 4: shows a schematic detail view of an inventive Ausgestal tion of the bottom plate in the area of the supports of the precast concrete elements.

Fig. 5: Shows the structure of a bow house according to the invention in a schematic sectional view from above.

In Figs. 1a and 1b whose construction and assembly of precast concrete elements 1 is shown using the example of a single-storey arch house according to the invention. In the upper view, which shows the bow house from the front, the bottom plate 2 is shown, which may also be formed from precast concrete parts. However, the bottom plate 2 is preferably erected on site in a casting (as a monolithic foundation plate) with water impermeable concrete. In static terms, this acts as a so-called "drawstring", in which the statically effective forces of the vault are initiated.In addition, in this component preferably already installed the floor heating (concrete core activation) .The surface is either sanded (suitable for floor coverings) or can be used as a finished floor surface (completely sanded and sealed), or a screed can be laid on the floor sheet The necessary thermal insulation under the floor slab is either by means of glass foam granules or with appropriate thermal insulation panels (strength It., Requirements from the energy certificate) erected.

The bottom plate 2 has two parallel concrete base 3, which are non-positively (and also by means of joint tape) connected to the bottom plate 2 and serve as an abutment for the precast concrete elements 1.

Each two bent precast concrete elements 1 are placed opposite to the on-site prepared concrete base 3 and abutment and placed at the apex to each other, so that the spring of the first precast concrete part in the groove 1.2 of the second precast concrete part 1 protrudes.

The setting up of precast concrete element 1 is preferably carried out with two cranes, as can be worked without supports in this case. Alternatively, the erection can take place with a crane and a mobile lowerable support for the respectively first erected precast concrete elements 1 of a sheet.

Preferably, the precast concrete elements 1, a plurality of small recesses 1.4, which are arranged along the lateral contact surface of the precast concrete elements 1. These small recesses 1.4 serve to connect the juxtaposed precast concrete elements 1 reinforcement technology.

In the Fig.1b the bow house of Fig. 1a is shown from above. In this example, the bow house consists of eight precast concrete elements 1, with two opposite precast concrete elements 1 forming an arc. Each sheet consists of two different precast concrete elements 1, wherein a precast concrete element 1 at the apex has a spring 1.1 and the other a groove 1.2.

In the example of Fig. 1b, the bow house consists of four such adjacent arches of precast concrete elements 1, the length of the house thus corresponds to the width of four precast concrete elements 1. Since it is theoretically possible to arrange any number of precast concrete elements 1 next to each other, a bow house be made in any length.

The width of a precast concrete element 1 is preferably between 0.5 and 3 meters, in particular between 2 and 2.5 meters. The arc width is preferably between 8 and 30 meters, in particular between 15 and 20 meters. The stitch height is preferably between 3 and 5 meters, in particular between 3.5 and 4.5 meters. The wall thickness of a precast concrete element 1 is preferably between 15 and 30 centimeters, in particular between 20 and 25 centimeters.

In the embodiment of Fig. 1b, the ceiling closure is made by the positive connection of the tongue and groove system, but preferably the precast concrete elements 1 are also connected at the apex reinforcement technology and / or by pouring concrete.

On the erected and reinforced technically connected precast concrete elements a conventional flat roof construction (as a warm roof or as a reversible roof) is laid and preferably applied to this on-site deposited soil together with humus again to allow intensive greening. Through the "soil inflow" (including intensive greening) on the vaulted ceiling creates a pleasant indoor climate (warm in winter and cool in summer) .By other arches from ready-mixed concrete elements 1 according to the invention on the building conclusion can be implemented on the one hand shading, on the other hand, a partially covered terrace The building can also be built as a semi-detached house due to its symmetrical construction.

The drainage of the roof is preferably carried out exclusively on both sides in the region of the concrete base 3 and arranged over the entire length of the house extending drainage lines. 5

In FIGS. 2a and 2b particularly preferred precast concrete elements 1 are shown. These have at the apex on two different areas, wherein in the first area a tongue and groove system for positive connection of two precast concrete elements 1 to a bow is present and in the second area a recess 1.3, with the opposite precast concrete elements 1 of the bow at the apex by reinforcement technology Measures are connectable and a cohesive ceiling closure can be produced.

As shown in Fig. 2a are preferably two such recesses 1.3 per ready-mixed concrete element 1 present in that region of the apex in which the adjacent precast concrete elements 1 are adjacent to each other, so always four precast concrete elements 1 by their adjacent recesses 1.3 are connected to each other and without the attachment of a formwork.

The connection is preferably carried out in that cast in the respective precast concrete elements 1 reinforcing elements 1.5, which protrude into the recess 1.3 with the reinforcing elements 1.5 of the adjacent recesses 1.3 are technically connected and the four adjacent recesses 1.3 subsequently poured with concrete to achieve a permanent connection of the four precast concrete elements 1.

The reinforcing elements 1.5 are preferably formed by reinforcing steel, in particular round steel rods. Preferably, the reinforcing elements 1.5 are designed as stirrup reinforcement, wherein the stirrup reinforcements of the respectively adjoining precast concrete parts 1 are connected to each other by the use of reinforcing steel.

In the area between the recesses 1.3, the vertex of the opposing precast concrete elements 1 is provided with a spring 1.1 and a groove 1.2 which, as shown in FIG. 2b, preferably have a semicircular shape. The fact that the groove 1.2 extends only over the central region of the vertex, the two opposite precast concrete elements 1 are fixed to each other in the longitudinal direction of the building. This advantageously achieves that the opposing precast concrete elements 1 obtained by the tongue and groove system both in the vertical direction, as well as in the horizontal direction when setting up their desired orientation, so that a Einjustieren the concrete precast elements 1 after compilation is not necessary.

As shown in FIGS. 2 and 2a, hoses 1.6, in particular electrical installation hoses, are preferably inserted into the casting mold during manufacture of the precast concrete elements 1 and thus integrated into the precast concrete element 1. As shown, the opening of the hose 1.6 may lie on the inside of the sheet or precast concrete element 1 near the vertex. Preferably, the building or the building part in this area on a suspended ceiling, in the space above the suspended ceiling installations (ventilation, cable ...) are laid. Since the position of the hose 1.6, which runs for example in the longitudinal direction of the precast concrete element 1, in the precast concrete element 1 is known, this can be drilled at any point of the arc and subsequently cables are drawn in particular for lighting elements.

Preferably, the same mold, or formwork is used for the preparation of the two concrete precast elements 1 of an arc, with only the formwork element for forming the groove 1.1, or spring 1.2 is changed at the apex. When using a modular mold or formwork for producing the precast concrete elements 1, for example, the recesses 1.3, 1.4 are adapted to the site of the precast concrete element 1, so that on the side surface of the precast concrete elements 1, which is intended at the end of the building, no recesses 1.3 , 1.4 are available. As shown in FIG. 2, the tongue and groove system preferably extends at least over a third, preferably at least over half, of the width of the precast concrete element 1.

As shown in Fig. 3, it is also conceivable uniformly executed precast concrete element 1 to use when each precast concrete element 1 at the apex both a spring 1.1 and a groove 1.2, wherein in opposite arrangement of two identical precast concrete elements 1, the spring 1.1 of the first Prefabricated concrete element 1 in the groove 1.2 of the second precast concrete element 1 protrudes and the spring 1.1 of the second precast concrete element 1 in the groove of the first precast concrete element 1. It is advantageous that only one type of precast concrete elements 1 is needed to build the bow house. As shown in FIG. 3, it is also possible to integrate in each precast concrete element 1 a plurality of tubes 1.6, in particular two each along the third lines of the precast concrete element 1.

In Fig. 4, a particularly preferred embodiment of the invention, the bottom plate 2 is shown in the region of the abutment. The abutment is formed by the base 3. In the area of the base 3, the bottom plate 2 is made thicker than in the central region of the arch, or building. As a result, the bottom plate 2 is relieved, resulting in a significant material savings. According to the invention, it is provided to extend the base plate 2 beyond the base 3, wherein this projection 2.1 of the base plate is inclined at its upper side so that rainwater draining from the roofing can flow down the incline of the slope into the drainage line 5. The widened region of the base plate 2 preferably projects slightly beyond the base 3 in the direction of the interior of the building. The height of the base 3, or the distance of the abutment to the bottom plate 2 can be arbitrarily dimensioned depending on the requirements of the building or the building part and is for example between 0 and 100 cm, in particular between 20 and 50 cm.

In Fig. 5, the construction of a particularly preferred bow house according to the invention is shown, wherein the outer bow outside the building, for example, as a patio roofing, is arranged. As can be seen in Fig. 5, the outer arc according to the invention placed spaced from the following arches of the building. This advantageously achieves that, on the one hand, a cold bridge from the outer arc to the interior of the building is prevented by the gap 9 and, on the other hand, a glazed connection in the gap 9 is made possible for façade elements, in particular a glass facade 8. The glass facade 8 is therefore mounted in the gap 8 between two sheets, can move in thermal expansion in the gap 8 and is used for thermal separation of the sheets. Particularly preferred is for the

Glass facade 8 insulating or heat protection glass used. In Fig. 5, the flat roof structure 6 and the earth bed 7 are shown schematically.

Claims (20)

claims 1. bow house of semi-curved precast concrete elements (1), characterized in that each two oppositely arranged precast concrete elements (1) form an arc, wherein the precast concrete elements (1) at the apex of the bow have a tongue and groove connection. 2. bow house according to claim 1, characterized in that the length of the bow house by the number of juxtaposed sheets of two oppositely arranged precast concrete elements (1) is determined. 3. bow house according to one of claims 1 and 2, characterized in that the precast concrete elements (1) at the apex each have at least one recesses (1.3), wherein the recesses (1.3) of two oppositely arranged precast concrete elements (1) are flush with each other. 4. arch house according to claim 3, characterized in that the precast concrete elements (1) along the vertex have two different areas, wherein in the first region a spring (1.1) or a groove (1.2) extends and in the second region a recess (1.3) present is, wherein the groove (1.2) or spring (1.1) preferably extends over at least one third of the length of the apex, more preferably over at least half the length of the apex. 5. bow house according to one of claims 3 to 4, characterized in that each precast concrete element (1) at the apex has two recess (1.3), wherein each of these recesses (1.3) with one of the recesses (1.3) of the opposite precast concrete element (1) and a recess (1.3) of the adjacent precast concrete element (1) is flush with each other. 6. bow house according to one of claims 1 to 5, characterized in that each precast concrete element (1) comprises both a spring (1.1) and a groove (1.2), wherein in opposite arrangement of two identical precast concrete elements (1) the spring (1.1) of the first precast concrete element (1) projects into the groove (1.2) of the second precast concrete element (1) and the spring (1.1) of the second precast concrete element (1) projects into the groove (1.2) of the first precast concrete element (1). 7. bow house according to one of claims 1 to 6, characterized in that precast concrete element (1) on each side surface at least one respective recess (1.4), wherein the recesses (1.4) of two adjacent precast concrete elements (1) are flush with each other. 8. bow house according to one of claims 3 to 7, characterized in that protrude from the precast concrete element (1) reinforcing elements (1.5) in one or more of its recesses (1.3, 1.4). 9. bow house according to one of claims 1 to 8, characterized in that in the precast concrete elements (1) hoses (1.6) are integrated. 10. bow house according to one of claims 1 to 9, characterized in that the width of a precast concrete element (1) between 0.5 and 3 meters is preferably between 2 and 2.5 meters, the wall thickness of a precast concrete element (1) preferably between 15 and 30 centimeters, the arc width of the sheet formed by two opposing precast concrete elements (1) is between 8 and 30 meters, preferably between 15 and 20 meters, and the stitch height of the sheet is between 3 and 5 meters, preferably between 3.5 and 4.5 meters is. 11. bow house according to one of claims 1 to 10, characterized in that the spring (1.1) and the groove (1.2) have a semi-circular shape. 12. A method for the construction of a bow house of semi-curved precast concrete elements (1) according to one of claims 1 to 11, characterized by the steps - on-site production of two spaced abutment, - placing the lower end of each precast concrete element (1) on each abutment, - against each other the upper ends of the precast concrete elements (1), so that the precast concrete elements (1) by the tongue and groove system and the two abutments are held in position and a self-standing arc is formed. 13. The method according to claim 12, characterized in that the abutments are erected on or in a bottom plate (2) which extends below the entire bow house. 14. The method according to claim 13, characterized in that the bottom plate (2) is wider than the arches and their abutment is erected, and so the abutment projects beyond the arc, the top of this projection (2.1) of the bottom plate (2) to the outside extending obliquely downwards is formed. 15. The method according to claim 14, characterized in that the bottom plate (2) in the region of the projection (2.1) and in the region of the abutment is built thicker than in the central region of the bottom plate (2). 16. The method according to any one of claims 13 to 15, characterized in that the abutment for the precast concrete elements (1) by the base plate (2) connected to base (3) in the height spaced from the bottom plate (2) are erected. 17. The method according to any one of claims 12 to 16, characterized in that in addition to the preceding arc in the manner described in claim 12, a following arc is erected until the desired length of the bow house is reached, with adjacent and / or opposite precast concrete elements ( 1) during or after the erection of the following sheets reinforcement technology and / or be connected by pouring concrete. 18. The method according to any one of claims 12 to 17, characterized in that lying outside the building decision sheets with a gap (9) spaced from the arches of the building interior are placed. 19. The method according to claim 18, characterized in that between the arches of the building interior and lying outside of the building decision arcs a facade, in particular a glass facade (8) is installed, which is slidably mounted in the gap (9). 20. The method according to any one of claims 12 to 19, characterized in that in the area below the apex of the arch of the bow house a suspended ceiling is attached. For this 3 sheets of drawings