SK285888B6 - Shaft system - Google Patents

Abstract

Shaft system composed of individual prefabricated building units, which may be assembled on the building site. Shaft system having at least one shaft unit (10, 310) with a straight inner pipe (12) and at least one junction unit (110) having an T-shaped inner pipe (112) with a lateral junction aperture (130). The building units have a portable outer shell (14, 114, 314) and a heat insulation layer (16, 116) and inner pipe (12, 112) which is formed longer than the outer shell (14, 114, 314). The heat insulation layer (16, 116) fixes the inner pipe (12, 112) in the outer shell (14, 114, 314).

Description

The invention relates to a shaft assembly of individual pre-fabricated building units which can be assembled on site, according to the preamble of claim 1.

BACKGROUND OF THE INVENTION

A similar system is known from U.S. Pat. No. 2,937,662.

In order to prevent heat loss, houses, especially apartment buildings, are increasingly insulated against drafts, especially with regard to thermal insulation regulations. However, sufficient ventilation must be ensured, which in most cases requires a complete air exchange in the living space within two hours. Vertical shafts are used for ventilation, for example brick shafts or concrete shafts, in which the inner tubes are additionally mounted.

Shaft grooves are usually provided in the walls of the house for guiding the waste water drainage pipe into which the waste water drainage pipes can be placed.

It is an object of the present invention to provide a shaft assembly which consists of cost-effective building units which can be quickly assembled on site by an unprofessional force even when the shell is being built, so that the shaft assembly can be plastered and / or paneled together with the walls. and is thus suitable as a ventilation system for central ventilation of a residential building.

SUMMARY OF THE INVENTION

The invention is described in the characterizing part of claim 1. The object is achieved by a shaft assembly of individual pre-fabricated building units which can be assembled on site, according to the invention, wherein at least one shaft unit with a straight inner tube and one connection unit with an inner tube T-shaped, with side connection hole. The building units are provided with a supporting outer shell and have a heat insulating layer that holds the inner tube in the outer shell. The inner tube is longer than the outer shell. The essence of the invention is that the inner tube is formed as a throat tube and the shaft assembly is part of a central ventilation system. An additional silencing unit and / or a ventilation unit can be used as an additional building unit.

The shaft units with a straight inner tube serve to form a vertical shaft, between which a connection unit with a lateral connection opening is installed at the required locations. A branch pipe can be connected to the side connection opening. A suction valve can also be inserted directly into the side connection opening.

The connection unit may be simply manufactured using a commercially available "T" piece, such as an inner tube, when the outer shell has a lateral recess for the connection piece of the "T" piece and has an interior extending at least from this recess extending up to the top or bottom. so that the "T" piece can be inserted eccentrically. After centering the longitudinal axis "T" of the piece on the axis of the outer surface of the outer shell, the lateral connection opening "T" of the piece abuts the outer wall in the recess area.

The supporting outer shell allows the construction of a transitional vertical shaft because the outer shell takes all weight forces when, for example, a vertical shaft is constructed from several building units, extending from the cellar floor to the roof floor.

The fluid medium is passed through the inner tube. As an internal pipe, for example, a conventional plastic pipe can be used, which is commonly used in waste water technology. This allows the rational and cost-effective production of building units.

The vertical shaft axis is determined by the interposed inner tubes. Due to the fixing of the inner tube in the outer shell, simple assembly is possible, the outer walls of the two successive building units being arranged in one plane.

Known technologies for the production of chimney elements can be used, where the outer dimensions of the shell correspond to the chimney shell part. This allows the rational and cost-effective production of building units.

The thermal insulation layer prevents condensate from precipitating in the shaft system, so no water drainage measures are required. In this case, the heat insulating layer may consist of a cured foam such as a polymer foam or foam concrete.

When the heat insulating layer consists of a cured foam, the inner layer can be centered with the outer shell during manufacture in the template. Subsequently, the intermediate space is poured out with fresh foam. After the foam has cured, the inner tube is fixed to the outer shell for a long time.

It is possible to form installation ducts for receiving water and heating pipes and / or power lines when at least one recess extending in the longitudinal direction is provided in the outer shell. After installing the required pipes and lines, the installation duct can be closed with a cover. In this way, very rational assembly of the pipes and lines on site is possible, and in case of need for repair these pipes and lines are accessible without punching, after the cover has been removed.

Especially when using the shaft assembly as a ventilation system in the central ventilation of a dwelling house, it is preferable that the outer shell has a rotationally symmetrical outer cross-section, and the thermal insulation layer fixes the inner tube coaxially to the outer shell. As a rotationally symmetrical outer cross-section, a round, eight or hexagonal or square cross-section is suitable. A preferred square cross-sectional shape.

For assembly, the inner tubes of the two building elements which are arranged one behind the other must be sealed to one another. Thereby their lateral coaxial axes determine the lateral position of the building elements. Since the thermal insulation layer fixes the inner tube coaxially to the outer shell, the outer walls of the rotationally symmetrical outer shell are also automatically coaxially aligned with each other. For square-section building elements, therefore, two building elements that are arranged one behind the other can be rotated with respect to one another and offset by 0 °, 90 °, 180 ° or 270 ° relative to each other, with the outer walls aligned. This is especially important when installing the connection unit.

When an additional soundproofing unit is additionally used as a building unit in a ventilation system, it can isolate both the "telephone sound" and the "installation sound" of a built-in ventilation unit. It is understood that with two or more sound-insulating units arranged one behind the other, a particularly strong sound attenuation is achieved.

When the inner tube is widened in the region of the soundproofing unit and its inner wall is provided with a sound absorbing liner, there is no reduction in the ventilation cross-section due to the liner.

If the natural air draft is not sufficient for the ventilation system, a ventilation unit can be additionally used. The ventilation unit is preferably installed in the roof space of the house.

The shaft assembly can be equipped with a roof passage unit for exhaust air removal. This can be, like a roof passage, equipped with a commercially available drain pipe. While the construction situation is decisive for the position of the vertical shaft, the position of the roof passage at an inclined roof depends on the position of the rafters and roof battens. The axial offset between the vertical shaft and the roof passage can be compensated when the connection of the roof passage to the outlet opening is made by means of a flexible hose. This roof passage unit can be used to extract air.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS The invention with reference to a preferred embodiment is explained in more detail with reference to the drawing in which: 1 is a plan view of a shaft unit with a straight inner tube for the shaft assembly, FIG. 2 is a longitudinal section along the line 11-11 of FIG. 1, FIG. 3 is a perspective view and a longitudinal sectional view of a T-shaped bending unit with an inner tube; FIG. 4, another shaft unit is shown in plan view.

DETAILED DESCRIPTION OF THE INVENTION

In FIG. 1 is a plan view of a building unit according to the invention, constructed as a shaft unit 10 with a straight inner tube 12 for the shaft assembly, and FIG. 2, this shaft unit is shown in longitudinal section along the line Π-Ι1 of FIG. The shaft unit 10 has a lightweight load bearing outer shell 14, the outer dimensions of which correspond to the chimney shell part. The outer shell 14 has a square cross section with a side length of 280 mm and a height of 332 mm. The inner tube 12 is a neck tube of plastic with an outer diameter of 125 mm. The inner tube 12 is coaxially mounted in the outer shell 14 by a heat insulating layer 16 of cured foam concrete. The outer shell 14 has a wall thickness of 45 mm. The interior also has a square cross-section, the corners being rounded with a radius of 60 mm. In the region of the corners of the outer shell 14, four through holes 18 with a diameter of 30 mm are formed, allowing the insertion of tensile anchors into one of the several shaft units 10 of the assembled shaft. The axes of the through holes 18 are spaced 35 mm from the outer surfaces of the outer shell 14 so that they are arranged in a square with a side length of 210 mm. In FIG. 2, it is clearly shown that the inner tube 12 is longer than the outer shell 14, the outer shell 14 having a height of 332 mm and the inner tube 12 having a length of 378 mm. The lower end section 20 of the inner tube 12, formed as a pointed end, therefore protrudes by 46 mm from the underside of the outer shell 14. When assembling several shaft units 10 into one shaft, the lower end section 20 of the mounted shaft unit 10 is inserted into the throat 22 of the inner tube 12 of the lower shaft units 10. In the upper end section 22, an outwardly directed circumferential groove is formed into which a circular cuff seal is inserted.

26, for the gas-tight and liquid-tight connection of the inner tubes 12.

In FIG. 3 is a perspective view and a longitudinal sectional view of another building unit, which is designed as a connection unit 110 with a T-shaped inner tube 112 and is provided with a side connection opening 130. The side connection opening 130 is arranged on a neck-shaped side connection socket 132 of the inner tube 112 in the "T" shape and permeates the recess 134 in the side wall 136 of the outer shell 114. The connection hole 130 closely fits to the outer wall of the outer shell 114.

From the underside, the side wall 136 to the recess 134 is made thinner than in other regions, resulting in an expansion of the inner space of the outer shell 114. Thus, the "T" -shaped inner tube 112 can be fitted eccentrically prior to spillage. After coaxial adjustment of the longitudinal axis "T" of the piece to the axis of the outer surfaces of the outer shell 114, the interspace can be filled with foam. After the foam has cured, the inner tube 112 is mounted in the outer shell 114.

In FIG. 4, another shaft unit 310 for a wastewater system is shown in plan view. This shaft unit 310 has a straight inner tube 12, an outer shell 314, a heat insulating layer 16, and a sound insulating layer 28 of sound insulating material. In the outer shell 314, a recess 38 extending in the longitudinal direction is formed, forming an installation channel in which the water and heating pipes 40, 42, 44 are arranged. After the installation of the conduit, the recess 38 can be closed by a cover 46.

Claims (8)

A shaft assembly of individual pre-fabricated building units, assembled on site, with at least one shaft unit (10, 310) with a straight inner tube (12) and at least one connection unit (110) with an inner tube (112) in the form of " T ', with a side connection aperture (130), wherein the building units are provided with a supporting outer shell (14, 114, 314) and a thermal insulation layer (16, 116) for attaching an inner tube (12, 112) which is formed as a neck tube , and is longer than the outer shell (14, 114, 314), characterized in that the inner TUBE (12, 112) is formed as a throat tube and that the shaft assembly is part of a ventilation system for centrally ventilating houses, in particular apartment houses. the building unit is connected to a noise attenuation unit and / or a ventilation unit. Manhole assembly according to claim 1, characterized in that the outer dimensions of the outer shell (14, 114, 314) correspond to the chimney part. Manhole assembly according to claim 1 or 2, characterized in that the outer shell (14, 114, 314) is made of lightweight concrete. Manhole assembly according to claims 1 to 3, characterized in that the thermal insulation layer (16, 116) consists of a cured foam material such as a polymer foam or foam concrete. A shaft assembly according to any one of the preceding claims, characterized in that at least one recess (38) extending in the longitudinal direction is formed in the outer shell (314) to form an installation duct. A shaft assembly according to claims 1 to 4, characterized in that the outer shell (14, 114, 314) has a rotationally symmetrical outer cross-section, wherein the inner tube (12, 112) is fixed coaxially in the outer shell (14, 114, 314). a thermal insulation layer (16, 116). Manhole assembly according to claims 1 to 6, characterized in that it is provided with a roof passage unit. A shaft assembly according to claims 1 to 7, characterized in that a sound-insulating layer (28) is formed between the inner tube (12) and the outer shell (14, 114, 314).