HUT77733A - Supply fitting with bypass house built in socle - Google Patents

Abstract

The invention concerns a built-in component to be arranged in floors with a through-flow housing comprising at least one inlet passage and at least one outlet passage constructed such that through-flow connection devices can be provided. On the housing, in the region of at least one of the passages, the built-in component has a flange member (7) which seals the passage externally with respect to the floor. Said flange member has a pipe-shaped attachment (9) for mounting the connection device.

Description

FIELD OF THE INVENTION The present invention relates to a fitting for a subfloor layer with a flow housing formed in connection with a flow-through connection fitting.

it has at least one inlet and one outlet.

Such built-in fittings are usually installed in subfloor layers, such as subfloor concrete, when it is necessary to conduct flowable media, such as water, to the floor, or conversely, flowable media, such as gases, from the floor to the atmosphere.

This is a typical application of drainage to the floor when rainwater is collected in a gutter when it is raining on the roof of a building and then has to be channeled through a gutter to the soil itself or, for example, to a sewer installed in the soil.

From this it is evident that one of the important applications of such anchoring fittings is that these fittings are fixed to the floor and thus embedded in, for example, concrete or asphalt. And since fittings to be connected to built-in fittings, such as rainwater drainpipes, must be routed, at least in their final section, to the concrete floor, replacing the end of the pipe due to a defect such as rusting is very labor-intensive and consequently expensive the solid concrete floor must be broken and restored after the defective miracle has been replaced.

Since the scope of application of such fittings is extremely diverse and thus requires the connection of the fitting to a wide variety of gauge sizes, it is necessary to prepare all possible gauges and sizes of the miracle to be interconnected, to can be replaced. By its very nature, this means that in addition to the significant labor involved in replacing the defective miracle, the cost of manufacturing and storing known built-in fittings is also high because of the number of fittings that need to be assembled and stocked. exists.

A known, artisanal assembly for incorporation into subfloor layers, such as subfloor concrete, typically includes a flow housing having at least one inlet opening and one outlet outlet formed in connection with the flowable connection fittings. For example, such a prefabricated fitting is embedded in subfloor concrete, and then a rainwater drain pipe is connected, for example, to the inlet of the fitting body so that water enters the inlet through the inlet and also exits through the inlet. the House. However, as mentioned above, the known built-in fittings have the disadvantage that they are designed to be directly connected therewith, so that a large number of variants are required of the built-in fitting for a variety of applications.

It is therefore an object of the present invention to overcome the drawbacks described and to improve the mounting assembly in such a way that a large number of application requirements can be met with a single mounting assembly and that the connection assembly to be connected to the mounting assembly is simplified.

The assembly to be incorporated into the substrate layers of the present invention includes a flow housing having at least one inlet through and one outlet through which is connected to the flow-through connection fittings, and which housing has at least one opening in the through flap and is provided with a miracle-shaped extension for connection to the coupling fittings.

The present invention is based on the following fundamental idea: the coupling fittings to be connected to the fitting do not have to be connected to the housing of the fitting, but the flange to be connected to the housing so that a variety of different types of connector assemblies can be connected to the same fitting.

An advantage of the built-in fitting according to the invention is that it is flowable

In order to connect the coupling fittings to the mounting fixture, the coupling fixtures must now be coupled with a miracle-shaped extension on the flange body and there is no need to connect the flow-through coupling fittings directly to the housing of the fixture. In other words, this means that in the case of a fitting according to the invention embedded in a subfloor such as subfloor concrete, the fitting assembly is connected to the flange body by a miraculous extension so that when the fitting assembly becomes due, the fitting so that the coupling assembly connected to the housing of the built-in assembly can be removed.

It is also a great advantage of the fitting according to the invention that there is no longer a need for a large number of fittings having different connection sizes, since the miracle-shaped extension of the flange body can be uniform and only a properly formed intermediate piece is required to connect the flow-through connector. the difference between the shaped extension and the coupling assembly, such as a diameter difference, can be bridged. This is advantageous in that it can subsequently be replaced with a flow-through coupling assembly, for example, with a coupling assembly having a diameter different from that of the previously installed coupling assembly. The subfloor must only be extended to the depth of the joint and the deep-seated fitting, for example, may remain intact.

The housing of the built-in assembly may be in the form of a multi-part housing comprising a bottom plate such as a cylindrical housing body and a connection plate for connecting to the flange body, wherein one of the flow-through connection assemblies may be connected to the housing body. In other words, the flow direction of the flush-mounted assembly is determined by the flange body on the one hand, since the flange body has a through opening and on the other hand by the housing body, because the housing body has an additional flow-through connection. defined from the flange body to the housing body and out of the housing body.

In a possible embodiment of the fitting assembly according to the invention, the housing body, the connection plate and the bottom plate are hermetically sealed together with the material to form a housing, mainly glued or welded, and between the connection plate and the flange body a bonding adhesive which seals the outlet through outward in the direction of the substrate.

The advantage of this solution is that, due to the hermetically sealed sandwich connection between the housing body, the connector plate and the bottom plate, the unwanted flow of fluid entering the mounting fixture into the substrate layer surrounding the fixture is prevented. If so

For example, if water could escape unwantedly, entering the subfloor layer, such as concrete, surrounding the mounting fixture would continuously destroy the subfloor layer.

In addition, a foil is disposed between the connector plate and the flange body, extending radially inwardly through the opening between the flange body and the connector plate, and extending radially outwardly beyond the housing of the mounting fixture into the substrate layer.

This solution ensures that, for example, unwanted penetration of water into the substrate layer surrounding the built-in assembly, such as concrete, is prevented, even where the foil is defective or incomplete, i.e. where it can be avoided to be embedded in the substrate layer there is an opening in the sealing foil. By inserting the foil into the sealing bond between the joint plate and the flange body, i.e., the hermetically sealing sandwich joint between the joint plate and the flange body, it is possible to prevent the foil from becoming an integral part of the sandwich joint and prevent water from passing through the foil. .

In a further embodiment of the fitting assembly according to the invention, the essential sealing in the substrate layer is further enhanced by securing the flange body to the connection plate by screwing it together with the adhesive material sealed between the flange body and the connection plate. can be clamped to the connector plate.

In other words, the sealing effect of the material-sealing bond (created by the adhesive inserted between the connector plate and the flange body) is further enhanced by the fact that a screw-pressed bond is formed. The extruded joint is formed by pressing the flange body and the connection plate together with the adhesive applied between them, thereby closing the inevitable gap between the flange body and the connection plate. The sealing effect is further facilitated by the fact that, according to the invention, the foil extends into the sealing joint between the connector plate and the flange body, thereby forming a hermetically sealing sandwich bond.

In a further embodiment of the built-in fitting according to the invention, the profile of the miracle-shaped extension is the same as that of the housing body. Thereby, it is ensured that the internal volume of the fitting assembly, as defined by the shape of the body section, will not be undesirably reduced by the miracle-shaped extension. For example, a reduction in volume would, for example, in the case of a rainwater drainage pipe, lead to a congested water at the height of the wonder-shaped extension, which would eventually swell back into the rainwater drainage pipe and overflow the rainwater drainage pipe.

In a further embodiment, the miracle-shaped extension may be formed as an extension forming an integral part of the flange body or closed with the flange body and / or material. In other words, the tubular armband is already molded on the flange body during manufacture of the flange body, but it is also possible for the miracle-shaped extension and the flange body to be manufactured in separate pieces and then connected to the shape and / or material by a sealing joint.

In a further embodiment, the miracle-shaped extension can be locked to a shape or material by means of a flow-through coupling assembly. The material is sealed by a bond, such as an adhesive inserted between the tubular joint and the flow-through connection assembly, to provide the necessary sealing of the entire assembly.

In a further embodiment of the invention, a mounting plate with at least one bore may be attached to the terminal board in such a way that the assembly integrated in the substrate layer can be subjected to a pressure test. In this case, for example, the tightness of the embedded assembly embedded in the sub-concrete can be subjected to a pressure test by pressing with water. To this end, the fitting, including the inlet and outlet inlets, is first vented and then filled with the water used for pressing. The operation is made possible by attaching to the terminal board a mounting plate with at least one bore, i.e. a mounting plate provided with a through vent hole; the hole is open during filling and can be closed by pressing with a sealing threaded plug.

An example of a fitting assembly according to the invention is

can be used as floor drain and / or for drainage of rainwater and / or ventilation systems for drainage systems, but can also be used e.g. also as a closure for a pipe cleaning opening.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail with reference to the drawings, in which: The attached drawings show

Figure 1 is a schematic side view and partly sectional view of a mounting assembly according to the invention; the

Figure 2 is a sectional view of an assembly mounted in a concrete layer and a vent pipe connected thereto; and the

Figure 3 is a sectional view of an assembly similar to that of Figure 2 and a drainage pipe connected thereto.

As shown in Fig. 1, in the embodiment shown, the fitting assembly 1 comprises a housing 2, which is a multi-part housing comprising a bottom plate 3, a connector plate 4 and a housing body 5.

The bottom plate 3, the connection plate 4 and the housing body 5 may be of any shape, although preferably the bottom plate 3 is of circular shape, the connection plate 4 is of circular shape and the housing body 5 is of circular shape. It is evident that a branch pipe 6 is connected to the casing 5 of the housing body, which may be glued to the housing body 5 for example to seal the housing 2 from a plastic such as PVC or HDPE (high density polyethylene). or welded, although the branch pipe 6 and the body 5 may be formed in one piece.

More generally, the housing 2 of the fitting assembly 1, when formed as a multi-piece housing, is formed by sandwiching the bottom plate 3, the connection plate 4 and the housing 5 to ensure airtight sealing. In other words, this means that the circular cylindrical body 5 with its bottom and top faces is inserted into the circumferential grooves in the bottom plate 3 and the connector plate 4 respectively, and there is closed by material such as gluing or welding with the base plate 3 and connector plate 4. - connected.

Since it is possible that the mounting fixture 1 may have to meet the sealing requirements, it is possible, after being integrated in the substrate layer, to attach a mounting plate (not shown) with a vent hole to the terminal plate 4; Thus, when the valve 1 is filled with water, the air contained therein can escape through the vent hole. The vent hole is then sealed with a hermetically sealed threaded plug and the valve 1 can be checked for leaks by pressing it with water.

As shown in the figure, an annular flange body 7 is placed on the upper side of the connection plate 4, which can be fastened by screwing 8 to the connection plate 4.

A miracle-shaped extension 9 is inserted into the inner peripheral surface of the flange body 7, which extends upwardly from the housing body 2 of the mounting assembly 1. A dotted adhesive is applied between the contact surface of the flange body 7 and the upper side of the connector plate 4, which, when the flange body 7 and the connector plate 4 are made of plastic such as PVC or HDPE, seals with material secures a bond. However, a film 10 is inserted between the flange body 7 and the radially outer part of the connector plate 4, which extends radially outwardly from the housing 2 of the fitting assembly 1 and is fluid or gaseous permeable to the tubular extension 9 and housing body 5. has an opening. However, at the radially outer part of the flange body 7, the foil 10 extends between the flange body 7 and the connection plate 4, more specifically in an adhesive material that connects the flange body 7 and the connection plate 4 so that when the screw 8 is tightened, the film 10 , Becomes an integral part of the pressed joint formed by 4 connecting plates and adhesive. This solution ensures that the built-in assembly 1 is sealed in the direction of the surrounding substrate layer, such as concrete or additional insulating material (screed or screed).

Fig. 2 schematically illustrates an application of the mounting assembly 1. A flange body 11 is mounted on the miracle-shaped extension 9 of the assembly 1, the miracle-shaped extension 12 of which is, for example, secured to material by a miracle-shaped extension 9 of the flange body. On the opposite side of the flange body 11, the flange body 11 is provided with an additional flange body on the flange body 11, which is also of miraculous shape and has an extension extending in the opposite direction of the flange body 1.

The last-mentioned miracle-shaped extension is connected to a vent pipe 13 so that, in the illustrated embodiment, the mounting fixture 1 can serve, for example, to supply fresh air to the space in the base layer (not shown) or to remove used air. For the sake of clarity, it is noted that the vent 13 extends into the atmosphere and that its portion towards the mounting fitting 1 is, for example, surrounded by a layer of humus; the humus layer is followed by a schematically illustrated drainage layer, followed by a further layer of subfloor, followed by an insulating layer such as a screed 14. Above the cover layer 14 is the aforementioned film 10. The mounting fixture 1 is embedded within these subfloor layers in an additional subfloor layer, such as subfloor concrete, such that, as shown in the figure, the entire fitting assembly (vent pipe, additional flange body, flange body 7, need not be disassembled) and a fitting 1), but if, for example, a larger diameter vent pipe is to be used, the substrate layers need only be dismantled to the depth of the flange body 7 or the upwardly extending miracle-like extension 9. In this place, for example, an additional spacer can be inserted without having to dismantle the substrate layer, for example the substrate concrete, which accommodates the mounting assembly 1.

Fig. 3 shows another embodiment of the mounting assembly 1. The structure of the individual substrate layers is the same as that shown in Figure 2, so we will not discuss this again here.

The vent pipe 13 shown in FIG. The water accumulating in the soil surrounding the drain member 15 can enter the drain member 15 through gaps and can be discharged through the mounting fixture 1 and the branch pipe 6. It should be noted that the illustrated application examples are provided for purposes of understanding only, for example, the structure of Fig. 3 may be incorporated into a flat roof of a building with the drain member 15 lying in the roof garden and the mounting fixture 1 e.g. be embedded in a solid roof structure.

From the foregoing, it is obvious that the mounting assembly 1 is a multifunctional device that can be used for a variety of purposes.

For example, it is also possible to install the fitting 1 as a floor drain in the basement floor. For this purpose, only one spacer ring, a grid frame and a drainage grate are mounted on the fitting 1, while a branch strainer can be inserted into the branch pipe 6 - here the drain pipe.

The built-in fixture 1 can be used as floor drain even in more demanding hygiene situations, such as kitchens or hydrotherapy units. In this case, a vapor lock can be mounted on the miracle-shaped extension 9 or extension. The layout will be similar to the

Shown in Figure 2, except that in Figure 2 • ·

The foil 10 shown here may be placed over a heat-insulating layer and a cover layer on the flange body 11, above which is an additional miracle-shaped extension with a grid frame and a drainage grid on top.

Finally, the mounting fitting 1 can also be used as a vent for the basic conductor in an arrangement similar to that shown in FIG. In this case, the fitting 1 does not ventilate or provide fresh air to an underground space, but a duct system, such as a drainage duct system, which is laid in a subsoil. Up to a plurality of fittings 1 having a function of the cleaning opening can be mounted on the piping system. Thus, no water is discharged with the mounting fixture 1 and there is a screw-on plate on the top of the drain element.

Claims (11)

An assembly for mounting in substrate layers with a flow housing, the housing having at least one inlet opening and one outlet outlet formed in connection with a flowable connection assembly, characterized in that , and is provided with a miracle-shaped extension (9) for connection to the coupling assembly, and the housing (2) is formed as a multi-part housing. Fitting according to Claim 1, characterized in that the housing (2) has a bottom plate (3), a housing (5) preferably of a circular shape and a connection plate (4) for connecting it to the flange body (7), and one of the connection fittings is connected to the housing body (5). Fitting according to Claim 1 or 2, characterized in that the housing body (5), the connection plate (4) and the bottom plate (3) are hermetically sealed together with the material to form a housing (2), in particular by sandwich bonding, in particular welded, and between the connector plate (4) and the flange body (7) there is an adhesive which sealingly connects the connector plate (4) and the flange body (7) to the through hole in the direction of the substrate seals it outwards. 4. Fitting according to any one of claims 1 to 3, characterized in that a foil (10) is inserted between the connector plate (4) and the flange body (7) which extends radially inwardly into the material sealing connection at the through opening and radially outwards the housing (2) into the substrate layer. it stretches. 5. Fitting according to any one of claims 1 to 4, characterized in that the flange body (7) is secured to the connection plate (4) by screwing (8), and by screwing (8) the flange body (7) with adhesive applied between the flange body (7) and the connection plate (4). together with the material, it can be clamped to the connector plate (4) to form a sealed pressed joint. 6. Fitting according to any one of claims 1 to 4, characterized in that the shape of the profile of the miracle-shaped extension (9) is the same as that of the body (5). 7. Fitting according to any one of claims 1 to 3, characterized in that the miracle-shaped extension (9) is formed as an extension forming an integral part of the flange body (7) or which is connected to the flange body (7). 8. An assembly according to any one of claims 1 to 6, characterized in that the miracle-shaped extension (9) can be locked to a shape or material by means of a flow-through coupling assembly. 9. A fixture according to any one of the preceding claims, characterized in that it is placed on a concrete floor or ceiling and / or on a concrete floor or ceiling. 10. A fitting according to any one of claims 1 to 4, characterized in that a mounting plate with at least one bore can be attached to the connection plate (4) in such a way that the fitting integrated in the base layer can be subjected to a pressure test. 11. Fitting according to any one of claims 1 to 4, characterized in that it is used as a closing device for an opening for rainwater drainage and / or ventilation and / or pipe cleaning of drainage systems.