NL8402068A - CONSTRUCTION EQUIPPED WITH A PREFABRICATED INPUT. - Google Patents

Abstract

The internal prefab service and supply shaft is connected gas- and water tightly to a transverse feed duct for service conduits. The duct is also gas-and water-proof. The duct and shaft are pref. prefab in one piece. The duct may be extended, using e.g. gas-and water-proof flanges. The duct end outside the building has a gas-and water-proof closure, with similar passages for the service conduits. The top of the service shaft has a similar closure, with a meter above it from which cables may extend to the consumer appliances.

Description

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Paul Joseph Marie Antonius Leinarts Sittard 5 Building with a prefabricated input pit.

The invention relates to a building provided with a prefabricated input well for utilities located within the building. The invention also relates to a prefabricated input well for such a structure and to a prefabricated meter box for use in such a structure.

When constructing buildings, whether for homes or for businesses, it is almost always necessary to provide certain so-called utilities therein. These utilities are of the most diverse nature. They include gas, water, electricity, sewage and in some cases central antenna systems, district heating and so on. The builder of the structures, for example a contractor, is responsible for the entire indoor construction of the installations that are necessary for the utilities. The utility lines, however, come from outside the building and the connection of the utilities located outside the building to the indoor installation is the responsibility of bodies other than the builder or contractor. Placing the necessary meters, for example for gas, electricity and water, is also carried out by a body other than the builder, for example the contractor.

30 Also, in most cases the authorities that provide the connections for the utilities and the authorities that install the meter are not the same. Because of all these different bodies, with their own responsibility, very good coordination between the bodies is necessary to build quickly, economically and safely. Practice has shown that this agreement can only be met very sporadically. After all, the different 3402068 -2-r agencies have their own timetables that often do not fit the schedule in which the builder or contractor does. construction has finished so far that the connections and the placement of the meters could be carried out.

5 Another problem with the construction of a building and the connection to the utilities arises because the government, usually through the authorities that connect the utilities, place the meters, issue regulations and set requirements for the construction 10 to be carried out by the builder. or contractor. For example, stringent requirements are imposed on the placement and course of pipes for gas, water and electricity. Particular attention is paid to safety. The institute that places the meters has also given regulations regarding the place where the meters must be installed, but especially also about the distances between the ends of the connections for the indoor pipes, that is, the pipes that belong to the house installation and the connections to which the 20 pipes of the utilities that are going to be connected outdoors. This is because certain types of meters are assumed to fit between the ends of the pipes in the building. The builder or contractor 25 is responsible for these distances.

Because of all the different bodies involved in the final realization of the complete, connected structure, it is often difficult to determine afterwards, in the event of deficiencies found, who must take on additional costs for remedying the defects. This is all the more urgent because when making the connections between the installations already present in the building, which are the responsibility of the builder or the contractor, respectively, and the supply lines of the utilities must increasingly be carried out by unskilled workers. The consequence of all these factors is 8402058 m- -3- which often requires improvisation, which obviously suffers from the safety and speed of connecting the structure to the utilities. This is especially true for safety. Even if the builder or contractor originally complied with all the relevant regulations, it may be necessary to improvise when making the connections, for example by bending pipes and using extra fittings, that safety is compromised.

10 As a result, the aforementioned controversy regarding responsibility may arise later. Obviously, this also causes delays in completing and delivering the structure.

In most buildings, the external pipelines for utilities, which must be understood to include both pipes and cables, are led to a so-called input well. In this input well the connections are made with the pipes that go to the meters and with the rest of the pipes for the installation.

Such import wells are usually located under the floor of the construction work and are located in the so-called crawl spaces under this “floor. A large part of the indoor pipes is transported via this crawl space to the various places in the construction work. these crawl spaces are subject to very strict regulations regarding safety and watertightness.

The input wells have traditionally been bricked, but in recent times input wells have also become known which are prefabricated and, for example, manufactured from poured concrete or plastic. In some of these input wells, holes have already been made in the side walls during manufacture for the passage of utility lines. No special measures have been taken with regard to the gas and watertightness of these penetrations.

The object of the invention is the 8402068 -4- listed above.

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avoid as far as possible disadvantages of the construction methods and connection work followed so far and also obtain other advantages.

A structure according to the invention is provided with a prefabricated input well for utilities located within the structure and is characterized in that the input well is gas and watertight and is connected to a transverse, gas and watertight tube protruding outside the facade for the pipes of the utilities, which 10 tube connects gas and watertight to the input well.

The safety regulations can easily be met by using a gas and watertight input well and the connecting gas and watertight tube that leads to the outside of the building. Since the tube ends outside the building, the authorities that provide the connections no longer need to enter the building. This avoids the above-mentioned battle questions regarding the person responsible for any defects after construction. This is particularly true when, according to a preferred embodiment of the present invention, the outer end of the sleeve is provided with a gas and watertight seal for the utility lines. Such a gas- and watertight seal can for instance be obtained in that permanent penetrations secured in the seal outside the facade are arranged in the seal outside the facade.

The input well will generally still be open at the top during installation. This open top can be closed by a gas-tight lid. Then the entire space inside the input well and the tube is gas and watertight. Of course, the pipes that go from the input well to the installations in the structure must also be made gas and watertight.

35 In general, the tube will have to protrude at least 50 cm 8402068 3r -¾ -5- from the facade to facilitate the connection of the utility lines. According to a special embodiment of the present invention, if the input well is located at a relatively small distance from the facade on the inside of the building, use can be made of an input well with a tube co-manufactured during the pre-manufacture. Input well and tube then form a whole. If the distance from the input well to outside the facade is greater and if this is necessary in connection with the construction of the structure, use can be made of tubular extensions; these can then be connected gas-tight and watertight to a co-prefabricated tubular part of the input well, for instance by means of flanges.

If desired, partitions can be arranged in the tubular part, whereby the space in the tube is divided into sections, each section serving as a kind of utility pipe.

If desired, and possibly prescribed, use can be made of more than a tube which connects on the one hand to the input well and on the other hand extends outside the facade. The cross section of the tubes can be round, square or otherwise shaped. Concrete, sheet metal or plastic can be used as material for the tubes.

Since the input well and the tube connected thereto are prefabricated and are placed by the builder or contractor at a specific place in the building, use can advantageously be made of a prefabricated meter box which is placed on top of the input well. The pipes of the utilities can then, for example, be guided through a gas- and watertight cover on the input well to the meter box, in such places that the meters are subsequently placed in the meter box. Because of the construction according to the invention it is easy to ensure that the passage of the pipes from the input well to the 8402058

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-6- meter box are in the right place, that is to say in such a place that the distances between the ends of these ducts and the ends of the indoor pipes are the required usually prescribed size for the placement of the meters.

The indoor pipes can go from the meter cupboard back to the input well and go there through one or more extra tubes, which are also gas and watertight, to the various places of the consumption points.

When using the invention, it is clear from the above that it can be ensured that the entire system of the utilities from the point outside the facade to the consumption points is gas and watertight. The crawl space is optimally secured in this way.

The invention will now be elucidated on the basis of a drawing in which: figure 1 shows a longitudinal section through a part of a building with an input well and a meter cupboard and figure 2 shows a cross section along line 20 A-A of figure 1.

In Figure 1, 1 denotes a facade with an above-ground part 2 and an underground part 3. 4 denotes an input pit which has a tubular connecting part 5 that runs through the facade and ends at 6. The utility lines for gas 7, for water 8, for electricity 9 as well as a ground line 10 and possibly other lines, not shown, for example for a central antenna system, run through this tubular part 5. In the drawn embodiment, a sewage connection 11 and a connection for district heating 12 also run through the tube. The tube 5 is here prefabricated with the input well 4 and forms a whole therewith. At the top, the input well 4 is sealed by a gas-tight and watertight cover 13. The pipes 7, 8, 9 and 10 and possibly other pipes and cables to the meter box also pass through this cover, in a gas- and water-tight manner. • Jp · ^ 14 located above the input well. The meter box can be made of fireproof material if this is prescribed. In the meter cupboard are the connections for the gas meter, the electricity meter and the 5 water meter and possibly for other meters. The input connection for the gas meter is marked with 15, for the water meter with 16 and for the electricity meter with 17. The output for the gas pipe is indicated with 18 and the output for the water pipe with 19. Between 15 and 18, the gas meter is and the water meter between connections 16 and 19. The distances between these connections 15-18 and 16-19 respectively meet the regulations of the utility companies. The electricity meter connection 17 is located in a location which may also be specified by the utility company. As can be seen from the drawing, the indoor pipes of gas and water go to the consumption points, back to the input well 4. They leave this well by an extra tube which carries the reference figure 20. 21 denotes an inspection cover arranged in the wall of the input well 4. A venting channel is indicated by 21.

In the input well 4, the connections can be made between the parts of the pipes coming out of the meter box and the parts of the pipes in the tube 5. However, it is not necessary to make these connections if the pipes and cables are directly connected to the meter box extends to the tube 5.

Figure 2 shows a cross-section along the line A-A of figure 1. The reference numerals 7, 8, 9, 30 and 10 correspond to the reference numerals of Figure 1. 23 indicates the inner pipe for the gas supply and 24 indicates the inner pipe for the water. An input line for telephone facilities is shown at 25 and an input line for a central antenna system at 26.

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Claims (9)

1. Structure provided with a prefabricated input well for utilities located within the structure, characterized in that the input well is connected to a transverse, gas- and watertight tube protruding outside the facade for the pipes of the utilities, which tube connects to the input well gas and watertight. 2. Structure according to claim 1, characterized in that the sleeve is formed by a part directly co-prefabricated with the inlet pit and one or more tubular extensions which are connected to it in a gas- and watertight manner, for instance by means of flanges. 3. Structure according to claim 1 or 2, characterized in that the pipes of the utilities located inside the tube at the end of the tube lying outside the facade are gas-tight and watertight. Structure according to claim 3, characterized in that the outer end of the sleeve 20 is provided with a gas- and watertight closure with permanent penetrations secured in the closure, gas- and watertight, to which the pipes lying outside the construction work of the utilities can be connected. Structure according to claim 4, characterized in that the closure consists of a detachable, gas- and watertight lid connecting to the tube. 6. Structure according to claim 1, 2, 3, 4 or 5, characterized in that the input well at the top side 30 is provided with a gas- and watertight closure in which penetrations for the pipes from the utilities to one located above the input well. meter box are present. 7. Structure according to claim 6, characterized in that the input well is provided with at least one additional gas- and watertight tubular 8402068 «4 * -9- part projecting transversely outside the well for accommodating indoor pipes extending from the meter cupboard to the consumption points. Prefabricated input well for use in a building structure according to claim 1, 2, 3, 4, 5, 6 or 7. Prefabricated meter box for use in a building structure according to claim 8, characterized in that the distance between the ends of the utility pipes entering the meter box and the ends of the corresponding indoor pipes to the consumption points is equal to the legally prescribed distance. Eindhoven, June 19, 1984 8402068