EP0386696A1 - Heavy duty floor gully - Google Patents

Abstract

In a heavy duty floor gulley (1) comprising an underlying gulley container (2) made of plastic as the first assembly, an intermediate piece (8) inserted into the gulley container as the second assembly, said intermediate piece being integrated into a barrier layer (A) in the sealing plane by a flange construction (12), an attached shaft (16) which is inserted into the intermediate piece from above, and a third assembly comprising an outer attached frame (24) and inner inlet grate (23) at the inlet to the attached shaft, at least one assembly is made from metallic material (cast iron or high-grade steel) for the purpose of adaptation of the floor gulley to high traffic loads, to regulations regarding sealing and to the corrosion to be expected, while keeping installation of the second and third assembly B2, B3 as simple as possible, and if both assemblies B2, B3 are composed of metallic material, the metallic material of these two assemblies B2, B3 is different. <IMAGE>

Description

The invention relates to a heavy-duty floor drain according to the preamble of claim 1.

In the case of floor drains which are highly stressed by traffic loads, it is known to produce all assemblies from cast iron. Apart from the complex and cost-intensive manufacturing effort, the installation is made difficult by the high weight of the individual assemblies and, above all, the effort for the bottom drainage container made of cast iron is unacceptably high, because it has purely water-bearing tasks and, in the case of a cast iron version, for automatic sinking and Tends to grow.

Furthermore, such heavy-duty floor drains are known, which as a whole are made of plastic in all assemblies. Although the weight ratios are more favorable here, the material costs for a corresponding plastic are very high. The drain tank no longer shows the tendency to sink automatically or to grow quickly. However, due to the high loads to be absorbed in the inlet area, a great deal of design and material-specific effort is required. In practice, another problem is the proper incorporation of the intermediate piece into the sealing plane, because, for example, the flange plane of the intermediate piece does not remain dimensionally stable when the fastening elements are tightened, so that the sealing area is damaged. The regulations to be observed here according to DIN 18195 part 5 and part 9 for building waterproofing can only be created with difficulty with floor drains of this type consisting entirely of plastic assemblies.

Finally, to design such heavy-duty floor drains as welded stainless steel constructions in order to meet the requirements with regard to resilience, corrosion resistance, simple installation and tightness in the sealing level is not justifiable in practice because of the high costs.

The invention has for its object to provide a heavy duty floor drain of the type mentioned, which is adapted in its concept to the different requirements in a universal manner and ko manufactured inexpensively, easily installed and can be incorporated into the sealing level in accordance with the applicable regulations, whereby it must be able to withstand the traffic loads even at high load levels.

The object is achieved according to the invention with the features specified in the characterizing part of patent claim 1.

With this modular mixing concept, the floor drain is ideally adapted to the various requirements. The plastic drainage container is inexpensive to manufacture and can easily fulfill its water management task over a long period of time. Because of its light weight, it does not tend to sink automatically in the ground. There is no risk of early growth. The plastic top shaft, which essentially only has to provide a position-securing and water-carrying function as well as the function of height compensation, can play out the advantages of the light and inexpensive plastic construction. Above all, the respective connection of metal with plastic is protected against rattling. On the other hand, the third assembly, when constructed from a metal material, has the advantage that the traffic loads can be absorbed without being passed on to the lower assemblies. If, on the other hand, the second assembly is made of metal material, the applicable regulations regarding the sealing in the sealing level can be fulfilled without any problems, because the metal is not deformed when the fastening screws are tightened. If the two assemblies, ie the second and the third assembly are made of metal material, then the metal material of the third assembly is selected with regard to the heavy traffic loads with cast iron, while the metal material for the second assembly is selected with regard to a perfect seal and easy connection on the sealing level is selected in stainless steel. Since the weight of the components and thus of the entire floor drain can be kept very low by using plastic components dominating the vertical extent in the floor drain, the floor drain can be easily inserted into the floor. The tendency to sit under its own weight or when shaken is hardly noticeable. The traffic loads are essentially only absorbed by the third module without reaching the other modules. Should If the floor level of the third module is set, the third module can also sink downwards because the possibility of adjustment between the other modules or components is ensured in a simple manner. The main advantage of this special floor drain is the three-way selection of materials for the assemblies. The upper assembly made of cast iron is preferred because it has to absorb the pressure load from the loads moving above it. Very high point loads can be absorbed here. The middle assembly has mating fits and cantilever flanges, which are most advantageously made of stainless steel. In the lower assembly there are narrow openings and the part is in the concrete or in the solid floor, so it is important that no oxidation occurs and the passages do not grow, which is ultimately achieved by the plastic and its smooth surface.

If the requirements with regard to the tightness in the sealing plane can be fulfilled in another way, the embodiment of claim 2 is expedient. Using the third cast iron assembly is particularly suitable where heavy traffic occurs. These floor drains are used in public roads, where all traffic and also exceptionally heavy vehicles with narrow wheels roll away, i.e. the specific load pressure is particularly high. In addition, the cast iron offers the least signs of wear with regard to pressure load.

Furthermore, the embodiment according to claim 3 is expedient. The top shaft inlet, which is inserted between the top frame made of cast iron and the inlet grate made of the same material, can indeed consist of cast iron, for reasons of weight, plastic would also be possible here, because only the suspended one Flange is only subjected to pressure, otherwise the part does not have to withstand any stress. The plastic flange can withstand the pressure load because it is clamped over a wide area and no specific point load can arise. The inventive idea would be, however, to preferably design the third assembly from cast iron because of the pressures to be absorbed.

The embodiment according to claim 4 has proven particularly advantageous shows, because the use of stainless steel does not deform the sealing surface for the film when tightening the fastening screws and thus the desired tightness is reliably fulfilled, rust problems and thus premature rusting do not occur and finally the part retains a low weight and can be conveniently placed in lower the floor and do not unnecessarily push the entire floor drain down.

In this context, the embodiment according to claim 5 is particularly advantageous because the one-piece fixed-flange construction can be created with the stainless steel metal material in a particularly tight and load-bearing manner and permanently. The fastening screws are welded onto the flange and when the fastening nuts are tightened, the flange does not deform, but maintains its flat surface for the clamped sealing film.

It has proven to be particularly advantageous to design the intermediate piece according to claim 6. Since the intermediate piece gets its shape essentially in the deep-drawing process, the flange attached to the upper edge can be shaped out in the same drawing process, so that no additional work processes and costs arise.

As an alternative, the embodiment according to claim 7 is also very advantageous, especially if you want a wider flange. The stainless steel material can be welded cheaply and also offers tight seams, so that the desired approaches such as flanges, noses, etc. can be provided easily and inexpensively for the particular material used without great costs.

Another advantageous measure is set out in claim 8. This results in a very resilient support of the intake grate, the forces from the traffic load being effectively transmitted to the support leg of the top frame without destroying the plastic of the top shaft rebate.

In the embodiment according to claim 9, hanging and removing a catch bucket is particularly easy. It is possible with cast iron as well as with plastic, the protruding retaining collar molded on to manufacture the piece.

The embodiment according to claim 10 is also important because the stacking frame has a very high structural strength with the lowest possible weight. The support ribs also improve the fit of the top frame in the floor.

An exemplary embodiment of the subject matter of the invention is explained using a schematic longitudinal section.

A heavy duty floor drain 1, i.e. A floor drain that is exposed to traffic loads includes from three assemblies B₁, B₂, B₃. In the assembly B₁ is a drain container 2, e.g. made of PVC, used in the ground, which in the area of its bottom 3 has either a vertical drain pipe 4 or a bend-like drain pipe 5 for the respective connection to the further sewer system K. An insert 6 is inserted into the drain container 2 in front of the drain connector 4 or 5. The insert 6 can either - as indicated - be an odor trap. However, a lifting pump, a backflow stop or the like is also conceivable. The drain container 2 has a plug-in flange 7 at the top, possibly with a sealing insert 13.

The second assembly B₂ is an intermediate piece 8, which consists of stainless steel in the present embodiment. The intermediate piece 8 has a lower shaft section 9 which is inserted into the drain container 2 and to which an intermediate part 10 which widens upwards joins a part 11 which extends approximately upwards with the outer dimension of the drain container 2. On the part 11, an outwardly projecting flange 12 is formed and welded, for example, which carries an annular loose flange 14 for receiving and fixing a sealing layer A, for example a barrier film S, which is fixed by means of distributed and fixed clamping screws 15 and the sealing layer A between them and holds the flange 12 sealingly. The intermediate piece 8 in the second assembly B₂ allows for height compensation by being slidably inserted into the drain container 2 and held in position by the seal 13 in the plug-in flange 7 by friction. The insertion dimension depends on the distance between the further sewage system and the ground level N used by traffic.

In the intermediate piece 8, an attachment shaft 16 is inserted from above, which is made of plastic, e.g. PVC, is made and has a lower tip end. Seals, not shown, can be provided between the part 11 and the attachment shaft 16. The wall of the attachment shaft 16 is designated 17 and contains predetermined breaking points or markings, not shown, at which the attachment shaft 16 is cut to the length required in each case. A further height compensation is possible with the attachment shaft 16, by firstly cutting it to length or secondly by pushing it less or farther into the intermediate piece 8. At the upper end of the top shaft 16, an inlet 18 is formed, through which the waste water reaches the drain tank 2. The inlet 18 is designed as a circumferential fold 19 with a transverse support web 20. In the fold 19 an existing cast-iron grate 23 is used, which is supported with its edge 30 on the support web 20. The inlet grate 23 is part of the third assembly B₃. The third assembly B₃ also contains an outer frame 24 made of cast iron, which has an approximately Z-shaped cross section with an upper, horizontal flange 25, an inner vertical flange 26 and a support leg 27 which engages under the support web 20. A narrow edge 28 extends downward from the horizontal flange 25. On the outside, support ribs 29 are integrally formed on the attachment frame 24 and extend under the support leg 27 on the underside. The cast iron top frame 24 is inserted together with the inlet 18 of the top shaft 16 and the inlet grate 23 approximately flush with the floor level N. The support frame 24 is supported from below, in turn holds the support web 20 of the support frame 16 with the support leg 27 and, via this, the inlet grate 23.

The inlet grate 23 is provided with water inlet openings 31 and integrated support ribs 32.

In the top shaft 16, a holding collar 21 is integrally formed on the inside below the fold 19, into which a conventional collecting bucket 22 or another insert part is removably secured in position.

Should the ground level settle under the traffic load or for other reasons, then the top frame 24 and thus the top shaft 16 follow the lowering movement, so that no components projecting above the ground level remain. Should the ground level rise for any reason, then the top shaft 16 is pulled further out of the intermediate piece 8. The traffic loads are absorbed by the cast iron top frame 24 and distributed into the ground. The other components of the floor drain 1 are kept free from these loads.

The fixed flange 12 is welded from the outset to the intermediate piece 8 made of stainless steel or integrally formed during the drawing process. The steel with its smooth surface and resistant meter strength keeps its plane level when tightening the clamping screws 15, so that the barrier film S is fixed completely flat sealed.

The cross section of the floor drain can be of any shape, i.e. have a round, oval or angular shape. Furthermore, it is conceivable to lead the drain out of the drain container 2 laterally if there is little height between the sewer system K and the floor level N.

Claims (10)

1. Heavy-duty floor drain (1), with an underlying drainage tank (2) connected to the further sewer system (K) made of plastic as the first assembly (B₁), with an intermediate piece (8) inserted into the drainage tank (2) at the top as the second assembly (B₂), which is incorporated in the sealing plane by a flange construction in a barrier layer, with a top shaft (16) inserted into the intermediate piece (8) from above, and with an upper, third assembly (B₃) from an outer top frame (24) and inner inlet grate (23) at the inlet of the attachment shaft (16), characterized in that at least one assembly (B₂ or B₃) consists of metal material from the second and third assemblies (B₂, B₃), and that in both assemblies consisting of metal material ( B₂, B₃) each consists of different metal materials. 2. Floor drain according to claim 1, characterized in that the third assembly (B₃) consists of cast iron. 3. Floor drain according to claims 1 or 2, characterized in that the Cast iron top frame (24) comprises the top shaft inlet (18) from the outside, while the cast iron inlet grate (23) is supported in the inlet (18). 4. Floor drain according to claim 1, characterized in that the second assembly (B₂) consists of stainless steel. 5. Floor drain according to claims 1 and 4, characterized in that the intermediate piece made of stainless steel (8) has on the edge a mounting flange (12) equipped with fastening elements (15) for receiving a barrier layer (S). 6. Floor drain according to claim 5, characterized in that when deep-drawing the intermediate piece (8) the fixed flange (12) is integrally formed on the upper edge. 7. Floor drain according to claim 5, characterized in that the fixed flange (12) is welded to the intermediate piece (8). 8. Floor drain according to claims 1 to 3, characterized in that the top shaft inlet (18) has a circumferential fold (19) with a support web (20) for the cast iron inlet grate (23) on a support leg (27 ) of the Z-shaped cross section of the cast iron top frame (24) is supported. 9. Floor drain according to claim 8, characterized in that in the top shaft inlet (18) below the fold (19) an inwardly directed retaining collar (21) for a refuse-collecting bin (22) is formed. 10. Floor drain according to claims 1 to 3, characterized in that the cast iron top frame (24) on the outside has a circumferential, depending edge (28), and that in the circumferential direction around the top frame (24) distributed, outer and from the edge (28 ) until support ribs (29) engaging under the support leg (27) are formed.

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