BE1019400A3 - IMPROVED ROOF GEL FOR HEAVEN WATER DISCHARGE AND SUPPRESSED USE IN UV HEAVEN WATER DISCHARGE SYSTEM. - Google Patents

Abstract

Roof gully for rainwater discharge in negative pressure, which gully has at least one gully bottom (2) and an air shut-off valve (3), wherein the gully bottom (2) is provided with an overflow edge (4) which corresponds to the highest sand in the placed condition of the gully bottom ( 2), characterized in that the air shut-off valve (3) has a hat-shaped design and comprises a bottom edge (8) which, in the placed position, is located outside the overflow edge (4) and this bottom edge (8) is located lower than the bottom side of the air shut-off valve (3) ) at the overflow edge (4).

Description

Improved roof chamber for rainwater drainage under reduced pressure and new use in UV rainwater drainage system.

The present invention relates to an improved roof chamber for rainwater drainage under reduced pressure and a new use thereof in a UV rainwater drainage system.

A UV rainwater drainage system or simply UV system is a rainwater drainage system that makes use of special roof gullies, more specifically roof gullies that fill the rainwater drainage system in underpressure.

UV rainwater drainage system are also referred to as underpressure rainwater drainage system or filling system.

In rainwater drainage systems, rainwater is drained to one or more points by providing the roof with a slight sloping at least.

From the drainage points, the rainwater is led through an opening in the roof or in a gutter to a drainage pipe.

With conventional rainwater drainage systems, the rainwater falls as it were through the drain pipe, only under the influence of gravity.

Downstream, the drain pipe is suitably connected to a further drain.

In the case of underpressure rainwater drainage systems, briefly referred to as underpressure systems, the drainage of the rainwater through the drain pipe is additionally energized by the underpressure that arises when the suction of air at the top of the drain pipe is prevented.

Suppression systems are known and usually comprise a drain pipe that leads from a roof or a collection point near the roof to a lower zone.

The higher end of the drain pipe is then connected to a trough-shaped element that is larger in top view than the section of the drain pipe. The higher edge of this trough-shaped element is situated higher than the inlet opening of the discharge pipe.

A cover plate is provided at a distance above the inlet opening of the drain pipe. The cover plate has a larger surface area than the section of the inlet opening, but a smaller surface area than the trough-shaped element.

The peripheral edge of the cover plate is provided on the inside of the upper edge of the trough-shaped element, possibly at a lower level than the upper edge of the trough-shaped element.

The whole of the trough-shaped element, also called the gully bottom, and the cover plate are usually called the gully.

In the event of heavy rainfall, the water arrow in the roof chamber rises above the aforementioned cover plate to prevent air intake at the top of the drain pipe.

Thus an underpressure is created. The pipe fills itself completely with water and is often referred to as a system with filling.

In other words, underpressure systems make use of the difference in height between the roof chamber and the outflow point to create underpressure.

Underpressure systems offer a greatly accelerated drainage of rainwater, not only thanks to better utilization of the drain pipe for the drainage of water with limited presence of air, but also due to the increased flow rate due to the underpressure.

All this makes it possible to use discharge pipes with a considerably smaller section.

As explained, the existing roof vents comprise a trough-shaped element, called the gully bottom, and a cover plate which is commonly referred to as an air valve.

However, when applying a UV rainwater drainage system as emergency drainage, some problems arise.

As an emergency discharge system, usually spouts, traditional aerated discharge systems or UV systems are provided.

The provisions for an emergency drainage system are increased in relation to the primary rainwater drainage system, so that they are only used if the rain intensity exceeds the drainage capacity of the primary system or if the primary system does not function.

Figure 1 schematically shows a known drain funnel or roof gully to clarify what follows.

The elevation OS is chosen in such a way that the emergency overflows are not addressed during normal rainfall and a properly functioning primary rainwater drainage system. A typical upstand height is between 30 mm and 60 mm, for example 50 mm here.

The floating height DH is the height above the roof chamber at which it achieves its design discharge capacity.

The floating height is related to the discharge capacity of the roof gully. The greater the discharge capacity, the higher the floating height becomes.

With conventional UV roof gullies, the floating height is between 30 mm and 55 mm, here for example 30 mm.

These two quantities, the elevation height OS and the floating height DH, determine the design height of the rainwater on the roof of one roof chamber.

For traditional aerated systems and spouts, this is also the height of the waterline above the roof at the location of the facility.

However, this cannot be said for UV systems. The height of the waterline above the roof for the dimensions of 50 mm for the elevation height OS and of 30 mm for the floating height DH given as an example may be higher than the sum thereof, in the example given higher than 80 mm.

A UV system only functions at design capacity when the water has reached the floating height DH in all roof gullies.

If one roof chamber draws in air, the entire system will malfunction.

A higher position of one of the roof gullies may be the result of usual building tolerances, as schematically illustrated in Figure 2.

In addition, the roof load due to the presence of rainwater entails deformations of the roof, as shown in Figure 3.

Such deformations entail the formation of pits and elevations or uproar, which causes the rainwater to rearrange, which changes the roof load. All this ensures that the roof load and the deformations have a dynamic character.

It is known that with typical roof spans of 12 m and 24 m, deformations of for example 15 mm and 30 mm or 1/800 of the span, for example, can result in double maximum height differences of 30 mm and 60 mm.

All this entails that for the elevation height OS and the floating height DH, the uplift due to load and the height difference due to construction tolerance must be added to arrive at the height of the waterline above the roof.

For the given usual dimensions of 50 mm for the upright height OS and 30 mm for the floating height DH, and from 30 mm to 60 mm for the possible maximum height differences, and of a building tolerance of, for example, 10 mm, a height of the water line above a low-lying part of the roof of 120 to 150 mm, which can lead to breakage of the roof construction.

The collapse of roofs due to water load occurs regularly, and the sensitivity of ÜV systems to height tolerances plays an important role in this.

If the waterline is too high locally, adjustments are necessary to lower the waterline.

It is assumed today that this is possible by applying one or more of the measures below.

- The replacement of high-lying larger roof vents with several smaller roof vents. Smaller roof vents have a lower floating height, which means that air is already sucked in with less water on the roof.

- It is also possible to lower the elevation height of the emergency overflow gullies, however, with the disadvantageous consequence that the emergency transfer system will come into operation earlier and will therefore become contaminated more often.

- A third method is to close off the roof vents to prevent air from being sucked in. The missing drainage capacity must be applied to lower parts of the roof.

- The fourth option is to separate a roof section and to install a separate emergency drainage system.

- Finally, low-lying parts of the roof can be filled with insulating material.

The present invention has for its object to offer an alternative and adequate solution to the problem posed.

To this end the invention relates to a roof gully for rainwater discharge under reduced pressure, which roof gully comprises at least one gully bottom and an air valve, the gully bottom being provided with an overflow edge corresponding to the highest situated edge in the placed state of the gully bottom, wherein the gully is characterized by the fact that the air valve is of hat-shaped design, wherein the bottom edge of the air valve when placed is located outside the overflow edge and this bottom edge is situated lower than the bottom side of the air valve at the overflow edge.

According to a special embodiment variant, the lower edge when placed is lower than the overflow edge of the bottom of the chamber.

When used as an emergency discharge, in which such a roof chamber is arranged on an elevation with elevation height OS, the lower edge of the air valve is preferably situated below the elevation height level.

The present invention also relates to a UV rainwater drainage system or simply UV system that uses at least two such roof gullies which are connected downstream to an associated suction line, which suction lines are connected to a common collector line which extends substantially horizontally, and which downstream is continued in a mainly vertically oriented line.

The above UV system preferably relates to an emergency drainage system for which the roof gullies are provided at a curb.

In that case the air valves are preferably provided with such a shape and dimensions that the lower edge of the air valve is preferably situated below the level of the upstand height.

The present invention also relates to the use of such a roof chamber according to the invention in a UV system for emergency discharge, with a view to reduced height sensitivity of the roof chamber.

As a result, the roof can be built with less stringent building tolerances and, in particular, with less strict requirements with regard to the maximum deformation of the roof construction.

A UV system according to the invention functions, in contrast to the known UV systems, even when the water has not reached the floating height DH in one or more of the roof gullies.

Indeed, if the water remains below the floating height DH of, for example, one of the roof gullies, for example because this roof gully is slightly higher due to building tolerances and / or some deformation of the roof by the rainwater load, but the level of the water reaches there above the lower edge of the air trap of the relevant roof gully, this roof gully does not draw in air and the other gullies in the UV system can or can cause underpressure by filling the service pipe.

The underpressure is perpetuated and the underpressure discharge takes place.

The underpressure can be formed if, for example, 30% of the roof gullies cause filling, for example when one of a total of two gullies in a UV system, or one of a total of three, or two of a total of five gullies, overflows or filling.

It is clear that the lower the lower edge reaches below the upstand, the less water is required to effect air sealing, the less sensitive the UV system for emergency discharge becomes to any height differences.

With the insight to better demonstrate the characteristics of the invention, a preferred embodiment of a roof gully for underpressure rainwater drainage according to the invention is described below as an example without any limiting character, with reference to the accompanying drawings, in which:

Figures 1 to 3 relate to the state of the art; figures 4 to 6 are schematic representations of variant embodiments of a roof gully according to the invention; Figure 7 shows a UV system according to the invention.

Figures 4 to 6 schematically show some mounted gullies 1 according to the invention, all arranged here on a curb.

These all comprise a gully bottom 2 and an air valve 3, wherein the gully bottom 2 is provided with an overflow edge 4 which corresponds to the highest situated edge in the placed state of the gully bottom 2, and whose height in the given embodiments coincides with the height of the rebellion.

The overflow edge 4 surrounds the access opening 5 of the gully bottom 2.

The air valve 3 is always characterized by the hat shape.

The hat shape is a direct consequence of, on the one hand, the higher-located central part 6 which extends over the access opening 5 of the bottom of the chamber 2 while retaining an intermediate opening 7 and, on the other hand, the lower-lying lower edge 8 which according to a particular aspect of the invention is situated lower than the overflow edge 4 of the bottom of the chamber 2 is located.

In general terms, the highest part of the lower edge 8 is situated lower than the lower side of the air valve 3 at the location of the overflow edge 4 of the cavity bottom 1, i.e. in line with this overflow edge 4.

As indicated in Figure 5, the lower edge 8 can be provided with laterally projecting portions, which, incidentally, can also be provided with a curved shape.

Figure 7 shows a ÜV system according to the invention, which here uses at least two roof vents 1a and 1b according to the invention as shown in Figure 4.

The UV system shown relates to an emergency drainage system. For this purpose, the roof gullies 1a and 1b are suitably provided on a curb 9a, 9b respectively, both with curb height OS equal to 50 mm.

The floating height DH, ie the height above the roof gully 1 at which it achieves its design discharge capacity, is here for both roof gullies 30 mm, which means that the two gullies should stand in the water for 80 mm in order for the design discharge capacity to be achieved for both gullies. la and lb.

As a result of building tolerance and / or roof deformations as a result of loads, the roof gullies 1 are not at the same height. For example, roof gully 1b is 40 mm higher than roof gully 1a.

This means that if the floating height DH of 80 mm is reached for the highest situated roof chamber 1B, the lower located chamber chamber 1a is already in the water for 120 mm. :

For the sake of clarity, Figure 7 shows no components of the primary drain system.

Downstream, the two roof gullies 1 of the UV emergency discharge system are connected to an associated suction line 10a and 10b, which suction lines 10 are connected to a common collector line 11 which extends substantially horizontally.

Downstream the collector line 11 is continued in a substantially vertically oriented position line 12 which leads to an outflow at ground level.

The operation of the UV system according to the invention as shown in Figure 7 is simple and as follows.

The water level as shown in the dashed line corresponds, for example, to the floating height of the roof chamber la.

Thanks to the hat-shaped design of the air separator 3 of the higher-lying roof chamber 1b, which is designed here such that the lower edge 8 is situated 20 mm lower than the overflow edge 4 on which it is arranged, the suction of air is prevented.

Water does not initially flow over the overflow edge 4 of this roof chamber 1b, but in view of the high influx of rain water into the lower roof chamber 1a, the underpressure discharge is initiated.

Indeed, the lower edge 8 of the air separator 3 is in contact with the water and thus forms a siphon and excludes air suction there.

Once the underpressure discharge has been used, it will be continued until air is sucked in, i.e. until the water level at the location of the higher-lying roof chamber 1b falls below the lower edge 8 of the air separator 3.

As a result of the underpressure in the UV system, water can also be drawn into the drain at the location of the higher-lying roof chamber lb.

If the higher-lying roof chamber 1b were not of the type according to the invention, air would be sucked in until the water level would have risen to the level of the air separator, i.e. to the relevant floating height DH.

A UV system according to the invention functions, in contrast to the known UV systems, also when in one or more of the roof gullies 1 the water has not reached the floating height DH.

Indeed, although the water only stays below the floating height DH of the higher-lying roof chamber 1b, but above the lower edge 8 of the air valve 3 of the relevant roof chamber 1b, this roof chamber does not draw in air and the other roof chamber 1a can UV system for underpressure by filling the line pipe.

The underpressure is perpetuated and the underpressure discharge takes place.

It is clear that the UV system can comprise several roof vents 1.

The underpressure can be formed if, for example, 30% of the roof gullies 1 cause filling, for example when one of a total of two roof gullies in a UV system, or one of a total of three, or two of a total of five roof gullies, overflow or filling.

It is clear that the lower the lower edge 8 extends below the upstand 9, the less water is required to effect the air seal, the less sensitive the ÜV emergency discharge system becomes to any height differences.

As a result, the roof can be built with less stringent building tolerances and, in particular, with less strict requirements with regard to the maximum deformation of the roof construction.

The present invention is by no means limited to the exemplary embodiments described and shown in the figures, but, a roof gully for underpressure rainwater drainage and a UV rainwater drainage system using at least two of such gullies can be designed in many shapes and sizes, without departing from the scope of the invention.

Claims (9)

A roof gully for rainwater discharge under reduced pressure, which roof gully comprises at least one gully bottom (2) and an air valve (3), wherein the gully bottom (2) is provided with an overflow edge (4) corresponding to the highest situated edge in the placed state of the vortex bottom (2), characterized in that the air valve (3) is of hat-shaped design and comprises a bottom edge (8) which, when placed, is outside the overflow edge (4) and this bottom edge (8) is lower than the bottom of the air valve (3) at the location of the overflow edge (4). Roof gully according to claim 1, characterized in that the lower edge (8), when placed, is lower than the overflow edge (4) of the gully bottom (2). Roof gutter according to claim 1 or 2, characterized in that the roof gully (1) is arranged on a curb (9) and that the lower edge (8) of the air valve (3) is situated below the level of the curb (9). UV rainwater drainage system, characterized in that at least for the highest located roof chamber, a roof chamber (1) according to one or more preceding claims is provided. UV rainwater drainage system according to claim 4, characterized in that it is provided with at least two roof gullies (1), and in that all roof gullies (1) are designed in the relevant UV rainwater drainage system according to claim 1, 2 or 3. UV rainwater drainage system according to claim 4 or 5, characterized in that the gullies (1) are connected downstream to an associated suction line (10), which suction lines (10) are connected to a common collector line (11) which extends substantially horizontally, and which is continued downstream in a substantially vertically oriented line (12). Use of a UV rainwater drainage system according to claim 4, 5 or 6, characterized in that it is used for the purpose of lowering the maximum roof load as a result of rainwater, in particular by at least at the highest located roof chamber (1), and optionally also with the other roof vents (1) of the relevant UV rainwater drainage system, to ensure that the air supply is already prevented when the water reaches the height of the lower edge (8) of the one or more air valves (3). 8. Use of. a UV rainwater drainage system according to claim 4, 5 or 6, characterized in that it is used with a view to obtaining less stringent building tolerances for the roof construction. Use of a UV rainwater drainage system according to claim 4, 5 or 6, characterized in that it is used with a view to obtaining less stringent requirements with regard to the maximum deformation of the roof construction.