SE529951C2 - Interface portion for a siphonic system - Google Patents

Description

l5 20 25 30 529 951 2 However, the experience of priming is mixed. Some systems may exhibit fast priming while others appear to exhibit slower priming. For example, some roof outlets / end pipe systems may have significantly slower priming than others. Thus, in the case of slow priming, the priming of the entire pipe system will be delayed and the unfortunate result is unintended water storage on the roof. Large amounts of water stored on the roof of a building can, in the worst case, destroy the roof with serious consequences for property and potentially human life.

OBJECTS OF THE INVENTION AND ITS MOST IMPORTANT PROPERTIES It is an object of the present invention to propose a solution to or reduction of the problems of the prior art. A main purpose is thus to solve the problem of reliably and faster achieving priming of a siphon system.

In accordance with the invention, this is achieved by an interface portion having the features of claim 1.

The invention stems from the realization that transitions in a siphon system, such as a vertical pipe network of different diameters or vertical pipe networks with constrictions, can act as traps for a gas, such as air. The entrapment of gas prevents the siphon effect and prolongs the process of filling the system with liquid (priming).

The invention provides an interface portion having an inner cross-sectional area that increases continuously from the inlet end to the outlet end for a length of the interface portion that is at least 0.3 times the inner diameter of the outlet end. Through this continuous increase over the specified length, gas is effectively prevented from being trapped downstream of the upstream portion. Thus, according to the invention, the interface portion contributes to a faster priming of the siphon system.

Advantageously, a transition between the inlet end and the upstream portion is substantially in the form of a curve with a radius of at least 0.15 times the inner diameter of the outlet end. In this way, the liquid passing through the transition can be made to more effectively follow, at least in part, the interface portion.

For a transition between the outlet end and the downstream portion, a similar transition as above is also advantageous and has similar advantages.

The remaining dependent claims describe further advantageous embodiments of the invention.

U.S. Pat. No. 5,522,197 discloses a choke for a roof outlet in a siphonic drainage system, said system comprising multiple roof outlets connected to the same pipe system. It solves the problem of providing separate roof outlet branches with correct flow resistances. The device consists of a deformable, annular element which is arranged in an outlet passage and which can be deformed to varying degrees, in order to restrict the passage to a corresponding degree. In one embodiment of the choke, a portion of the choke may inadvertently resemble the interface portion of the present invention to the extent that it has a portion with an inner cross-sectional area that increases continuously. However, the length of the portion of the choke exhibiting this increase is too short to achieve the priming effect of the interface portion of the present application and the transition radii are non-existent. Furthermore, U.S. Patent 5,522,197 addresses only the problem of flow resistors and does not discuss in any way, implicitly or explicitly, the present problem of priming a siphon system and there are no references to this problem or to the solution in accordance with the present invention at all.

Brief Description of the Drawings Embodiments exemplifying the invention will now be described with reference to the accompanying drawings, in which: Fig. 1 schematically shows background art to the invention; priming behavior, Fig. 3 shows an abrupt interface portion with constriction of a coupling member for a siphonic drainage system according to prior art, Fig. 4 shows an interface portion of the invention in relation to a roof outlet, Fig. 5 shows an enlargement of the interface portion in Fig. 4 Fig. 6 shows another embodiment of the interface portion according to the invention in relation to a roof outlet, Figs. 7a and 7b show an enlargement of the interface portion in Fig. 6 in two different views, Fig. 8 shows another embodiment of the interface portion according to the invention in relation to a roof outlet, Fig. 9 shows the interface portion according to the invention inr Fig. 10 shows the interface portion according to the invention housed in a roof outlet in a siphonal drainage system, and Fig. 11 shows the interface portion according to the invention housed in a pipe to a siphon system. Detailed Description of Illustrative Embodiments First, the insight of the invention regarding the problem of priming a siphonic system will be described. Fig. 2 shows a reason for the problem of slow priming in some siphon systems. The figure shows as an example of a siphon system a siphon drainage system 6. The system 6 includes a roof outlet 4, which has an outlet pipe 13, and an end pipe 23 with a larger diameter than the outlet pipe 13. In case of rain, rainwater 14 collects in the outlet bowl of the roof outlet 4. 15. The water flows down through the outlet pipe 13 and into the end pipe 23. Since the end pipe 23 in this case has a larger diameter than the outlet pipe 13 and the coupling means connecting them shows an abrupt change in diameter, the water forms a jet 16 which has a smaller diameter than the end tube 23. This causes air 17 to be trapped inside the end tube 23. Due to this air, the system will not operate siphonically. Instead, the system works entirely through gravity and therefore has a significantly lower water transport capacity. In order for the siphon effect to begin, the end pipe 23 (with gravity) must be filled with water up to the outlet pipe 13 and all air must be evacuated. This filling will be slow and sometimes does not happen at all, even after a long time.

The same problem can also occur in a special case of a siphon drainage system. This is the case with a coupling member 18 with a constriction. Such a displacement coupling member 18 according to the prior art is shown in Fig. 3. Its function is to connect an end pipe 23 directly to an outlet bottom 9 of the drainage system, without any outlet pipe in between.

The constriction 19 is in this case necessary to adapt the opening 7 in the outlet bowl 15 to the air baffle 20. If the opening 7 becomes too large in relation to the size of the air baffle 20 above, the function of the baffle 20 may only allow 10 30 529 951 water entering the drainage system, to deteriorate. This is because air can be constantly drawn into the pipe system next to the air baffle 20, and full flow will never be achieved at tolerable water depths on the roof. For example, end pipes 23 in Figs. 6 and 8, if connected directly to the outlet bowl 15 or the base plate, would possibly create this situation. The constriction 19 in Fig. 3 addresses this, but unfortunately, due to the abrupt transition from a small cross-sectional area to a large cross-sectional area, the problem described in the previous paragraph may occur.

To summarize, abrupt transitions in pipeline diameters in siphon systems can cause problems with priming.

Furthermore, in designs of siphonic roof drainage, there is often a need for end pipes with larger inner diameters than the outlet pipes of roof outlets.

To arrange any incompatibilities for different parts of a siphon system, a new design of a transition interface portion 1 is proposed. To exemplify such an interface portion 1, a siphon drainage system 6 is shown in Fig. 4. This siphon drainage system includes a roof outlet 4. , which has an outlet pipe 13. The outlet pipe 13 is connected to a coupling member 5, which in turn is connected to an end pipe 23. The direction of the flowing water is downwards in the figure; from the roof outlet 4 through the outlet pipe 13, then through the coupling member 5 and into the end pipe 23. The inventive interface portion 1 is in this figure, by way of example, housed in the coupling member 5. For definition, the siphon system is said to have an upstream portion 2 and a downstream portion 3. In the example, the upstream portion 2 corresponds to the outlet pipe 13 and the downstream portion 3 corresponds to the lower part of the coupling member 5. The interface portion 1 extends between an inlet end 10 and an outlet end 11. The inlet end 10 shall be in communication with the outlet portion 2. the end ll shall be in communication with the downstream portion 3.

Furthermore, the interface portion 1 is arranged to bring, in use, the upstream portion 2 into liquid communication with the downstream portion 3. The inner cross-sectional area of the interface portion 1 increases continuously from the inlet end 10 to the outlet end 11 for a length L of the interface portion 1 which is at least 0. times the inner diameter D of the outlet end 11 (see Fig. 5).

Through this continuous increase, the interface portion counteracts an accumulation of a gas downstream of the upstream portion 2, i.e. in the interface portion 1 and downstream of the interface portion 1. This is because the water, instead of forming a jet as in Fig. 2, at least partially follows the walls of the interface portion 1. When doing so, the water may form a kind of lid which traps the air in the interface portion 1 and / or the downstream portion 3 and pushes the air out of the system 6, thus facilitating priming of the system 6.

Thus, the idea of the interface party is to replace abrupt transition parties in siphon systems. In this way, the interface portion enables at least a portion of the liquid in the siphon system to follow the wall of the interface portion. Examples of such abrupt portions that can be replaced by the interface portion are a change from a small diameter tube to a large diameter or a constriction in a tube, as exemplified above. A transition from the interface portion 1 to the upstream portion 2 and / or the downstream portion 3 of the siphonic system should preferably be smooth and may advantageously be substantially in the form of a curve with a radius R of at least 0.15 times the inner diameter D of the outlet end 11, see for example Fig. 5. 15 15 20 25 30 529 951 It will be appreciated that the interface portion may be provided in several ways. For example, it can be provided as an integral part of a building block of a siphon system, as an integral part of a roof outlet, a pipe or a coupling member. In Fig. 10, the interface portion 1 is provided as an integral part of a roof outlet 4. Examples of coupling means are given in Figs. An example of such a sleeve insert 24, inserted into a tube, is shown in Fig. 9. An example of an interface portion 1 integrated with a tube is given in Fig. 11.

When the interface portion is provided as an integral part of a building block by a siphon system, either end of that building block may be provided, if necessary, with optional connectors for connecting the building block, including the interface portion, to other building blocks in the siphon system. Such couplings include threads 25, flanges 8 and other conventional coupling means. Examples of threads 25 and flanges 8 can be found, for example, in Figures 5 and 6. Coupling by welding would of course also be possible.

In the particular case of a siphon system which is a siphon drainage system, the upstream portion of the siphon drainage system to which the inlet end of the interface portion is to be connected may be part of a roof outlet, such as an outlet pipe 13 or an outlet bottom 9. A such a part can be studied in, for example, Figs. 4 and 6. For an outlet bottom, it is possible to adapt the inlet end either to be connected to the outside or the inside of the outlet bottom. Such outlet bottoms 9 and inlet ends 10 are shown in Figs. 6 and 8. Figs. 7a and 7b are enlarged views in different views of Fig. 6. The outlet end 11 is similarly arranged to be connected to a downhole 529. 951 stream portion 3 which is part of an end pipe of a siphon drainage system.

Referring to Fig. 5, the length L of the interface portion 1, as mentioned, should be at least 0.3 times the inner diameter D of the outlet end 11 in order for a favorable priming effect to begin to occur. An increase of said length L from between 0.3 to 0.5 times said inner diameter D gives an increased priming effect.

Sometimes an even stronger priming effect can be observed if the length L of the interface portion 1 is at least 0.5 times the inner diameter D of the outlet end ll.

The material in the building block that includes the interface sections is selected to match the material of other building blocks to which the building block of the interface section is to be connected. For example, welding or solvent welding of plastic materials, mechanical couplings, or welding of steel and other metals can be used to make a connection.

The wall of the interface portion 1 can be designed to be more or less smooth, the main requirement being that the water must be led to at least partially follow the same.

It should be noted that it is not necessary for the cross-sections of the pipe network in the siphon system to be circular.

Other cross-sections such as square, rectangular or elliptical are also applicable. Although the interface portion according to the invention is particularly useful in pipe systems for siphonic roof drainage, it can of course also be used in any siphonic pipe system where transitions between different diameters must be provided.

Claims (17)

10 15 20 25 30 529 951 ll Patent claim Interface portion (1), for a siphon system (6), which siphon system (6) has an upstream portion (2) and a downstream portion (3), the interface portion (1) having an inlet end (10), to be connected to the upstream portion (6). 2), an outlet end (11), to be connected to the downstream portion (3), wherein the interface portion (1) is arranged to bring into use, the upstream portion (2) in fluid communication with the downstream portion (3), characterized by that the inner cross-sectional area of the interface portion (1) increases continuously from the inlet end (10) to the outlet end (11) for a length (L) of the interface portion (1) which is at least 0.3 times the inner diameter (D) of the outlet end (11); , so that the interface portion counteracts an accumulation of a gas downstream of the upstream portion (2), to facilitate priming of the system. Interface portion (1) according to claim 1, characterized in that a transition between the inlet end (10) and the upstream portion (2) is substantially in the form of a curve with a radius of at least 0.15 times the inner diameter of the outlet end (11). Interface portion (1) according to claim 1 or 2, characterized in that a transition between the outlet end (11) and the downstream portion (3) is substantially in the form of a curve with a radius of at least 0.15 times the inner diameter of the outlet end (11). ). Interface portion (1) according to one of Claims 1 to 3, characterized in that the interface portion is housed in a roof outlet (4) for a siphonic drainage system. 10 15 20 25 30 529 951 12 Interface portion (1) according to one of Claims 1 to 3, characterized in that the interface portion is accommodated in a sleeve insert for a pipe. Interface portion (1) according to one of Claims 1 to 3, characterized in that the interface portion is housed in a tube. Interface portion (1) according to one of Claims 1 to 3, characterized in that the interface portion is housed in a coupling member. Interface portion (1) according to one of Claims 5 to 7, characterized in that the inlet end (10) is arranged to be connected to the upstream portion (2) by connecting threads. Interface portion (1) according to one of Claims 5 to 8, characterized in that the inlet end (10) is arranged to be connected to the upstream portion (2) by an interconnecting flange (8). Interface portion (1) according to one of Claims 5 to 9, characterized in that the inlet end (10) is arranged to be connected to an upstream portion (2) which is part of a roof outlet (4) for a siphonic drainage system. 11. ll. Interface portion (1) according to claim 10, characterized in that the inlet end (10) is arranged to be connected to an outlet pipe (13) of the roof outlet (4). Interface portion (1) according to claim 10, characterized in that the inlet end (10) is arranged to be connected to an outlet bottom (9) of the roof outlet (4). 10 15 20 529 951 13 Interface portion (1) according to claim 12, characterized in that the inlet end (10) is arranged to be connected to the outside of the outlet bottom (9) of the roof outlet (4). Interface portion (1) according to claim 12, characterized in that the inlet end (10) is arranged to be connected to the inside of the outlet bottom (9) of the roof outlet (4). Interface portion (1) according to one of Claims 1 to 14, characterized in that the outlet end (11) is arranged to be connected to a downstream portion (3) which is part of an end pipe for a siphonic drainage system. Interface portion (1) according to one of Claims 1 to 15, characterized in that the length (L) of the interface portion (1) is between 0.3 and 0.5 times the inner diameter (D) of the outlet end (11). Interface portion (1) according to one of Claims 1 to 15, characterized in that the length (L) of the interface portion (1) is at least 0.5 times the inner diameter (D) of the outlet end (11).