NO20141121A1 - drainage - Google Patents

Description

The background of the invention

Technical area

The invention relates to fluid control in general and more specifically to a system for and a method for controlling and improving the flow of liquid in a drainage system.

Background technology

From the known technique, reference must be made to traditional drainage systems for use for sewage/wastewater and storm water. Fluid from the inlet is collected, and is typically conveyed via one or more sumps and collection tanks and on to an outlet where the fluid is typically treated, such as a sewage treatment plant, before being emptied and deposited in suitable locations. Pipes are used for connection between inlets, basins and treatment plants, possibly also manifolds or branch pieces that connect two or more pipes together to form one pipe.

The principle is based on liquid flowing under its own weight, and is called gravity flow. Sumps, pipes and manifolds are open, allowing air to enter the drainage system and thereby limiting the amount of liquid that the system can remove. In addition, the use of a manifold will pose a risk of liquid flowing from a higher part of the system out of a lower inlet.

Brief overview of the invention

Problems that had to be solved with the invention

In the past, common drains were laid, i.e. waste water, drain water, roof irrigation and stormwater were led to the outlet which was a stream, river or the sea. Later, the liquid was taken into a treatment plant before it was released further into the recipient.

For this reason, it is a main aim of the present invention to provide a system for and a method for controlling and improving the flow of liquid in a drainage system and which overcomes the problems mentioned above.

Brief review of the drawings

In the following, the invention will be described in more detail with reference to the drawings which show several examples of implementation, and where

fig. 1 schematically shows parts of a drainage system

fig. 2 schematically shows a liquid foam

fig. 3 schematically shows a full-flow foam

fig. 4 schematically shows the effort in the sump

fig. 5 schematically shows a bridge with vacuum suction to draw water away

fig. 6 schematically shows waste water-heated pavement

fig. 7 schematically shows detail of insert in sump shown in Fig. 4

fig. 8 schematically shows an embodiment of heating pavements

fig. 9 schematically shows an embodiment of heating a parking space

Detailed description of the invention

In the following, the invention will be described in more detail with reference to the drawings which show several examples of execution, and in which Fig. 1 schematically shows a drainage system.

Expansion foam shown in fig. 2 can receive large quantities of waste water in a short time and delay the discharge to prevent overloading of the system downstream. Several of these can be used in parallel and in series, and can possibly be controlled to keep the downstream capacity optimal.

Full flow foam is shown in fig. 3. This basin automatically turns it into full flow and it is an advantage that air is let in in a controlled manner when the water quantities decrease in order to maintain the vacuum for as long as possible. It is shown here either by holes or a valve that can control in several ways, e.g. by a float, electronic, etc.

It is an advantage that the pipe rises a little before it starts to fall, then full flow is achieved much faster as less water height above the outlet is required before a vacuum is achieved.

Insertion is shown in fig. 4 and 7. A typical area of use here is in sand catch basins. Here, the vacuum chamber is placed in first and connected to the full-flow pipe that goes through all the basins and to the recipient. The funnel insert is then mounted, which has a small outlet at the bottom where water and sand are led down into the existing basin. The sand falls out and the water flows out as a self-fall through the original drain. When the quantities of water increase, the water level in the funnel rises and the water flows into the vacuum chamber. There, a ball or fender will first float up and the water flows out as a full stream. As water volumes increase, more and more floats will open, and the opposite happens when water volumes decrease. Then the floats close evenly again and you avoid strong shocks that would regurgitate if you only had a closing and opening device.

It has proven beneficial to use elongated floating bodies as fenders for use on boats instead of bales.

Bridge is shown in fig. 5. A typical area of use is the protection of users and to reduce the use of raising the level along parts of a river. Preferably, a formwork is set up in e.g. fiberglass and installs all the divers/water intakes so that the pipes can be connected to this prefabricated intake.

The water is led in full-flow pipes past the critical area and back out into the river further down. Here, if desired, they can be fitted with generators. Pipes and intakes must be anchored/loaded.

The vacuum means that larger masses of water can be drawn away and it is avoided that the masses of water put the bridge element under water, which could then have been in a strong current with associated tensile forces.

Elements for use for heating/melting snow are shown in fig. 6, 8 and 9. Typical areas of use are pavements, football pitches, car parks or collection areas for snow where the contaminated melt water is fed back into the waste water line and to the treatment plant. One element uses the waste water directly and here the water flow is stopped until the water has cooled and then replaced with new hot waste water. Flushing of storm water, possibly with added chemicals to prevent growth, is carried out as required.

The heat can be extracted either directly from the waste water, which then runs in pipes in the ground, or indirectly with heat pipes, so the evaporation part extends down into the waste water, while the condensation end is arranged in the ground near the surface. Hatpipes provide great heat transfer capability, and a break in the waste water network is avoided if the pipes near the surface are damaged. Such a solution can also be used on a self-falling system. Fig. 8 shows an area of use which can be a pavement where 3 elements are mounted in width, and how the entire white row must be replaced when the temperature has approached the freezing point. Fig. 9 shows a parking area where each of the shaded fields in the corners are areas where the snow from the parking space is deposited and melted away. If it contains environmental toxins, the melt water is sent back into the waste water line and to the treatment plant.

The flow rate in the system can be adjusted with valves, typically motor valves. It is also possible to use a supply of gas, typically air, to reduce the vacuum, which in turn reduces the suction power. The valve can also be combined with the supply of gas.

Industrial applicability

The invention finds its usefulness when used in drainage systems to improve performance and remedy peaks in volumes that must be handled in a short time. It separates existing communal facilities in a simpler way by either digging shallower and using smaller dimensions, and new inserts can be placed in existing sumps.

Claims (1)

1. A drainage system (200), comprehensive at least one sump (350, 360, 370) for receiving a liquid from a drain, the sump comprising at least one inlet and at least one outlet, level gauge (431) to register when the liquid exceeds an upper level (436), level gauge (431) to register when the liquid drops below a lower level (435), at least one pipe, the pipe being operatively connected to the outlet (212, 222) of the basin, at least one valve (202), the valve being connected to at least one of the basin and the pipe, characterized in that the valve in a closed state prevents outflow from the sump and prevents gases from entering the pipe, and that gases do not enter the pipe when liquids exceed the lower level in the basin, as the pipe is connected to a part which on the inside of the basin extends downwards.