SE513004C2 - Sewage systems and ways of managing wastewater including buffer and collection tanks - Google Patents

Abstract

A sewage system has a first source of waste water (10), which discharges heavily polluted water, in the form of a toilet or the like, a second source of waste water (20) of another type, which is adapted to discharge less polluted water, and a network of waste pipes (1). A buffer tank (30) is connected between the first source of waste water (10) and the network of waste pipes (1) for collecting waste water from the first source of waste water (10), and a storage tank (40) is connected between the second source of waste water (20) and the network of waste pipes (1) for collecting waste water from the second source of waste water (20). The sewage system is arranged for common intermittent flushing of waste water into the network of waste pipes (1).

Description

i __.._ .. = -. ...__ 10 15 20 25 30 35 513 004 2 on the smaller amount of water in relation to the amount of paper and faeces. Stops in sewer systems can cause many problems for the environment and to get rid of the stop, the pipes are flushed. This is a time-consuming, complicated and expensive eatra measure and the intended water savings are reduced or absent.

For good function with low-flush toilets in a building, it is generally required that the sewer pipe network in the building is dimensioned especially for this. Existing buildings therefore often require extensive and costly renovations.

Many toilet seats are also used as “trash cans”, which means that large amounts of water are flushed out in connection with this.

SUMMARY OF THE INVENTION An object of the present invention is to provide water-saving improvements for wastewater management.

A special object of the invention is to enable water savings in existing buildings without requirements for extensive renovations.

These and other objects, which will appear from the following description, are achieved according to the invention by a drainage system and a method, which are of the kind initially indicated and which in addition have the features stated in the characterized parts of claim 1 and patentkray 9.

From a first waste water source, which can be a toilet slipperlike, comes heavily polluted water.

From a second waste water source, which can be a shower, a washbasin or the like, comes less polluted water. In conjunction with the invention, highly contaminated water means in particular that the water comprises sludge and sediment-forming substances, and with less contaminated water that the water contains relatively smaller amounts of sludge and sediment-forming substances. The water from the two waste water sources is collected in separate tanks, one ~~; :: 'It «M; m new ;;. 3Lvævss1fir_mw =' ~ = ~ '~» @ == <= ~ «ff L: f- rx <\ '\ 10 15 20 25 30 35 513 004 3 buffer tank for heavily polluted water and a collection tank for less polluted water.

The less polluted water is used for intermittent flushing of the heavily polluted water in the sewer pipe network, which means that the total flow of water can be reduced without the risk of a blockage in the sewer pipe network. In particular, a much smaller amount of water can be used in a toilet to flush it. This water saving offers several benefits because the amount of water used and soiled can be reduced. Furthermore, the water flow through a building is reduced, which, at least in cold countries, leads to an energy saving because it becomes a smaller amount of water that absorbs and dissipates heat when it is led through the house. A special advantage is that hot waste water from, for example, a shower can remain for a time in the collection tank and release a large part of its heat content to the building.

Through intermittent flushing of the wastewater, it is possible to control where the heavily polluted water is led and where the less polluted water is led, which enables environmentally friendly use of the waste share in the wastewater. This principle can be used for all types of waste management where wastewater with different degrees of pollution is generated, but a particularly suitable application is leaching of organic waste, as this can be used as a fertilizer if it is not mixed with other excessively chemically polluted wastewater.

By letting the collection tank flush out of the buffer tank in response to a control signal, good cleaning of the buffer tank is obtained at the same time as you can control when flushing should take place. A simple and in many cases suitable control signal is that the buffer tank is flushed out when the collection tank is filled to a certain predetermined level. In order for rinsing not to take place at inappropriate times, for example at night when a rinsing can wake up neighbors, a valve is advantageously arranged to be able to prevent rinsing out of the buffer tank.

The valve that controls when the flushing of the buffer tanks is to take place can alternatively also be centrally controlled, which means that it is possible to control the type of wastewater that is discharged at different times. At certain times, for example, the buffer tanks can be emptied and during the rest of the day, excess water from washbasins and the like can be allowed to drain into the sewer system.

The collection tank and the buffer tank are integrated with the sources of the waste water (toilet, washbasin, shower, etc.). For example, in a special embodiment for bathrooms, a toilet and a washbasin can be integrated into a sanitary unit. From the shower and washing machine and similar waste water sources, the water can be led to the collection tank in the sanitation unit.

For kitchens, a special embodiment, such as a kitchen unit, can be built together by a first waste water source, which emits heavily polluted water, in the form of a waste grinder or similar equipment for food waste and a second waste water source such as a sink.

Such units for kitchens and bathrooms can then be connected to the house's friendly drain pipe network.

Preferred embodiments are set out in the dependent claims. W According to a particular aspect of the invention, a toilet with a fold-down toilet bowl is integrated with a washbasin. The less polluted water from the washbasin is collected in a collection tank and the more heavily polluted water from the toilet is collected in a buffer tank. The water in the collection tank is used to flush out the buffer tank into the drain pipe network. The toilet seat is flushed before and after use. The tiltability and flushing of the toilet bowl makes it easier to empty and wash the chair clean, which means that you can use less water than with a normal toilet.

When timing the wastewater, you can have a separation unit in connection with the building or in connection with a block, such as a well, which by sedimentation of glam from the heavily polluted water takes advantage of 10 15 20 25 30 35 513 004 5 organic waste from toilets and other sources for mainly organic waste, such as a food waste grinder. Since the buffer tanks are only emptied at certain times, the water in the separation well stands still for a long time, so the sludge and water have time to layer before the next round of wastewater is flushed there. The amount of less polluted water that is not needed for flushing out the buffer tanks can meanwhile be led past the separation well so as not to disturb the layering process therein. The sludge that collects in the separation well can then be used as fertilizer, as it practically only comprises pure organic waste that has not been mixed with chemicals and heavy metals from industrial wastewater.

The control of the flushes can also be adapted so that the general sewer network is utilized correctly. With such control, the dimensions of the pipe network can be made smaller because you no longer need to dimension to cope with a "worst-case scenario". Furthermore, the control provides the possibility that the emptying of the buffer tanks is adapted with regard to what takes place at the treatment plant.

Through the knowledge of what kind of wastewater comes at certain times, the treatment plants can also adapt their treatment processes better to the kind of pollutants that can be expected to come with the water. Separation bass songs, for example, work better if they are left alone for a long time. With a smaller total flow through the treatment plant, it will be easier to give the water in the pools a chance to stand in peace and stratify.

Brief Description of the Drawings In the following, embodiments of the invention will be described in more detail with reference to the accompanying drawings.

The drawings show, by way of example, a sewage system and the units that are suitably used in such a sewage system. liiih fi i ix fl hnunnumm .. | in.ul..m \ nw »w» han-val ..,. uu ... ......, ..._ 10 15 20 25 30 35 513 Û04 6 Fig 1 viser schematically how the sewer system can be adapted to be accommodated in a building.

Fig. 2 schematically shows how the sewer system in the building connects to the surrounding sewer pipe network.

Fig. 3 shows a sanitary unit in which a toilet and a washbasin are built together.

Fig. 4 shows a sink with an integrated waste management unit.

DESCRIPTION OF PREFERRED EMBODIMENTS A drainage system in a building comprises, with reference to Fig. 1, a first waste water source 10, in the form of a toilet; which emits heavily contaminated water, a second waste water source 20, in the form of a washbasin, which emits obstructed contaminated water. The system further comprises a buffer tank 30 for collecting the waste water from the fresh waste water source 10, and a collection tank 40 for collecting the waste water from the second waste water source 20. The water collected in the collection tank Q0 is used for intermittent flushing of the water in The buffer tank 30. This can be done, for example, by passing the water from the collection tank 40 through the buffer tank 30, but this can also be done by the buffer tank 30 and the collection tank 40 being connected in parallel to the drain pipe network 1 and by first emptying the buffer tank 30 and the collecting tank. 40 is emptied immediately thereafter.

Fig. 2 shows a building with waste water sources and a sewage pipe network 1, which leads waste water from the building to a treatment plant 3, via a separation well 2.

Wastewater is led in the sewer pipe network 1, to the separation well 2, in which the water stands still so that the water and the sludge therein can layer so that the waste can be removed. Residual wastewater is then passed on in the public sewer pipe network 1 to finally end up in a treatment plant Thanks to the time control of the flushing, it is possible with system-friendly this embodiment to separate sludge from the! I i I if «; @.:;: 3: 1s-a¿w ps; -a kan ars» n @ ;; Msr1; w> 1; sas; “ss, as ss ¿>: i¿ ;:; S «: '10 15 20 25 30 35 513 004 7 waste water near the source without requirement for complete chemical and biological treatment in this intermediate stage.

A sanitary unit 100, shown in Fig. 3, is a suitable embodiment of a part of the drainage system according to the invention, and has the main components; a washbasin 120, a collection tank 140, a toilet 110 and a buffer tank 130. The sink 121 of the washbasin is connected to the collection tank 140, in which the slightly contaminated water is stored. The toilet seat 110, which can be folded up and down, is folded up after use and emptied via an emptying channel 111 in the buffer tank 130. The buffer tank 130 is in turn connected to the drain 1. The collection tank 140 is filled above a certain level. valve (not shown) and the water in the collection tank 140 is led via a pipe 141 down to the buffer tank 130, which is flushed out, and further out through the housing drain 1. The fold-up and fold-down means that the toilet takes up less space when not in use.

The toilet seat 110 is folded up and down by means of a pressure cylinder (not shown), which is double-acting, which utilizes the pressure on the incoming water and which is operated by means of a control valve (not shown). The water on the dead side of the cylinder, which is forced out of the cylinder when it is operated, is used for pre- and post-flushing of the toilet seat.

When the toilet 110 is to be used, it is unfolded by moving a control lever (not shown) which operates the control valve, which opens for incoming water which is led to the pressure cylinder. The pressure cylinder folds out the toilet seat 110 to its user position at the same time as the water from the dead side of the pressure cylinder is led into the toilet seat 110 to wet it.

When you have finished the toilet, move the control lever to a closed position. The control valve then instead controls the water flow to the other side of the pressure cylinder which folds up the toilet seat 110. The water from the death side is also in this case returned to the toilet seat 110.

On the way to the toilet 110, the water passes a cy- '-' - ,. ~, ï - * <1..f ~ '-1'! - = 1 "» -. I ~ f.) 1f ~ '3¿ =,. C-xjlíë: fi

Claims (12)

10 15 20 25 30 35 513 004 ll PATENT REQUIREMENTS A sewage system comprising at least one first waste water source (10; 110; 210), which is arranged to discharge heavily polluted water, such as a toilet or the like, at least one second waste water source (20; 120; 220) of another kind, which is arranged to emitting less polluted water, and a drain pipe (1), to which the first waste water source (10; 110; 210) and the second waste water source (20; 120; 220) are connected, and 140; 240), between the second waste water source (20; 120; 220) and a collection tank (40; which is connected to the flue pipe network (1) for collecting waste water from the second waste water source (20; 120; 220), the sewage system being arranged for common intermittent flushing of waste water in the sewage pipe network (1), characterized in that the sewage system further comprises a buffer tank (30; 130; 230), the first waste water source (10; 110; 210) and sewage pipes connected between it the net (1) for collecting waste water from the first waste water source (10; 110; 210, wherein the collecting tank (40; 140; 240) is arranged to be emptied into and flushed from the buffer tank (30; 130; 230) in response to a control signal, wherein the first waste water source (110; 210), the collection tank (140; 240), and the buffer tank (130; 230) are connected to an integrated unit (100; 200) and the unit is connected to the sewer pipe network (1). Drainage system according to claim 1, wherein in the drain pipe network (1) downstream of the buffer tank (30; 130; 230) there is a separation unit (2), which is arranged to separate pollutants from the waste water between the intermittent flushes in the drain pipe network (1). . Sewage system according to claim 2, in which the separation takes place by sedimentation of sludge from the wastewater. f v 1999-09-03 os 25 g \ pac \ mgn \ ans \ 199s \ p: 9a14s5.dec iimfum fl ... m. ~ .... m..i..u.:. .. (... | .. w .. 10 15 20 25 30 35 513 004 * 12 Sewage system according to one of the preceding claims, in which the second waste water source (120; 220) is integrated in the unit (100; 200). A sewage system according to any one of the preceding claims, wherein the first waste water source (110) is a toilet. : i A sewage system according to any one of claims 1-4, wherein the first waste water source (210) is a food waste disposal unit, such as a waste grinder or the like; 1 A drainage system according to claim 5, wherein the toilet (110) is flushed before use. Drainage system according to claim 5 or 7, in which the toilet (11D) is foldable up and down. 9. A method of managing waste water from at least one first rinsing water source (110; 210) which gives off heavily polluted water, such as a toilet or the like, and at least one other waste water source (120; 220), which gives off less contaminated water, characterized by measures of collecting the waste water from the first waste water source (110; 210) in a buffer tank (130; 230), and collecting the waste water from the second waste water source (120; 220) in a collection tank (140; 240), to combine the first waste water source (10; 110; 210X, up the collection tank (l40; 240), and the buffer tank (¥ 30; 230) into an integrated unit (l00; 200), to copy the unit (l0O; 200) to a drain pipe network (1), smoothly flushing the waste water from the collection channel (p40; 240) and the buffer tank (130; 230) to the drain pipe network (1), and emptying the buffer tank tank (130; 230) in response to a control signal. ) by 10.:The method of handling wastewater according to claim 9, at which the acid signal is emitted at predetermined times. l I I I! . I 2f ~ a1w ~ vn§vst1c§ ::: ~ ß- fi avtmsï_: ïsï: §asï2ss￧ »ss; w; rn¿; -3: 1! .- 1. I I! I I 513kr AÛÜTÅA 13 11. ll. A method of handling wastewater according to any one of claims 9-10, in which sludge in the wastewater is separated from the wastewater. A method of handling wastewater according to claim 11, 5 in which the separation takes place by sedimentation. 1999-09-03 08:25 g: \ pat \ mgn \ ans \ l998 \ p298l4SS .doc