BE1028212B1 - Installation for a buffer system for collecting, storing and reusing rainwater - Google Patents

Abstract

Device (1) for a buffer system for collecting, storing and reusing rainwater for a building, characterized in that the device (1) is a buffer (2) in the form of at least one water tank (3) with level sensor (9) for collecting rainwater and the device (1) further contains at least one drain pump (12) for discharging the water from the buffer (2) to the sewage system and at least one recovery pump (15) for the reuse of rainwater from the buffer ( 2) for both internal use in the building and for external use outside the building, and a controller (16) for driving the drain pump (12), which controller (16) contains and/or receives data related to predicted or expected rainfall, and where in the event of predicted or expected heavy rainfall, the drain pump (12) will maximally empty the buffer via a discharge pipe (13) before the predicted heavy rainfall will occur.

Description

device for a buffer system for collecting, storing and reusing rainwater, 9 S The present invention relates to a device 9 for a buffer system for collecting, storing and reusing rainwater. reuse of rainwater, more specifically a buffer system for a building in an urban environment.

: 10 Global warming and the growing problem that this entails is a well-known 9 phenomenon, 9 There is an evolution in the climate whereby summers are becoming warmer and drier 'while winters are becoming warmer and wetter, which can result in a water shortage as well as an extremely low ground level in the summer and a large water surplus in the winter, which can lead to flooding and water nuisance in, for example, village and city centers.

These changes in climate change no longer appear to be immediately reversible and this trend is expected to continue in the coming decades.

Own water collections for homes, where rainwater is collected and stored in a rain well after which it can be reused, are already known.

A disadvantage of this type of own water collection is that they only collect a small part of the rainwater, while the majority of the rainwater will be lost through the drainage from the rainwater system to the public sewerage system, more specifically to the rainwater discharge.

| of the sewage system, which in many cases is separated from | dry weather collector of the sewage system for the discharge of sanitary and other waste water. The object of the present invention is to provide a solution to the aforementioned and 3 other drawbacks. To this end, the invention relates to a device for a buffer system for collecting, storing and reusing rainwater for a building, characterized by 9 that the device has a buffer in the form of | at least one water tank for collecting rainwater is included and the device further contains at least one drain pump for discharging the water from the buffer to the sewage system and at least one recovery pump for the reuse of rainwater from the buffer for both internal use in the building and externally use outside the building, and a controller for controlling the drain pump, which controller contains and/or receives data related to a predicted or expected rainfall, and where the drain pump will maximally empty the buffer in the event of a predicted or expected heavy rainfall via a discharge pipe before the predicted heavy rainfall will occur, the advantage of this invention is that in periods when large peak flows are expected, the control will activate the buffer to partially or maximally empty its contents before the predicted rainfall has

9 location has been found so that the capacity of the buffer is maximum | is, 9 Another advantage of the present invention is that it | 5 is resizable allowing buildings of all sizes to be provided with such furnishings. The buffer is preferably connected to a separate rainwater discharge from a public sewerage system by means of a supply pipe.

The advantage of this is that, in the event of heavy rainfall, the rainwater inlet of the public sewer is relieved as much as possible by draining the rainwater inlet from the rainwater inlet of the sewerage to the buffer, which is then emptied to the maximum at that time in order to reduce the risk of flooding in this way. The device preferably comprises a controllable shut-off valve for closing off the supply pipe and a dirt sensor for detecting contamination of the supplied rainwater, which dirt sensor is connected to the control, which is such that the controllable shut-off valve is closed in case the contamination has reached or exceeded a certain level. This offers the advantage that the buffer cannot be contaminated by the supply of contaminated rainwater from the rainwater discharge of the public sewage system.

Preferably, the device includes a controllable shut-off valve for shutting off the supply line and a | level sensor for measuring the water level in the : buffer that is connected to the control that is rodanig that # 5 the shut-off valve is closed when the level in the 9 buffer has reached a certain level or has exceeded 9, 9 An advantage of this is that the buffer cannot be overloaded by rainwater from the rainwater discharge.

The control is such that the buffer is emptied to a greater or lesser extent as a function of the water level indicated by the level sensor and the amount of predicted rainfall.

In this way it can be ensured that the buffer does not have to be completely emptied to be able to collect the predicted amount of rainfall per m®, so that energy and usable rainwater from the buffer can be saved. of a branch pipe is in communication with the supply pipe and the device can further comprise a controllable calamity valve for diverting contaminated rainwater from the rainwater discharge to the calamity basin, the calamity valve being in communication with the control which is such that the rainwater is diverted only from the calamity basin when the contamination has reached or exceeded a certain level.

This offers the advantage that contaminated rainwater that may have passed the shut-off valve can | are co-trapped in the calamity basin to protect: S from contaminating the buffer. 9 Furthermore, the device is provided with a dirt filter for 9 stopping large pieces of dirt, which is located # between the shut-off valve and the emergency valve, as well as with a 9 10 sand filter for filtering out small solid particles 9 and waste materials, wherein the sand filter is placed in 9 the supply line between the buffer and the emergency valve.

An advantage of this in-house water purification is that it partly relieves the water purification stations of the purification of rainwater for facilities for which non-potable water can be used. The calamity basin and/or the sand filter and/or the buffer are provided with an inspection shaft for inspection. and their content, if any.

The device comprises an inspection pit in the supply line, which inspection pit is placed within the building, for example with an access from the basement.

In a preferred embodiment, the buffer is located under the basement floor of the building, more preferably under the foundation of the building and possibly between the foundation piles of the building, so that no loads are applied to the buffer.

As a result, the buffer does not take up any extra space and { no extra surface area is required for the building. | 5 Preferably, 9 an infiltration neck is provided in the discharge pipe between the drainage pump and the rainwater discharge 9 of the public sewerage system to enable | drained rainwater can gradually penetrate into the ground 9, at least as far as the ground is not saturated with | 10 rainwater, Zen The advantage of this is that the infiltration basin can maintain the groundwater level cp in, for example, warm and/or dry summers.

The infiltration basin is provided with an overflow where the excess rainwater is discharged via the drainage pipe to the rainwater discharge of the sewerage system.

The rainwater will therefore infiltrate from the infiltration basin into the subsoil or run off to the rainwater discharge of the public sewer system.

In addition, the device is also provided with a system for collecting rainwater from the roof of the building and that fish is led through a collection pipe to the buffer, wherein an alternating jump filter, which works according to the known skimmer effect, is provided in the collection pipe in which leaves and other debris are filtered out and diverted to the discharge line downstream of the infiltration basin.

+ BE2020/5245 : in a practical embodiment, the building may also be equipped with | solar panels com the consumption of the pumps at least | 5 partially compensated, 9 With the insight to better demonstrate the features of the invention, a preferred embodiment is described below, by way of example without any limiting character: | 10 of an arrangement for a buffer system according to the 9 invention, with reference to the accompanying drawings, | in which: figure 1 schematically represents the arrangement of the buffer system according to the invention; figure 2 represents an alternative embodiment according to figure 1. Figure 1 shows a schematic representation of a buffer system according to the invention for collecting, storing and reusing rainwater for a building.

The device 1 contains a buffer 2 in the form of at least one water tank 3, more specifically of four water tanks Sa, 3b, Jo, Sd in the case of the figure, for collecting rainwater, which water tanks 3 are located under the building, at preferably among the cellar clerk 4. The water tanks 3 are connected to each other at the bottom by means of a supply line 5 which also connects the water tanks 3 to one or more wells 6, more specifically in the case of the example with two pump wells | 6, and further with an inspection pit 7. | 3 The water tanks 3 are preferably connected at the top to each other and 9 to the environment by means of venting pipes 8. 9 The water tanks 3 are accessible from the basement floor 4 for inspection via an inspection pit 7. The buffer 2 is provided with a level sensor 3 for detecting the level of rainwater in the buffer

2.

The pump pits 6 and inspection pits 7 are connected via a supply line 5 with a controllable shut-off valve 17 therein, which supply line 5 communicates with the rainwater discharge 10 of the public sewage system for the supply of rainwater by gravity, for which purpose the buffer 2 is located below the level of the The rainwater discharge 10 is separated from the dry-weather discharge 121 of the public sewage system which is provided for the discharge of used sanitary water. In addition, the device 1 comprises at least one drain pump 12 for discharging rainwater from a pump sump 6 to the rainwater discharge 10 from the public sewerage system via a discharge pipe 13 in which there is an infiltration basin 14 | cogeno. | The device 1 is also provided with at least one recuperation pump 15, more specifically in the case of figure 9 of two recuperation pumps 15a and 156, for the reuse # of rainwater from the buffer 2. The recuperation pumps 153 and 15b can discharge rainwater from a pump well 6 that receives rainwater from the buffer 2 for both internal sanitary use in the building and possibly also external use outside the building, such as for the adjacent building or for watering the garden or for supplying mobile water cisterns of the public authorities or In addition, the device 1 includes a controller 16 that commands and/or receives data, inter alia, regarding predicted or expected rainfall,

In the event of predicted or expected heavy rainfall, this controller 16 can control the drain pump 12 and the buffer 2 to empty the buffer as much as possible before the predicted heavy rainfall would occur,

Figure 2 shows a more extensive alternative embodiment of the invention, in which case the device 1 is inter alia provided with different filters, supply options, maintenance and inspection options and safety provisions.

| so the device 1 can for instance be provided with a controllable shut-off valve 17 for closing the 9 supply line 5 and a dirt sensor 18 for detecting | of contamination of the rainwater supplied. 9 The dirt sensor 18 is connected to the aforementioned control 16 { which is such that the controllable shut-off valve 17 closes the 9 supply line 5 if the water Le is heavily polluted by dirt or toxic substances or hazardous substances or the like. The control 16 can additionally provide be of a program which, in function of the signal from the level sensor 93, closes the shut-off valve 17 when the water level in the buffer 2 has reached or has exceeded a certain level. be provided with a dirt filter 19 in the supply line 5 for retaining large pieces of dirt, which dirt filter 19 is located in front of the shut-off valve 17. The device 1 can be provided with a calamity basin 20 which is connected to the supply line by means of a branch line 21 5 containing a controllable emergency valve 22 in order to immediately close the supply line 5 in the event that the rainwater in the rainwater discharge 10 is contaminated and to divert the contaminated rainwater from the rainwater discharge 10 to the calamity basin 20 where it can be temporarily collected for subsequent disposal. evacuate for appropriate cleaning or other treatment.

# The controllable emergency valve 22 is preferably a valve which immediately reacts via the control 16 to the signals 9 from the dirt sensor 18 and for this purpose is a valve with a fast | > activation system comparable to, for example, that of an 9 airbag, 9 In addition, the device 1 may be provided with a 9 sand filter 23 for filtering out small solid particles and waste materials, wherein the sand filter 23 9 is placed in the supply line 5 between the buffer 2 and the calamity valve 22. The calamity basin 20 and the sand filter 23 are preferably each provided with an inspection pit 7 which is accessible, for example, from ground level 24 and along which the calamity basin 20 and the sand filter 23 can be inspected and maintained internally,

Furthermore, the device 1 is preferably provided with a system for collecting rainwater from the roof of the building, which is led to the buffer 2 via a collecting pipe 25, wherein the collecting pipe 25 contains an alternating jump filter 26 in which leaves and other dirt are provided. are filtered out and diverted to the drainage pipe downstream of the infiltration basin 14, Bi) preferably the infiltration basin 14 and the 39 crossover filter 26 are placed below ground level 24,

9 In a practical embodiment, in addition to the { controllable buffer system, the building may also be equipped with | solar panels to reduce the consumption of the pumps at least | partially compensate Le, | 5 9 The operation of the device is logical and robust, 9 the device with intelligent control functions as follows #. 9 19 Rainwater is preferably supplied by means of a supply pipe 5 from the rainwater discharge 10 of the 9 public sewer system to the buffer 2. 9 The rainwater possibly flows past the open shut-off valve 17 and emergency valve 22, through the dirt filter 19 and sand filter 23 In the event that the rainwater is polluted, its supply can be stopped by closing the shut-off valve 17 in the supply line 5 and whereby, by closing the emergency valve 22, the contaminated rainwater flows through the shut-off valve 17 tcch would have passed can be diverted to the calamity basin 20 to prevent the buffered water from being polluted 253. The recovery pumps 15a and 15b, respectively for internal use for sanitary facilities and for possible external use, pump the rainwater from a pump sump 5, which is connected via the supply line 5 to the buffer 2 for obtaining rainwater from t the buffer 2.

| in case of predicted heavy rain the { ai feed pump can be controlled by the control for the | draining the rainwater from the buffer, # The drain pump 12 then preferably pumps rainwater up 9 from the pump sump 6 and discharges the rainwater via the 9 discharge pipe 13 in the direction of the rainwater discharge 10 9 of the sewerage system, wherein the drained rainwater first | 10 passes along the infiltration basin 14 and the surplus 9 rainwater, which cannot be taken up by the infiltration basin 14 due to saturation, via an overflow 27 | end up: in the drainage pipe 13 and thus can flow off 9 to the rainwater collector 10.

The present invention is by no means limited to the embodiments described by way of example and shown in the figures, but a device according to the invention can be realized in all kinds of shapes and dimensions without departing from the scope of the invention,

Claims (1)

9 Conclusions, 9 5 L.- Device (1) for a buffer system for the collection, storage and reuse of rainwater 9 | for a building, characterized in that the device (1) contains a buffer (2) in the form of at least one water tank (3} with level sensor (93) for collecting rainwater and the device {1} furthermore contains at least one drain pump ( 12) for the discharge of the water from the buffer {2} to the sewage system and at least one recovery pump (15) for the reuse of rainwater from the buffer {2} for both internal use in the building and for external use outside the building, and a controller (16) for driving the drain pump (12), the controller (16) containing and/or receiving data relating to predicted or expected rainfall, and wherein the drain pump {12} in predicted or expected heavy rainfall maximally emptied the buffer through a discharge pipe (13) before the predicted heavy rainfall will occur, 2.7 Device {1} according to claim 1, characterized in that the buffer {2} is connected to a separated rainwater discharge {10} of a public sewerage system by means of a supply line (5) for buffering rainwater from the rainwater discharge {10}. Device (1) according to claim 2, characterized in that the device (1) comprises a controllable shut-off valve (17) for closing the supply line {5} and a level sensor {53} for measuring the water level in the | buffer connected to the control (16) which is such that the shut-off valve (17) is closed when the | rainwater in the buffer (2) has reached or exceeded a certain level 9 5. 9 the device {1} according to claim 2 or 3, thereby | characterized in that the device (1) commanded a controllable shut-off valve {1773 to close off the supply line {5} and a dirt sensor {18} for detecting a contamination of the supplied rainwater, which dirt sensor (18) is in communication with the control (16) which is such that the controllable exhaust valve {17} is sicted in case the L5 contamination has reached or exceeded a certain level, Device {1} according to claim 4, characterized in that the device {1} comprises a calamity basin (20) which is connected to the supply line (5) by means of a branch line (21) and the device {1} furthermore comprises a controllable calamity valve (22) for diverting contaminated rainwater from the rainwater discharge {10} to the calamity basin (20}, wherein the calamity valve (22) is in communication with the control {16) which is soda-like that the rainwater flows to the calamity basin {20} is closed when the contamination has reached or exceeded a certain level. Device (1} according to claim 5, characterized in that the device (1) is provided with a dirt filter (193 [for retaining large pieces of dirt] which is: located BEFORE the shut-off valve (37) and which is located in the | supply line (5) a sand filter (23) is provided between the buffer (2} and the emergency valve (22) 7. Device (1) according to claim 1L or 3, characterized in that the level sensor (9) detects the level of the water 9 in the buffer {2} determines and the control (16) is programmed to pump the buffer {2} more or less empty depending on the amount of predicted rainfall. A device {13 according to one of the preceding claims, characterized in that the buffer (2) is provided with deaeration pipes (83. $.- Device {1} according to claim 1, characterized in that the device {1} has at least one recovery pump {15a } contains for internal use for sanitary facilities in the building and at least one other recovery pump {15b) for external use of the building, ij. Device {1} according to claim 9, characterized in that behind the recovery pump (15) for external use is a filter (28) is provided, i.e. device {1} according to any one of the preceding claims, whereby the buffer {2} is located under the building. | 17 BE2020/5245 9 12. Device {1} according to the previous | claims, characterized in that the buffer {2} is located 9 below the cobblestone floor {4} of the building. 9 5 13. Device (13 according to one of the preceding 9 claims, characterized in that the buffer {2} is located # under the foundation of the building, ld. Device (13 according to one of the preceding claims, characterized in that the buffer {2} is located between the foundation piles of the building. Device (1) according to claim 1, characterized in that the discharge pipe {13} opens into the rainwater tank inlet {10} of the public sewerage system and wherein the discharge pipe (13 ) an infiltration basin (14) is provided between the drain pump (12) and the rainwater tank feed {10} of the public sewage system. 16. Device {13 according to claim 15, characterized in that the drain pump (i2} and recovery pumps (15) pump waler up from a sump {6} which is in communication with the buffer {2} and which is provided with an inspection utility (7} for inspecting the well (6). i.e. Device (1) according to claim 5, characterized in that the calamity basin (20) and/or the sand filter (23} and/or the buffer (2) are provided with an inspection pit (7) for inspecting it. 3% +8 BE2020/5245 Device {1} according to claim 1, characterized in that the device {1} is provided with a system for collecting rainwater coming from the dax of the building and in that it has a collecting pipe (25) to | 53 the buffer is passed, whereby in the sump pipe (25) F an inter-change filter (26) is provided in which leaves and 9 other dirt are filtered out and are diverted to the 9 discharge pipe downstream of the infiltration basin 9 19 9 18,- Device {1} according to any one of the preceding 9 claims, characterized in that the building is equipped with solar panels to at least partially compensate for the consumption of the pumps (12 and 15),