FR2923501A1 - AUTONOMOUS MECHANISM FOR RECOVERING WASTEWATER THEN FILTERED WATER PRESSED WATER PRESSURE OF DISTRIBUTION NETWORKS. - Google Patents

Abstract

The invention relates to an autonomous transfer mechanism for the purpose of recovering water that has already been used and previously filtered, a mechanism that is operated and enslaved mainly to the existing pressure of an individual or collective distribution network for domestic, agricultural or industrial water. , the consumption is thus simultaneous recoveryThe invention aims in particular and among others the recovery of wastewater for reuse in particular for the supply of toilet tanks or for external watering after, decantation, filtration, purification or any other means of depollution .., waters collected in a reserve appropriate to the volumes and permanent needs of the different users.

Description

The invention aims, in particular and among other things, the recovery of wastewater for reuse in particular for the supply of toilet tanks or external watering after settling, filtration, purification or any other means of pollution control, water collected in a reserve appropriate to the volumes and permanent needs of the different users. The invention relates to an autonomous transfer mechanism for the purpose of recovering water that has already been used and previously filtered, a mechanism that is operated and enslaved mainly to the existing pressure of an individual or collective distribution network for domestic, agricultural or industrial water. ; consumption is thus simultaneous with recovery.

The system consists of a set [1], Fig. 1, of two turbines [2] and [3], FIG. 5 & 6, equipped with pallets judiciously and differently oriented; these turbines are coupled by axes [4] and [5], FIG. 7, to a reduction system [6], FIG. 6 & 7, each of these two turbines being housed in a single chamber and perfectly sealed [7], Fig. 7 & 8.

The chamber [7], Fig. 5, is connected to the pressurized water supply of the distribution network, the pressurized water entering through the orifice [9], FIG. 5, actuates the vane turbine [2], FIG. 5, and exit through the orifice [10], FIG. 5, thus returning to the pressurized pipeline of the distribution network. The vane turbine [2], FIG. 5, under the pressure of the water, actuates the vane turbine [3], Fig. 6 under a higher rotational speed since [2] and [3] are coupled by a reduction system [6], Fig.7, this set [1] can be substituted according to the water pressure by a system [ 27] dynamic exchange vacuum suction due to the opening of the pressurized water network, a system operating a Venturi type process thus using the depression during the passage of water under pressure.

The used waters, called used, are directed towards a set [11], fig. 8, of three elements: a degreasing tank [12], a purifier [13] and a tank [14]. The chamber [8], FIG. 6 & 7, is connected to the tank [14], Fig. 8, through a pipe [15], Fig.6 & 8, provided with a non-return strainer; when rotating the turbine [3], Fig. 6 & 7, the contents of the tank [14], Fig. 8, is sucked and then rejected through a pipe [16], FIG. 8, to another tank placed high [17], Fig. 8. Each time the water is used under pressure, filtered water is collected. The autonomy of the system consists in not using outside energy (electricity, gas, steam, ...) when the pressurized water distribution network is in service and functioning, but only using the pressure water distribution networks.

The axis [18], FIG. 8, the vane turbine [3], FIG. 6 & 7, is connected to a dynamo or alternator system [19], Fig. 8, which supplies a battery [20], FIG. 8, as soon as the pressure of the distribution network is sufficiently large. In the case of insufficient pressure, the dynamo or alternator system [19] is disengaged by a clutch-clutch mechanism [21], Fig. 8.

In case of insufficient pressure, the battery [20], Fig. 8, will provide the energy needed for a pump [24], Fig. 8, which will allow the flow of the previously filtered water contained in the tank [14], FIG. 8, to the tank [17], fig. 8. The system therefore works even in the case of shutdown of water distribution networks; thus the feeding of the toilets and urinals is ensured by the tank [17], Fig. The reservoir [17], FIG. 8 is nevertheless connected to a pressurized water distribution circuit which will fill it in the case of maintenance or failures of the entire system [1], FIG. 1. The battery [20], Fig. 8, can also be powered by a mini wind turbine [22], Fig.8, or a panel of photovoltaic cells [23], Fig. 8, or both.

The entire device is completely autonomous and managed by a PLC [25], Fig. 8, placed in the cabinet [26], Fig.8.

Claims (5)

1) Autonomous transfer system (set 1 - Fig; 1) for the recovery of water already used and previously filtered. System operated and servocontrolled to the existing pressure of a distribution network, individual or collective, domestic, agricultural or industrial water; consumption is thus simultaneous with recovery. 2) System according to claim 1 characterized in that the only energy used is the incoming water pressure [9], Fig. 7, of these distribution networks, without any loss of volume or additional consumption caused by the system [10], FIG. 7. 3) System according to claim 2 characterized in that the incoming water of the network 10 actuates a vane turbine [2] coupled by a mechanism [6] to a second vane turbine [3]. 4) System according to claim 3 characterized in that the coupling mechanism [6] increases the rotational speed of the second turbine [3], provided with sliding vanes. 5) System according to claim 4 characterized in that the rotation of the second turbine 15 [3], flows a suction [15] in a reservoir [14] of water already used.