ES2443999B1 - Turbine for a wastewater collection facility and its rotor cleaning procedure - Google Patents

Abstract

Turbine suitable for being inserted in a wastewater collection facility of a building or group of buildings, comprising a turbine body (10), a rotor provided with an axle (25) and several blades (20), the body provided with a substantially cylindrical part (11) whose axis is substantially parallel to the axis (25) of the rotor, and several ducts (30) for the entry of wastewater into the body (10), each of which at its once it comprises a mouth (32) to connect the conduit (30) to the installation and a nozzle (31) to connect the conduit to the cylindrical part (11) of the body (10), so that the diameter of the nozzle is at less three times smaller than the diameter of the mouth. In a cleaning procedure of such a turbine, a pressure switch keeps a pair of solenoid valves closed if it detects that the upstream pressure (sanitary water line) is less than or equal to the downstream pressure (inside the turbine).

Description

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DESCRIPTION

Turbine for a wastewater collection facility and its rotor cleaning procedure

The present invention relates to a turbine suitable for being inserted in a wastewater collection facility of a building or a group of buildings, comprising a turbine body and a rotor provided with a shaft and several blades; The body may be provided with a substantially cylindrical part whose axis is substantially parallel to the axis of the rotor. The invention also relates to a rotor cleaning process of such a turbine.

STATE OF THE PREVIOUS TECHNIQUE

It is known to generate electric energy by means of a turbine interposed in a wastewater downpipe of a building. US4246753 discloses a turbine of this type, comprising a body 12 and a rotor provided with a plurality of blades 30. Wastewater acquires kinetic energy in the downspout and enters the body through an inlet conduit 22, hits the blades and rotate the rotor, and leave the body through an outlet duct 40 towards the sewer. The inlet and outlet ducts are vertical, and their diameters are approximately equal to the diameter of the downpipe. The rotational energy of the rotor can be transformed into electrical energy by means of a generator 52. A clean water line 64 can feed injectors 48 and 50, with the aim of cleaning the blades by means of a pair of jets of pressurized water.

The fact that this turbine is simply interposed in the downspout, without being adapted to the somewhat irregular nature of the wastewater flow or to the relatively small flow thereof, limits the turbine's energy efficiency quite a bit.

EXPLANATION OF THE INVENTION

An objective of the invention is to improve the energy efficiency of a turbine of the type described in the previous section.

According to one aspect of the invention, the turbine comprises several conduits for the entry of wastewater into the body, each of which in turn comprises a mouth for connecting the conduit to the installation and a nozzle for connecting the conduit to the cylindrical part of the body, so that the diameter of the nozzle is not larger than a third of the diameter of the mouth, preferably not more than a quarter of the diameter of the mouth (32). In this way two important improvements are achieved: several water jets enter the turbine and the water enters faster. In addition, the use of several inlet ducts facilitates their connection to several downspouts, which may even have different directions, and also facilitates the installation of the turbine by allowing it to be placed in the most convenient place, which is not necessarily where the downspout is.

According to another aspect of the invention, at least one blade, although preferably all of them, comprises a groove at its distal end, that is, at the opposite end of the rotor hub, which is the proximal end of the blade. In a blade devoid of this slit, as the blade is rotating, the blade initially comes into contact with the water jet on its rear face (i.e., against the direction of rotation of the blade), whereby at first the water jet opposes the advance of the blade, although the inertia of the blade makes it continue to advance until the jet impacts on the front face of the blade (in favor of the direction of rotation of the blade). Therefore, for a brief initial period the water jet not only does not accelerate the blade but also slows it down. With the slit this does not happen because in this case, as the impact occurs a little later and with the blade a little more advanced, the initial contact already occurs on the front face of the blade. The slit may be "U" shaped and may have a depth of between a third and a fifth of the length of the blade.

In one embodiment, at least two inlet ducts may be arranged on the cylindrical part (11) of the body (10) such that the points of intersection of the axes of symmetry of said ducts with said cylindrical part define thereon a direction substantially parallel to the axis of the rotor, that is, the inlet ducts can be arranged on the surface of the cylinder in axial direction, whereby several jets can simultaneously hit the same blade (which, where appropriate, can have several corresponding grooves ).

In another embodiment, or in combination with the previous embodiment, at least two inlet ducts may be arranged on the body in a direction substantially perpendicular to the axis of the rotor, that is, by imagining the body as a cylinder, the inlet ducts may be arranged on the surface of the cylinder on a circumference thereof, whereby each jet can hit a different blade at each moment (or at least most of the time).

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The axis of the nozzle can form an angle between 45 ° and 60 ° with the tangent to the cylindrical part of the body at the point of intersection of the cylindrical part of the body with the axis of the nozzle. This can enhance the advantageous effect of the slit.

In one embodiment, the diameter of the turbine may be less than 90 centimeters; Thus, the turbine is relatively comfortable to install. With this relatively small size, it is preferable that the turbine rotor comprises between 12 and 14 blades.

The turbine can comprise a tube for the entry of clean water into the body, and also a pressure switch, a first solenoid valve and a second solenoid valve disposed in said tube, the second solenoid valve being downstream of the first solenoid valve. This allows the blades to be cleaned in a programmed or automatic way.

According to one aspect of the invention, in a rotor cleaning process of this turbine the pressure switch can keep the first solenoid valve and the second solenoid valve closed if it detects that the upstream pressure of the first solenoid valve is less than or equal to the water pressure below the second solenoid valve, thus preventing dirty water from entering the clean water system.

To begin a cleaning session, said procedure may comprise the steps of:

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open the first solenoid valve keeping the second closed;

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open the second solenoid valve keeping the first one open.

This makes it even more difficult, if not impossible, for dirty water to enter the clean water facility.

To end the cleaning session, said procedure may comprise the steps of:

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close the second solenoid valve keeping the first one open;

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close the first solenoid valve keeping the second closed.

Similarly, this makes it even more difficult, if not impossible, for dirty water to enter the clean water facility.

Other objects, advantages and features of embodiments of the invention will be apparent to the person skilled in the art from the description, or can be learned with the practice of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

Particular embodiments of the present invention will now be described by way of non-limiting example, with reference to the accompanying drawings, in which:

Figure 1 represents a turbine with three inlet ducts arranged circumferentially; Figure 2 represents the blades of a turbine like that of Figure 1; Figure 3 represents a turbine with two axially arranged inlet ducts; and Figure 4 represents the connection of a turbine like that of Figure 3 to two downspouts, one vertical and one horizontal.

DETAILED EXHIBITION OF MODES OF EMBODIMENT

A turbine according to the invention may comprise several inlet ducts and / or blades provided with a groove at its distal end. The turbine of figures 1 and 2 comprises a body 10 of generally cylindrical shape, which in turn comprises a cylindrical part proper 11 and two side walls 12. The turbine also comprises blades 20 mounted on a bushing (not shown) integral to a rotation axis 25, which crosses the side walls of the turbine and can be mechanically connected to an electric generator (not shown). The set of the blades, the hub and the shaft constitutes the rotor of the turbine.

The turbine further comprises several ducts 30 (in figure 1 there are three and in figure 3 are two) for the entry of wastewater into the body 10. As can be seen in figure 4, the inlet ducts 30 constitute a narrowing between the downspouts 50 and the body 10 of the turbine, so that the water enters faster inside the body 10; the narrowest part of the inlet duct 30 (the one that is connected to the cylindrical part 11 of the body 10) is a nozzle 31, and the widest part of the inlet duct 30 (the one connected downstream 50) is a mouth 32 The diameter ratio between the mouth 32 and the nozzle 31 can be between 3 to 1 and 5 to

1. The diameter of the mouth 32 may be, for example, 300 mm, and that of the nozzle 31 of 70 mm. The turbine also comprises an outlet pipe 35 that connects to the sewer.

The turbine can be connected to several downspouts 50 of the building through the inlet ducts 30, although a single downspout can also be connected to several inlet ducts. The downspouts 50 can have any

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address. Naturally, the turbine can be intercalated in any sewage pipe, such as a sewer or a sewage system, or in a more or less clean water pipe.

The blades 20 may be flat or may be slightly arched, both longitudinally and transversely (or both). As can be seen in Figure 2, each blade 20 comprises a "U" shaped recess 22 formed at the distal end of the blade. The blade may have a length of, for example, 40 cm, and the depth of the slit 22 may be about 10 cm at the deepest point and its width about 8 cm at the distal end of the blade. The number of blades can be 14. The slot 22 is in correspondence with the nozzle 31 of the inlet duct 30, so that the jet leaves the nozzle in a direction such that the first impact of the jet on the blade (which is rotating) occurs at the bottom of the groove and on the front face of the blade, that is, even at the beginning of the contact the jet hits the blade in favor of its direction of rotation.

In the embodiment of Figures 1 and 2, the three inlet ducts 30 are arranged circumferentially (ie, in a direction perpendicular to that of the axis 25) in order to be able to impact on three different blades at the same time. In the embodiment of FIG. 3, the two inlet ducts 30 are arranged axially (that is, in a direction parallel to that of the axis 25) so as to be able to impact on the same blade with twice the force. In the latter case, the blades may be provided with two slits 22, in correspondence with the nozzles 31 of the inlet ducts.

Naturally, whether or not the inlet ducts 30 are circumferentially arranged or arranged axially (or both), there can be any number of inlet ducts; The configuration and size of the turbine can be adapted to the number and arrangement of the inlet ducts.

Between the mouth 32 and the outlet pipe 35, a bypass pipe (also called “by-pass”, not shown) can be arranged to ensure that, in the event of an incident in the turbine, the flow of wastewater out of the Building is not interrupted.

The turbine admits the entry of sewage, not just gray water, and the solid waste present in said sewage is quite shredded after its interaction with the blades 20, which favors its evacuation.

The turbine can comprise a tube (or several tubes) for the entry of clean water (not shown) in order to clean the blades 20 and the inside of the body 10. Said tube is connected to the sanitary water line and comprises a pressure switch and two solenoid valves (not shown) arranged in series. The cleaning procedure is as follows:

-The solenoid valves are closed; when you have to proceed to a cleaning session (which can be scheduled

or automatic), the first solenoid valve (upstream) is opened but the second solenoid valve (downstream) is kept closed; then the second solenoid valve is also opened.

-The solenoid valves are open; When the cleaning session has to be completed, the second solenoid valve is closed first and then the first solenoid valve is also closed.

This prevents sewage from the turbine from entering the sanitary water line. For greater safety, the pressure switch keeps the two solenoid valves closed if the pressure in the domestic water line is less than or equal to the pressure inside the turbine, or perhaps even if it is only very little.

The turbine can be made of or with various materials, for example stainless steel or PVC.

Although only some particular embodiments and examples of the invention have been described herein, the person skilled in the art will understand that other alternative embodiments and / or uses of the invention are possible, as well as obvious modifications and equivalent elements. In addition, the present invention encompasses all possible combinations of the specific embodiments that have been described. The numerical signs relating to the drawings and placed in parentheses in a claim are only intended to increase the understanding of the claim, and should not be construed as limiting the scope of the claim's protection. The scope of the present invention should not be limited to specific embodiments, but should be determined only by an appropriate reading of the appended claims and the explanation of the invention.

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Claims (15)

image 1 image2 image3 1. Turbine capable of being inserted in a wastewater collection facility of a building or group of buildings, comprising a turbine body (10) and a rotor provided with a shaft (25) and several blades (20), the body being provided with a substantially cylindrical part (11) whose axis is substantially parallel to the axis (25) of the rotor, characterized by the fact that it also comprises several conduits (30) for the entry of wastewater into the body (10 ), each of which in turn comprises a mouth (32) for connecting the conduit (30) to the installation and a nozzle (31) to connect the conduit to the cylindrical part (11) of the body (10), so that the diameter of the nozzle is not larger than a third of the diameter of the mouth.

2.

Turbine according to claim 1, characterized in that the diameter of the nozzle (31) is not larger than a quarter of the diameter of the mouth (32).

3.

Turbine according to claim 1 or 2, characterized in that at least two inlet ducts (30) are arranged on the cylindrical part (11) of the body (10) such that the intersection points of the symmetry axes of said ducts with said cylindrical part define therein a direction substantially parallel to the axis (25) of the rotor.

Four.

Turbine according to claim 1 or 2, characterized in that at least two inlet ducts (30) are arranged on the body in a direction substantially perpendicular to the axis (25) of the rotor.

5.

Turbine according to any of the preceding claims, characterized in that the axis of the nozzle (31) forms an angle between 45 ° and 60 ° with the tangent to the cylindrical part (11) of the body (10) at the point of intersection of said cylindrical part with the axis of the nozzle.

6.

Turbine according to claim 5, characterized in that at least one of the blades (20) comprises a groove (22) at its distal end.

7.

Turbine according to claim 6, characterized in that each blade (20) comprises at least one of said slits (22).

8.

Turbine according to claim 6 or 7, characterized in that at least one slit (22) is "U" shaped.

9.

Turbine according to any of claims 6 to 8, characterized in that the depth of at least one slit (22) is between one third and one fifth of the length of the blade (20).

10.

Turbine according to any of the preceding claims, characterized in that the diameter of the turbine is less than 90 centimeters.

eleven.

Turbine according to claim 10, characterized in that the rotor comprises between 12 and 14 blades (20).

12.

Turbine according to any of the preceding claims, characterized in that it comprises a tube for the entry of clean water into the body (10), and also a pressure switch, a first solenoid valve and a second solenoid valve disposed in said tube, the second being solenoid valve downstream of the first solenoid valve.

13.

Process for cleaning the rotor of a turbine according to claim 12, characterized in that the pressure switch keeps the first solenoid valve and the second solenoid valve closed if it detects that the upstream pressure of the first solenoid valve is less than or equal to the downstream pressure of the second solenoid valve.

14.

Method according to claim 13, characterized in that it comprises the steps of:

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open the first solenoid valve keeping the second closed;

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open the second solenoid valve keeping the first one open.

15. Method according to claim 14, characterized in that it comprises the steps of:

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close the second solenoid valve keeping the first one open;

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close the first solenoid valve keeping the second closed.

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