ITMI20131320A1 - PLANT FOR ENERGY RECOVERY FROM FLUIDS - Google Patents

Description

IBI-15276 Description of the industrial invention entitled: "PLANT FOR THE RECOVERY OF ENERGY FROM FLUIDS"

by DEMARIA Giovanni Mario and IMERI Tomor

in ALESSANDRIA (AL)

Inventors: DEMARIA Giovanni Mario, IMERI Tomor.

TEXT OF THE DESCRIPTION

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The present invention relates to a system for recovering energy from a fluid flow, in particular water, exploiting the positive and negative pressure values depending on the level differences of the water storage basins arranged along the hydraulic circuit constituting the system.

The plant of the present invention is substantially composed of a column of fluid placed under negative (static) pressure, from which the liquid is taken by means of a pump which is transferred to the falling part with a positive pressure, using a compensation circuit consisting of various elements that allow a flow of fluid to be sent to the energy generator with a positive thrust consisting of the sum of the forces generated in the various phases of the path followed by the fluid.

The characteristics of the plant according to the present invention will result from the following detailed description of its components and subsequently of the operating principle of the plant itself, referring to the attached drawing which shows in schematic form both the constitution of the plant and its operation. Each component of the system can be made with the elements and materials most suitable for the purpose, the diagram below being given purely by way of example for a full understanding of the invention. The numbers and letters listed correspond to those shown on the diagram.

1) Large fluid reservoir, located on the surface of the ground, where the volumes and surfaces are determined by the needs of the system itself. This basin can be of an artificial nature, but also natural, such as a lake, river, sea, stream etc. , where the levels, volumes, surfaces will be constant or little variable, this part will always be the part at a lower level than the other parts that make up the plant itself, such as the sea surface level understood as zero. This basin, in addition to being natural, can be of the artificial type built with construction materials, such as concrete, steel, plastic, glass, etc. The characteristics of the materials must have a low coefficient of friction to facilitate the movement of fluids, in any case this basin must have technical construction characteristics such as to allow resistance to the stresses of the forces acting externally and internally to it. This basin can be of an open or totally closed nature, this choice will be dictated by the needs of the type of system itself, whether it works with natural pressure, or with artificial pressure.

2) Fluid level in the reserve (1) and in the exchange chamber (7).

3) Gas found in the reserve (1), in the exchange chamber (7), and also in the Lung Gas Chamber (17).

4) (4 a1) Inlet pipe in the reserve (1) and (4 a2) outlet pipe in the reserve (1). These pipes must be arranged below the level of the fluid in the reservoir (1) and are used for different applications.

C) Tap to check the level (2) in the reserve (1).

D) Large tap (gate valve) located above the cover of the reserve (1), and is used to balance the mass of fluid in the system in natural balance when the system works under natural pressures.

E) Tap used to inject pressure into the reserve (1); this pressure is then transferred to the cardinal points of the system such as in the exchange chamber (7) and in the lung gas chamber (17)

R) Sleeve used to apply measuring instruments such as the barometer.

5) Fluid rising pipe - This constructive element is sized according to the operating needs and the quantity of fluid to be moved through it, the geometric shapes of this part may vary according to the technical and operating requirements. This part can be made with different types of material, suitably with a low coefficient of fluid friction, and extremely low fluid flow rates, construction characteristics that are resistant to the forces at play inside and outside this part.

6) Lower gate used to fill the system.

7) Exchange chamber located in the upper part of the system; this part requires absolute isolation from the external conditions and that its constructive geometric characteristics make it resistant to the internal and external forces at play. The surfaces and volumes of this part as well as its geometric shapes are to be evaluated according to the quantities of fluid or gas present in it and which determine the efficiency of the system.

8) Tap for venting of liquid or gaseous fluids inside the exchange chamber (7).

9) Sleeve with tap for attachments of measuring instruments which will indicate the forces inside it and any negative or positive jolts.

10) Fluid compensation reserve, which is connected under the exchange chamber (7), always positioned parallel to the rising pipe (5) and at the same height; this part serves to feed the suction of the pump (12) keeping the fluid level constant. The variation in the upper part of this triggers a recall of fluid and it must be borne in mind that the geometric shape and the surfaces can facilitate this recall of fluid, benefiting from the yield of the system, the dimensions must take into account the flow velocities and the quantities of fluid output, the construction materials of this part will have to withstand the internal and external forces involved, the geometric shapes will be evaluated according to the performance.

11) Suction pipe, this component connected to the pumping system is totally immersed in the previous compensation reserve component (10), the position of this component is parallel to the part in which it is immersed, its dimensions are proportional to the exchange quantities; this part will have a higher internal flow rate. This tube can be geometrically constructed with shapes that make suction easier, the materials to be used require low resistance to the flow of fluids and good insulation from the external fluid.

12) Pump or fluid exchange system, this part of the system can use any type of pump or fluid exchange system as long as the suction creates values equal to the negative pressure values found in the exchange chamber when it is in static condition (before starting the pump); the equality of these pressures facilitates the exchange of fluid from suction to discharge in positive pressure, the pump discharge is connected in an isolated way from influences due to the release compensator; this part that accompanies the flow of the fluid is suitably conical in shape, in which the flow is unified into a bundle of suitable dimensions for the output quantities and to increase the flow velocities and increase the dynamic dragging; the construction materials of this exchange or pumping system are recommended with low friction coefficients.

13) Tap for venting the section between the suction pipe (11) and the compensation chamber (14), is placed to ensure the venting of air or gas inside the exchange section.

14) Compensation chamber that serves as a point of exchange for pressure, volumes, density between pump outlet and release compensator that when the dynamic process of acceleration of the fluid is triggered, the gas contained in the upper part that exceeds the fluid level is compressed or decompressed in such a way that the pump discharges freely and that the flow of fluid is free in its own fall and can take the benefits of gravity and acceleration induced by the pump; these components require geometries, volumes and surfaces suitable for the quantity of fluid at the outlet, the construction characteristics must withstand external and internal forces.

15) Cock for venting the gas and liquid in the compensation chamber (14).

16) Accompanying cone which is positioned perpendicular above the collector of the duct (18) almost to the bottom of the compensation chamber (14), which serves to accompany the fluid in a laminar way, leaving the pump.

17) Lung gas chamber, is a gas reserve that serves to ensure the release of the fluid in free fall, thanks to the difference in density between the fluid and the gas itself, creating the space necessary for the advancement of the fluid exiting the pump.

18) Collector of the pipe that goes downwards which is located under the conical accompanying pipe (16) of the pump outlet (12), serves to facilitate the collection of the fluid and then continues in the pipe (19) towards the turbine (26 ) down. This collector can be conical, and also cylindrical, but conical is preferred for better efficiency, and must be made with rigid material and possibly coated with material with a low coefficient of friction.

19) Conduit that serves to accompany the fluid downwards in the direction of the turbine (26), it can be of different shapes such as square, cylindrical and conical, preferably conical for better efficiency, as the material must be rigid and possibly coated with materials with low coefficient of friction.

20) Gate valve of the pipeline (19) which is used to make regular filling of the system and to ensure that during filling there is no air or gas inside the section.

21) Pipe connecting the reserve (1) at the bottom, with the gas chamber (17) at the top, with the respective taps (21a) and (21b).

22) Cock with sleeve to check and command or measure the flow of gas or air in the gas chamber (17)

23) Pipe connecting the compensation chamber 14 with the lung gas chamber (17).

24) Tap used to vent the gas or fluid in the turbine chamber (25).

25) Turbine chamber.

26) Turbine, which can be of different types such as Kaplan, Peltron, Francis and so on.

27) Discharge cone in reserve (1).

A description of the operating principle of the system now follows with reference to its components listed above.

The system is filled with fluids regularly through its tap inlet (6) specially built for this operation. The closure of the tap (20) above the turbine chamber (25) is ensured and, once the system fluids have been put at the correct level, using the special taps for regulating the fluids, such as tap (C) for the level of the large reserve (1), tap (8) for the exchange chamber (7), tap (13) for bleeding the suction pipe (11) and pump (12), and the exchange chamber with tap (15) during filling , respecting the levels (2) already pre-established and foreseen for operation, it is ensured that all the parts where the fluid flows do not have conditions that hinder the correct operating cycle, and once the system is loaded regularly, the procedure for commissioning.

By opening the large gate valve (D) located above the reservoir (1), all the mass of the fluid in the rising pipe (5) brings the exchange chamber (7) to negative pressure and consequently all the fluid in the system, where all the pressure values in the system are conditioned by atmospheric pressure (static condition).

According to these values, the fluid in the exchange chamber (7) has the highest negative pressure value. Starting from the top downwards there is a pressure situation where the values found in the exchange chamber (7) are based on the height of the system itself, the pressure value starting from the exchange chamber (7) upwards towards the large reserve (1) will go from a negative pressure up to a pressure equal to that of the large reserve (1) itself, i.e. atmospheric pressure.

The same pressure value is also found in the suction pipe (11), which is totally immersed in the fluid contained in the compensation reservoir (10) which communicates at the same level as the large reservoir (1) starting on the basis of the pressure of the large reservoir ( 1) up to its maximum height which is under negative pressure minus (-).

The same pressure value also occurs in the descent column starting from the pump (12), with negative pressure then down into the compensation chamber (14) and column (19) which towards the turbine (26) which is at the pressure of the large reserves (1). (From point 12 pressure minus, to point 26 atmospheric pressure).

All these positive or possibly negative pressure values are present when the pump exchanger 12 is not in operation (Static Condition)

To create a situation in which one can take advantage of the dynamic movement of the fluid, the pump (12) must be activated which creates a pressure condition from the large reserve (1) to the inlet of the pump (12) through the suction pipe 11 negative dynamics, equal to the negative static pressure condition previously created statically in the exchange chamber (7).

At the same time, the fluid at the pump outlet (12) assumes a positive pressure condition, which divides the influence of the negative pressure at the inlet of the pump (12) from the positive at the outlet, and consequently the pressure condition of the descent column changes. from point 12 it pumps up to point 26 turbine, including the pressure condition of the lung gas chamber (17). The quantity of outgoing flow and the pressure condition created by the pump 12 must be compensated with the accompanying cone (16) which extends almost as far as the collecting cone (16) perpendicular to the column 19, with the compensation chamber (14) and the lung gas chamber (17) which connect via the duct (28) and is located above the plant level. In these conditions it is possible that the outlet pressures of the pump (12) are recovered thanks to the fall of the accelerating fluid from point 12 to point 26 in conjunction with the gravitational effect also added positively to the fall of the fluid that comes out of the cone outlet (27) falling directly into the large reserve (1) and then repeating the system cycle again.

The operation of the system with induced pressure is now described.

The process of filling the system with fluid is the same as indicated above.

The operating process is also the same except that in this case there is induced positive pressure. By inducing pressure from the tap (E) into the large reserve (1) depending on the physical construction of the system, there is no limit in injecting pressure.

The only difference is that in the system as above there are different positive values, in the large reserve (1) and in the lung gas chamber (17) there is the maximum positive pressure, while in the exchange chamber (7) there is pressure lower, from that of the large reserve (1).

The large reserve 1 and the buffer gas chamber 17 have the same pressure value because they are connected by means of the duct 21 which is controlled with the respective taps (21 a) and (21 b).

In this case, to drain the fluid into the large reserve (1), pipes with diameters and surfaces calculated according to the pressure induced in the system are used.

Having thus described in detail the plant as well as its operation, it must be understood that only one of its preferred embodiments has been illustrated here, but that numerous variations, modifications, additions and / or replacements of parts can be made to the individual components, without for this to depart from its fundamental principles and without even going out of its scope of protection, as it is also defined in the attached claims.

Claims (4)

Claims 1) System for the recovery of energy from fluids, comprising a fluid reserve (1) at the lowest level of the system, an exchange chamber (7), a compensation reserve (10), an exchange pump (12) , a compensation chamber (14), a gas buffer chamber (17), and a turbine (26), all connected to each other in a closed circuit, in such a way that a flow of fluid with a positive thrust constituted by the sum of the forces generated in the various phases of the path followed by the fluid. 2) Plant according to claim 1, in which said exchange chamber (7) is located in the upper part of the plant, to which the fluid arrives from the reserve (1) through a rising pipe (5), said fluid coming out of a compensation reserve pipe (10) to rise through a suction pipe (11) coaxial to it, feeding the exchange pump (12) in depression. 3) Plant according to claim 1 and 2, in which said compensation chamber (14) serves as a pressure, volume, density exchange point between the fluid leaving the pump (14) through an accompanying cone (16) and the fluid coming from the lung gas chamber (17) to send the resulting fluid through a collector (18) to a duct (19) which feeds it to the turbine (26). 4) Plant according to the preceding claims, in which the fluid used by the turbine (26) present in the turbine chamber (25) is returned to cycle in the reserve (1) through an exhaust cone (27).