BRPI0802828A2 - sliding hydraulic turbine - Google Patents

Abstract

The SLIDING HYDRAULIC TURBINE brings together characteristics peculiar to the generating faculty by capturing a volume of water in its natural, continuous course and storing it, and then transforming it into mechanical energy and then into electrical energy. Designed by principles governed by the laws of physics and fluid mechanics, in a floating and modular way, allowing its use isolated or agmphate, without any aggression to the ecosystem.

Description

"SLIDING HYDRAULIC TURBINE"

The present patent refers to a sliding hydraulic turbine that has the function of generating electric energy, using existing water resources in their natural form, thus providing the preservation of the watercourse, its bed and its margins, while also preserving the ecosystem. .

In order to solve the inconveniences resulting from aggressive hydroelectric installations of the ecosystem, a turbine was developed, through which the generation of electric energy does not depend on fixed or flooding, thus providing greater efficiency directly using the potential hydraulic energy of the river. in its course on the turbine rotor.

The sliding hydraulic turbine consists of housings, baffle plates, spacer modules, cooling water reservoirs, sealing caps, suction chambers, rotors, flexible blades with different shapes and lengths, elastic couplings, low-power electric generators, frequency converters, panels. water pumps, gate valve gates, central gate, rubber sheet, sliding bearings, fixed bearings, hydraulic units, hydraulic unit rooms, hydraulic cylinders, transverse cylindrical base, fish stop pipe, flow controls, level, vibration, rotation, temperature, indoor and outdoor cameras, presence sensors, speakers, sirens, computerized control room, own software for each satellite controlled installation, room for transformer and auxiliary generator motor, prefabricated reinforced concrete modules , comc access stairs orrimão, walkway with railing, these form in line in the sentidotransverse of the river a set of turbines.

The sliding hydraulic turbine can be better understood by the following detailed description, in line with the attached figures, where:

FIGURE 1 is a front view of the six turbine assembly. FIGURE 2 is a top view of the six turbine assembly.

FIGURE 3 is a section of the turbine assembly, side bearing and aquatic passageway.

FIGURE 4 is a side view of the central fixed bearing and side spacer module with electrical cable outlet.

FIGURE 5 is a side view of the control room between the central fixed bearings and central turbine gate.

FIGURE 6 is a section of the rotor turbine with flat blade fixed rotor blades.

FIGURE 7 is a section of the turbine with rotor and U-shaped flexible blades.

FIGURE 8 is a view of the flat bar fixed flexible shovel.

FIGURE 9 is a view of the "U" profile fixed flexible shovel.

FIGURE 10 is a section of the turbine spacer module with mounted low speed electric generator.

FIGURE 11 is an enlarged view of the assembly of the spacer modules, housing, turbine rotor.

FIGURE 12 is a side view of the low-power electric generator.

FIGURE 13 is an enlarged detail of the mounting of the polar magnetic plates, permanent magnets and silicon steel key sections of the low-speed electric generator.

FIGURE 14 is a front view of the low speed generator with assembly of its components.

FIGURE 15 is an enlarged detail of the mounting of the silicon steel blade blades.

With reference to figure (1) it can be observed the housing (1) has structural function and to protect the turbine rotor installed inside against contained external elements and moving inside the river. Spacer modules (2) house the low speed electric generators (3), directly coupled to the turbine rotors with elastic couplings (4). The baffle (5) regulates the height of the water column formed in front of the turbines through the actuation of the hydraulic cylinders (6) driven simultaneously by the corresponding hydraulic central. Directly coupled to the ends of the rods of the hydraulic cylinders (7), the sliding bearings (8) support and slide on the side fixed bearings (9) and on the central fixed bearings (10), the assemblies formed by three turbines. In the lower part of the carcasses (1), gate valves (11) are installed, which regulate the openings of the river water flow, used for the propulsion of the rotor of each turbine, and are individually actuated through hydraulic cylinders (12). Central gate (13) with opening and closing actuation made by hydraulic cylinder (14), which transfers all the weight of the gate to the metal beam (36) where it is mounted. All hydraulic cylinders are driven by hydraulic units (15) installed within rooms (16), accessed via stairs (17) and (18).

The hydraulic oil used to drive the cylinders is driven by the hydraulic piping (19). Stairs (20) and (21) allow access to control rails (22) and (23) of the transformer. Inside the transformer room (23) an auxiliary generator motor is installed to supply electric power when there is no external power supply. On the upper part of each three-turbine assembly is assembled a prefabricated beam (24) with reinforced concrete that connects the lateral fixed bearing (9) to the central fixed bearing (10) forming a gantry, is used as a walkway for access to all systems. turbine control system. On either side of the beam (24) is mounted railing (25) for protection. Between the side and center fixed bearings, rods (26) made of carbon round bars are installed, used for leveling the fixed and counter-bearing bearings. The support structure of the turbine system is composed of a transverse cylindrical base (27), formed by prefabricated reinforced concrete modules, where openings (28) allow the access of aquatic life to its interior, is supported and fixed on the transverse beams. (29) elongitudinal (30). Fish and other seraquatic pipes are composed of prefabricated tubular modules (31) with reinforced concrete, vertical inspection tubes (32) and horizontal outlet tubes (33).

Referring to Figure (2) one can see the tubular modules (31), vertical inspection tubes (32), horizontal outlet pipes (33), all prefabricated with reinforced concrete, mounted along the river banks and interconnected to transverse cylindrical base (27), these allow the transposition of fish and other aquatic beings to the water reservoir formed in front of the turbines, continuing the course. Housings (1), spacer modules (2), sliding bearings (8), hydraulic cylinders (6) actuating the gate-type gate, central gate (13), opening and closing operation via hydraulic cylinder (14), access (17) and (18) the rooms (16) of the hydraulic units (15), stairs (20) and (21) access to the control and transformer rooms, suction chambers (34).

With reference to figure (3) it is possible to observe the pipe for fish passage, it is composed of prefabricated tubular modules (31) with reinforced concrete, they are mounted to the river banks with inclination of 4 ° with respect to the horizontal plane. By not aligning the center lines of the modules, inverted steps can be formed to reduce the speed and pressure of the internal water flow to the pipe. Inspection vertical tubes (32) allow access to the interior, prefabricated reinforced concrete horizontal outlet tubes (33) allow the exiting of fish and other aquatic beings to complete the transposition of the turbine system. Together they make up the pipe for the passage of fish and other aquatic beings. The transverse cylindrical base (27) and the fixed side bearing (9) are mounted and fixed on the transverse (29) and longitudinal (30) beams, where the hydraulic cylinder (7) is used for raising and lowering the turbine assembly, coupled to the sliding bearing (8). The railing (25) is installed on either side of the beam (24), stairs (17) and (18) to access the room (16) of the hydraulic unit (15).

Referring to figure (4), the central fixed bearing (10) prefabricated with reinforced concrete can be seen. It has a support track (35) on its upper side with an inclination of 70 ° from the horizontal plane which facilitates the sliding of all equipment supported by the hydraulic cylinder (7). The transverse cylindrical base (27) is formed by joining prefabricated reinforced concrete modules of different shapes and fittings, supported and fixed on the transverse beam (29) and longitudinal (30). They have the function of supporting the horizontal load imposed by the volume of river water and the vertical loads of the equipment mounted on them, keeping them stable. Electrical cables (42) run from the side spacer module and are interconnected to the frequency converters installed inside the electrical panel, later connected to the transformer.

With reference to figure (5) one can see the central gate (13), made of galvanized or non-galvanized carbon steel plates, is mounted between and supported on the central fixed bearings (10), where the opening and closing movement is made through the hydraulic cylinder (14) fixed to the metal beam (36).

Referring to figure 6, the housing (1), rotor (37), flexible blades (38) made of rubber or similar materials are arranged equidistantly at their outer perimeter. Valve type gate (11) is designed with dimensions proportional to the turbine housing where it will be mounted, fixed side rails (39) act as a guide, it is driven through the hydraulic cylinder (12) which allows its opening or closing according to the need of flow regulation. passing water for rotor drive, metal shield (40) of hydraulic cylinder (12). Rubber sheet (41) mounted on the upper end of the baffle plate to protect the equipment mounted on the upper part of the spacer modules and casings that make up the turbine system. Suction chamber (34) made of carbon-galvanized or non-galvanized steel plates reinforcements arranged in their length, fixed to the shell and ribbed to the lateral spacers by screwed connections, sealing rubber (43), supported on the transverse cylindrical base (27).

Referring to figure (7), one can see the housing (1), the rotor (37), flexible blades (42), made of rubber or similar materials, arranged equidistantly at their outer perimeter. Gate type gate (11) is designed with dimensions proportional to the turbine housing where it will be mounted, fixed side rails (39) act as a guide, is driven by hydraulic cylinder (12) which allows its opening or closing according to the need of flow regulation. 'Passing water for impeller propulsion, metallic protection (40) of hydraulic cylinder (12). Rubber sheet (41) mounted on the upper end of the baffle plate to protect the equipment mounted on the top of the spacer modules and casings that make up the turbine system. Suction chamber (34) made of galvanized or non-galvanized carbon steel sheets, with reinforcements arranged in their length, fixed to the housing and ribbed to the side spacers through bolted connections, sealing rubber (43), supported by the transverse cylindrical base (27 ).

Referring to figure (8), the shape of the flexible blade (38) and the fixing with screws on flat bars welded to the rotor side can be observed.

Referring to figure (9), the shape of the flexible blade (42) and the fastening with bolts on "U" profile welded to the rotor side can be seen.

Referring to figure (10), the deflection plate (5) made of galvanized or non-galvanized carbon steel plates, with reinforcements arranged in their length, can be fixed by welding over the whole assembly or with joints (44), rubber seal (45), fixed to the outer part of the entire structure. The opening of the baffle plate is made by hydraulic cylinders (6) which, when actuated, increase the volume of water facing the set of turbines, as a consequence the increase of the water gap. The spacer module (2) is made of galvanized or non-galvanized carbon plates, has a circular shape and dimensions that vary depending on the loads applied to it. It has in the upper access access with rectangular caps (46) and another circular (47), with holes in all the contour that allow their fixation through stainless steel screws, after receiving vulcanization for a perfect seal.

Inside the spacer module is mounted on the basal metal structure (48) the low speed electric generator (3), water pump (49) which supplies water from the reservoir (8) for cooling the outer ring of the low speed electric generator housing. The reservoir water (8) is cooled using the river water at room temperature in contact with the outer surface plate of the spacer. A rubber damper (50) or similar material is installed on the underside of the spacer module. Its function is to adjust the height of the rotor blades according to the operational need with the aid of the hydraulic cylinder (7). Transverse cylindrical base (27), openings (28) for access thereto, prefabricated reinforced concrete modular plates (51) installed before and after the turbine assembly regulate the flow of water in and out of the turbines.

Referring to figure (11), one can see the housing (1), which is designed with dimensions that vary according to the available hydraulic power.

The plate thicknesses and diameters are previously defined as a function of the stresses that will be submitted and the calculated generation power. It is manufactured with galvanized or non-galvanized carbon steel plates. Its purpose is to protect the rotor (37) inside it, against external elements contained. and moving within the river. Spacer module (2) houses the low speed electric generator (3) mounted on the metal base frame (48) and directly coupled to the shaft end (52) of the motor (37) with elastic coupling (4). The rotor (37) is made of galvanized or non-galvanized carbon steel plates with a diameter and length that would depend on the amount of electricity generation desired.

The ends of the shaft (52) are mounted on hubs with sealed bearings and may be with graphite gaskets, seals or hydraulic seals.

The rotor (37) has on its outside diameter flexible blades (38) made of rubber or similar materials, are fixed throughout the rotor length spaced equidistantly on the perimeter. They have flexibility contrary to the direction of rotation of the rotor, which allows the passage of stones, sand, gravel, among other elements contained and moving within the river.

The flexible blades receive the hydraulic pressure of the river transforming it into mechanical energy, later with the rotor movement of the rotor (37), in electric energy. On the spacer modules (2) and the housing (1) are mounted the baffle plate (5), driven by hydraulic cylinders (6), openings (28) for access to the interior of the transverse cylindrical base are arranged below the spacer modules (2) between the prefabricated reinforced concrete plates (51).

Referring to figure (12), one can observe the low speed electric generator, cylindrical housing structure (53), the silicon steel blade sections (54) are mounted on its internal diameter, the rotor (55) outer diameter is mounted on the outside diameter. assembled polar (56) and permanent magnet (57) magnetic plates.

Referring to figure (13), one can observe the sectors of silicon-steel blades (54) mounted on the inside diameter of the cylindrical housing structure (53), polar magnetic plate (56) fixed on the outside diameter of the rotor (55) through threaded bolts (58), permanent magnet (57), copper rod (59), steel pin (60), copper rod connection ring (61), key (62), brass strip ( 63), flanged tubes (64) for outgoing water from the maze (65) external to the housing (53).

Referring to figure (14), one can see the cylindrical shell structure (53), silicon steel blade sections (54), flanged tube (64), labyrinth (65), tie rod (66), clamping (67), copper coil (68), polar magnetic plates (56), permanent magnet (57), crossbar (58), rotor (55), shaft (69), key (70), bearings (71) , housing cover (72), closure covers (73), plugs (74), seals (75), oil level sight (76), internal air revolution blades (77).

Referring to Figure 15, one can see the cylindrical shell structure 53, silicon steel blade sections 54, rotor 55, polar magnetic plate 56, permanent magnet 57, crossbar ( 58), copper rod (59), steel pin (60), copper rod connection ring (61), brass strips (63), tie rod (66), non-magnetic clamping ring (67) , phase insulated copper coil (68), closure caps (73), flanged tube (64), maze (65), internal air revolution blades (77).

Claims (6)

1. The SLIDING HYDRAULIC TURBINE is an equipment for the generation of electricity that, through the use of existing water resources in its natural form, produces electricity for 24 hours of operation, according to results obtained in practical tests, first using several prototypes that confirmed the veracity of the method and subsequently Objectively designed, your entire operating system is automated, with rotating, vibration, temperature, deflux, and water level control sensors, monitored remotely over multiple cameras positioned at strategic points. The turbine has a valve-type gate on the underside of the housing to control the flow of water that exerts hydraulic pressure on the flexible blades disposed on the outer perimeter of the rotor, initiating the rotation movement and consequent production of electrical energy. The turbine, being designed in modules, allows us various mounting combinations. Its rotation produces a natural oxygenation in water caused by flexible paddles, thus providing more life to microorganisms and other aquatic species. Its constitution consists of: housing (1), spacer modules (2), low-power electric generator (3), elastic couplings (4), baffle plate (5), hydraulic cylinders (7), sliding bearings (8), fixed bearings seals (9), central fixed bearings (10), gate type gate (11), hydraulic cylinders (12), central gate (13), hydraulic cylinder (14), hydraulic units (15), rooms (16), stairs ( 17) and (18), hydraulic piping (19), ladders (20) and (21), control rooms (22) and transformer (23), beam (24), railing (25), tie rods (26), transverse cylindrical base (27), openings (28), transverse beams (29), longitudinal beams (30), tubular modules (31), vertical inspection tubes (32), horizontal outlet pipes (33), suction chambers ( 34), support track (35), metal beam (36), rotor (37), flexible blades (38) and (42), fixed side rails (39), metal shield (40), rubber sheet (41) sealing rubber (43), hinges (44), rubber seals (45), rectangular cover (46), cap (47), metal base (48), water pump (49), shock absorber (50), modular plates (51), shaft (52), generator housing (53), silicon steel blades (54), rotor (55), polar magnetic plates (56), permanent magnets (57), transverse rod (58), copper bar (59), steel pin (60), connection ring (61), key (62), brass strips (63), flanged tubes (64), maze (65), tie rods (66), clamping ring (67), copper coil (68), shaft (69), key (70), bearings (71), bearing housing cover (72), closure covers (73), plugs (74), seals (75), level gauge (76), internal air revolution blades (77).