ITMO20100022A1 - METHOD AND SYSTEM OF TRANSFORMATION OF A HYDRAULIC FLOW IN ELECTRIC ENERGY BY ROAD VEHICLES - Google Patents

Description

DESCRIPTION

METHOD AND SYSTEM OF TRANSFORMATION OF A HYDRAULIC FLOW INTO ELECTRIC ENERGY BY ROAD VEHICLES

FIELD OF APPLICATION OF THE INVENTION

The present invention is part of the field of waste energy recovery systems and more precisely it concerns an apparatus and a method for obtaining electrical energy from the circulation of road vehicles.

The need is felt to obtain electricity with alternative systems in order to reduce emissions and production costs.

EXPOSURE AND ADVANTAGES OF THE FOUND

The purpose of the present invention is to make available to the art a system for the self-production of electrical energy by means of the use of motorized vehicles.

In essence, the method involves self-producing said energy by passing vehicles in defined portions of the carriageway equipped with compression and pumping units for a fluid circulating in a closed circuit defined between at least two tanks, one of which has a fixed volumetric capacity while the other with variable volumetric capacity between two limit conditions of full / empty; during said transition from full to empty the tank with variable volumetric capacity controls a kinematic mechanism for transforming a linear to rotary motion connected to a current generator by means of interposed multiplication means.

The apparatus that carries out the above comprises a multiplicity of compression means, such as pumps, placed in suitable seats on or inside the carriageway and suitable for being controlled in compression, or crushing, by vehicles in transit, and in expansion by spring return means. Following the compression action, said pumping means are connected to a distributor to which they send a determined quantity of fluid; said distributor is connected to one or more tanks with variable volumetric capacity, in the example defined by the internal chamber of a hydraulic cylinder: the fluid sent under pressure by the pumping means increases, by raising it, the hydraulic cylinder and the filling limit is reached ( maximum height) a limiting valve is opened so that the fluid flows out towards an accumulation tank and the tank with variable volumetric capacity slowly descends, under the action of its own weight or additional masses, dragging with it a rack which is assembled with a gear and multiplier means which rotate a shaft connected in turn to a low voltage current generator. An inverter allows you to raise the voltage. The whole apparatus is controlled by a PLC which manages the opening and closing phases of the opening valves of the variable capacity tanks. The fixed capacity tank allows the necessary quantity of fluid to be reintroduced into the compression means described above following the restoration of the initial condition given by the return springs.

The advantage obtained from the present invention is that of producing energy at very low cost, because the normal circulation of motor vehicles is exploited.

Said objects and advantages are all achieved by the method and system for transforming a hydraulic flow into electrical energy by means of road vehicles, object of the present invention, which is characterized by the provisions of the appended claims.

BRIEF DESCRIPTION OF THE FIGURES

This and other characteristics will become more evident from the following description of some embodiments illustrated, purely by way of non-limiting example in the accompanying drawing tables.

Figure 1: an elevation view of the system in question Figure 1A: a top view of the access ramp, with a plurality of pumping means and the diagram of the hydraulic circuit

Figure 2: Figure 1A again with the details more evident,

Figure 3: in detail two compression means according to two of their limit configurations, i.e. rest and maximum compression,

Figure 4: a sectioned detail of the deceleration ramp with the plurality of compression means

Figure 5: detail of the lower part of the storage tanks, variable and fixed, with PLC controlling the outflow regulation valves,

Figure 6: a detail of the tanks or accumulators with variable capacity,

Figure 7: a detail of a variable capacity tank, with motion transformation kinematics and apparatus for converting mechanical energy into electrical energy.

DESCRIPTION OF THE INVENTION

With particular reference to the figures, the system suitable for producing electrical energy according to the method in question is illustrated.

Basically, the system produces electricity following the activation of a closed hydraulic circuit which loads one or more hydraulic cylinders in an accumulation phase and subsequently transforms said accumulated energy according to a linear / rotary transformation process. to a current generator from which the desired effect will be obtained.

The aforementioned actuation of the hydraulic circuit takes place economically thanks to the passage of motor vehicles in defined portions of the carriageway, where compression and pumping means or units are located, forming part of the circuit itself.

In other words, the compression means or units are driven by crushing by the vehicle in transit above them, so as to establish a flow of fluid moving between at least two tanks, of which the first is for storage, with a fixed volumetric capacity, and a another expansion, with variable volumetric capacity (between two limit conditions of full / empty).

EXAMPLE OF REALIZATION OF THE FIND

With particular reference to Figure 1, 1 indicates as a whole an apparatus for transforming the hydraulic energy of a closed circuit into electrical energy, by activating a motor vehicle 16 while traveling on the street.

It should be noted immediately that in the example the system uses an artificial platform or bump 2, of the type commonly used to slow down the vehicles 16, however, without going out of the required protection area, the system can be incorporated flush with the carriageway or at the same level. of the road surface.

In the case described, a platform 2 or hump or deceleration ramp is placed and fixed integral with the carriageway. The ramp 2 is formed by two up and down ramps so as to raise the vehicle 16 that passes and between said two ramps there are placed a plurality of rows 3 of equidistant units 4 for the compression and pumping of a hydraulic circuit defined by the means 13 , 14, 20, 17, 11 and 4 same.

The rows 3 are adjacent to each other, however they can also be placed spaced apart without however departing from the scope of protection of the invention. Naturally each row 3 is of such width as to allow the passage of a motor vehicle or a motor vehicle, thus occupying the width of at least one carriageway.

Preferably, the means 4 of two adjacent rows 3, according to the top view of Figures 1 and 2, are positioned staggered so as to allow a safe crushing action by the wheels 15; however, without however departing from the scope of protection of the invention, the means 4 of two adjacent rows 3 can be placed equidistant and in line with the adjacent ones.

Each of the means 4 is protected at the top by at least one metal plate 2B and by a coating 2A preferably in plastic material covering the ramp, so as to hide and protect the rows 3 and the compression means 4.

The compression means 4 perform the function of pumps in the hydraulic circuit so as to establish a unidirectional flow which from a storage tank 17, with a fixed volumetric capacity, leads to one or more cylinders 20, that is to say, accumulators with variable capacity between two conditions full / empty limit and during said transition from full to empty, the return stroke down due to gravity and the opening of a suitable regulating valve 18, the cylinder 20 drags with it a rack 25 so as to inducing a motion of transformation from linear to rotary being connected to a reel 26 and other multipliers 27 integral with a current generator 28. Said spool 26 is a unidirectional primary gear, which is activated in rotation only in one direction of actuation of the rack 25.

With particular reference also to Figures 3 and 4, a compression unit 4 is described in detail, consisting of two sliders 4A and 4B, of different section, integral with each other.

The 4A slider is much larger than the 4B.

Said sliders 4A and 4B, preferably cylindrical, are located and can slide vertically in corresponding seats of the body 3 which forms the row of the aforementioned ramp 2.

Sealing gaskets 5 and 6 are placed on said sliders 4A and 4B.

Unit 4 is kept in rest position by two or more springs 7, acting between body 3 and slider 4A.

For said rest position the slider 4B defines an expansion chamber 8A; as a result of the downward thrust imparted by the weight of the vehicle in transit, the wheel 15 in the example, the sliders 4A and 4B descend, reducing the chamber 8A which is now brought to a smaller volume, indicated in the figure with 8B.

This volume variation of the internal chamber produces a fluid flow: thanks to suitable non-return valves 9 and 10 on each unit 4 a flow is established which, in compression, sends the fluid in the circuit 12 towards a distributor 13, while in expansion (ie restoration of the initial configuration of the chamber 8A following the thrust of the springs 7) said fluid is recalled through the unidirectional valve 9 connected to the inlet conduit 11 connected to an accumulation and collection tank 17, with fixed capacity.

From what has been said, it follows that the means or units 4 are adapted to be controlled in compression, or crushing, by the vehicles in transit, and in expansion by spring return means.

Following the compression action, the means 4 pump, through the ducts 12, the fluid to the distributor 13, sending each quantity of fluid corresponding to a precise volume (difference between volume 8B and volume 8A). Said distributor 13 is an integral part of the circuit) and has the function of collecting the quantity of pumped fluid from all units 4 and sending the fluid under pressure to one or more outlets 14, or delivery ducts to the aforementioned one or more tanks. 20 with variable volumetric capacity (specifically an internal chamber of a hydraulic cylinder).

The ducts 14 rise inside the rod to come out inside the chamber of the cylinder 20 itself defined by the liner 21 and by the piston 23.

The fluid compressed by the pumping means 4 causes the hydraulic cylinder 20 to expand; once the filling limit has been reached (the maximum height in this case), a regulation valve 18 on the cylinder is opened and the weight of the piston 23 or of the liner 21 induces the regulated outflow of fluid towards the aforementioned storage tank 17 . During the descent, the variable volumetric capacity tank, under the action of its own weight or additional masses, drags with it the integral rack 25 which rotates the pinion or sprocket 26 and multiplier means 27 which rotate a connected shaft in turn to a low voltage current generator 28.

An inverter 29 raises the voltage to acceptable values required by the market.

The system and the apparatus are controlled by one or more PLC 19 which manage the different phases, first of all the valves 18 for the flow of the fluid from the tanks 20 with variable capacity towards the storage tank 17.

Eventually further shut-off valves, not shown, can be placed on the pipes 14 in order to intercept and / or regulate their passage towards the tanks 20.

The PLC 19 also acquires information through a series of proximity sensors 24 placed at the ends of the tanks 20 so as to send information about the achievement of their condition of minimum or maximum volumetric capacity.

The fixed capacity tank 17 allows the necessary quantity of fluid to be reintroduced into the compression means following the restoration of the initial condition given by the return springs.

Claims (1)

RIVE N DICAZIO N I 1. Method for the production of electricity characterized by the fact that it provides for the self-production of said energy through the passage of motor vehicles in defined portions of the carriageway equipped with compression and pumping units for a fluid circulating in a closed circuit defined between at least two tanks, one with fixed volumetric capacity while the other with variable volumetric capacity between two limit conditions of full / empty; during said transition from full to empty the tank with variable volumetric capacity controls a kinematic mechanism for transforming a linear to rotary motion connected to a current generator by means of interposed multiplication means. . System (1) for transforming a hydraulic flow into electrical energy, said hydraulic circuit defined by means (13, 14, 20, 17, 11, 12, 4) suitable for defining a closed circuit, characterized in that said hydraulic circuit comprises means or units (4) which can be activated in compression by the weight of a motor vehicle (16) during its march on the road; said means (4) being adapted to perform the function of pumps of the hydraulic circuit so as to establish a unidirectional flow from a storage tank (17) with fixed volumetric capacity, towards one or more accumulators (20) with variable capacity; said accumulators (20) defining two limit conditions of full / empty so that during said transition from full to empty, following the opening of at least one regulating valve (18), said accumulator or tank (20) drags with it © an integral rack (25) so as to induce a motion of transformation from linear to rotary being connected to a reel (26) and other multipliers (27) integral with a current generator (28). 3. System (1) according to claim 2, characterized by the fact that said compression unit (4) comprises two sliders (4A) and (4B) of different section, integral with each other and sliding vertically in corresponding seats of a body (3) and is kept in rest position by springs (7), acting between the body (3) and the slider (4A); for said rest position the cursor (4B) defines a chamber (8A) which is reduced as a result of the downward thrust, imparted by the weight of the vehicle in transit; said volume variation of the internal chamber produces a flow of fluid which sends the fluid to a distributor (13), an integral part of the circuit, connected in turn to said one or more tanks (20) with volumetric capacity. 4. System, according to claim 2, characterized in that it is controlled by one or more PLCs (19) which manage the different phases, including the valves for the outflow of the fluid from the tanks (20) with variable capacity; said PLC (19) also acquires information through a series of sensors (24) near the tanks (20) so as to send information about the achievement of their condition of minimum or maximum volumetric capacity. 5. System, according to claim 2, characterized in that said tank (17), with fixed capacity, allows to reintroduce the necessary quantity of fluid into the compression means (4) following the restoration of the initial condition given by the springs ( 7) of recall. 6. Use of motorized vehicles for the self-production of reusable energy, especially in electricity, according to the provisions of the preceding claims.