Description:FORM 2
The Patent Act 1970
(39 of 1970)
COMPLETE SPECIFICATION
(Section 10; rule 13)
Title of Invention
COMPACT INTEGRATED SYSTEM FOR GENERATION OF RENEWABLE GREEN ENERGY

APPLICANT:
ENVIRO RECYCLEAN PRIVATE LIMITED
House No. 17, Govind Bhavan,
1st Floor, S V Road, Malad (W),
Mumbai, Mumbai City, Maharashtra, India, 400064
F
The following specification particularly describes the nature of the invention and the manner in which it is performed

FIELD OF THE INVENTION
[001] The present invention relates to a compact integrated system for generation of renewable green energy that is environment friendly. More particularly the system utilizes renewable resources to produce green energy and provides a means to efficiently consume the renewable resources in a convenient manner.
BACKGROUND OF THE INVENTION
[002] Renewable energy sources, such as wind and solar energy, hold immense potential to transform our energy systems and reduce our dependence on fossil fuels. These sources harness natural elements and offer a cleaner and more sustainable alternative to traditional forms of energy generation. However, despite their numerous advantages, the widespread utilization of wind and solar energy faces certain challenges and limitations. Understanding these problems is essential for addressing them effectively and accelerating the transition towards a greener and more renewable energy future. There are several reasons why renewable energy sources such as wind and solar energy are not used as extensively as conventional energy sources. Here are some of the problems associated with their widespread adoption:
[003] One of the main challenges with wind and solar energy is their intermittent nature. Their generation depends on weather conditions, such as sunlight and wind availability. This intermittency makes it difficult to match the electricity supply with the constantly changing demand, which can lead to issues with grid stability.
[004] The intermittent nature of renewable energy sources highlights the need for efficient energy storage systems. Energy storage technologies, such as batteries, are essential for storing excess energy during periods of high generation and releasing it during times of low generation. However, the cost and scalability of energy storage systems still pose challenges to their widespread implementation.
[005] The integration of renewable energy sources into the existing energy infrastructure can be complex and costly. For example, wind turbines and solar panels require specific installation sites and extensive transmission networks to deliver electricity to consumers. The development of such infrastructure requires significant investments and planning.
[006] While the costs of renewable energy technologies have decreased over the years, they still face challenges in terms of cost competitiveness compared to conventional energy sources. Fossil fuels have benefited from long-established infrastructure and economies of scale, making them relatively inexpensive. However, as renewable technologies continue to advance and economies of scale improve, the cost gap is gradually narrowing.
[007] Despite these challenges, there is a growing recognition of the importance of transitioning to renewable energy sources due to their environmental benefits and the need to address climate change. Continued advancements in technology, supportive policies, and increased investments are helping to overcome these problems and drive the broader utilization of wind and solar energy.
[008] US8330296B2 describes an environmentally friendly combination of wind turbine and solar energy collectors are provided. Solar photovoltaic material is secured to the surface of the wind turbine tower to augment the power generation capability of a wind turbine. The wind turbine energy output is controlled by a power management program and may be combined with the solar power energy that is generated from solar photovoltaic material covering the surface area of the body of the wind turbine's tower through an electrical subsystem associated with the wind turbine, an electrical subsystem associated with the solar energy collection system, and a combination subsystem conductively coupled both the electrical subsystem associated with the wind turbine and the electrical subsystem associated with the solar energy collection system.
[009] US9587631B2 describes an apparatus having a plurality of counter rotating Solar/wind collection panels which are mounted on respective counter rotating collars. The orientation of the panels is controlled by servo motors. Torque from the counter rotating collars is combined by a set of gears with the combined torque driving rotation of a power collecting column. Torque from the power collecting column is transmitted to a power transfer column through gears in a gearbox and then to a flywheel which has an armature as part of a motor generator whereby mechanical energy can be converted to electrical energy with the motor generator. Solar energy from the PV panels is routed to a power conditioning unit which is also connected to the motor generator.
[0010] US20130106193A1 discloses a wind-capture assembly comprising: i) one or more wind sails evenly distributed circumferentially around a central axis thereof; and ii) a solar-energy capture means on an outer surface of the wind-capture assembly; and c) a turbine assembly comprising an anchoring base, an electrical generator and an output shaft; the wind-capture assembly rotatably mounted on the output shaft and coupled thereto; the hybrid wind-solar energy device configured to convert energy harnessed by the wind capture assembly to electrical energy, wherein: interaction of the one or more wind sails with wind induces rotation of the wind-capture assembly and turbine assembly around the central axis; and the outer surface of the wind capture assembly is directly exposed to sunlight throughout daylight hours.
[0011] IN202311018784 discloses a system comprises of solar PV panel, small wind system, three-phase rectifier converter to convert AC power from wind turbine to DC power, DC-DC boost power converter, DC-DC buck converter, PI controller and Maximum Power Point Tracking (MPPT) controller. The MPPT controller is modeled and simulated using a DC-DC converter for hybrid system to increase the power output. The system of Present invention is uniquely designed to get the maximum power form each source at different variation of the parameters at the input wind speed and solar radiation.
[0012] The patents cited demonstrate the necessity of constructing a system that not only addresses the challenges of large space installation but also aligns with urban environments while maximizing energy generation and ensuring cost-effectiveness. The cited documents also do not address the issue to generate green energy during low sun light and low wind speed days along with having a very high efficiency to generate green energy. Therefore, the current invention effectively fulfills the requirement and overcomes the loopholes in the prior art.
OBJECT OF THE INVENTION
[0013] The objective of the present invention is to provide a compact integrated system for generation of renewable green energy from renewable sources including solar and wind energy.

[0014] Yet another objective of the present invention is to provide a compact integrated system that efficiently generates electricity by utilizing wind and solar energy concurrently.

[0015] Yet another object of the present invention is to provide a compact integrated system that efficiently generates electricity without requiring large space of land particularly delivering the urban energy requirements.

[0016] Yet another objective of the present invention is to keep the central axis of the system in a static position that provides support to top concentrated solar panel section to utilize solar energy.

[0017] Yet another objective of the present invention is to provide a cost effective, efficient, and portable system that generate electrical energy from the renewable sources.

[0018] Yet another objective of the present invention is to reduce the friction in the system to give high number of revolutions per minutes (RPM) thus generate high energy from renewable sources.

[0019] Yet another objective of the present invention is to provide a means that aids in generation of twice the energy output from rotating wing at the same number of revolutions per minute (RPM).

[0020] Yet another object of the present invention is to reduce the cost of operation along with minimizing the cost of maintenance of the green energy generation system.

[0021] Yet another object of the present invention is to reduce the cost of infrastructure and initial project setup in order to meet the urban energy needs along with reducing the risk of bird life during the process of green energy generation.

SUMMARY OF THE INVENTION
[0022] Within the scope of this application, it is expressly envisaged that the various aspects, embodiments, examples and alternatives set out in the preceding paragraphs, in the claims and/or in the following description and drawings, and in particular the individual features thereof, may be taken independently or in any combination. Features described in connection with one embodiment are applicable to all embodiments, unless such features are incompatible.
[0023] The present invention generally relates to a compact integrated system for generation of renewable green energy from renewable sources without utilizing much space for the installation of the system thereby provides energy in an environment friendly manner along with saving the cost and installation time of the user.
[0024] In an aspect of the present invention, a compact integrated system for generation of renewable green energy involves an integrated system having a top concentrated solar panel (CSP) section, central vertical axis wind turbines (VAWT) section at the middle, a bottom gear box and rotor dual converter (GBRDC) section, top CSP section includes solar platform attached with solar section frame tilted at 45o angle on both right and left side, attached at all four sides to capture sunlight throughout the day from any angle of the sun path, solar section frame capture highest intensity of sunlight at varied angle of sun for maximum energy production, refractors, reflect sunlight towards solar panels, magnifying glass cover refract maximum sunrays to solar panels to facilitate generation of electricity.
[0025] In an aspect of the present invention, the wind energy is produced by the central VAWT section and bottom gear box rotor and dual converter (GBRDC) section, multiple wings are attached with wing handle(s) fixed on central axis, with the flow of air wings rotate causing rotation of multiple gear(s) associated with the central axis, rotation of wings causes rotation of magnetic bearings(s) which rotates multiple gears, the rotation of magnetic bearing(s) and gear(s) generates kinetic energy, the kinetic energy is transferred to wind energy inside the generator associated with the rotor(s), rotor(s) are associated with the dual convertor, the dual convertor attached with the system converts solar energy and wind energy for the distribution.
[0026] Various objects, features, aspects and advantages of the inventive subject matter will become more apparent from the following detailed description of preferred embodiments, along with the accompanying drawing figures in which like numerals represent like components.
BRIEF DESCRIPTION OF THE DRAWINGS:
[0027] The illustrated embodiments of the subject matter will be understood by reference to the drawings, wherein like parts are designated by like numerals throughout. The following description is intended only by way of example, and simply illustrates certain selected embodiments of devices, systems, and methods that are consistent with the subject matter of present invention.
Figure 1: Isometric view of integrated system
Figure 2: Front view of hollow central axis with top concentrated solar panel (CSP) section and bottom gear box rotor dual converter (GBRDC) section
Figure 3: Side view of the integrated system
Figure 4: Front view of central axis
Figure 5 a: Shows pitch angle, rotor radius, and chord length of wings
Figure 5 b: Front view of integrated system showing rotor height
Figure 6: Structure of a wing
Figure 7: Shows the aerodynamics of the integrated system
Figure 8: Front view of gear box rotor dual converter section
DETAILED DESCRIPTION OF THE INVENTION
[0028] The following is a detailed description of embodiments of the disclosure depicted in the accompanying drawings. The embodiments are in such detail as to clearly communicate the disclosure. However, the amount of detail offered is not intended to limit the anticipated variations of embodiments. On the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit, and scope of the present disclosure as defined by the appended claims.
[0029] In the following description, numerous specific details are set forth in order to provide a thorough understanding of embodiments of the present invention. It will be apparent to one skilled in the art that embodiments of the present invention may be practiced without some of these specific details. Embodiments of this disclosure relates to the field of speech analysis and, more specifically, to systems and methods for enactment of visual speech using neural network. Also addresses challenges related to background noise, voice denoising, lip movements, and spectrogram processing, resulting in improved speech quality and intelligibility in various visual settings.
[0030] If the specification states a component or feature “may”, “can”, “could”, or “might” be included or have a characteristic, that particular component or feature is not required to be included or have the characteristic.
[0031] As used in the description herein and throughout the claims that follow, the meaning of “a,” “an,” and “the” includes plural reference unless the context clearly dictates otherwise. Also, as used in the description herein, the meaning of “in” includes “in” and “on” unless the context clearly dictates otherwise.
[0032] The present invention relates to a compact integrated system for generation of renewable green energy from renewable source without causing much loss of energy during the process and generating high energy under varied environmental conditions including low wind speed and cloudy weather thereby provides an efficient, environment friendly alternative to fulfill urban energy needs.
Construction of the system
[0033] A cover 205 preferably a glass cover 205 functions to cover the panels 203. The panels 203 used are solar panels 203 and reflectors 204 primarily refract, redirect rays towards the solar panels 203, which facilitates generation of electrical energy from solar energy. The glass cover 205 used may include but not limited to magnifying glass, specular mirror strategically aligned to increase / magnify intensity of sun rays to the solar panel(s) 203 to increase the productivity and efficiency. The angle of mirror is preferably 45o. Multiple reflectors 204 attached internally with the solar section frame 202. The frame 202 is placed above the attachment means 206 which is rectangular frame 206, the frame 202 is placed such that it redirects maximum sun rays towards the panel(s) 203. The reflectors 204 reflects maximum sunrays towards the solar panel(s) 203 to produce maximum solar energy from the solar panel(s) 203. The shape of glass cover 205 is such that the reflectors 204 redirects the maximum sunrays towards the solar panel(s) 203 during the entire day. The glass cover 205 is coated with a layer of colorless, anti-dust and water repellent material to increase the durability and efficiency of the integrated system 100 to produce green energy from renewable source.
[0034] Solar panel(s) 203 facilities the generation of electrical energy from the solar energy. When solar panels 203 are exposed to photons of sunlight (very small packets of energy) it releases electrons and produces an electric charge. This photo Voltic charge creates an electric current (direct current). The direct current is captured by the wirings inside the solar panel, this direct current is transferred to alternating current inside the system 100 and distributed. The panel(s) 203 are solar panels 203 which may include but not limited to monocrystalline solar panel(s) which are metallurgical silicon made by silicon dioxide and carbon.
[0035] A central axis 305 is placed vertically, the central axis 305 is attached internally with the top CSP solar section 200. The central axis 305 remains in static position to efficiently hold the top CSP section 200. The central axis 305 is preferable made up of a stainless-steel material, provide strength to keep the central axis static and reduce the 70% unnecessary weight from the wings 303 thus, ensure higher efficiency of electricity generation at the same speed of wind. Multiple wing(s) 303 are attached with wing handles 301a, 301b, 301c, 301d fixed with the central axis 305. The wings 303 rotates with the flow of wind and the material used for the wings 303 are preferably fiber material to avoid deposition of dust and damage from water.
[0036] Multiple bearing(s) 304a, 304b associated with the central axis 305 at upper and lower end of the central axis 305. The bearing(s) 304a, 304b are magnetic bearings 304a, 304b that aids in rotation of wings 303 to generate the electricity. Thus, the bearing(s) 304a, 304b facilitates the rotation of the system 100. The rotor(s) 402a, 402b are attached with multiple gears 401a, 401b, 401c, 401d, 401e. The gears 401a, 401b, 401c, 401d, 401e are associated with the magnetic bearings(s) 304a, 304b. The rotor(s) 402a, 402b are associated with a generator 405 to transfer the kinetic energy from the gear(s) 401a, 401b, 401c, 401d, 401e and the bearing(s) 304a, 304b to the rotor(s) 402a, 402b so as to generate electrical energy thereby generates wind energy. The magnetic bearing(s) 304a, 304b are preferably permanent magnetic bearings. The magnetic bearings 304a, 304b is oil free bearing system that utilizes electromagnetic forces to maintain the relative position of the rotor 402a, 402b to a stationary component (stator). An advanced electronic control system adjusts these electromagnetic forces in response to forces generated from the rotation of wings 303. The Rotor(s) 402a, 402b are associated with a generator 405 to transfer the kinetic energy obtained by the rotation of the gear(s) 401a, 401b, 401c, 401d, 401e and bearing(s) 304a, 304b to the rotor(s) 402a, 402b. The transfer of kinetic energy results in generation of electrical energy thereby generates wind energy. The magnetic bearings 304a, 304b are preferably permanent magnetic bearings that facilitate frictionless rotation of the wings 303 at a low wind speed to provide 250% higher efficiency, the permanent magnetic bearings 304a, 304b provides a shelf life of 25 to 30 years.
[0037] A dual convertor 403 associated with the gear(s) 401a, 401b, 401c, 401d, 401e. The convertor 403 converts the solar energy obtained from the solar panel 203 and wind energy obtained from the kinetic energy from the rotation of the wing(s) 303 for distribution. A control panel 406 is attached at bottom GBRDC section 400 monitor performance, production of energy, distribution of energy by the system 100 to generate green energy from renewable sources.
[0038] A control panel 406 is an electrical control panel 406, a metallic box that allows the user to operate the system 100 mechanically by using electricity. The control panel 406 monitor performance, production of energy, distribution of energy by the system 100.
[0039] Sensor(s) 404 used are preferably speed sensors 404. The speed sensors 404 uses the variable reluctance magnetic sensing principle, where a cylindrical permanent magnetic core with a coil wire wound around it, mounted on the stationary hub carrier, axle casing or back plate, produces a magnetic field. The magnetic field produced overlaps the rotating excitor ring. The control panel functions to monitor and control speed of said wings 303 below 100 revolutions per minute. If the speed of the rotation of wings 303 goes above 100 round per minutes, the system 100 shuts down. Thus ensures the safety of the product from damage due to high wind speed. The speed of rotation of the wings 303 is monitored below 100 revolutions per minute by multiple of sensors 404 fixed inside the GBRDC section 400, the sensors 404 are preferably speed sensor(s) that maintains the speed of the wings 303 below 100 revolutions per minute to generate electricity even at low wind speed.
[0039] Figure 7 shows the speed controller 407 and aerodynamics 408 of the system 100. Figure 6 shows various angle(s) and edge(s) of wing(s) 303 including, angle of attack 303a, leading edge radius 303b, mean camber line 303c, trailing edge 303d, trailing edge angle 303e, chord 303f, chord line 303g, leading edge 303h. Figure 5 shows chord length 306, pitch angle 307 is 90o, rotor radius 308 is 8 inch and rotor height is 402c
[0040] A dual convertor 403 includes one convertor in conduction and another convertor is blocked. So, at a time one convertor operates and the reactor is not required between convertors. When the converter is working it acts as a rectifier and supply the load current. When both the convertors are in circulating current a current limiting reactor is connected between the DC terminals of both the convertors. The dual convertor 403 converts the solar energy obtained from the solar panel 203 and wind energy obtained from the kinetic energy as a result of rotation of the wing(s) 303 for the distribution.
[0041] Gear(s) 401a, 401b, 401c, 401d, 401e are toothed cylindrical/ roller shaped components that meshes with another toothed cylindrical element to transmit power from one shaft to another. The principal use is to obtain different torque and speed ratios or to change the direction of the driving and driven shaft.
[0041] Wing separator(s) 302a, 302b are attached with the magnetic bearing(s) 304a, 304b where the wing separator 302a, 302b functions to hold the multiple wing(s) 303. Multiple handle(s) 301a, 301b, 301c, 301d are attached with the central axis 305 and holds the wings 303 at upper and lower edge. The wings 303 rotate with the flow of air causing rotation of the magnetic bearing(s) 304a, 304b to generate the kinetic energy.
Dimensions of various sections
[0042] The dimensions of various sections of the system 100 includes 6 feet 1 inch. The top CSP section 200 is 1 foot in height, 2 feet 5 inches in width. The reflector(s) 204 are 8 inches in length. The solar panel(s) 203 covers 1 foot 6 inches in length. The central VAWT section 300 is 4 feet 1 inch in height. The wing(s) 303 are 3 feet 6 inches long. The distance between solar platform 201 and wing handle 301a, 301b is 5 inches. The bottom GBRDC section 400 is 1 foot in height.
Working of the system
[0043] A body convenient to hold and place in open areas to generate green electricity from the wind and solar energy in order to meet the higher energy requirement of urban areas of the country. The body is an integrated system 100 especially designed to generate green energy from the renewable sources particularly wind and solar energy. The integrated system 100 is placed in an open land to get sufficient access of sunrays and wind. The integrated system 100 includes a top Concentrated Solar Panel (CSP) section 200 connected to a central Vertical Axis Wind Turbine (VAWT) section 300 fixed to an upper end of a bottom Gear Box Rotor Dual Converter (GBRDC) section 400. The lower end of the bottom GBRDC section 400 is placed on the ground.
[0044] The top CSP section 200 capture the solar energy, enhance the intensity of the sun rays and reflect the maximum sunrays. The reflection of maximum radiations received from the sun towards the desire angle allows the generation of maximum solar energy by the top CSP section 200.
[0045] As the sun rays reaches a magnifying glass cover 205, the magnifying glass cover 205 intensify the radiation(s) of sun, thus by magnifying the sun rays maximum number of sun rays reach towards the solar panel(s) 203. The magnifying glass cover 205 intensify the radiations throughout the day to get maximum energy output. The refraction of maximum number of sun rays towards the solar panel(s) 203 results in generation of higher solar energy even during cloudy days when the intensity of sun rays is relatively less. The magnifying glass cover 205 is dome shaped. The dome shape of the magnifying glass cover 205 is 2 feet 5 inches in width and ensures that the maximum sunrays are magnified which are then refracted towards the solar panel 203 to generate maximum solar energy from solar panel(s) 203.
[0046] A frame 202 which is a solar section frame 202 provides support to the magnifying glass cover 205 and a reflector(s) 204 where the magnifying glass cover 205 is placed above the solar section frame 202 and the reflector(s) 204 are attached internally with the solar section frame 202. The solar section frame 202 is placed above the rectangular frame 206, the solar section frame 202 is placed such that it redirects maximum sun rays towards solar panel(s) 203. The solar section frame 202 at an angle of 45o at all four sides capture sunlight throughout the day from any angle of the sun path. The reflectors 204 reflects maximum sunrays towards the solar panel(s) 203 to produce maximum solar energy from the solar panel(s) 203. The reflector(s) 204 are placed at the internal side of the cover 205. The cover is glass cover 205. The glass cover 205 is associated with solar section frame 202 functions to intensify the sun rays by refracting maximum rays towards the solar panel 203 to provide maximum energy production during cloudy days, the glass cover 205 is dome shaped to enhance the intensity of sunlight. The solar section frame 202 is placed above a rectangular frame 206 and the solar panel(s) 203 thus, solar section frame 202 functions to cover the rectangular frame 206 and the solar panel 203. Multiple solar panels are affixed inside the rectangular frame 206. The solar section frame 202 is placed in a tilted position, the solar section frame 202 is tilted externally at right and left edge at an angle of 40o - 50o preferably 45o in order to redirect maximum sun rays towards the solar panels 203. The solar section frame 202 is dome shaped at external end connected with tilted right and left edge(s). The solar section frame has tilted right and left edges and is 1feet 6 inches in width.
[0047] The tilted right and left edges of solar section frame 202 at an angle of 45o ensures that the reflectors 204 are attached at an angle of 45o thus the reflectors 204 reflect maximum sunrays towards the solar panel 203 to facilitate the generation of electrical energy from the solar energy. The radiations are reflected throughout the day as the solar section frame 202 covers all four sides of the top CSP section 200.
[0048] The integrated system 100 includes a central vertical axis wind turbine (VAWT) section 300 the upper portion is attached with a platform 201. The platform 201 is a solar platform 201. The platform 201 which is a solar platform 201 is present at the base of the CSP section 200. The platform 201 is associated with an attachment means 206 connected with the central VAWT section 300. The lower portion of VAWT section 300 is attached with the upper end of the bottom gear box rotor dual converter (GBRDC) section 400. The bottom gear box rotor dual converter (GBRDC) section 400 is placed on the ground. The panel(s) 203 which are solar panel(s) 203 are attached with an attachment means 206. The attachment means 206 is a rectangular frame 206 it is connected at an upper portion of the central VAWT section 300. The panel(s) 203 facilitate generation of electrical energy from the solar energy. The electrical energy produced by the solar panel(s) 203 is transferred to bottom gear box rotor dual (GBRD) convertor section 400 via central axis 305.
[0049] The vertical axis wind turbine (VAWT) section 300 includes a central axis 305, the central axis is placed in a vertical manner. The central axis 305 is internally attached with top CSP solar section 200. The central axis 305 remains in static position. The static position of the central axis 305 efficiently holds top CSP solar section 200. The central axis 305 is hollow 305a and allow internal electrical wiring. The central axis 305 is attached with multiple magnetic bearing(s) 304a, 304b. The magnetic bearing(s) 304a, 304b ensure the rotation of multiple wings 303 attached with the central axis 305.
[0050] The handles 301a, 301b, 301c, 301d are attached with the central axis 305 holds wings 303 are attached by means of multiple. The handles 301a, 301b, 301c, 301d holds wings 303 at the upper and lower edge of central axis 305. As the wind flow(s) the movement of wind causes the rotation of wings 303, the magnetic bearings 304a, 304b attached with the central axis aids the rotation of wings 303 to generate electricity. The wings 303 are attached via handles 301a, 301b, 301c, 301d to the central axis 305. The flow of air rotates gear(s) 401a, 401b, 401c, 401d, 401e to generate kinetic energy. The kinetic energy is converted to electrical energy by rotor(s) 402a, 402b which are associated with the generator 405 to generate wind energy. Multiple magnetic bearing(s) 304a, 304b associated with the central axis 305 at upper and lower end of the central axis 305 wherein the magnetic bearing(s) 304a, 304b functions to rotate the system 100.
[0051] The magnetic bearings 304a, 304b are associated with multiple wing separator 302a, 302b. The wing separators 302a, 302b are attached with the magnetic bearing(s) 304a, 304b, the wing separators holds multiple wings 303 that rotates via rotation of the magnetic bearings 304a, 304b. The magnetic bearings 304a, 304b are attached with multiple gears 401a, 401b, 401c, 401d, 401e. With the rotation of wings magnetic bearings 304a, 304b rotates which in return are associated with multiple gears 401a, 401b, 401c, 401d, 401e. The rotation of magnetic bearings 304a, 304b results in rotation of multiple gears 401a, 401b, 401c, 401d, 401e the gears are associated with multiple rotors 402a, 402b. The rotors 402a, 402b are associated with a generator 405.
[0052] The rotation of magnetic bearings 304a, 304b, gears 401a, 401b, 401c, 401d, 401e generates kinetic energy which is transferred to wind energy thereby generates wind energy. The transfer of kinetic energy to wind energy takes place inside the generator 405 which is associated with the rotor 402a, 402b. A dual convertor 403 placed adjacent to gears 401a, 401b, 401c, 401d, 401e aids in conversion of solar energy obtained from the solar panels 203 and wind energy from the rotation of wings 303 for the distribution.
[0053] A control panel 406 associated with the bottom GBRDC section 400 monitor the performance, production of energy, distribution of energy by the system 100. The energy production and distribution is displayed on control panel 406. The control panel 406 monitor the performance of the system 100. The system 100 generates green electricity simultaneously from solar and wind energy. The GBRDC section 400 includes multiple speed sensors 404. The speed sensors 404 monitor the speed of the rotation of the wings 303 below 100 revolutions per minute. When the speed of the air is high and is causing the rotation of wings at a speed more than 100 revolutions per minute, the speed sensors 404 will send the signal to the control panel to shut off the system 100. The closing of the system above the speed of 100 revolutions per minute ensures the durability of the system even in all weather conditions.
[0054] While the foregoing describes various embodiments of the invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof. The scope of the invention is determined by the claims that follow. The invention is not limited to the described embodiments, versions or examples, which are comprised to enable a person having ordinary skill in the art to make and use the invention when combined with information and knowledge available to the person having ordinary skill in the art.
, Claims:WE CLAIM:

1. An integrated system to produce green energy from renewable sources, comprising of:

a) an integrated system 100 includes a top Concentrated Solar Panel (CSP) section 200 connected to a central Vertical Axis Wind Turbine (VAWT) section 300 fixed to an upper end of a bottom Gear Box Rotor Dual Converter (GBRDC) section 400, wherein a lower end of said bottom GBRDC section 400 is placed on ground;

b) a platform 201 present at the base of said CSP section 200, wherein said platform 201 is associated with an attachment means 206 connected with said central VAWT section 300;

c) a plurality of panel(s) 203 attached with said attachment means 206, wherein said panel(s) 203 facilitate generation of electrical energy from the solar energy;

d) a frame 202 placed above said attachment means 206 wherein, said frame 202 is placed such that it redirects maximum sun rays towards said panel(s) 203;

e) a cover 205 associated with said frame 202 functions to intensify the sun rays by refracting maximum rays towards said panel 203 to provide maximum energy production during cloudy days, said cover 205 is dome shaped to enhance the intensity of sunlight;

f) a plurality of reflectors 204 attached internally with said frame 202 wherein, said reflectors 204 reflects maximum sunrays towards said panel(s) 203 to produce maximum solar energy from said panel(s) 203;

g) a central axis 305 placed vertically, attached internally with top CSP solar section 200 wherein, said central axis 305 remains in static position to efficiently hold said top CSP section 200;

h) a plurality of bearing(s) 304a, 304b associated with said central axis 305 at upper and lower end of said central axis 305 wherein said bearing(s) 304a, 304b facilitates the rotation of said system 100;

i) a plurality of rotor(s) 402a, 402b attached with a plurality of gears 401a, 401b, 401c, 401d, 401e associated with said bearings(s) 304a, 304b wherein said rotor(s) 402a, 402b are associated with a generator 405 to transfer said kinetic energy from said gear(s) 401a, 401b, 401c, 401d, 401e and said bearing(s) 304a, 304b to said rotor(s) 402a, 402b to generate electrical energy thereby generates wind energy;

j) a dual convertor 403 associated with said gear(s) 401a, 401b, 401c, 401d, 401e wherein said convertor 403 converts said solar energy obtained from said panel 203 and wind energy obtained from said kinetic energy from said rotation of said wing(s) 303 for distribution; and

k) a control panel 406 attached at bottom GBRDC section 400 monitor performance, production of energy, distribution of energy by said system 100 to generate green energy from renewable sources.

2. The integrated system to produce green energy from renewable sources as claimed in claim 1 wherein, said bearing(s) 304a, 304b are magnetic bearing(s) 304a, 304b that aids in rotation of wings 303 to generate electricity.

3. The integrated system to produce green energy from renewable sources as claimed in claim 1 wherein, said panel(s) 203 are solar panel(s) 203 which may include but not limited to monocrystalline solar panel(s) which are metallurgical silicon made by silicon dioxide and carbon.

4. The integrated system to produce green energy from renewable sources as claimed in claim 1, wherein a plurality of wing separator(s) 302a, 302b are attached with said magnetic bearing(s) 304a, 304b said wing separator 302a, 302b functions to hold a plurality of wing(s) 303.

5. The integrated system to produce green energy from renewable sources as claimed in claim 1 wherein, a plurality of handles 301a, 301b, 301c, 301d are attached with said central axis 305 holds said wings 303 at upper and lower edge, wherein said wings 303 rotate with the flow of air causing rotation of said bearing(s) 304a, 304b to generate the kinetic energy.

6. The integrated system to produce green energy from renewable sources as claimed in claim 1 wherein, said platform 201 is a solar platform 201, said attachment means 206 is a rectangular frame 206 connected at an upper portion of said central VAWT section 300, said central axis 305 is hollow 305a for internal electrical wiring.

7. The integrated system to produce green energy from renewable sources as claimed in claim 1 & 6 wherein, said frame 202 is solar section frame 202, said solar section frame 202 functions to cover said rectangular frame 206 and said solar panel 203.

8. The integrated system to produce green energy from renewable sources as claimed in claim 1 & 7 wherein, said solar section frame 202 is placed in a tilted position, said solar section frame 202 is tilted externally at right and left edge at an angle of 40o - 50o, said solar section frame 202 is dome shaped at external end connected with tilted right and left edge(s).

9. The integrated system to produce green energy from renewable sources as claimed in claim 1, wherein, speed of rotation of said wings 303 is monitored below 100 revolutions per minute by plurality of sensors 404 fixed inside said GBRDC section 400, said sensors 404 preferably speed sensor(s) maintains said speed of said wings 303 below 100 revolutions per minute to generate electricity even at low wind speed, said system 100 shuts down as revolution of wings 303 goes above 100 revolutions per minute to ensure durability of said system 100 in all weather conditions.

10. The integrated system to produce green energy from renewable sources as claimed in claim 1 wherein, said cover 205 is a glass cover 205 which may include but not limited to magnifying glass, specular mirror strategically aligned at an angle of preferably 45o to increase / magnify intensity of sunlight to said solar panel(s) 203.

11. The integrated system to produce green energy from renewable sources as claimed in claim 1 wherein, said plurality of magnetic bearing(s) 304a, 304b are preferably permanent magnetic bearings that facilitate frictionless rotation of said wings 303 at a low wind speed to provide 250% higher efficiency, said permanent magnetic bearings 304a, 304b provides a shelf life of 25 to 30 years.

12. The integrated system to produce green energy from renewable sources as claimed in claim 1 wherein, said glass cover 205 is coated with a layer of colorless, anti-dust and water repellent material to increase the durability and efficiency of said system 100.

13. The integrated system to produce green energy from renewable sources as claimed in claim 1 wherein said wing(s) 303 are preferably fiber material, said central axis 305 is preferably made up of a stainless-steel material, said central axis 305 which is static, reduces 70% unnecessary weight from said wings 303 and ensures higher efficiency at same wind speed.

14. The process to generate electricity via integrated system by using renewable sources includes:

a) placing integrated system 100 in an open land to get sufficient access of sunrays and wind;
b) refracting sunrays towards solar panel(s) 203 by means of a magnifying glass cover 205;
c) reflecting sunrays towards a solar panel 203 by means of a reflector(s) 204 placed internally to said glass cover 205;
d) transferring electrical energy produced by solar panel(s) 203 to bottom gear box rotor dual (GBRD) converter section 400 via central axis 305;
e) rotating wing(s) due to flow of air rotates gear(s) 401a, 401b, 401c, 401d, 401e to generate kinetic energy;
f) converting kinetic energy to electrical energy by rotor(s) associated with generator 405 to generate wind energy;
g) displaying energy production, energy distribution on control panel 406;
h) monitoring performance of said system 100 with the use of control panel 406 for displaying energy production and energy distribution; and
i) Generating green electricity simultaneously using solar and wind energy.

Dated 28th day of November, 2023