APPARATUS FOR AN IMPROVED POWER SYSTEM

Abstract

A wind and water power generation system is presented. The wind and power generation system has a roof mounted gutter system with an internally integrated turbine. The internally integrated turbine has a connection to an externally positioned wind scope. Thus, the rain run-off causes the internal turbine to rotate to generate power and the external wind scope allows the internal turbine to turn without rain.

Claims

1. A wind and water power generation system, the power generation system comprising: a roof mounted gutter system with an internally integrated turbine having a connection to an externally positioned wind scope, wherein the externally position wind scope having a wind guider, wherein the wind guider directs a wind into a top of a drain, wherein when a rain run-off occurs the internal turbine being configured to rotate to generated power and the internal internally integrated turbine being configured to rotate by the rain run-off by the externally positioned wind scope.

2. The wind and water generation system of claim 1, further comprising a cone and one or more wind guides, where the one or more wind guides direct wind funneled through the cone to the externally positioned wind scope.

3. The wind and water generation system of claim 1, wherein the internally integrated turbine is a water turbine.

4. The wind and water generation system of claim 1, wherein the external scope is a wind turbine.

5. The wind and water generation system of claim 1, wherein the internally integrated turbine has one or more turbine blades.

6. The wind and water generation system of claim 5, wherein the one or more turbine blades shape is trapezoidal.

7. The wind and generation system of claim 1, further comprising one or more batteries, where the one or more batteries are coupled to the internally integrated turbine to capture energy.

8. The wind and water generation system of claim 7, wherein the batteries are coupled to the internally integrated turbine by an electrical wire.

9. The wind and water generation system of claim 1, wherein the rain run-off is directed to at least one drain pipe.

10. The wind and water generation system of claim 9, wherein the internally integrated turbine is coupled to the at least one drain pipe.

11. The wind and water generation system of claim 9, wherein the at least one drain pipe is for water.

12. The wind and water generation system of claim 9, wherein the at least one drain pipe is for wind.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0011] FIG. 1 is a view of an exemplary wind and water energy generation system.

[0012] FIG. 2 is an exemplary view of the wind and water energy generation system of FIG. 1.

DETAILED DESCRIPTION

[0013] Reference will now be made in detail to the present preferred embodiments, examples of which are illustrated in the accompanying drawings. All terms in the plural shall also be taken as singular and vice-versa. Further, any reference to he shall also be applicable to she and vice-versa.

[0014] Referring now to FIG. 1, a wind and water energy generation system 200 for generating power is shown. The wind and water energy generation system 200 is useful for capturing wind and producing electrical current which can be stored. The wind and water energy generation system 100 can be adapted for a house or other building.

[0015] The exemplary wind and water energy generation system 100 has a drain pipe 108, wind catcher 202, and one or more batteries 218. The one or more batteries 218 are useful for storing the energy or electricity captured by the wind and water energy generation system 100.

[0016] The wind catcher 102 catches the wind. The wind catcher 102 has a wind cone 202 and a tail fin 204. The tail fin 204 is useful for guiding the wind catcher 102 to a direction in which the wind is coming from. The wind cone 202 receives the wind.

[0017] The wind catcher 102 is coupled to the drain pipe 108. The drain pipe 108 provides a medium for directing and harnessing the wind power. The drain pipe has at least one ball bearing 104 and at least one internal wind turbine 210.

[0018] The one or more ball bearings 104 are useful in providing a smoothness the rotation of the wind catcher 102. The one or more ball bearing 104 are coupled on a first side 101 of the wind catcher 102 and coupled to the top 107 of the drain pipe 108. The ball bearings 104 are contained in a circular housing 105.

[0019] The internal turbine 210 is couple on an inside (not shown) of the drain pipe 108 a first location 109. The internal turbine 210 is in direct line with the wind in the drain pipe 108 and generates electrical energy from the wind.

[0020] Moving now to FIG. 2, an exemplary wind and water energy generation system is presented. The energy generation system 200 is able to use the rain water to produce energy and when it is not raining, to use the wind to generate energy.

[0021] A roof (not shown) has at least one gutter 106 and at least one drain pipe 108 that is used to whisk away the water from the roof during a rain. The wind and water energy generation system 200 is coupled to the at least one gutter 106 and the at least one drain pipe 108.

[0022] The wind and water energy generation system 200 has the wind cone 202 for receiving wind generate by nature. The wind cone can be made of any material such as aluminum, plastic, vinyl, etc. The exemplary wind cone 202 is conical in shape but any shape that allows the wind to be caught and directed will be acceptable as a wind cone 202.

[0023] Coupled to the wind cone 202 is a wind guider 204. The wind guider may be made of any material such as vinyl, aluminum, metal, plastic, etc. The wind guider 204 receives the wind pulled thru the wind cone 202 and directs the wind 205 towards an external turbine 206. The external turbine 206 has blades and the blades rotate to generate wind into the drain pipe 108.

[0024] The wind and water energy generation system 200 also has an internal turbine 210. The internal turbine 210 is used to generate energy from either water or wind directed through the drain pipe 108. The internal turbine has a paddle 212. The paddle 212 is rotated by the wind or water in the drain pipe 108.

[0025] The paddle 212 is coupled to a pole 214. The pole 214 is rotated by the paddle 212. The pole 214 has internal turbine blades 216. The internal turbine blades 216 are turned to generate energy by the pole 214. The pole 214 coupled to the internal turbine blades 216 collects the energy produced by the internal turbine blades 216 and is coupled to at least one battery 218 by a wire 220. The wire 220 may be any type of wire that can carry electrical energy such as a coax cable, an electrical wire, etc.

[0026] The battery 218 is any type of battery that can store energy and then be used to provide energy to another outlet. The battery shown is a car battery, but may be an industrial battery, a series of batteries, etc.

[0027] The features described with respect to one embodiment may be applied to other embodiments or combined with or interchanged with the features of other embodiments, as appropriate, without departing from the scope of the present invention.

[0028] Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims.