get a stick n a propeller n fix them the way that they make electricity is by moving an magnet inside coils of wire so attach a magnet to the inside of the propeller and wrap coils of wire around the magnet but with 1mm of space between. attach both ends of the wire to an applience e.g a light and it will work
The height of a wind turbine has no impact on the turbine's output wattage. The factors that effect the watts produced are: * The efficiency of turbine design (this is at most 59%) * the density of the air * the radius of the turbine (that is, the length of each fin) * the velocity of the wind passing through the turbine An 80 ft tall turbine would presumably have a fin length (that is, turbine radius) of at most 30 ft. Thus, at sea level on a 59 degree (F) day, in an 8 m/s (18mi/h) wind, with the most efficient turbine design possible, you would generate approximately 15.4 Kilowatts. See: http://en.wikipedia.org/wiki/Wind_turbine#Potential_turbine_power
The inventor of the wind turbine was Charles F. Brush in 1888.
A wind turbine is a form of electric generation. On top of a tall pole there is a turbine (fan thing) and the wind spins it around. The turbine is connected to a motor which generates an electromagnetic flow from the motion.
i too need this design
A wind turbines uses the wind to power an electricity generator.
David Rivkin has written: 'Wind turbine systems' -- subject(s): Wind turbines 'Wind turbine technology and design' -- subject(s): Wind turbines, Design and construction 'Wind turbine operations, maintenance, diagnosis, and repair' -- subject(s): Industrial technicians, Maintenance and repair, Wind turbines, Training of, Design and construction
The main function of a wind turbine blade is to capture the energy from the wind and convert it into rotational energy to spin the turbine and generate electricity. The design of the blade is crucial in maximizing energy capture efficiency and overall turbine performance.
A turbine blade slows down the speed of wind as it passes through, converting the kinetic energy of the wind into rotational energy to drive the turbine. The amount of speed reduction depends on the design and size of the turbine blade.
The spines on a wind turbine are called blades. These blades capture the energy from the wind and convert it into rotational motion to generate electricity. The design and length of these blades play a crucial role in determining the efficiency and power output of the wind turbine.
A wind tip refers to the end section of a wind turbine blade. It is designed to capture the energy from the wind and convert it into rotational motion to generate electricity. The shape and design of the wind tip are crucial for maximizing the turbine's efficiency in capturing wind energy.
It depends on the manufacture and design of the wind turbine. Some small turbines can maximize power output with a wind speed of 10 mph. Larger turbines may be designed for higher wind speeds. Some won't even start spinning until the wind speed is over 10 mph.
A wind turbine loses energy due to factors such as friction in the mechanical components, electrical losses in the generator, and inefficiencies in the conversion of kinetic energy from the wind into electrical energy. Additionally, wind turbulence, blade design, and air resistance can also contribute to energy losses in a wind turbine.
The height of a wind turbine has no impact on the turbine's output wattage. The factors that effect the watts produced are: * The efficiency of turbine design (this is at most 59%) * the density of the air * the radius of the turbine (that is, the length of each fin) * the velocity of the wind passing through the turbine An 80 ft tall turbine would presumably have a fin length (that is, turbine radius) of at most 30 ft. Thus, at sea level on a 59 degree (F) day, in an 8 m/s (18mi/h) wind, with the most efficient turbine design possible, you would generate approximately 15.4 Kilowatts. See: http://en.wikipedia.org/wiki/Wind_turbine#Potential_turbine_power
A wind turbine makes wind for scientific study.
The maximum power output of a wind turbine depends on its size and design. On average, commercial wind turbines have power outputs ranging from 2 to 8 megawatts. However, advancements in technology may increase this range in the future.
The length of a rotor blade on a wind turbine can vary depending on the turbine size and design. On average, rotor blades can range from 116 to 328 feet (35 to 100 meters) in length for utility-scale turbines.
Wind turbines have blades that rotate when the wind blows, converting the kinetic energy of the wind into mechanical energy. This mechanical energy is then converted into electricity by a generator inside the turbine. The turbine's orientation and design help to maximize the capture of wind energy.