TECHNICAL FIELD

The present invention relates to an electricity production system which provides production of electricity by means of moving a length inside magnetic field.

PRIOR ART

Energy sources decrease every passing day and depending on this, the energy need increases every passing day. The most popular energy type used today is electrical energy. New alternative methods are developed for producing electrical energy for meeting the demand which occurs depending on the increasing need. Electrical energy is essentially produced by means of electromagnetic ways by means of generator systems, and electrical energy can also be produced by means of heat, light wind, pressure, nuclear, geothermal or tidal methods, etc. However, production of electrical energy by means of these methods is not sufficient for meeting the increasing demand. Therefore, the most efficient electrical energy production method is production of electrical energy by means of electromagnetic force lines from mechanical energy electromagnetically.

As a result, because of the above mentioned problems, an improvement is required in the related technical field.

BRIEF DESCRIPTION OF THE INVENTION

The present invention relates to an electricity production system, for eliminating the above mentioned disadvantages and for bringing new advantages to the related technical field.

An object of the present invention is to provide an electricity production system which provides production of electricity as a result of moving a length by forming magnetic field.

In order to realize the abovementioned objects and the objects which are to be deducted from the detailed description below, the present invention is an electricity production system for providing production of electricity from movement energy formed as a result of rotational movement of a length, which comprises a weight at a first end and a first magnetic field generator at a second end, in its own axis. Accordingly, the subject matter electricity production system comprises a second magnetic field generator operated at a turned on condition while the first magnetic field generator is at a first position and operated at a turned off condition while the first magnetic field generator is at a second position in order for the length to rotate in its own axis; a second drive element operated for providing passage of said second magnetic field generator between said turned-on condition and said turned-off condition; a first drive element for providing production of electricity from the movement energy formed by the length actuated as a result of magnetic field formed by operating said second drive element. Thus, electricity is produced from the movement of the length which moves inside the formed magnetic field.

In a possible embodiment of the present invention, a control unit is provided for controlling operation of said first drive element and said second drive element.

In another possible embodiment of the present invention, at least one sensor is provided which is operated for measuring the magnetic field change in order to be able to detect whether said first magnetic field generator is at the first position or at the second position. Thus, continuity of the system is provided by providing operation of the second magnetic field generator between the turned-on condition and turned-off condition in accordance with the amount of change of the magnetic field.

In another possible embodiment of the present invention, a power supply is provided between said first drive element and said second drive element.

In another possible embodiment of the present invention, the first drive element is configured to provide transfer of the generated electricity to the power supply in order to be stored and/or used.

In another possible embodiment of the present invention, the control unit is configured to realize the process steps of:

- providing exerting of a force for actuation of the length,

- detecting that the first magnetic field generator is at the first position in accordance with the magnetic field value measured by the sensor,

- turning on the second magnetic field generator by means of the second drive element,

- detecting that the first magnetic field generator is at the second position in accordance with the magnetic field value measured by the sensor,

- turning off the second magnetic field generator by means of the second drive element, - converting movement energy into electrical energy by means of the first drive element,

- transferring electrical energy to the power supply for being stored.

BRIEF DESCRIPTION OF THE FIGURES

In Figure 1 , a representative view of an electricity production system is given.

In Figure 2, a representative view of the operation scenario of an electricity production system is given.

DETAILED DESCRIPTION OF THE INVENTION

In this detailed description, the subject matter is explained with references to examples without forming any restrictive effect only in order to make the subject more understandable.

The present invention relates to an electricity production system (10) which provides production of electricity by moving a length (100) inside a magnetic field.

As shown in Figure 1, the length (100) provided to said electricity production system (10) comprises a weight (111) at a first end (110). Said weight (111) can be an object, etc. which has a changing mass depending on the length and movement of the length (100). There is a first magnetic field generator (121) provided at a second end (120) of the length (100). In a possible embodiment of the present invention, a permanent magnet is used as the first magnetic field generator (121). There is a first drive element (130) placed to the middle position of the length (100) and operated in a manner providing movement of the length (100). In a preferred embodiment of the present invention, electrical motor is used as the first drive element (130). The first drive element (130) is configured to provide rotation of the length (100) in its own axis. The first drive element (130) moreover provides production of electrical energy by means of the magnetic field formed depending on the movement of the length (100). The first drive element (130) is provided in a manner connected to a power supply (500) for providing storage of the produced electrical energy. In a preferred application, said power supply (500) can be a battery, etc. There is a second drive element (400) connected to another end of the power supply (500). In a preferred application, said second drive element (400) can be an electrical motor, etc. There is a second magnetic field generator (200) provided in a manner realizing transition between a turned-on condition and a turned-off condition by operating said second drive element (400). In a possible embodiment of the present invention, a permanent magnet which can be turned on and turned off is used as said second magnetic field generator (200). There is at least one sensor (300) provided in a manner sensing the magnetic field change formed by the length (100) in accordance with the second magnetic field generator (200). There is a control unit (600) which takes the information, indicating that the length (100) is at a first position or at a second position, from said sensor (300).

With reference to Figure 1 and 2, different methods can be used for providing the first movement of the length (100) provided in said electricity production system (10). One of said methods is to apply a force to the length (100) from an external movement provider. Another method is to provide operation of the first drive element (130) by means of said control unit (600) and to provide the first movement to the length (100). The control unit (600) provides detection of the magnetic field change formed depending on the position of the first magnetic field generator (121), provided on the length (100) and actuated by means of said movement provider or by means of operating of the first drive element (130), with respect to the second magnetic field generator (200). Depending on the position of the length (100), the second magnetic field generator (200) is brought to the turned on condition or to the turned off condition by means of the control unit (600). The control unit (600) provides operation of the second drive element (400) for providing transition of the second magnetic field generator (200) between turned on condition and turned off condition in accordance with the magnetic field change information taken from the sensor (300). During the transition of the second magnetic field generator (200) between turned-on condition and turned-off condition, a magnetic field is formed between the first magnetic field generator (121) and the second magnetic field generator (200). As a result of said magnetic field, the length (100) is accelerated. Depending on the movement of the length (100), electrical energy is produced by means of the first drive element (130). The produced electrical energy is transferred to the power supply (500) in order to be stored and/or in order to be used.

An exemplary operation scenario of the present invention is described below;

First of all, the control unit provides operation of the first drive element (130) and provides actuation of the length (100). Another method is to provide actuation of the length (100) depending on a force exerted by means of an external movement provider. The weight (111) provided at the first end of the length (100) and the first magnetic field generator (121) provided at the second end of the length (100) are passing near the second magnetic field generator (200) during each rotation of the length (100). The length (100) is accelerated as a result of the magnetic field formed between the first magnetic field generator (121) and the second magnetic field generator (200). Thus, the length (100) continues to accelerate and rotate. The control unit (600) provides detection of the magnetic field change, formed depending on the position of the first magnetic field generator (121), provided to the length (100), with respect to the second magnetic field generator (200), by means of the sensor (300) after the first drive element (130) is operated. The control unit (600) detects that the length (100) is at the first position as the control unit (600) takes the first magnetic field change information of the length (100) from the sensor (300). In this case, the control unit (600) provides operation of the second drive element (400). The second drive element (400) provides turning on the second magnetic field generator (200). The control unit (600) detects that the length (100) is at the second position as the control unit (600) receives the second magnetic field change information of the length (100) from the sensor (300). In this case, the control unit (600) provides operation of the second drive element (400). The second drive element (400) provides turning off the second magnetic field generator (200). As the second magnetic field generator (200) is operated between the turned on condition and the turned off condition, magnetic field is produced between the second magnetic field generator (200) and the first magnetic field generator (121). By means of the effect of the formed magnetic field, the length (100) accelerates without consuming energy. Depending on the movement of the length (100), movement energy is converted into electrical energy by means of the first drive element (130). The produced electrical energy is transferred from the first drive element (130) to the power supply (500) in order to be stored.

In an exemplary embodiment of the present invention, energy is produced through the energy production system (10) provided in an energy plant which provides production of energy. In the energy production system (10), the rod, which has weight (111) at one end and which has permanent magnet at the other end, is actuated by means of an electrical motor. When the actuated rod passes through the peak point, the sensor senses the magnetic field change of the rod. The magnet, which can be turned on and turned off in accordance with the data received by means of the sensor, is brought to the turned on condition. As a result of the magnetic field formed by turning on the magnet which can be turned on and turned off, the rod is accelerated towards the magnet which can be turned on and turned off. When the rod arrives at the closest position to the magnet which can be turned on/off, the sensor senses the magnetic field change of the rod again. In accordance with the data received from the sensor, the magnet, which can be turned on/off, is brought to the turned off condition. The rod accelerates for the second tour and continues the rotational movement thereof. There is an electrical motor for providing turning on/off of the magnet which can be turned on/off. The electrical motor, connected to the rod, and the electrical motor, connected to the magnet which can be turned on/off, are connected to a battery. The electrical motor, connected to the rod, provides production of electrical energy by means of the effect of the magnetic field which is formed depending on the movement of the rod. The produced electrical energy is stored in order to be used at the battery. The energy, stored in the battery, can be used in operation of electrical motors, and the produced excessive energy can be transferred for use in electrical plant.

The protection scope of the present invention is set forth in the annexed claims and cannot be restricted to the illustrative disclosures given above, under the detailed description. It is because a person skilled in the relevant art can obviously produce similar embodiments under the light of the foregoing disclosures, without departing from the main principles of the present invention.

REFERENCE NUMBERS

10 Energy production system 100 Length 110 First end

111 Weight 120 Second end

121 First magnetic field generator 130 First drive element 200 Second magnetic field generator

300 Sensor

400 Second drive element 500 Power supply 600 Control unit