The invention relates to an electric power production system, which can be used in any environment that comes to mind including vacuum of space such as all places and fields that need electric power, all plants, dwellings, road and street lamps, all vehicles that are driven by an electric motor in a manner to enable unlimited use of vehicles without the need for charging.

Background of the Invention High-speed or low-speed production model generators and alternators currently used worldwide for electric power production can produce energy by using the following resources;

liquid fossil fuels or,

fossil fuels such as natural gas or,

- gaseous fuels such as LPG or,

wind power or,

hydropower or,

thermal power or,

nuclear power and such.

By means of these resources both renewable and nonrenewable, energy production can be achieved limited to our world, through the use of natural resources such as "water and wind", i.e. energy production by interaction with an external actuator. In energy production methods in the world, necessary resources for production systems consist of and are limited to these. In this case, compared to the system of the invention in terms of economy, another actuating element, nonrenewable property, producibility and also renewable property, energy can not be produced any more under any circumstance where these resources are inadequate, where their outcome and effects are prone to disappear any minute or where there are no resources, for example when there is no nuclear, liquid or gaseous fuels, when there is no wind or when water flow rate is at an insufficient level and energy production is completely ceased and the use of these production sources is terminated.

Consequently, due to the negative aspects mentioned above and in order to eliminate factors such as the helplessness and inadequacy of the existing solutions about the matter and production costs, the system of the invention is realized in the technical field.

Object of the Invention

The invention, inspired by the existing conditions, aims to solve the abovementioned negative aspects.

The system of the invention provides the following advantages and contributions to the nature and humankind compared to existing systems: The system of the invention has a characteristic such that the initial motion of the system is provided by an accumulator or a similar chargeable actuating source, and motor vehicles use the accumulator for at most 5-1 0 seconds during startup and then the accumulator is charged. However, unlike the accumulators used in vehicles being subject to intense charge-discharge use due to lighting, heating and such; the system of the invention barely uses the accumulator. Therefore, the accumulator in the system will have a lifetime exactly equal to its shelf life. In other words, accumulator used in the system of the invention will be replaced once in at least 6-7 years. This can be thought as a passenger car, which works day and night for 6-7 years by refueling the tank once in 6-7 years. This is a significantly major contribution to the nature.

In the system of the invention, a problem such as the system not working due to accumulator shut down does not occur. Because the system also has a feedback system as well as the accumulator and accumulator charging system. The accumulator starts being charged after performing the initial startup function. The accumulator can be disabled when necessary and it can also operate while being charged. This provides a system in which the source is entirely local; which does not need an external source; which is exceedingly self-sufficient; which produces a hundred and even thousand times of what it consumes and also which recovers what it consumes by 0, 1 % "one per thousand" of what it produces.

The system of the invention provides 100% cost benefit compared to energy production systems working with liquids, vapor or gas.

The system of the invention will be produced as an independent energy production system, which will meet the demands of any dwelling, workplace, industrial field and any area due to the production capacity at the desired power. This will eliminate the network dependence and the obligation to be actually connected to the network for all places with electricity usage and as well possess an extremely significant strategic importance. For example, it will eliminate the dependence of the transportation vehicles such as metro, electric train and such to power lines. This will provide an incredible advantage to the enterprise in terms of production costs of transportation vehicles and such, eliminate the highest expense: energy costs and make a contribution to humans by lowering the price of products manufactured by the enterprise besides providing competitive advantage to the enterprise, increasing the market demand and expanding the market share of the enterprise.

When production cost of the present system is considered, the energy produced by the system of the invention will be entirely "free" except for the purchase value of the system and accumulator replacement costs once in 6-7 years. This is an unarguable cost advantage.

Everyone using the system of the invention will have an energy source entirely under their own control, in other words they will have their own, entirely independent energy source. This is an unarguable use advantage contribution. The system of the invention will provide unlimited ease of use in terms of portability.

To summarize, the system of the invention has all the unlimited advantages of an energy source, which doesn't exist in any of the existing systems currently used; which produces continuous FREE energy without consuming energy and which is dreamt to be an endless source. Furthermore, the system of the invention doesn't have any negativities and problems - which are complained about and undesired - of the existing systems currently used.

The system of the invention will provide a permanent solution to the most important problem of humanity by replacing the systems operating with fossil fuels and polluting the environment despitefully, as an entirely clean energy source which does not pollute the environment.

The system of the invention provides a system started up by an accumulator or a similar chargeable actuating source and keeps the 100W, 24V BLH/DC (Brushless DC) or standard DC motor powered by an actuating source continuously charged and running.

The actuating source, i.e. accumulator, will be kept charged by being continuously charged by a proper rectifier. A self-feeding electric power production system is developed so as to achieve the abovementioned objects. This system contains: an accumulator,

a drive operated by the mentioned accumulator; controlling the number of revolutions and the operation of an actuator; and connected to the mentioned actuator by actuator feeding means,

the mentioned actuator, which rotates a drive shaft,

at least one moving disc rotated by the mentioned drive shaft, at least two magnetic components whose magnetic poles are opposing each other on the mentioned moving disc,

fixed discs positioned opposite both surfaces of the mentioned moving disc,

at least two coils, with at least one positioned on the mentioned fixed discs; placed right across the mentioned magnetic components; interacting with N pole and S pole of the magnetic components upon rotating of the disc and producing energy at its output,

accumulator feedback system, which transmits energy to the accumulator.

The structural and characteristic features and all advantages of the invention will be more clearly understood by the figures given below and detailed written description addressed to the figures. Therefore, the evaluation should be done by taking into account these figures and detailed description. Figures to help understand the invention

Figure 1 , is a general diagram showing the components of a preferred embodiment of the system of the invention and the connections between these components. Unnumbered arrows in Figure 1 either show the connection or the direction of energy transmission between relevant components.

Figure 2, is an outer two-dimensional view of discs and coils in the system of the invention.

Figure 3, is a two-dimensional view showing the magnetic components and coils on the disc in the system of the invention.

Figure 4, is a general diagram showing the components of another preferred embodiment of the system of the invention and the connections between these components. Unnumbered arrows in Figure 4 either show the connection or the direction of energy transmission between relevant components.

Part References

1 . Accumulator

2. Drive

3. Accumulator charging generator

31 . Accumulator charging means

4. Actuator

41 . Actuator feeding means

42. Drive shaft

5. Rectifier

51 . Feedback means

6. Moving disc

61 . Magnetic component

61 1 . N pole

612. S pole

7. Fixed disc

71 . Coil

8. Magnetic field interrupter

9. Motion transfer mechanism

10. Reducer 1 1 . Reducer shaft

12. Control

13. Potentiometer Figures do not necessarily need to be scaled and details, which are not crucial to understand the present invention could be omitted. Furthermore, at least substantially identical components or components with at least a significant number of identical functions are indicated by the same number. Detailed Description of the Invention

In this detailed description, preferred embodiments of the electric power production system of the invention are described only to have a better understanding of the subject.

Electric power production system of the invention contains; accumulator (1 ), drive (2), accumulator charging generator (3), actuator (4), drive shaft (42), rectifier (5), moving disc (6), magnetic component (61 ), coil (71 ), magnetic field interrupter (8), motion transfer mechanism (9), accumulator charging means (31 ), actuator feeding means (41 ) and feedback means (51 ).

Characteristics and functions of the components contained in the system of the invention will be explained below: - Accumulator (1 ): Accumulator (1 ), enables the actuator (4), i.e. electric motor, to operate via the drive (2). Energy of the system is supplied by the Direct Current (DC) source, accumulator (1 ). System can be started up once and then deactivated. On the other hand, this direct current source can be used to feed the system continuously if necessary. Input value is preferably 24 V. Accumulator (1 ) enables the actuator (4), i.e. electric motor, to operate.

Drive (2): Drive (2) can be fed from both the accumulator (1 ) and the alternating current (AC) voltage from inside or outside the system, wherein it controls the rotation and operation of the actuator (4). Accumulator charging generator (3): It is a motor that generates direct current through being driven by the drive shaft (42) and charges the accumulator (1 ) continuously. Accumulator charging cables (31 ) are fireproof silicon cables like all the other cables and they provide the connection with the accumulator (1 ) for charging purposes.

Actuator (4): Actuator (4) is an electric motor, which is 100W, 24 V BLH/DC (Brushless DC) or standard DC type with at least 3000 rotations per minute, and it provides the main drive and efficiency of the system with powerful torque. Actuator feeding means (41 ) are fireproof silicon cables that provide the connection between the drive (2) and actuator (4). Drive shaft (42) goes through the center of the moving disc (6). Drive shaft (42) is the shaft that transfers the rotation momentum provided by the actuator (4) to moving discs (6) and thus enables moving discs (6) to rotate at the desired speed.

Rectifier (5): Rectifier (5) is a feed system that supports the charging of the accumulator (1 ) by using 1 10V, 220V and/or 380V electricity produced in the electric power production system. Rectifier (5) has auto- detection in a manner to stop charging automatically when accumulator (1 ) is fully charged and to start charging when charge drops to a certain level. Rectifier (5) is composed of an electronic circuit. Rectifier (5), which is connected to the output of the coils (71 ) and fed by 220V AC current supplied by the coils (71 ), transmits a direct current of 24 volts 20 amperes to the accumulator (1 ) through feedback means (51 ). With this quality the rectifier (5) is the system, which keeps the accumulator (1 ) that loses maximum 9,8 Amperes in an hour, full with half of 20 Amperes it produces while it feeds the actuator (4), i.e. the DC motor, of 24V and 100W with the remaining 10 Amperes not used by the accumulator (1 ). The system of the invention is operated by an accumulator (1 ) or a similar chargeable actuating source; this actuating source is charged continuously and it keeps preferably the 12V, 100W BLH/DC motor, i.e. the actuator (4), operating. The actuating source, i.e. accumulator (1 ), will be kept full by being charged by a proper rectifier (5) continuously. That is to say, the primary task of the rectifier (5) is to provide charge continuously to 24V, 200Ah (voltage 24 V, capacity 200 Ah) accumulators (1 ), which feed the DC motor (actuating source) that operates the system and in the meantime to feed the DC motor (actuating source) that operates the system as long as the rectifier is connected to the 220 volts ~50Hz feed produced by the system itself and not outsourced under any circumstances. In case feed energy of the rectifier (5) is cut due to some reason, then the accumulators (1 ) in the system will step in so as not to leave the DC motor, fed by the rectifier, (5) without power, and thus the system will operate for at least 18 hours without interruption. Furthermore, in a preferred embodiment containing the rectifier, a deep discharge protection unit is placed inside the rectifier (5) so as to prevent the accumulators (1 ) from being subject to deep discharge and becoming useless due to the interruption of the Feedback Energy feeding the rectifier (5) and due to this interruption lasting very long. Deep discharge protection unit is a protection unit for preventing stationary accumulators (1 ) from being subject to deep discharge and breaking down. In deep discharge protection unit, when accumulator (1 ) voltage drops below a certain value; loads in the system are disconnected from the accumulator (1 ) and when the accumulator (1 ) is charged; the loads are automatically put into use. Since the connection between the accumulator (1 ) and DC motor system will be cut if accumulators (1 ) drop down to lower limit voltage, the system will not have power and energy production will cease. So as to prevent this situation, an accumulator (1 ) with proper values is selected. Actuator (4) that operates the system, i.e. DC motor, will be fed by an accumulator (1 ) of 24V - 200Ampere power. When the feedback energy that feeds the rectifier (5) is back on, the rectifier (5) will keep feeding the system and simultaneously keep the accumulator (1 ) full by charging it. Power drawn by the mentioned DC motor is maximum 9,8Ah if it works under continuous load. But the system will never operate under load. Because the coils (71 ) that produce energy in the system are in the group of coils without. Therefore, the DC motor will not draw more than 5-6Amp/Hour power. On the other hand, the charge and system feeding power of the rectifier (5) will be 20Amp/Hour. As is clearly seen here, the system produces energy and in the meantime achieves the necessary energy input by feedback. The network electricity used in our houses is 220 volts ~50Hz. The energy produced by the system of the invention is exactly equal to this value.

Feedback means (51 ) are fireproof silicon cables that provide the transfer of energy from the rectifier (5) to the accumulator (1 ).

- Moving disc (6) is a circular disc structure, which contains fixed magnetic components (61 ) inside.

Magnetic component (61 ): Magnetic components (61 ) are magnetic sources that enable coils (71 ) to produce power by variable "N/S" magnetic interaction. They are flat oval shaped. Mentioned magnetic components (61 ) may have different diameters, preferably 50mm. Also their thickness may vary but the preferred thickness is 20mm.

Fixed disc (71 ): Coils (71 ) are arranged on the stationary fixed disc (71 ) and the fixed disc (71 ) is positioned across the moving disc (6).

Coil (71 ): Coils (71 ) produce power, as they are components structured in order to generate the targeted power and current, depending on different wire thickness and number of turns, by interacting with the magnetic components (61 ).

Magnetic field interrupter (8): Magnetic field interrupter (8) prevents the magnetic components (61 ) on a moving disc (6) from affecting the coils (71 ) that another moving disc (6) interacts with. Therefore, power- producing coils (71 ) are not affected by the opposite magnetic field. Magnetic field interrupters (8) are placed between coils (71 ) interacting with different moving discs (6) in case moving discs (6) are placed one after another. When there is one moving disc (6) or when moving discs (6) are aligned laterally, magnetic field interrupters (8) won't be used since they are not necessary.

Motion transfer mechanism (9): Motion transfer mechanism (9), which is a system preferably made up of belts and pulleys, enables the charging of the accumulator (1 ) by transferring the motion, rotation momentum from the drive shaft (42) to the accumulator charging generator (3) and thus activating the accumulator charging generator (3).

Working principle of a preferred embodiment (Figure 1 ) of the system of the invention containing the abovementioned components is as follows: First of all the accumulator (1 ) is switched on by using on/off control (12) in order to feed the drive of the DC motor. Accumulator (1 ) operates the drive (2) and the drive (2) operates the actuator (4), i.e. motor. Drive (2) provides rotational motion to the actuator (4), i.e. motor, and from there to the drive shaft (42) by a potentiometer (13) performing speed increasing/decreasing function. Moving disc (6) fixed to the shaft also rotates when the shaft is rotating. Magnetic components (61 ) are placed on the mentioned moving disc (6) as indicated before. Coils (71 ) are positioned at both sides of the moving disc (6). Magnetic components (61 ) pass in front of the coils (71 ) by means of the rotation movement of the moving disc (6) to achieve power production. Produced electric power is obtained at the output of coils (71 ).

Furthermore, the system contains at least one accumulator feedback system in order to charge the accumulator (1 ). Accumulator feedback system can be formed by the accumulator charging generator (3) or rectifier (5) as well as both the accumulator charging generator (3) and the rectifier (5) together if necessary. The system of the invention can be used between 60-3000 rpm. Over 1000 rpm, the rectifier (5) and accumulator charging generator (3) can be used separately or together. Under 1000 rpm, only rectifier (5) can be used. Because accumulator charging generator (3) can produce power only above 1000 rpm.

Accumulator charging generator (3) is connected to the drive shaft (42) rotated by the actuator (4) and to the motion transfer mechanism (9). Accumulator charging generator (3) is operated by means of rotational motion of the drive shaft (42). Operated accumulator charging generator (3) produces energy and feeds the accumulator (1 ). The rectifier (5) is operated by the electric power obtained from coils (71 ). The rectifier (5), which is connected to the output of coils (71 ) or any output of the system, provides the transfer of electric power at a suitable value to the accumulator (1 ). These feedbacks can be used as alternatives in the system. Accumulator charging generator (3) and rectifier (5) can be used instead of each other or both can exist in the system. When both exist in the system, if accumulator charging generator (3) or rectifier (5) breaks down, working equipment performs the feedback function instead of the other.

System of the invention contains at least one moving disc (6). This moving disc (6) may contain at least two magnetic components (61 ) arranged laterally opposing each other as N pole (61 1 )/S pole (612). Fixed disc (7) with at least one coil (71 ) placed on top of it, is located across the mentioned magnetic components (61 ) on both left and right sides facing the moving disc (6). Therefore, each coil (71 ) faces the N pole (61 1 ) of a magnetic component (61 ) and the S pole (612) of the other magnetic component (61 ).

As a result, the system of the invention yields power with properties <220>V 50 Hz. from the output of the coils (71 ) by means of 2 magnetic components (61 ) and 2 coils (71 ). Number of windings and wire thickness of the coil (71 ) determine the current and output power of the energy. On the other hand, diameter of surfaces on which the N pole (61 1 ) or the S pole (612) of the mentioned magnetic components (61 ) are located should be the same as the diameter of coil (71 ) surfaces facing the N pole (61 1 ) or the S pole (612).

In a preferred embodiment of the invention, number of moving discs (6) is 3. Each moving disc (6) is equipped with 36 flat and oval magnetic components (61 ). N pole

(61 1 ) of 18 magnetic components (61 ) and S pole (612) of 18 magnetic components (61 ) are located on the right side of the moving disc (6); whereas the opposite S pole

(612) of the mentioned N pole (61 1 ) of these 18 magnetic components (61 ) and the opposite N pole (61 1 ) of the mentioned S pole (612) of the other 18 magnetic components (61 ) are located on the left side of the moving disc. A total of 72 coils (71 ) are placed right across each mentioned magnetic component (61 ) facing both sides of the moving disc (6), in a manner to have 36 across one side and 36 across the other; with the same surface dimensions as the magnetic components (61 ); producing power of 55 volts, alternating current (AC) and 6 amperes. Since there are 3 moving discs (6), there are totally 216 coils (71 ), with 72 on each moving disc (6). The mentioned coils (71 ) can be with or without a core. In coils with core, metal foils constitute a resistance against the magnetic components (61 ) during loading. This means additional loads to the system. Moreover, system of the invention utilizes a coil (71 ) without core. The reason for utilizing a coil (71 ) without core is to achieve "0" load, i.e. no load, on the energy producing system no matter how much energy is used or even if all the power produced by the system is consumed and thus not to have any performance loss. In the system of the invention, if mentioned moving discs (6) are placed one after another, magnetic field interrupters (8) are placed in between the coils (71 ) between two moving discs (6) so as to prevent the interference of magnetic fields as mentioned before while explaining the characteristics of magnetic field interrupters (8). If moving discs (6) are aligned laterally, the use of magnetic field interrupters is not necessary. In the system of the invention, rotational speed of the actuator (4), consequently of the moving discs (6), is 3.000 rpm. This rotational speed is constant and because of that, its value in terms of Mhz is 50 Mhz. Because the rotational speed of 3.000 rpm in 1 second is 3.000/60=50, i.e. 50 Mhz. This is a constant value. This means that there are no current and power fluctuations in the system. In other words, considering: Power source input of the system is provided through the accumulator

(1 ),

The current supplied by the accumulator (1 ) is direct current, Direct currents do not have fluctuation the rotational speed of 3.000 rpm will not change. That is to say that the rotational speed is constant. Therefore, "N pole (61 1 )" passes in front of each coil (71 ) 25 times and "S pole (612)" passes in front of each coil (71 ) 25 times per second in a constant and equal manner, fixing the frequency of the current to 50 Mhz.

In the system of the invention, there are 216 coils (71 ) as mentioned before when 3 moving discs (6) are used. Mentioned coils (71 ) are preferably without core and each of these coils (71 ) possesses 55V-6A power characteristics and they are in groups of 4 coils (71 ) in series connection. Thus, each group has 220V-6A characteristics. Since coils (71 ) are in groups of 4, 216 coils (71 ) constitute 54 groups. These groups again form groups of 10. Each group of 10 has parallel connection within. Therefore, a system with 220V-60A power, possessing the exact same properties with the electricity network system is created. In this manner the system has 5 groups of 10. The remaining 4 groups of 4 coils (71 ), i.e. 16 coils (71 ), also have parallel connection between them and therefore they form a power source with 220V-24A output. This power is used to support the accumulator (1 ) so as to provide feedback to the system.

In an alternative embodiment of the system of the invention, a separate actuator (4), i.e. motor, can be used for each moving disc (6). When moving disc (6) is not used, motor rotating that moving disc (6) does not get activated as well.

In another preferred embodiment of the system of the invention, moving disc (6) may contain a sufficient number of - preferably 50 - magnetic components (61 ) arranged laterally opposing each other as N pole (61 1 )/S pole (612). Fixed disc (7) with 1 more number of coils (71 ) - preferably 51 - than the number of magnetic components placed on top of it, is located across the mentioned magnetic components (61 ) on both left and right sides facing the moving disc (6) (When number coils (71 ) is 1 more than that of magnetic components (61 ), 50 Hz./second N/S fluctuation oscillation of the current is achieved). In this system, due to the sufficient number of magnetic components (61 ) and coils (71 ), electric power with 220V 50 Hz characteristics can be obtained from the output of coils (71 ).

The abovementioned another preferred embodiment (Figure 4) of the invention contains, two accumulators (1 ) in series connection and with an input value of

12V,

a drive (2) operated by the mentioned accumulator (1 ); controlling the number of revolutions and the operation of an actuator (4); and connected to the mentioned actuator (4) by actuator feeding means (41 ),

a 1 :50 reducer that reduces 3.000 rpm rotational speed of the actuator (4), controlled by the mentioned drive (2), to 60 rpm.

- the mentioned actuator (4), which rotates a drive shaft (42),

at least one moving disc (6) rotated by the mentioned drive shaft (42),

50 magnetic components (6) whose magnetic poles are opposing each other on both surfaces the mentioned moving disc (6),

fixed discs (7) positioned across both surfaces of the mentioned moving disc (6),

51 coils (71 ), positioned on the mentioned fixed discs (7) and right across the mentioned magnetic components (61 ); coming face to face with the N pole (61 1 ) and S pole (612) of magnetic components (61 ) consecutively upon rotation of the moving disc (6) and interacting with 25 times S pole (612) and 25 times N pole (61 1 ) change in 1 second and producing 50 Hz electric power.

a rectifier (5) transferring a specified amount of the electric power obtained from the output of the mentioned coils (71 ) back to the accumulator (1 ) by feedback means (51 ) Detailed information about the reducer used in the mentioned embodiment (Figure 4) is given below:

Reducer (10), is connected to the 3.000 rpm drive shaft (42) of the actuator (4) (24V, 100W DC Motor) fed by the accumulator (1 ), while reducing the rotational speed of the drive shaft (42) to 60 rpm by using 1 :50 (conversion ratio) reduction rate "Reducer" (10) application, it also increases the torque of the drive shaft (42) by the same ratio so as to enable the reducer shaft (1 1 ) to move with high torque. Maximum torque of the motor, i.e. actuator (4), at 3.000 rpm is 30 Nm. As a result of reducing this rotation to 60rpm by means of the mentioned reducer (10), rotational torque of the reducer shaft (1 1 ) is increased by 50 fold compared to the drive shaft (42) and reaches maximum 30Nm X 50 =1 .500Nm. Even if it is assumed that the system will operate at average torque power and this value is 15Nm, rotational torque of the reducer shaft (1 1 ) will then be 15Nm X 50 = 750 Nm or below; 10Nm X 50 = 500 Nm. Since 1 horsepower = 736 Nm, rotational torque of the reducer shaft (1 1 ) will be a bit more than 1 Horsepower even at average torque value. On the other hand, it is more than enough for the system to have a maximum rotational torque of 400 - 500 Nm at the reducer shaft (1 1 ). However, the system will be more consistent and stable as the rotational torque of the reducer shaft (1 1 ) increases.

In the mentioned embodiment, as explained before, 51 coils (71 ) are placed on each fixed disc. Mentioned coils (71 ) are without core and connected in series with each other; and each coil (71 ) is structured, considering internal losses to be "9% in average", to produce current corresponding to 4,9V. Thus, the system can produce current corresponding to a voltage of 50 x 4,9V = 245V. Considering 9% loss in the system, the value corresponding to the current value obtained from the system is; 245V - (245V X %9) = 220 V. A BLH DC motor with 100W 24V characteristics will be used for the system to operate and this motor will consume maximum 9,8 Ah power from the accumulator (1 ). The system will contain an accumulator (1 ) of total capacity 24V, 200Ah and while 100W BLH DC motor (actuator) consumes maximum 9,8 Amperes per hour "actually 5,5 Amperes", the rectifier (5) will produce 20 Amperes per hour keeping the accumulator (1 ) full and feeding 24V 100W BLH DC Motor (actuator) in the meantime. In case 220V-feeding system of the rectifier (5) malfunctions, i.e. accumulator (1 ) cannot be charged, still in the accumulator (1 ) system;

Discharging time of an accumulator without being charged = Ampere value of the accumulator / Ampere-hour drawn from the accumulator.

The accumulator (1 ) cannot be fully discharged under any circumstances. 10% of the ampere value remains in the accumulator (1 ). Therefore, discharging of a 200Ah accumulator means 180A is consumed. In this case, if the system works without charge and under load continuously; the accumulator (1 ) is discharged in:

180A / 9,8Ah = 18,5 hours.

This means, even if the system works under load, it can continue operating without interruption for 18,5 hours. However, since the system uses 5,5 Amperes, when the system operates without load and charge continuously, the discharging time of the accumulator will be:

180A / 5,5Ah = 32,7, approximately 33 hours, i.e. nearly 1 ,5 days.

This will provide plenty of time and convenience for the technical support team coming to respond to the failure. In all technical responses; a new system device with exactly the same characteristics of the system to be repaired will be brought to the response point; this device will be connected to the system without leading to interruption; malfunctioning device will be transferred to the technical unit; after this device is repaired, it will be placed in the system again and brought into use.

Ampere equivalent of the power generated by a portable power production system of minimum 1 kw/h production capacity is AT LEAST 83,33 Amperes. This means that the system produces AT LEAST 83,33 Amperes "1 kw/h" electricity with maximum 9,8 Ampere "100W" input.

System of the invention relates to an electric power production system, which can be used in any environment that comes to mind including vacuum of space such as all places and fields that need electric power, all plants, dwellings, road and street lamps, all vehicles that are driven by an electric motor or as power source of stationary or mobile electric motors in a manner not requiring any charging and enabling unlimited use. Regarding energy losses occurred during the studies of all embodiments mentioned above; statements in paragraphs below are given.

Thermodynamics; Due to the increasing demand for power as a result of the rapid improvement in textile industry beginning from the early 18th century and inability to meet this demand by human or animal power, steam engines have emerged. First successful steam engines made by Thomas Savery in 1697 and Thomas Newcomen in 1712 in England, James Watt developing these machines between 1765-1766 and his research on unknown characteristics of steam until that day constitute the most significant stages in this field. Many more researchers becoming interested in this field has lead to the emerging of Thermodynamics.

The term Thermodynamics was first used by the English Scientist Lord Kelvin in a publication in 1849. The word Thermodynamic was derived from therme(heat) and dynamis(power) words in Latin. Thermodynamics can be defined as a branch of Physics dealing with energy and transformation of energy. Moreover, thermodynamics is also defined as the "science of energy and entropy" in our day. Thermodynamics; has a very wide application range from automobiles to planes and space crafts, from electric power plants to air conditioning systems and computers. Mentioned Laws of Thermodynamics are explained below,

a) First Law of Thermodynamics, mentions that total internal energy of any system is related to the heat supplied to or removed from the system and work done. In other words, first law of Thermodynamics points out the law of conservation and transformation of energy and it emphasizes that energy is related to thermodynamics.

According to the law of conservation and transformation of energy, energy cannot be destroyed or created out of nothing, however it is transformed from one form of energy to another by various physical and chemical processes. If we formulate this: we get U=Q-W. This means, Total Internal Energy is the difference between Heat and Work. "Here U represents the total internal energy, Q represents heat and W represents work".

Second law of Thermodynamics, "Second law of thermodynamics expresses that processes can go in a certain direction but not the reverse. "A change of state can only occur if it satisfies both the first and second law of thermodynamics". For example; Fuel consumed by an automobile going up a hill cannot be refilled to the tank when the automobile goes down the hill by itself. Thus, change of state is unidirectional.

First law of thermodynamics does not have any limitations on the direction of change of state. According to the first law, heat can entirely be transformed into work, In other words, according to the first law, it is possible to make a motor that can do work without giving off heat, energy etc. from the system to the environment. This means a 100% efficient motor. However, the second law has some limitations for this. Kelvin-Planck statement in the second law of thermodynamics explains this situation: "It is impossible to construct a machine which works in cycle and does work continuously by exchanging heat with only one heat source". Clausius explains the relation of cooling and heating machines (air-conditioner, refrigerator...) with the second law of thermodynamics as follows: "It is impossible to construct a heat pump (or a cooling machine) which will transfer heat from a low temperature heat source to a high temperature heat source without affecting the environment". In other words, "It is impossible for heat to flow from a low temperature environment to a high temperature environment without external work".

Third Law of Thermodynamics, "If a system approaches absolute zero, 0 Kelvin (-273 Celsius degrees), all particles approaching this temperature will have equal entropy". This law also has a conventional description as the second law.

This law actually means, entropy of a particle at 0 Kelvin will drop down to zero (0) and all particles will have equal energy. (Entropy can be defined as a measure of the disorder in the system)

d) Zeroth Law of Thermodynamics: This law is actually the simplest one, which needs to be learned at the beginning. However, it is called the zeroth law since it was found later and presented as a fundamental physics principle by R. H. Fowler in 1931 . It implies, considering any x, y and z particles; if y and z are in thermal equilibrium when x and y are also in thermal equilibrium, then x and z are also in thermal equilibrium. Consequently Tx=Ty=Tz. These values simply explained within the context of thermodynamics, i.e. complete compliance with the relational basis of the total internal energy of a system with Q/W; adherence to the first law of thermodynamics and essential need and dependence on "work" done for motion transfer, in other words transfer content; complete compliance with the second law of thermodynamics stating "processes can go in a certain direction but not the reverse" constitute the entire scientific basis of the real characteristics of the system.

There are 5 fundamental cycle laws for internal combustion, constant volume or constant pressure piston engines that operate by using energy.

These are:

1 ) Constant volume (Otto) cycle,

2) Constant pressure (Diesel) cycle,

3) Dual cycle,

4) Stirling cycle,

5) Ericsson cycle.

First two cycles constitute the basis of the embodiment of the invention. Since the 3rd Cycle law is based on 1 st and 2nd Cycle laws together, this law can also be included in our description. Here, we would like to define our system based on the first 2 cycle laws that take place in accordance with the laws of thermodynamics:

> CONSTANT VOLUME (OTTO) CYCLE:

Constant volume cycle was first explained by Beau de Rochas in 1862 and first applied by Nikolaus August Otto in 1876. Otto introduced the first compression, four- stroke, internal combustion piston motor into the market within the same year.

> CONSTANT PRESSURE (DIESEL) CYCLE:

Rudolf Diesel produced a motor named after him and obtained a patent in 1892. The cycle of this motor is called the Diesel Cycle. In Otto motor, air and fuel being compressed together decreased the performance. In Diesel motor, air and fuel are compressed separately so as to increase the performance. This motor provides up to £=24/1 compression ratio. This cycle is made up of one constant pressure one constant volume and two isentropic processes.

The aim of these motors, both CONSTANT VOLUME (OTTO) CYCLE and CONSTANT PRESSURE (DIESEL) CYCLE, is to provide the cycle of piston and its rods by means of fuel actuating the ""Crank" shaft through spark plugs or due to internal combustion under high pressure and to produce various works by this cycle.

These cycle laws are presented as basis here since they especially fall within the definition of first and second laws of thermodynamics. That is to say, according to the first 3 cycle laws constituting the basis of the system of the invention, like these internal combustion motors use an energy source such as gas, fuel, diesel fuel, natural gas, Ipg or biofuels or wind and hydro power to produce much higher output of "work, heat, motion, energy, driving power etc." as compared to the input energy source as a result of ignition or pressure; and like the abovementioned Otto Motor and Diesel Motor function within the frame of and depending on the laws of thermodynamics, the system of the invention also functions within the frame of the same rules. Furthermore, it functions by using a direct current source, which is not rapidly consumed, high cost or polluting the environment significantly like "wind power, hydropower, gas, fuel, diesel fuel, natural gas, Ipg or biofuels" used by these motors and which does not stop producing energy when wind flow and water flow rate is insufficient. And it functions by only using a small portion of the energy it produced so as to keep this direct current source, 24V 200A accumulators, charging and full continuously and a using DC motor, connected to this energy source, operating by using 24V, 100W, max 9,8 Ah. Consequently, just like vehicles with different power needs such as "passenger cars, transport vehicles, trucks, ships, planes etc." using "gas, fuel, diesel fuel, Ipg or biofuels", the system of the invention also "produces various kilowatts depending on different energy demands".

Our system functions in compliance with the first and second laws of Thermodynamics. That is to say, during the period the actuator (4) uses maximum 9,8 A (100W) power (voltage) and 24 VDC, i.e. in 1 hour; 1 KW ["1000W"83,33Ah]' power (voltage) and current corresponding to 220VAC is obtained. Therefore (83,33Ah/9,8Ah) = 8,5 times more the input (use & consumption) value is obtained. In the meantime, an almost negligible part of this value, obtained by FEEDBACK APPLICATION, is used to continuously charge and keep FULL the accumulator (1 ), which feeds the system by means of "Accumulator Charging Generator (3) or Rectifier (5)". Similarly the following statement would be correct: we can think of a hypothetical recycling in-cycle conversion system placed at the exhaust outlet of an internal combustion motor consuming liquid or gaseous fuel to produce electric power or used for transportation purposes, as a system converting the output of the exhaust to fuel again and keeping the vehicle's tank full all the time. However, such a system does not exist. But similarly; our system uses maximum 9,8Ah power and gains, for example 1 KW ["1000W"83,33Ah] power (voltage) and current corresponding to 220VAC, by a BLH/DC motor of 24V, 100W, wherein the assumption that a very small portion of the gain is used just like the analogy of a hypothetical recycling in-cycle conversion system placed at the exhaust outlet to convert the exhaust outlet products back to fuel, is completely realized by our system.

The following example may be presented only for informative and illustrative purposes. For example; magnet gauss value of our "self-feeding power production system" of the invention, with 1 kilowatt/h (1000wh) production capacity, is lower than the magnet gauss value of a "self-feeding power production system" with a higher production capacity and is higher than the magnet gauss value of a "self-feeding power production system" with a lower production capacity. Just like the various power possessed by 1200cc, 1300cc and 1500cc motors. In this case, the corresponding ampere value of a "self-feeding power production system" of the invention, which has 1 kilowatt/h production capacity; which operates with a 24V 100W max 9,8ah input BLH/DC motor; is 83,33ah. The produced current value is 220V, 50Hz.