KR102494026B1 - Non-Rotation Type Alternating Current Generator Capable of Mulitplying Output Voltage - Google Patents

Abstract

The present invention relates to a non-rotating alternating current generator capable of doubling the output voltage, comprising: a DC power supply unit 110; A controller 120 providing a switching signal; and an AC output unit 130, wherein the AC output unit 130 includes an iron core 131, a pole piece 133, field windings 134 and 135 to which the DC power is supplied, and the pole piece 133 ) may include an armature winding 136 wound around the iron core 131 between field windings 134 and 135 to output the AC power by induced electromotive force, and the AC output unit 130 and the DC power supply unit 110, so that DC power from the DC power supply unit 110 is constantly supplied to the AC output unit 130, so that AC output unit 130 continuously outputs power to supply power A power supply 140 (POWER SUPPLY) is provided, and the movement of electrons is achieved by turning on / off power at a certain duty to the field winding stacked inside the unit, which is an AC output unit. Electromotive force can be obtained by the rotation of magnetic flux, and power supply uses direct current (DC) power, cuts off and supplies power according to a set duty, and provides different directions to the field, so that conventional rotary synchronous generators It is characterized by generating an alternating electromotive force in the same form as rotating.

Description

Non-Rotation Type Alternating Current Generator Capable of Multiplying Output Voltage}

The present invention relates to a non-rotating AC generator capable of doubling the output voltage, and more particularly, to a structure capable of doubling the output voltage made of a structure capable of obtaining an electromotive force such as physically rotating only by turning off the power It relates to a non-rotating alternator.

In addition to electric vehicles, there is a growing need for high-efficiency AC power generators such as household power use and emergency power use in buildings.

As more and more places use electricity, safety and convenience are gradually emerging.

On the other hand, a previously applied and registered technology (Registration No. 10-1913746, registered on October 25, 2018) by the applicant of the present invention (title of the invention: AC power generator capable of adjusting frequency and voltage) has been disclosed. According to this, a structure capable of generating non-rotating alternating current has been proposed, but various problems have occurred, such as low efficiency due to a large amount of heat generated.

[Prior art literature]

(Patent Document 0001) Patent Publication No. 10-2014-0078732 (2014.06.25)

(Patent Document 0002) Japanese Unexamined Patent Publication No. 2000-353627 (2000.12.19)

An object of the present invention has been proposed to solve the conventional problems as described above, and problems, stability, and utilization due to power loss and efficiency degradation due to external forces such as heat, friction, speed, and resistance of existing rotary synchronous generators. It is an object of the present invention to provide a non-rotating AC generator capable of doubling a non-rotating output voltage in order to solve various problems such as compatibility and affinity.

Another object of the present invention is to provide a non-rotating alternator capable of doubling the output voltage to improve problems caused by power loss and efficiency deterioration by utilizing structural advantages of generating AC power but not rotating.

A non-rotating AC power generator capable of doubling the output voltage according to a preferred embodiment of the present invention for achieving the above object includes a DC power supply unit 110; A control unit 120 that provides a switching signal to cut off the DC electricity for a certain period of time and at a certain period; and an AC output unit 130 that converts the DC power into AC power and outputs the DC power according to a switching signal of the control unit 120, wherein the AC output unit 130 includes an iron core 131 and the iron core 131 ), between the magnetic pole pieces 133 arranged in the length direction of the magnetic pole pieces 133, and between the magnetic field windings 134 and 135 wound around the iron core 131 to which the DC power is supplied, and the magnetic pole pieces 133 As one unit formed by stacking a structure including an armature winding 136 wound around the iron core 131 and outputting the AC power by the induced electromotive force by the field windings 134 and 135, the AC output unit 130 ) and the DC power supply unit 110, so that DC power from the DC power supply unit 110 is constantly supplied to the AC output unit 130 so that AC output unit 130 continuously outputs AC As equipped with a power supply 140 (POWER SUPPLY) that serves to supply power,

It is possible to obtain electromotive force by rotating the magnetic flux due to the movement of electrons only by turning on/off the power with a certain duty to the field winding stacked inside the unit, which is an AC output unit, and the power supply is DC ( Using DC) power, power is cut off and supplied according to a set duty, and while providing different directions to the field, generating alternating electromotive force in the same form as the rotation of the existing rotary synchronous generator,

The unit consists of one or more units, and switching is possible for each unit,

The stacking part of the field winding and the armature inside the unit alternately stacks the field winding and the armature to a hollow core to assemble one unit, and the shape of the core is not limited to a hollow type, but is a triangular or square shape ego,

The size of the diameter of the inner cylinder is variable, and a non-rotating AC power generator capable of doubling the output voltage is provided, characterized in that the hollow diameter serves as a ventilation hole to have a cooling function.

In addition, in the laminated structure of the unit, as the wiring of the electromagnet proceeds in a series and parallel structure, the compressed part is divided into both sides, so that when the unit is compressed, it is not deflected to one side, and the compressive strength is kept constant while being divided into both sides When the unit is compressed, the line that used to act as the height is divided into many directions, so when the unit is compressed, it can be compressed with greater strength, making the wiring work easier and more convenient. It is characterized by solving the short circuit problem caused by

In addition, the AC output unit has a structure in which the number of armatures is greater than the number of electromagnets, and the total height of the finally stacked units is in close contact with each other due to the increase in compression force. Characterized in that it has a compact structure do.

In addition, it is characterized in that all armatures constituting the unit have the same height.

In addition, in the case of the first field and the second field inside the unit, when DC electricity is supplied to the first field, the first field is stimulated, the second field does not operate, and then the second field When DC electricity is supplied, the second field is stimulated and the first field is not operated, and while the alternating magnetic flux is continuously generated in this way, the alternating magnetic flux is linked to the armature to generate an alternating electromotive force. Since the magnetic poles of the first field and the second field are interlinked, it is characterized in that more magnetic poles are given to the armature than conventional synchronous generators.

As described above, according to the AC power generator capable of doubling the output voltage according to the present invention, the efficiency of the AC generator is improved and the worry of failure is reduced by providing an AC power generator utilizing the structural advantage of not rotating. there is

In addition, although AC power is generated using DC power, there is an effect that it is possible to provide a high-efficiency AC power generator that is stable and easy to control the output, rather than a conventional synchronous generator using rotational kinetic energy.

1 is a block diagram showing an AC power generator according to the prior art.
2 is a schematic diagram showing some configurations (units) of AC power generators according to the prior art.
3 is a block diagram showing an AC power generator according to an embodiment of the present invention.
4 is a schematic diagram showing an example in which some components (units) of an AC power generator according to an embodiment of the present invention are compared with some components (units) of the related art.
5 is a schematic diagram showing an example of a wiring method of some components (units) of an AC power generator according to an embodiment of the present invention and some components (units) of the related art.
6 is a diagram schematically illustrating a structure of an AC generator (or generator) capable of outputting AC by alternating magnetic flux according to an embodiment of the present invention.
7 is a diagram schematically showing the direction of a magnetic field in the structure of a unit of an AC generator (or generator) capable of outputting AC by alternating magnetic flux according to an embodiment of the present invention.
8 is a view showing how the number of units changes.

Since the present invention can make various changes and have various embodiments, specific embodiments will be illustrated in the drawings and described in detail.

However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

Terms used in this application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, the terms "include" or "have" are intended to designate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other features It should be understood that the presence or addition of numbers, steps, operations, components, parts, or combinations thereof is not precluded.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in the present application, they should not be interpreted in an ideal or excessively formal meaning. don't

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in more detail. In order to facilitate overall understanding in the description of the present invention, the same reference numerals are used for the same components in the drawings, and redundant descriptions of the same components are omitted.

The AC power generator of the present invention will be described in detail with examples as follows, and the scope of the present invention is not limited to the examples.

An embodiment of the present invention relates to an AC power generator utilizing a structural advantage of not rotating.

An embodiment of the present invention is a non-rotating AC generator made of a structure capable of obtaining electromotive force such as physically rotating only by turning off the power.

Referring to Figures 1 and 2, the prior art AC generator includes a DC power supply unit 110; A control unit 120 that provides a switching signal to cut off the DC electricity for a certain period of time and at a certain period; and an AC output unit 130 that converts the DC power into AC power and outputs the DC power according to a switching signal of the control unit 120, wherein the AC output unit 130 includes an iron core 131 and the iron core 131 ), between the magnetic pole pieces 133 arranged in the length direction of the magnetic pole pieces 133, and between the magnetic field windings 134 and 135 wound around the iron core 131 to which the DC power is supplied, and the magnetic pole pieces 133 may include an armature winding 136 wound around the iron core 131 and outputting the AC power by induced electromotive force by the field windings 134 and 135.

In contrast, according to the present invention of FIGS. 3 and 4, the AC generator of the present invention includes a DC power supply unit 110; A control unit 120 that provides a switching signal to cut off the DC electricity for a certain period of time and at a certain period; and an AC output unit 130 that converts the DC power into AC power and outputs the DC power according to a switching signal of the control unit 120, wherein the AC output unit 130 includes an iron core 131 and the iron core 131 ), between the magnetic pole pieces 133 arranged in the length direction of the magnetic pole pieces 133, and between the magnetic field windings 134 and 135 wound around the iron core 131 to which the DC power is supplied, and the magnetic pole pieces 133 may include an armature winding 136 wound around the iron core 131 and outputting the AC power by induced electromotive force by the field windings 134 and 135, and the AC output unit 130 and the DC power supply unit 110 ), so that DC power from the DC power supply unit 110 is constantly supplied to the AC output unit 130 so that AC output unit 130 continuously outputs power to supply power A power supply 140 (POWER SUPPLY) is provided.

The control unit 120 may include a rotation switching unit that provides a switching signal to cut power at regular intervals, and a rotation control unit that adjusts the signal of the rotation control unit to a speed.

The frequency and voltage of the AC power can be easily controlled by the control unit 120 .

In the AC output unit 130, the field winding may be wound on the upper and lower parts of the iron core, respectively, with the armature winding as the center.

The pole piece of the AC output unit 130 may be formed between the outermost side of the field winding, between the field windings, and between the field winding and the armature winding, respectively.

Due to the advantage of the non-rotating structure of the AC output unit 130, no separation distance error occurs, and the quality of electricity can be improved. Heat problems caused by inertia and the like can be improved.

The iron core, pole piece, winding wire, and armature winding of the AC output unit 130 constitute a first unit, and the DC power is sequentially supplied to the field windings of the first unit and the second unit to form the armature winding. Single-phase AC power can be output through the

A second unit having the same configuration as the first unit and a third unit having the same configuration as the first unit may be further included, and the DC power may be sequentially supplied to output three-phase AC power through the armature winding.

Referring to FIG. 4, looking at the arrangement between the armature (winding) and the electromagnet (referring to the first and second windings), the conventional structure (a) has a first winding (electromagnet) (N pole) between the electromagnets. <->S pole) and the second bank winding (electromagnet) (S<->N) are vertically stacked and arranged, and this structure is continuously repeated.

In the conventional unit stack structure, as heat is generated by energy generated by repeated demagnetization after magnetization of the electromagnet, the amount of heat generated increases and the efficiency decreases.

That is, in the case of a conventional unit laminated structure, the NS electromagnet and the SN electromagnet that generate magnetism are in close contact, so there is a case where the temperature due to heat inside the unit rises high due to radiant heat. Therefore, the DUTY ratio of power switching could not be increased, and it was difficult to guarantee safety. In addition, as the heat generated by the electromagnet also affects the armature, there is a problem in that an abnormality occurs in output power. In other words, the most problematic part in the conventional unit structure was the heat problem. There was a safety problem when the generator was operated for a long time due to the heat inside the unit.

In addition, in the stacked structure of previous conventional units, the number of electromagnets is greater than the number of armatures. However, even if the laminated structure of the modified unit of the present invention has a structure in which the number of armatures is greater than the number of electromagnets or has a laminated structure of the same number of armatures and electromagnets as in the prior art, the total height of the finally laminated units is the compression force It is characterized by the fact that a compact structure was created by closely contacting each other due to the increase of

In addition, the laminated structure of the conventional unit is limited to one, and has become a single-phase or three-phase structure depending on the switching method. However, according to the stacked structure of the units of the present invention, switching is also possible for each unit.

On the other hand, in the laminated structure of the unit of the present invention, the height of the armature must be the same (required condition: YOO'S LAW).

Looking at an example of the unit stack structure of the present invention in FIG. 4, FIG. 4 (b) has a difference in the stack structure in that one NS electromagnet and one SN electromagnet are disposed between the armatures. According to this unit structure, since the NS electromagnets and SN electromagnets that generate magnetism are separated from each other with the interlinking armature interposed therebetween, heat due to demagnetization of the electromagnets is dispersed so that internal heat is not deflected to only one side. Therefore, the duty ratio of power switching is set to a certain ratio or higher, and the stability of the output can be secured due to the stable switching of the electromagnet. That is, in the structure of FIG. 4 (b), stability of output power is secured while solving the problem of the previous structure of FIG. 4 (a).

In addition, in the present invention, when finishing the unit, unlike the conventional unit (in the conventional unit, a short circuit occurred in the iron piece of the connection part, resulting in a breakdown or a risk of fire) by coating the unit with epoxy itself, in the conventional unit The problem of was improved (difference in manufacturing method).

In addition, in the conventional unit (see FIGS. 2 and 4 (a)), while manufacturing a unit using a general enameled copper coil, while a certain temperature (130 degrees Celsius, the temperature at which the insulation of a general enameled copper wire withstands) is exceeded, the enameled copper wire The insulation of is destroyed and the electromagnet is short-circuited, and power is concentrated toward the short-circuited electromagnet due to the resultant change in resistance value, and the power flows infinitely to the short-circuited side. At the same time, a safety problem occurred due to a spark.

According to the unit laminated structure of the present invention, the insulation temperature (200 to 220 degrees Celsius) is increased by changing the polyester copper wire (conventional unit) to the polyesterimide copper wire. Therefore, it is possible to have a stable input power and output power structure.

The stacked structure of the unit of FIG. 4(c) is the stacked structure of the unit of another embodiment composed of devices other than the SN electromagnet in the stacked structure of the unit of FIG. 4(b). The laminated structure of these units also has an effect of improving the laminated structure of the unit of FIG. 4(a).

Change of power type

Although the stacked structure of the conventional unit of FIG. 4 (a) had a problem of heat generation, only AC output is possible. That is, an AC output could be obtained through alternating magnetic flux of DC AC, and when using DC power, a diode or an inverter had to be used to convert AC to DC once.

On the other hand, in the laminated structures of the improved units of FIGS. 4 (b) and 4 (c), AC is obtained through the power of NS and SN, and when the position of the SN electromagnet is reversed to NS and stacked, DC output can be obtained (can be manufactured as a DC generator for DC electronic products and can be miniaturized).

The stacked structure of the unit in FIG. 4(d) is the same as the stacked structure of the unit in FIG. ), and the description thereof will be continued below.

Change in output power (see Fig. 5)

In the conventional unit wiring method of FIG. 4 (a), the electromagnets were wired in a parallel structure. While assembling the unit in the same direction in order to reduce the sense of distance of the eye line of the electromagnet connected to the (+) terminal, there was a high risk of short-circuiting in the area where the eyes of the NS electromagnet and SN electromagnet overlap. The quality is good, the output is higher (separation distance). However, as the thickness of the coil of the inner line acts as a height, there was a problem in compressing the unit (a difference in compressive strength occurs) (see FIG. 5). About 1mm The diameter of the coil will affect the height of the unit.

On the other hand, in the laminated structure of the unit according to the embodiment of the present invention (see FIG. 4(d)), as the electromagnet wiring proceeds in a series and parallel structure, the compressed part is divided into both sides, and when the unit is compressed, one side It is not deflected to , and it is divided into both sides, so that the compressive strength can be kept constant, and the quality of electricity is better. In addition, when the unit is compressed, as the eye line that acts as height is divided into many directions, when the unit is compressed, it can be compressed with more strength, resulting in higher output (separation distance). In this structure, wiring work is also easier and more convenient than in the conventional unit structure.

As for the wiring method, the wiring of the electromagnet was performed in a parallel structure. While assembling the unit in the same direction in order to reduce the sense of distance of the eye line of the electromagnet connected to the (+) terminal, there was a high risk of short-circuiting in the area where the eyes of the NS electromagnet and SN electromagnet overlap. The quality is good, the output is higher (separation distance). However, as the thickness of the coil of the inner line acts as a height, there was a problem in compressing the unit (a difference in compressive strength occurs) (see FIG. 5). About 1mm The diameter of the coil will affect the height of the unit.

On the other hand, in the laminated structure of the unit according to the embodiment of the present invention (see FIG. 4(d)), as the electromagnet wiring proceeds in a series and parallel structure, the compressed part is divided into both sides, and when the unit is compressed, one side It is not deflected to , and it is divided into both sides, so that the compressive strength can be kept constant, and the quality of electricity is better. In addition, when the unit is compressed, as the eye line, which used to act as height, is divided into many directions, when the unit is compressed, it can be compressed with greater strength, resulting in higher output (separation distance). In this structure, wiring work is also easier and more convenient than in the conventional unit structure.

Change of input power (see Fig. 5)

The parallel structure of the conventional unit of FIG. 4 (a) is a one-way connection, and the biggest problem is the short circuit problem due to the compression of the unit, and in addition, as the entire electromagnet is connected in parallel, the input power and IGBT capacity There were limits.

In contrast, in the stacked structure of the unit of the embodiment of the present invention of FIG. 4 (b), the connection of the serial and parallel structure is a multi-directional connection, which solves the biggest problem, the short circuit problem due to the compression of the unit, and in addition, the entire electromagnet As they are connected in series and parallel, free adjustment is possible in terms of input power and IGBT capacity. Since the resistance can be increased through the IGBT with respect to the input voltage of 100V, for example, the conventional input limit of 50V can be increased to 100V. Also, the number of IGBTs can be reduced.

Referring to FIG. 6, although partially described above, the present invention provides an AC generator (or generator) structure capable of outputting AC by alternating magnetic flux, (also referred to as a smart electronic generator) (based on the inventor's last name Also referred to as applying CHOI'S LAW). That is, the best law is a new law applied to AC generators, and is a law indicating that the output can be doubled by stacking the armatures using the structural technology of the unit.

The AC generator according to FIG. 6 also applies the electromagnetic induction action of the rotary synchronous generator, and the principle of generating a magnetic field by inputting power to the field winding and linking the magnetic flux to the armature is the same, but the problems of the existing rotary synchronous generator are solved. To compensate, it is a structure in which the electromagnetic field can be rotated only by power switching to obtain an electromotive force equal to or greater than the physical rotation.

Figure 6 (b) is a diagram illustrating a conventional rotary synchronous generator. A synchronous generator is a synchronous alternator that converts mechanical power that rotates into electricity into electrical output, and is a generator that operates at a set rotational speed (rpm) to generate AC power at a constant frequency. So far, synchronous generators have applied electromagnetic induction, and when DC electricity is applied to the field winding of the rotor, the field is excited, and as the field rotates, the magnetic flux is linked to the stator winding to generate alternating electromotive force. However, in this rotation process, there is a problem of output degradation due to various problems such as rotation resistance, rotation friction, heat generation, bearing friction coefficient problem, deceleration phenomenon, and precision problem, and noise, life shortening, and danger due to vibration. And it has a number of difficulties that are very difficult to utilize space.

On the other hand, (a) of FIG. 6 is a diagram illustrating a part of the non-rotating AC generator unit. The non-rotating alternator has the same application of electromagnetic induction, but it is a generator made to supplement and solve the problem of existing rotation, and has a structure that can obtain the same electromotive force as physically rotating only by switching power. It is a stationary, non-rotating (stationary) generator that does not rotate physically, but only turns on/off power to the field winding stacked inside the unit at a certain duty to generate electricity due to the movement of electrons. It is a generator that can obtain electromotive force by rotating magnetic flux.

The power supply uses direct current (DC) power, cuts and supplies power according to a set duty, and provides different directions to the field while generating alternating electromotive force in the same form as the rotation of the existing rotary synchronous generator. is a generator

Unlike existing synchronous generators, it is stationary, so problems such as rotational resistance, rotational friction, heat generation, friction coefficient of bearings, and deceleration caused during rotation can be reduced. No exposure to risks. Space utilization is superior to existing synchronous generators, and the separation distance at which magnetic force is linked to the armature is constant compared to when the synchronous generator rotates, and because the field winding and armature are in close contact, more magnetic fields can be linked. Due to its structure, it is possible to obtain safer and higher quality electricity than a rotary synchronous generator by using the field winding and the upper and lower magnetic poles of the field magnet at the same time. Above all, it is unique in that it can make simple and safe power generation.

7 is a diagram showing a stacked portion of a field winding and an armature inside a unit. One unit can be assembled by stacking the field winding and armature alternately on a hollow core (the diameter of the inner cylinder is variable-the hollow diameter serves as a ventilation hole and has a cooling function) core. However, the shape of the core is not limited to a hollow shape, and the inside may also have a polygonal (not shown, triangular, rectangular, or other shape) shape. The number of fields and armatures must be designed appropriately for the capacity, and since the core and field, core and armature, and field and armature in the unit are in contact, special attention must be paid to the insulation part, and the insulation of the core part or pole piece part It should be made very certain. When the field is divided into the first field and the second field, when DC electricity is supplied to the first field, the first field is stimulated and the second field does not operate. Then, when DC electricity is supplied to the second field, the second field is stimulated and the first field does not operate. As the alternating magnetic flux is continuously generated in this way, the alternating magnetic flux is linked to the armature to generate an alternating electromotive force. Looking at the action of electromagnetic induction of a synchronous generator, it is the same principle that when the rotating field rotates, the N pole and the S pole continue to alternately apply magnetic poles to the stator winding (see (a) and (b) of FIG. 7). The most important thing here is that the first field and the second field inside the unit do not link the magnetic poles to one armature 1:1, but the first field and the second field magnetic poles link 1:1+α, Gives more stimulation to the armature than conventional synchronous generators. It can be easily compared with the conventional studies, and it can be seen as using the magneto magnetic force and using the magneto magnetic force inversely at the same time. The length of the unit can be manufactured according to the desired capacity. It must be stacked in the number suitable for the output capacity, and the output voltage varies according to the wiring method. When the output voltage and capacity are determined, the corresponding input must also be designed according to the appropriate capacity.

8 is a diagram showing how the number of units changes. Referring to FIG. 8, the number of fields and armatures inside the unit is arbitrarily determined, and the number of fields and armatures is small (a) by increasing the number (b ) units can be manufactured, so the number of fields and armatures is not limited.

As described above, according to the non-rotating AC power generator according to the present invention, by providing an AC power generator utilizing the structural advantage of not rotating, the efficiency of the AC generator is improved and the fear of failure is reduced.

In addition, although AC power is generated using DC power, it is possible to provide a high-efficiency AC power generator that is stable and easy to control the output, rather than a conventional synchronous generator using rotational kinetic energy.

As described above, the optimal embodiment has been disclosed in the drawings and specifications. Although specific terms are used herein, they are only used for the purpose of describing the present invention and are not used to limit the scope of the present invention described in the claims or defining the meaning. Therefore, those of ordinary skill in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

133: pole piece
134,135: armature (field)
136: electromagnet

Claims (5)

In the non-rotating AC power generator capable of doubling the output voltage,
DC power supply unit 110; A control unit 120 that provides a switching signal to cut off the DC electricity for a certain period of time and at a certain period; and an AC output unit 130 that converts the DC power into AC power and outputs the DC power according to a switching signal of the control unit 120, wherein the AC output unit 130 includes an iron core 131 and the iron core 131 ), between the magnetic pole pieces 133 arranged in the length direction of the magnetic pole pieces 133, and between the magnetic field windings 134 and 135 wound around the iron core 131 to which the DC power is supplied, and the magnetic pole pieces 133 As one unit formed by stacking a structure including an armature winding 136 wound around the iron core 131 and outputting the AC power by the induced electromotive force by the field windings 134 and 135, the AC output unit 130 ) and the DC power supply unit 110, so that DC power from the DC power supply unit 110 is constantly supplied to the AC output unit 130 so that AC output unit 130 continuously outputs AC As equipped with a power supply 140 (POWER SUPPLY) that serves to supply power,
It is possible to obtain electromotive force by rotating the magnetic flux due to the movement of electrons only by turning on/off the power with a certain duty to the field winding stacked inside the unit, which is an AC output unit, and the power supply is DC ( Using DC) power, power is cut off and supplied according to a set duty, and while providing different directions to the field, generating alternating electromotive force in the same form as the rotation of the existing rotary synchronous generator,
The unit consists of one or more units, and switching is possible for each unit,
The stacking part of the field winding and the armature inside the unit alternately stacks the field winding and the armature to a hollow core to assemble one unit, and the shape of the core is not limited to a hollow type, but is a triangular or square shape ego,
A non-rotating AC power generator capable of doubling the output voltage, characterized in that the size of the diameter of the inner cylinder is variable, and the hollow diameter serves as a ventilation hole to have a cooling function. According to claim 1,
In the laminated structure of the unit, as the wiring of the electromagnet proceeds in a series and parallel structure, the compressed part is divided into both sides, so that when the unit is compressed, it is not deflected to one side, and the compressive strength can be kept constant while being divided into both sides When the unit is compressed, the line, which used to act as height, is divided into many directions, so when the unit is compressed, it can be compressed with greater strength, making the wiring work easier and more convenient, and the short circuit caused by the compression of the unit A non-rotating AC power generator capable of doubling the output voltage, characterized in that it solves the problem. The unit of claim 1, wherein the AC output unit has a structure in which the number of armatures is greater than the number of electromagnets, and finally, the total height of the stacked units is in close contact with each other due to the increase in compression force, resulting in a compact structure. A non-rotating AC power generator capable of doubling the output voltage, characterized in that. The non-rotating AC power generator capable of doubling the output voltage according to claim 1, characterized in that all armatures constituting the unit have the same height. The method of claim 1, in the case of the first field and the second field inside the unit, when DC electricity is supplied to the first field, the first field is stimulated, the second field is not operated, and then, When DC electricity is supplied to the second field, the second field is stimulated and the first field does not operate, and while the alternating magnetic flux continues to be generated in this way, the alternating magnetic flux is linked to the armature to generate an alternating electromotive force. A non-rotating AC power generator capable of doubling the output voltage, characterized in that it gives more stimulation to the armature than a conventional synchronous generator because the magnetic poles of the first field and the second field interlink.

Images