阅读说明：本技术 一种能源差速器 (Energy differential mechanism ) 是由 杨培应 于 2019-06-29 设计创作，主要内容包括：本发明涉及一种能源差速器。其包括：输出单元,包括输出框架和设置于所述输出框架上的极化线圈和真空频率线圈,所述极化线圈和真空频率线圈的铁芯是永磁铁空心铁体,极化线圈处理电流通过流经所述真空频率线圈,而将所述电能转换至所述输出线圈；输出单元,包括输出线圈和感应线圈和输入线圈,所述输入线圈和输出线圈和感应线圈的铁芯是永磁体,所述感应线圈的能源以感应电能供给输出线圈和供给元器件使用。本发明的有益效果为：这种能源差速器在使用时,用磁场极化能源补回空间单极化数据能源使用,达到处理空间单极化能源使用。(The invention relates to an energy differential. It includes: the output unit comprises an output frame, and a polarizing coil and a vacuum frequency coil which are arranged on the output frame, wherein iron cores of the polarizing coil and the vacuum frequency coil are permanent magnet hollow iron bodies, and the polarizing coil processes current to flow through the vacuum frequency coil so as to convert the electric energy to the output coil; and the output unit comprises an output coil, an induction coil and an input coil, wherein the iron cores of the input coil, the output coil and the induction coil are permanent magnets, and the energy of the induction coil is supplied to the output coil and the components by induction electric energy. The invention has the beneficial effects that: when the energy differential mechanism is used, magnetic field polarized energy is used for supplementing space single-polarized data energy, so that space single-polarized energy can be processed for use.)

1. An energy differential, comprising: the output unit comprises an output frame, and a polarizing coil and a vacuum frequency coil which are arranged on the output frame, wherein iron cores of the polarizing coil and the vacuum frequency coil are permanent magnet hollow iron bodies, and the polarizing coil processes current to flow through the vacuum frequency coil so as to convert the electric energy to the output coil; and the output unit comprises an output coil, an induction coil and an input coil, wherein the iron cores of the input coil, the output coil and the induction coil are permanent magnets, and the energy of the induction coil is supplied to the output coil and the components by induction electric energy.

2. The energy differential of claim 1, wherein the output frame has an input coil disposed thereon, the output frame configured as a square frame, the input coil positively polarizing the electrical energy, the input coil disposed against an edge of the induction coil in the changing magnetic field of the induction coil and the vacuum frequency and polarizing coils.

3. The energy differential of claim 2, wherein the output frame is further provided with a polarizing coil, the polarizing coil varying from the vacuum frequency coil and the output and input coils, the polarizing coil being disposed relative to the vacuum frequency coil edge and in the varying magnetic field of the vacuum frequency coil and the induction coil.

4. An energy differential according to claim 2 or claim 3 wherein the output frame is further provided with induction coils which vary between the vacuum frequency coil and the polarisation coil, the induction coils being disposed peripherally relative to the output and input coils and being located in the varying magnetic fields of the output and input coils and the vacuum frequency and polarisation coils.

5. The energy differential of claim 2, 3 or 4 wherein the output frame is further provided with vacuum frequency coils that vary from the input and output coils and the polarizing coil, the vacuum frequency coils being symmetrically disposed with respect to the polarizing coil in varying magnetic fields of the input and polarizing and output coils and the induction coil.

6. An energy differential according to claim 2, 3, 4 or 5 wherein the output frame is further provided with an output coil which varies from the induction coil and the vacuum frequency coil and the polarisation coil, the output coil being disposed relative to the edge of the induction coil in the varying magnetic field of the vacuum frequency coil and the induction coil and the polarisation coil.

Technical Field

The invention belongs to the technical field of electronics, and particularly relates to an energy differential mechanism.

Background

The invention is the latest technology, and mainly uses the energy polarization vacuum magnetic energy density energy to supplement the single polarization data energy for use, thereby achieving the purpose of supplementing the space single polarization data energy for use.

Disclosure of Invention

In order to achieve the optimal use effect of supplementing space single polarization and polarization data energy change, the invention provides an energy differential mechanism which adopts the energy differential mechanism, and the energy polarized vacuum magnetic energy density energy is used for supplementing the single polarization data energy to use, so that the space single polarization data energy is supplemented to use.

The technical scheme adopted by the invention is as follows:

the invention relates to an energy differential. It includes: the output unit comprises an output frame, and a polarizing coil and a vacuum frequency coil which are arranged on the output frame, wherein iron cores of the polarizing coil and the vacuum frequency coil are permanent magnet hollow iron bodies, and the polarizing coil processes current to flow through the vacuum frequency coil so as to convert the electric energy to the output coil; and the output unit comprises an output coil, an induction coil and an input coil, wherein the iron cores of the input coil, the output coil and the induction coil are permanent magnets, and the energy of the induction coil is supplied to the output coil and the components by induction electric energy.

Preferably, the output frame is provided with an input coil, the output frame is configured as a square frame, the input coil positively polarizes the electric energy, and the input coil is disposed opposite to the edge of each induction coil, and is located in the varying magnetic fields of the induction coil and the vacuum frequency coil and the polarization coil.

Preferably, the receiving frame is further provided with a polarizing coil, the polarizing coil changes in the vacuum frequency coil and the output coil and the input coil, and the polarizing coil is arranged relative to the edge of the vacuum frequency coil and is positioned in the changing magnetic field of the vacuum frequency coil and the induction coil.

Preferably, the output frame is further provided with an induction coil, the induction coil changes in the vacuum frequency coil and the polarization coil, and the induction coil is arranged relative to the edges of the output coil and the input coil and is positioned in the changing magnetic fields of the output coil, the input coil, the vacuum frequency coil and the polarization coil.

Preferably, the output frame is further provided with a vacuum frequency coil, the change of the vacuum frequency coil is changed by the input coil, the output coil and the polarizing coil, and the vacuum frequency coil is symmetrically arranged relative to the polarizing coil and is positioned in the changing magnetic fields of the input coil, the polarizing coil, the output coil and the induction coil.

Preferably, the output frame is further provided with an output coil, the output coil changes in the induction coil, the vacuum frequency coil and the polarization coil, and the output coil is arranged opposite to the edge of the induction coil and is positioned in the changing magnetic field of the vacuum frequency coil, the induction coil and the polarization coil.

Preferably, the output frame is further provided with a permanent magnet, the change of the permanent magnet is changed by the vacuum frequency coil and the output coil, the input coil and the induction coil and the polarization coil, and the permanent magnet is arranged in parallel relative to the inside of the output frame and is positioned in the change magnetic field of the vacuum frequency coil and the output coil, the induction coil and the input coil and the polarization coil.

The invention has the beneficial effects that: when the energy differential mechanism is used, magnetic field polarized energy is used for supplementing space single-polarized data energy, so that space single-polarized energy can be processed for use.

Drawings

FIG. 1 is a schematic view of an energy differential of a preferred embodiment of the present invention.

In the figure: 1. a support; 2. an input coil; 3. an output coil; 4. a vacuum frequency coil; 5. a polarizing coil; 6. an induction coil; 7. and a permanent magnet.

Fig. 2 shows a vacuum frequency coil and a polarization coil provided by the present invention.

Detailed Description

As shown in FIG. 1, the invention provides an energy differential, which comprises an output unit. The energy differential and its various components of the present invention will be described in detail below.

As shown in fig. 2, the present invention provides a vacuum frequency coil and a polarizing coil.

As shown in fig. 1, the output unit comprises an output frame 1, and an input coil 2 and an induction coil 6 which are arranged on the output frame 1, and a vacuum frequency coil 4 and a polarization coil are mutually parallel, wherein input energy of the input coil 2 flows through the vacuum frequency coil 4 and the polarization coil 5, the induction coil 6 and a permanent magnet 7, and the single polarization energy system is processed and combined to be transmitted to the output coil 3.

As shown in fig. 2, the output unit comprises an output frame 1, and a vacuum frequency coil 4 and a polarization coil 5 which are arranged on the output frame 1, wherein the polarization coil 5 processes energy conversion transmission of the permanent magnet 7 and the induction coil 3 to the vacuum frequency coil 4, and the vacuum frequency coil 4 processes energy conversion transmission of the polarization coil 5 to the output coil 3.

As a first preferred embodiment of the output unit, as shown in fig. 1, an input coil 2 is provided on an output frame 1, the output frame 1 is configured as a square frame, the input coil 2 positively polarizes electric power, and the input coil 2 is disposed edgewise with respect to an induction coil 6 in a varying magnetic field of the induction coil 6 and a vacuum frequency coil 4 and a polarization coil 5.

The second preferred embodiment is based on the first preferred embodiment, as shown in fig. 1, the output frame 1 is further provided with a polarizing coil 5, the polarizing coil 5 is changed from the vacuum frequency coil 4, the output coil 3 and the input coil 2, and the polarizing coil 5 is arranged relative to the edge of the vacuum frequency coil 4 and is positioned in the changing magnetic field of the vacuum frequency coil 4 and the induction coil 6.

The third preferred embodiment is based on the second preferred embodiment, as shown in fig. 1, the output frame 1 is further provided with an induction coil 6, the change of the induction coil 6 is changed by the vacuum frequency coil 4 and the polarization coil 5, the induction coil 6 is arranged relative to the edge of the output coil 3 and the input coil 2, and is positioned in the changing magnetic field of the output coil 3 and the input coil 2 and the vacuum frequency coil 4 and the polarization coil 5.

The fourth preferred embodiment is based on the third preferred embodiment, as shown in fig. 1, a vacuum frequency coil 4 is further disposed on the output frame 1, the variation of the vacuum frequency coil 4 is generated by the variation of the input coil 2, the output coil 3 and the polarizing coil 5, and the vacuum frequency coil 4 is symmetrically disposed with respect to the polarizing coil 5 and is located in the varying magnetic field of the input coil 2, the polarizing coil 5, the output coil 3 and the induction coil 6.

The fifth preferred embodiment is based on the fourth preferred embodiment, as shown in fig. 1, the output frame 1 is further provided with an output coil 3, the output coil 3 is changed by the induction coil 6, the vacuum frequency coil 4 and the polarizing coil 5, and the output coil 3 is arranged relative to the edge of the induction coil 6 and is positioned in the changing magnetic field of the vacuum frequency coil 4, the induction coil 6 and the polarizing coil 5.

The sixth preferred embodiment is based on the fifth preferred embodiment, as shown in fig. 1, the output frame 1 is further provided with a permanent magnet 7, the change of the permanent magnet 7 is changed from the vacuum frequency coil 4 and the output coil 3, the input coil 2, the induction coil 6 and the polarization coil 5, the permanent magnet 7 is arranged in parallel relative to the inside of the output frame 1 and is positioned in the changing magnetic field of the vacuum frequency coil 4, the output coil 3, the induction coil 6, the input coil 2 and the polarization coil 5.

Thus, reference may be made to the following as the operating principle of the energy differential of the sixth preferred embodiment:

when energy is input to the input coil 2, whereby a changing magnetic field is present around the input coil 2, the input coil 2 is arranged around the induction coil 6 and the vacuum frequency coil 4 and the permanent magnet 7, so that correspondingly polarized energy is generated in the coils of the induction coil 6 and the vacuum frequency coil 4. Similarly, the input energy of the input coil 2 is supplemented to the single-polarized data energy source from the induction coil 6, the permanent magnet 7, the vacuum frequency coil 4, the polarization coil 5 and the output coil 3 by the polarized electric energy source through the magnetic field in sequence, and the permanent magnet ferromagnetic strength in the coil is supplemented to the single-polarized data energy source by the electric energy polarized vacuum magnetic energy density energy source, so that the space single-polarized data energy source is supplemented to be used.

The present invention is not limited to the above-mentioned preferred embodiments, and any other products in various forms can be obtained by anyone in the light of the present invention, but any changes in the shape or structure thereof, which have the same or similar technical solutions as those of the present application, fall within the protection scope of the present invention.