CN110620441A

CN110620441A - Heat changer

Info

Publication number: CN110620441A
Application number: CN201910581731.2A
Authority: CN
Inventors: 杨培应
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-06-30
Filing date: 2019-06-30
Publication date: 2019-12-27

Abstract

The invention relates to a heat changer. It includes: the output unit comprises an output frame, and an input coil, a vacuum frequency coil and an induction coil which are arranged on the output frame, wherein iron cores of the input coil, the vacuum frequency coil and the induction coil are permanent magnets, and energy input by the input coil flows through the vacuum frequency coil to convert the electric energy into the induction coil and the output coil; and the output unit comprises an output coil and a heater, wherein the iron core of the input coil is a permanent magnet, the heater is provided with a vacuum frequency coil, and the energy of the vacuum frequency coil is supplied to the induction coil and the output coil for use. The invention has the beneficial effects that: when the heat converter is used, the current polarized permanent magnet is used for forming the magnetic fluid and combining the current to heat the current for transmission, so that the current space transmission distance is increased.

Description

Heat changer

Technical Field

The invention belongs to the field of electronic machinery, and particularly relates to a heat changer.

Background

The invention relates to a novel technology which mainly uses magnetic energy to periodically release heat energy to combine and output current for use, thereby improving the electric energy use efficiency and the current space transmission use efficiency.

Disclosure of Invention

In order to improve the optimal use efficiency of a current energy space transmission system, the invention provides a heat changer. The current polarized permanent magnet for the heat converter is adopted to form a magnetic fluid combined with current heating and current transmission, so that the current space transmission distance is increased.

The technical scheme adopted by the invention is as follows:

the invention relates to a heat changer. It includes: the output unit comprises an output frame, and an input coil, a vacuum frequency coil and an induction coil which are arranged on the output frame, wherein iron cores of the input coil, the vacuum frequency coil and the induction coil are permanent magnets, and energy input by the input coil flows through the vacuum frequency coil to convert the electric energy into the induction coil and the output coil; and the output unit comprises an output coil and a heater, wherein the iron core of the input coil is a permanent magnet, the heater is provided with a vacuum frequency coil, and the energy of the vacuum frequency coil is supplied to the induction coil and the output coil for use.

Preferably, the output frame is provided with an input coil, the output frame is configured as a square frame, the input coil is changed in the output coil and the vacuum frequency coil and the heater and the induction coil, and the input coil is arranged in the heater and is positioned in the changing magnetic field of the vacuum frequency coil.

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

Preferably, the output frame is further provided with a vacuum frequency coil, the change of the vacuum frequency coil is changed from the output coil and the induction coil and the heater, and the vacuum frequency coil is arranged opposite to the edge of the induction coil and is positioned in the change magnetic field of the output coil and the induction coil.

Preferably, the output frame is further provided with a heater, the heater is changed from the input coil, and the heater is arranged relative to the edge of the input 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 input 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 and the induction coil.

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

The invention has the beneficial effects that: when the heat converter is used, the current polarized permanent magnet is used for forming the magnetic fluid and combining the current to heat the current for transmission, so that the current space transmission distance is increased.

Drawings

Fig. 1 is a schematic view of a heat changer according to 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. an induction coil; 6. a heater; 7. and a permanent magnet.

Detailed Description

As shown in fig. 1, the present invention provides a thermal converter, which includes an output unit. The heat detector of the present invention and its various parts will be described in detail below.

As shown in fig. 1, the output unit includes an output frame 1, an input coil 2 and a heater 6 which are arranged on the output frame 1, a vacuum frequency coil 4, an induction coil 5 and an output coil 3 which are mutually parallel, electric energy input by the input coil 2 flows through the heater 6 and the permanent magnet 7 to heat the permanent magnet 7 to form a thermal magnetic fluid, electric energy input by the input coil 2 passes through the vacuum frequency coil 4 to form periodic magnetic energy to fuse the magnetic energy of the permanent magnet 7 and the heater 6, and the induction coil 5 induces the magnetic energy of the vacuum frequency coil 4 to transmit to the sub-output coil 4.

As a first preferred embodiment of the power output unit, as shown in fig. 1, an input coil 2 is further provided on an output frame 1, the output frame 1 is configured as a square frame, the input coil 2 is changed in the output coil 3 and the vacuum frequency coil 4 and the heater 6 and the induction coil 5, and the input coil 2 is provided inside the heater 6 and is located in the changing magnetic field of the vacuum frequency coil 4.

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

The third preferred embodiment is based on the second preferred embodiment, as shown in fig. 1, a vacuum frequency coil 4 is further disposed on the output frame 1, the change of the vacuum frequency coil 4 is changed by the output coil 3, the induction coil 5 and the heater 6, and the vacuum frequency coil 4 is disposed opposite to the edge of the induction coil 5 and is located in the changing magnetic field of the output coil 3 and the induction coil 5.

The fourth preferred embodiment is based on the third preferred embodiment, as shown in fig. 1, the output frame 1 is further provided with a heater 6, the change of the heater 6 is changed from the input coil 2, and the heater 6 is arranged relative to the edge of the input coil 2.

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 from the induction coil 5, the vacuum frequency coil 4 and the input coil 2, and the output coil 3 is arranged relative to the edge of the induction coil 5 and is positioned in the changing magnetic field of the vacuum frequency coil 4 and the induction 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 output coil 3, the vacuum frequency coil 4, the input coil 2 and the heater 6, the permanent magnet 7 is arranged in parallel with the heater 6 relative to the inside of the output frame 1, and is positioned in the changing magnetic fields of the output coil 3, the vacuum frequency coil 4, the input coil 2 and the induction coil 5.

Thus, as the operation principle of the thermoswitzer of the tenth preferred embodiment, reference can be made to the following:

when the electric energy input by the input coil 2 flows through the heater 6 and the permanent magnet 7 to heat the permanent magnet 7 to form a heat energy magnetic fluid, the electric energy input by the input coil 2 passes through the vacuum frequency coil 4 to form periodic magnetic energy to fuse the magnetic energy of the permanent magnet 7 and the heater 6, and the induction coil 5 induces the magnetic energy transmission sub-output coil 3 of the vacuum frequency coil 4. Similarly, the electric energy of the input coil 2 sequentially uses a magnetic energy system from the heater 6, the permanent magnet 7, the vacuum frequency coil 4, the induction coil 5 and the output coil 3 through a magnetic field, and the magnetic strength of the permanent magnet in the coil forms magnetic fluid combination current heating current transmission by using current polarization permanent magnet to achieve the purpose of improving the current space transmission distance.

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.

Claims

1. A thermal transducer, comprising: the output unit comprises an output frame, and an input coil, a vacuum frequency coil and an induction coil which are arranged on the output frame, wherein iron cores of the input coil, the vacuum frequency coil and the induction coil are permanent magnets, and energy input by the input coil flows through the vacuum frequency coil to convert the electric energy into the induction coil and the output coil; and the output unit comprises an output coil and a heater, wherein the iron core of the input coil is a permanent magnet, the heater is provided with a vacuum frequency coil, and the energy of the vacuum frequency coil is supplied to the induction coil and the output coil for use.

2. The electric energy input by the input coil flows through the heater and the permanent magnet to heat the permanent magnet to form a heat energy magnetic fluid, the electric energy of the input coil passes through the vacuum frequency coil to form periodic magnetic energy to fuse the magnetic energy of the permanent magnet and the heater, and the induction coil induces the magnetic energy transmission sub-output coil of the vacuum frequency coil.

3. A thermistor according to claim 1, characterized in that an input coil is arranged on the output frame, which output frame is configured as a square frame, the input coil varying in output coil and vacuum frequency coil and heater and induction coil, the input coil being arranged in relation to the heater interior, in the varying magnetic field of the vacuum frequency coil.

4. A heat transducer according to claim 2, wherein the output frame is further provided with an induction coil which varies from the input coil and the vacuum frequency coil and the output coil, the induction coil being disposed peripherally relative to the vacuum frequency coil and the output coil in the varying magnetic field of the output coil and the vacuum frequency coil.

5. A heat changer as claimed in claim 2 or 3, wherein the output frame is further provided with a vacuum frequency coil which varies between the output coil and the induction coil and the heater, the vacuum frequency coil being disposed opposite the edge of the induction coil in the varying magnetic field of the output coil and the induction coil.

6. The thermal changer of claim 2, 3 or 4, wherein the output frame is further provided with a heater, the heater variation being in the input coil variation, the heater being disposed relative to the input coil edge.

7. The heat changer as claimed in claim 2, 3, 4 or 5, wherein the output frame is further provided with an output coil, the output coil varies from the induction coil and the vacuum frequency coil and the input coil, and the output coil is disposed opposite to the edge of the induction coil and is located in the varying magnetic field of the vacuum frequency coil and the induction coil.