CN110556999A - Transformer type generator - Google Patents
Transformer type generator Download PDFInfo
- Publication number
- CN110556999A CN110556999A CN201810597742.5A CN201810597742A CN110556999A CN 110556999 A CN110556999 A CN 110556999A CN 201810597742 A CN201810597742 A CN 201810597742A CN 110556999 A CN110556999 A CN 110556999A
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- CN
- China
- Prior art keywords
- iron core
- magnetic flux
- coil
- permanent magnet
- window
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- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K35/00—Generators with reciprocating, oscillating or vibrating coil system, magnet, armature or other part of the magnetic circuit
- H02K35/02—Generators with reciprocating, oscillating or vibrating coil system, magnet, armature or other part of the magnetic circuit with moving magnets and stationary coil systems
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- Engineering & Computer Science (AREA)
- Power Engineering (AREA)
- Synchronous Machinery (AREA)
Abstract
The invention relates in particular to a transformer-type generator similar to the arrangement of a transformer core and coils arranged on the core. The iron core loop is provided with a window space for cutting off the iron core, the iron core window provided with the permanent magnet in the iron core loop corresponds to the position supplementing magnetizer, the iron core window not provided with the permanent magnet in the iron core loop corresponds to the position supplementing permanent magnet, the position supplementing magnetizer and the position supplementing permanent magnet are arranged on a rotor, the position supplementing magnetizer and the position supplementing permanent magnet arranged on the rotor rotate towards the space direction of the iron core window corresponding to each other when the rotor rotates, the position supplementing process is that the position supplementing magnetizer and the position supplementing permanent magnet enter the iron core window when not entering the iron core window, the space between the iron core and the window of the iron core is completely supplemented, and the iron core is moved out of the window of the iron core, so that the change of no magnetic flux, weak magnetic flux, strongest magnetic flux, weak magnetic flux and no magnetic flux can be generated in an iron core loop, and the coil wound on the iron core can generate induced electromotive force corresponding to the change of the magnetic flux in the iron core, thereby achieving the power generation of the transformer type generator.
Description
Technical Field
The invention relates in particular to a transformer-type generator similar to the arrangement of a transformer core and coils arranged on the core.
The iron core loop is provided with a window space for cutting off the iron core, the iron core window provided with the permanent magnet in the iron core loop corresponds to the position supplementing magnetizer, the iron core window not provided with the permanent magnet in the iron core loop corresponds to the position supplementing permanent magnet, the position supplementing magnetizer and the position supplementing permanent magnet are arranged on a rotor, the position supplementing magnetizer and the position supplementing permanent magnet arranged on the rotor rotate towards the space direction of the iron core window corresponding to the position supplementing magnetizer and the position supplementing permanent magnet respectively when the rotor rotates, the position supplementing process is that the position supplementing magnetizer and the position supplementing permanent magnet enter the iron core window when not entering the iron core window, the space between the iron core and the window of the iron core is completely supplemented, and the iron core is moved out of the window of the iron core, at the moment, the changes of no magnetic flux, weak magnetic flux, strongest magnetic flux, weak magnetic flux and no magnetic flux can occur in an iron core loop, and the coil wound on the iron core can generate induced electromotive force corresponding to the change of the magnetic flux in the iron core, so that the purpose of generating electricity by the transformer type generator is achieved.
Background
As is well known, the power generation principle of a generator is that a wire in a magnetic field makes a motion of cutting a magnetic line, or the wire in the magnetic field does not move and the magnetic field moves, so that the wire in the magnetic field generates an induced current.
The traditional excitation coil is electrified to establish a magnetic field, the traditional permanent magnet is electrified to establish a magnetic field, and the traditional magnetic field is explored for improving the efficiency of the generator from coil movement to coil non-movement and permanent magnet movement.
However, in any current exploration for improving the efficiency of the traditional generator, the defects that only the coil embedded in the slot of the generator core bears the magnetic flux, and the coil part not embedded in the slot of the generator core only plays the role of connecting the coil and does not bear the magnetic flux cannot be overcome.
The coil of the traditional generator is composed of a plurality of turns of coils, each turn of coil has the phenomenon that the coil is not embedded in the iron core groove, the coil parts which are not embedded in the iron core groove only play a role in connecting each turn of the coil to form a complete coil, and the resistance of the coil which cannot be embedded in the iron core groove is the bottleneck for improving the efficiency of the traditional generator.
Disclosure of Invention
The invention aims to overcome the bottleneck restricting the improvement of the efficiency of the traditional generator and provide a high-efficiency generator which enables each turn of the generator to bear the action of magnetic flux.
The rotor of the transformer type generator is in a static state in a normal state, when the rotor rotates due to external force, the magnetizer and the permanent magnet which are arranged on the rotor synchronously rotate along with the rotor, gradually move to a window which is disconnected with the corresponding iron core, gradually enter the window, and then move out of the window, wherein the process is the process that the magnetic flux in the iron core is changed from absent to present, from weak to strongest, from strongest to weak, and from weak to absent, namely the process that the coil wound on the iron core generates induced current corresponding to the change of the magnetic flux in the iron core, namely the process that the transformer type generator generates electricity.
The external force drives the rotor of the transformer type generator to regularly rotate, the magnetizer and the permanent magnet on the rotor regularly supplement the position of the iron core window corresponding to the magnetizer and the permanent magnet, regular magnetic flux changes are generated in the iron core, and the coil wound on the iron core generates induced current which changes correspondingly to the regular changing magnetic flux in the iron core, so that the normal power generation of the transformer type generator is realized.
When the external force for driving the rotor of the transformer type generator to rotate disappears, the rotor stops rotating, and the generator stops generating electricity.
Drawings
1 piece of the attached drawings of the invention
FIG. 1 plan view
In the drawings
1-one side bearing of transformer type generator rotor 31
2-iron core of coil ends 4 and 5
3-windows on iron cores of coil ends 4 and 5
4-coil end
5-the other end of the coil
6-iron core of coil ends 7 and 8
7-coil end
8-the other end of the coil
9-windows on iron cores of coil ends 7 and 8
10-position-compensating permanent magnet 11 and rotor 31 connecting rod
11-coil end 7 and 8 iron core window position-complementing permanent magnet
12-coil end
13-the other end of the coil
14-permanent magnets on cores of coil ends 12 and 13
15-N pole iron core of coil ends 12 and 13
16-windows on the cores of coil ends 12 and 13
17-S pole core of coil ends 12 and 13
18-coil end
19-the other end of the coil
20-N pole core of coil ends 18 and 19
21 permanent magnet on iron core of coil ends 18 and 19
22-S pole core of coil ends 18 and 19
23-windows in the cores of coil ends 18 and 19
24-coil end 18 and 19 iron core window complement position magnetizer
25-position-compensating magnetizer 24 and rotor 31 connecting rod
26-Transformer Generator rotor 31 Another side bearing
27-position-compensating permanent magnet 28 and rotor 31 connecting rod
28-coil end 4 and 5 iron core window position-complementing permanent magnet
29-position-compensating magnetizer 30 and rotor 31 connecting rod
30-coil end 12 and 13 iron core window complement position magnetizer
31-transformer type generator rotor
Detailed Description
Referring to the attached figure 1 of the specification, the power generation function of the transformer type generator is realized by the following steps:
In a normal state, the rotor 31 of the transformer type generator is in a static state, and no current is output from the coil end 4 and the other end 5 of the coil, the coil end 7 and the other end 8 of the coil, the coil end 12 and the other end 13 of the coil, and the coil end 18 and the other end 19 of the coil of the transformer type generator.
When the rotor 31 of the transformer type generator is driven to rotate by external force, the position supplementing permanent magnet 28, the position supplementing permanent magnet 11, the position supplementing magnetizer 30 and the position supplementing magnetizer 24 which are arranged on the rotor 31 rotate synchronously with the rotor, when the rotor rotates to the position shown in the attached drawing 1 of the specification, the iron core window 9 of the coil end 7 and the coil end 8 is subjected to position supplementing by the position supplementing permanent magnet 11, and along with the position supplementing, the magnetic fluxes in the iron core 6 of the coil end 7 and the coil end 8 can generate the phenomena of no magnetic flux, weak magnetic flux, strongest magnetic flux, weak magnetic flux and no magnetic flux, wherein the magnetic fluxes generated by the N pole magnetic fluxes of the position supplementing permanent magnets 11 of the coil end 7 and the iron core window of the coil end 8 flow to the S pole through the iron cores 6 of the coil ends.
When an electrical appliance is connected between the coil end 7 and the other end 8 of the coil, alternating current flows. Meanwhile, the windows 23 of the N-pole iron core 20 and the S-pole iron core 22 attached to the two ends of the permanent magnet 21 on the coil ends 18 and 19 compensate the position of the position compensated magnetizer 24, at this time, the N-pole iron core 20 and the S-pole iron core 22 of the coil ends 18 and 19 form a magnetic flux loop through the position compensated magnetizer 24, the magnetic flux in the loop flows from the N pole of the permanent magnet 21 to the S pole, the magnetic flux change process is no magnetic flux, weak magnetic flux, strongest magnetic flux, weak magnetic flux and no magnetic flux, an electric appliance is connected between the coil ends 18 and 19, and alternating current flows through the electric appliance.
Similarly, when the iron core windows 3 of the coil end 4 and the coil end 5 are complemented by the position complementing permanent magnet 28, an alternating current also flows when an electrical appliance is connected between the coil end 4 and the coil end 5. When the window 16 between the coil end 12 and the N-pole iron core 15 and the S-pole iron core 17 of the coil end 13 is complemented by the complement magnetizer 30, an alternating current also flows when an electrical appliance is connected between the coil end 12 and the coil end 13.
The above discussion only takes 4 groups of coils as an example to explain the generation process of the power generation function of each group of coils of the transformer type generator, and in practical application, multiple groups of power generation coils can be arranged according to objective requirements, and the connection mode of the multiple groups of coils can output single-phase alternating current, three-phase alternating current and direct current.
Claims (3)
1. A transformer type generator is characterized in that the structure and arrangement of a coil and an iron core are similar to those of a transformer, the difference is that the coil on the iron core is not connected with a power supply, a window space for disconnecting the iron core is arranged on the iron core, an iron core window provided with a permanent magnet in an iron core loop corresponds to a position-supplementing magnetizer, a window not provided with the permanent magnet in the iron core loop corresponds to the position-supplementing permanent magnet, a rotor is added, a magnetizer and a permanent magnet corresponding to the window space of the iron core are arranged on the rotor, when the rotor rotates, the magnetizer and the permanent magnet arranged on the rotor rotate towards the corresponding iron core window, when the magnetizer and the permanent magnet on the rotor rotate to the iron core window, the change of magnetic flux in the iron core from no-weak to-strong, from strong-weak to no occurs, and the change of the magnetic flux in the iron core is from the magnetizer and the permanent magnet to the iron core window, until the iron core window is completely repaired, and then the iron core window is moved out from the completely repaired iron core window.
The magnetic flux in the iron core loop changes from zero to weak, from weak to strongest, from strongest to weak and from weak to zero, so that the coil wound on the iron core generates induced current corresponding to the magnetic flux change in the iron core, the rotor rotates regularly under the driving of external force, the magnetizer and the permanent magnet arranged on the rotor can regularly complement the corresponding window on the iron core, and the coil wound on the iron core can generate induced current corresponding to the regularly changed magnetic flux in the iron core, thereby achieving the purpose of generating electricity.
2. In a normal state, the rotor 31 of the transformer type generator is in a static state, and no current is output from the coil end 4 and the other end 5 of the coil, the coil end 7 and the other end 8 of the coil, the coil end 12 and the other end 13 of the coil, and the coil end 18 and the other end 19 of the coil of the transformer type generator.
When the rotor 31 of the transformer type generator is driven to rotate by external force, the position supplementing permanent magnet 28, the position supplementing permanent magnet 11, the position supplementing magnetizer 30 and the position supplementing magnetizer 24 which are arranged on the rotor 31 rotate synchronously with the rotor, when the rotor rotates to the position shown in the attached figure 1 of the specification, the position supplemented permanent magnet 11 is supplemented by the coil end 7 and the iron core window 9 of the coil end 8, and along with the position supplementing, the magnetic fluxes in the iron core 6 of the coil end 7 and the coil end 8 can generate the phenomena of no magnetic flux, weak magnetic flux, strongest magnetic flux, weak magnetic flux and no magnetic flux, wherein the magnetic fluxes generated by the N pole magnetic fluxes of the position supplementing permanent magnets 11 of the coil end 7 and the iron core window of the coil end 8 flow to the S pole through the iron cores 6 of the coil ends 7 and 8.
When an electrical appliance is connected between the coil end 7 and the other end 8 of the coil, alternating current flows. Meanwhile, the windows 23 of the N-pole iron core 20 and the S-pole iron core 22 attached to the two ends of the permanent magnet 21 on the coil ends 18 and 19 compensate the position of the position compensated magnetizer 24, at this time, the N-pole iron cores 20 of the coil ends 18 and 19, the S-pole iron core 22 and the position compensated magnetizer 24 form a magnetic flux loop, the magnetic flux in the loop flows from the N pole of the permanent magnet 21 to the S pole, the magnetic flux changes in a non-magnetic flux, weak magnetic flux, strongest magnetic flux, weak magnetic flux and no magnetic flux, and an electric appliance is connected between the coil ends 18 and 19, so that alternating current flows through the electric appliance.
3. Similarly, when the iron core windows 3 of the coil end 4 and the coil end 5 are complemented by the position complementing permanent magnet 28, an alternating current also flows when an electrical appliance is connected between the coil end 4 and the coil end 5. When the window 16 between the coil end 12 and the N-pole iron core 15 and the S-pole iron core 17 of the coil end 13 is complemented by the complement magnetizer 30, an alternating current also flows when an electrical appliance is connected between the coil end 12 and the coil end 13.
The above discussion only takes 4 groups of coils as an example to explain the generation process of the power generation function of each group of coils of the transformer-type power generator, and in practical application, multiple groups of power generation coils can be arranged according to objective needs, and the connection mode among the multiple groups of coils determines that the transformer-type power generator can output single-phase alternating current, three-phase alternating current and direct current.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201810597742.5A CN110556999A (en) | 2018-06-01 | 2018-06-01 | Transformer type generator |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201810597742.5A CN110556999A (en) | 2018-06-01 | 2018-06-01 | Transformer type generator |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN110556999A true CN110556999A (en) | 2019-12-10 |
Family
ID=68736112
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN201810597742.5A Pending CN110556999A (en) | 2018-06-01 | 2018-06-01 | Transformer type generator |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN110556999A (en) |
Citations (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN1302471A (en) * | 1998-05-16 | 2001-07-04 | 韩国能量技术有限公司 | Magnetic circuit for rotating apparatus |
| US20140125178A1 (en) * | 2012-11-05 | 2014-05-08 | Kenneth David Chase | Magnetic electrical generator |
| CN104508960A (en) * | 2012-05-30 | 2015-04-08 | 普罗图特斯有限公司 | An electromagnetic generator transformer |
| CN204669157U (en) * | 2015-05-30 | 2015-09-23 | 谭会 | A kind of disk generator |
| CN106100274A (en) * | 2015-08-28 | 2016-11-09 | 戴珊珊 | The permanent magnet reluctance motor of outer rotor exchange independent excitation |
-
2018
- 2018-06-01 CN CN201810597742.5A patent/CN110556999A/en active Pending
Patent Citations (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN1302471A (en) * | 1998-05-16 | 2001-07-04 | 韩国能量技术有限公司 | Magnetic circuit for rotating apparatus |
| CN104508960A (en) * | 2012-05-30 | 2015-04-08 | 普罗图特斯有限公司 | An electromagnetic generator transformer |
| US20140125178A1 (en) * | 2012-11-05 | 2014-05-08 | Kenneth David Chase | Magnetic electrical generator |
| CN204669157U (en) * | 2015-05-30 | 2015-09-23 | 谭会 | A kind of disk generator |
| CN106100274A (en) * | 2015-08-28 | 2016-11-09 | 戴珊珊 | The permanent magnet reluctance motor of outer rotor exchange independent excitation |
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| PB01 | Publication | ||
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Application publication date: 20191210 |