CA2703677A1 - Magnetic flux interruption electrical generator - Google Patents
Magnetic flux interruption electrical generator Download PDFInfo
- Publication number
- CA2703677A1 CA2703677A1 CA 2703677 CA2703677A CA2703677A1 CA 2703677 A1 CA2703677 A1 CA 2703677A1 CA 2703677 CA2703677 CA 2703677 CA 2703677 A CA2703677 A CA 2703677A CA 2703677 A1 CA2703677 A1 CA 2703677A1
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- CA
- Canada
- Prior art keywords
- magnetic flux
- inductive
- winding
- current
- induced
- Prior art date
- 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.)
- Abandoned
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K19/00—Synchronous motors or generators
- H02K19/16—Synchronous generators
- H02K19/22—Synchronous generators having windings each turn of which co-operates alternately with poles of opposite polarity, e.g. heteropolar generators
- H02K19/24—Synchronous generators having windings each turn of which co-operates alternately with poles of opposite polarity, e.g. heteropolar generators with variable-reluctance soft-iron rotors without winding
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- Engineering & Computer Science (AREA)
- Power Engineering (AREA)
- Synchronous Machinery (AREA)
Abstract
The invention provides an improved electrical generator. The improvement relates to the assembling of the inductor and inductive windings both on the stator one after another and no winding on the rotor, wherein rotor comprises a non ferromagnetic main shaft with ferromagnetic segments on its outer surface as magnetic flux interruption elements, wherein each assembly of an inductor and an inductive winding and the magnetic flux interruption element construct an electrical generator cell, wherein by connecting the conductor windings to a DC current a magnetic flux circuit is generated in the above mentioned cells, wherein by turning the rotor the generated magnetic flux is interrupted and thus an electrical current is induced in the inductive windings.
Description
Magnetic Flux Interruption Electrical Generator The invention provides an improved electrical generator. The improved electrical generator is more simplified and requires less maintenance because of having no windings and related components on the rotor.
Summery Of The Invention The magnetic flux interruption electrical generator, comprising a common ferromagnetic stator with inner cogs, wherein the cogs are winded, wherein every other winding is a conductor with a conductive winding in between, a rotor with a non ferromagnetic shaft and ferromagnetic segments on its outer surface as magnetic flux interruption elements, wherein by connecting the conductor windings to a DC current any combination of a stator cog with a conductor winding, an adjacent stator cog with a conductive winding and a magnetic flux interruption elements can close a magnetic flux circuit, wherein by I
turning the rotor, the magnetic flux circuit will be interrupted in each conductive winding, wherein the conductive windings are charged and thus an electrical current is induced in the inductive windings.
Brief Description Of The Drawings Fig. 1A and1 B show a conceptual demonstration of the magnetic flux interruption electrical generator, comprising a ferromagnetic core, one inductor winding, two inductive windings and one moveable magnetic flux interruption element and the method of generating electricity.
Fig. 2A shows the stator with inductor and inductive windings Fig. 2B shows the rotor with a non ferromagnetic shaft and the ferromagnetic interruption elements on its outer surface.
Fig. 3A and 3B show the assembled AC electrical generator and the generated magnetic fluxes by turning the rotor clockwise.
Fig. 4A and 4B shows the assembled DC electrical generator and the generated magnetic fluxes by turning rotor clockwise.
Description The invention provides a magnetic flux interruption electrical generator and a method of generating electricity. The method of generating electricity according to the invention which is shown in Fig.1 A and Fig. 1 B, comprising the ferromagnetic core(l 01), the magnetic flux interruption element(102), the inductor winding(103), the inductive windings(104) and(105), wherein the magnetic flux interruption element(102) is moveable from position "a" to position "b" and vice versa, wherein by connecting the inductor coil(103) to a DC current, a magnetic field is generated in the inductor winding (103), wherein by means of movement of the magnetic flux interruption element(102) from position "a" to position "b" and vice versa, the induced magnetic fluxes(106) and (107) in inductive windings are interrupted periodically, wherein the inductive windings are charged and thus the electrical current is induced in the inductive windings.
According to the invention, the magnetic flux interruption electrical generator comprises the main components as shown in Fig. 2A and Fig. 2B, being a common ferromagnetic stator cylinder(201) having cogs protruding of out its inner surface, and a rotor(200) having the magnetic flux interruption elements(202) on its outer surface. In the ferromagnetic stator cylinder(201) the cogs have windings, wherein every other winding is a conductor with a conductive winding in between. The rotor(200) comprises a non ferromagnetic main shaft(204), a non ferromagnetic material (203) as holder of the magnetic flux interruption elements that are fixed on its outer surface.
The assembled magnetic flux interruption electrical generator is shown in Fig.
3A/B and Fig. 4A/B, wherein the conductor windings are connected to a DC current, whereby the magnetic fields are generated in the inductors.
In Fig. 3A/B the conductor windings are connected to a DC current, whereby every other magnetic pol is opposite(S or N), as shown in Fig. 3A the magnetic flux circuit (308) is closed from pols "S" to "N" between the inductor winding(305) and the inductive winding(306) through the magnetic flux interruption element(302), wherein the inductive winding(306) is charged and thus the electrical current is induced in the inductive winding(306).
By turning the rotor clockwise from position "a" to position "b" as shown in Fig. 3B, the magnetic flux interruption element(302) moves and interrupts the magnetic flux(308) and closes the magnetic flux circuit(309) between inductive winding(306) and inductor winding(307), wherein the inductive winding(306) will be charged again and thus the electrical current is induced in the inductive winding(306) but the current induced in position "b" is in opposite direction of the current induced in position "a", wherein the Alternative Current(AC) is induced in all inductive windings.
In Fig. 4A/B the conductor windings are connected to a DC current, whereby all the magnetic pols are the same(S or N), as shown in Fig. 4A the magnetic flux circuit(408) is closed from pols "S" to "N" between the inductor winding(405) and the inductive winding(406) through the magnetic flux interruption element(402), wherein the inductive winding(406) is charged and thus the electrical current is induced in the inductive winding(406). By turning the rotor clockwise from position "a" to position "b"
as shown in Fig. 4B, the magnetic flux interruption element(402) moves and interrupts the magnetic flux(408) and closes the magnetic flux circuit(409) between inductive winding(406) and inductor winding (407), wherein the inductive winding(406) will be charged again and thus the electrical current is induced in the winding(406), but in this arrangement the induced current in position "b" is in the same direction of the induced current in position "a", wherein the Direct Current(DC) is induced in all inductive coils.
Summery Of The Invention The magnetic flux interruption electrical generator, comprising a common ferromagnetic stator with inner cogs, wherein the cogs are winded, wherein every other winding is a conductor with a conductive winding in between, a rotor with a non ferromagnetic shaft and ferromagnetic segments on its outer surface as magnetic flux interruption elements, wherein by connecting the conductor windings to a DC current any combination of a stator cog with a conductor winding, an adjacent stator cog with a conductive winding and a magnetic flux interruption elements can close a magnetic flux circuit, wherein by I
turning the rotor, the magnetic flux circuit will be interrupted in each conductive winding, wherein the conductive windings are charged and thus an electrical current is induced in the inductive windings.
Brief Description Of The Drawings Fig. 1A and1 B show a conceptual demonstration of the magnetic flux interruption electrical generator, comprising a ferromagnetic core, one inductor winding, two inductive windings and one moveable magnetic flux interruption element and the method of generating electricity.
Fig. 2A shows the stator with inductor and inductive windings Fig. 2B shows the rotor with a non ferromagnetic shaft and the ferromagnetic interruption elements on its outer surface.
Fig. 3A and 3B show the assembled AC electrical generator and the generated magnetic fluxes by turning the rotor clockwise.
Fig. 4A and 4B shows the assembled DC electrical generator and the generated magnetic fluxes by turning rotor clockwise.
Description The invention provides a magnetic flux interruption electrical generator and a method of generating electricity. The method of generating electricity according to the invention which is shown in Fig.1 A and Fig. 1 B, comprising the ferromagnetic core(l 01), the magnetic flux interruption element(102), the inductor winding(103), the inductive windings(104) and(105), wherein the magnetic flux interruption element(102) is moveable from position "a" to position "b" and vice versa, wherein by connecting the inductor coil(103) to a DC current, a magnetic field is generated in the inductor winding (103), wherein by means of movement of the magnetic flux interruption element(102) from position "a" to position "b" and vice versa, the induced magnetic fluxes(106) and (107) in inductive windings are interrupted periodically, wherein the inductive windings are charged and thus the electrical current is induced in the inductive windings.
According to the invention, the magnetic flux interruption electrical generator comprises the main components as shown in Fig. 2A and Fig. 2B, being a common ferromagnetic stator cylinder(201) having cogs protruding of out its inner surface, and a rotor(200) having the magnetic flux interruption elements(202) on its outer surface. In the ferromagnetic stator cylinder(201) the cogs have windings, wherein every other winding is a conductor with a conductive winding in between. The rotor(200) comprises a non ferromagnetic main shaft(204), a non ferromagnetic material (203) as holder of the magnetic flux interruption elements that are fixed on its outer surface.
The assembled magnetic flux interruption electrical generator is shown in Fig.
3A/B and Fig. 4A/B, wherein the conductor windings are connected to a DC current, whereby the magnetic fields are generated in the inductors.
In Fig. 3A/B the conductor windings are connected to a DC current, whereby every other magnetic pol is opposite(S or N), as shown in Fig. 3A the magnetic flux circuit (308) is closed from pols "S" to "N" between the inductor winding(305) and the inductive winding(306) through the magnetic flux interruption element(302), wherein the inductive winding(306) is charged and thus the electrical current is induced in the inductive winding(306).
By turning the rotor clockwise from position "a" to position "b" as shown in Fig. 3B, the magnetic flux interruption element(302) moves and interrupts the magnetic flux(308) and closes the magnetic flux circuit(309) between inductive winding(306) and inductor winding(307), wherein the inductive winding(306) will be charged again and thus the electrical current is induced in the inductive winding(306) but the current induced in position "b" is in opposite direction of the current induced in position "a", wherein the Alternative Current(AC) is induced in all inductive windings.
In Fig. 4A/B the conductor windings are connected to a DC current, whereby all the magnetic pols are the same(S or N), as shown in Fig. 4A the magnetic flux circuit(408) is closed from pols "S" to "N" between the inductor winding(405) and the inductive winding(406) through the magnetic flux interruption element(402), wherein the inductive winding(406) is charged and thus the electrical current is induced in the inductive winding(406). By turning the rotor clockwise from position "a" to position "b"
as shown in Fig. 4B, the magnetic flux interruption element(402) moves and interrupts the magnetic flux(408) and closes the magnetic flux circuit(409) between inductive winding(406) and inductor winding (407), wherein the inductive winding(406) will be charged again and thus the electrical current is induced in the winding(406), but in this arrangement the induced current in position "b" is in the same direction of the induced current in position "a", wherein the Direct Current(DC) is induced in all inductive coils.
Claims (6)
1.The concept of the magnetic flux interruption electrical generator and the method of generating electricity by interrupting the magnetic flux is shown in Fig.
1A/B, wherein the simplified electrical generator unit comprising a ferromagnetic core(101), an inductor winding(103), two inductive windings(104) and (105), and a magnetic flux interruption element(102), wherein the magnetic flux interruption element(102) is moveable from position "a" to position "b" and vice versa, wherein by connecting the inductor winding (103) to a DC current, a magnetic field is generated in the inductor winding(103), wherein by means of movement of the magnetic flux interruption element(102) from position "a" to position "b" and vice versa, the generated magnetic flux(106) and(107) in the inductive windings(104) and (105) are interrupted periodically, wherein the inductive windings(104) and (105) are charged and thus an electrical current is induced in the inductive windings(104)and (105).
1A/B, wherein the simplified electrical generator unit comprising a ferromagnetic core(101), an inductor winding(103), two inductive windings(104) and (105), and a magnetic flux interruption element(102), wherein the magnetic flux interruption element(102) is moveable from position "a" to position "b" and vice versa, wherein by connecting the inductor winding (103) to a DC current, a magnetic field is generated in the inductor winding(103), wherein by means of movement of the magnetic flux interruption element(102) from position "a" to position "b" and vice versa, the generated magnetic flux(106) and(107) in the inductive windings(104) and (105) are interrupted periodically, wherein the inductive windings(104) and (105) are charged and thus an electrical current is induced in the inductive windings(104)and (105).
2. According to claim 1, the magnetic flux interruption electrical generator comprises the main components as shown in Fig. 2 A/B, a common ferromagnetic stator cylinder (201), and a rotor (200) having the magnetic flux interruption elements (202) on its outer surface. In the ferromagnetic stator cylinder (201) the cogs are winded, wherein every other winding is a conductor with a conductive coil in between. The rotor (200) comprises a non ferromagnetic main shaft (204) and a non ferromagnetic material (203) as holder of the magnetic flux interruption elements that are fixed on its outer surface.
3. According to claim 2, the assembled magnetic flux interruption electrical generator is shown in Fig. 3A/B, wherein the conductor windings are connected to a DC
current, whereby the every other magnetic pol is opposite (S or N), as shown in figure 3A the magnetic flux circuit (308) is closed from pols "S" to "N" between the inductor coil (305) and the inductive coil(306) through the magnetic flux interruption element(302), wherein the inductive coil (306) is charged and thus the electrical current is induced in the inductive coil (306). By turning the rotor clockwise, from position "a" to position "b"
as shown in Figure 3B, the magnetic flux interruption element(302) moves and interrupts the magnetic flux(308) and closes the magnetic flux circuit(309) between the inductive coil (306) and the inductor coil(307), wherein the inductive coil(306) will be charged again and thus the electrical current is induced in the inductive winding (307) but the induced current in position "b" is in the opposite direction of the induced current in position "a", wherein the Alternative Current(AC) is induced in all the inductive windings.
current, whereby the every other magnetic pol is opposite (S or N), as shown in figure 3A the magnetic flux circuit (308) is closed from pols "S" to "N" between the inductor coil (305) and the inductive coil(306) through the magnetic flux interruption element(302), wherein the inductive coil (306) is charged and thus the electrical current is induced in the inductive coil (306). By turning the rotor clockwise, from position "a" to position "b"
as shown in Figure 3B, the magnetic flux interruption element(302) moves and interrupts the magnetic flux(308) and closes the magnetic flux circuit(309) between the inductive coil (306) and the inductor coil(307), wherein the inductive coil(306) will be charged again and thus the electrical current is induced in the inductive winding (307) but the induced current in position "b" is in the opposite direction of the induced current in position "a", wherein the Alternative Current(AC) is induced in all the inductive windings.
4. According to claim 2, the assembled magnetic flux interruption electrical generator is shown In Fig. 4A/B, wherein the conductor windings are connected to a DC
current, whereby all the magnetic pols are the same(S or N), as shown in Fig. 4A the magnetic flux circuit(408) is closed from pols "S" to "N" between the inductor winding (405) and the inductive winding(406) through the magnetic flux interruption element (402), wherein the inductive winding(406) is charged and thus the electrical current is induced in the inductive winding(406). By turning the rotor clockwise from position "a"
to position "b" as shown in Fig. 4B, the magnetic flux interruption element(402) moves to interrupt the magnetic flux(408) and closes the magnetic flux circuit(409) between the inductive winding(406) and the inductor winding(407), wherein the inductive
current, whereby all the magnetic pols are the same(S or N), as shown in Fig. 4A the magnetic flux circuit(408) is closed from pols "S" to "N" between the inductor winding (405) and the inductive winding(406) through the magnetic flux interruption element (402), wherein the inductive winding(406) is charged and thus the electrical current is induced in the inductive winding(406). By turning the rotor clockwise from position "a"
to position "b" as shown in Fig. 4B, the magnetic flux interruption element(402) moves to interrupt the magnetic flux(408) and closes the magnetic flux circuit(409) between the inductive winding(406) and the inductor winding(407), wherein the inductive
5 winding(406) will be charged again and thus the electrical current is induced in the inductive winding(406) but in this arrangement the induced current in position "b" is in the same direction as the induced current in position "a", wherein the Direct Current(DC) is induced in all the inductive windings.
Drawings Figure 1A
Figure 1B
Figure 2A
Figure 2B
Figure 3A
Figure 3B
Figure 4A
Figure 4B
Drawings Figure 1A
Figure 1B
Figure 2A
Figure 2B
Figure 3A
Figure 3B
Figure 4A
Figure 4B
6
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CA 2703677 CA2703677A1 (en) | 2010-06-08 | 2010-06-08 | Magnetic flux interruption electrical generator |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CA 2703677 CA2703677A1 (en) | 2010-06-08 | 2010-06-08 | Magnetic flux interruption electrical generator |
Publications (1)
Publication Number | Publication Date |
---|---|
CA2703677A1 true CA2703677A1 (en) | 2011-12-08 |
Family
ID=45217982
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CA 2703677 Abandoned CA2703677A1 (en) | 2010-06-08 | 2010-06-08 | Magnetic flux interruption electrical generator |
Country Status (1)
Country | Link |
---|---|
CA (1) | CA2703677A1 (en) |
-
2010
- 2010-06-08 CA CA 2703677 patent/CA2703677A1/en not_active Abandoned
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Legal Events
Date | Code | Title | Description |
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FZDE | Dead |
Effective date: 20130610 |