KR20240064343A - Outer-rotor type permanent magnet synchronous generator - Google Patents

Abstract

The present invention relates to an external rotation type permanent magnet synchronous generator, which includes a casing part installed inside a passage part, a fixed shaft part fixed to the casing part, a stator part installed around the outer periphery of the fixed shaft part, and a stator part installed spaced apart from the stator part. It is characterized by comprising a rotor part, a magnet part installed around the inner circumference of the rotor part, a turbine part installed in the rotor part, a guide part installed in the casing part, and a blade part that cools the internal space of the casing part by blowing. . Therefore, the present invention provides the effect of easily generating power by the flow of small force or wave power and improving power generation efficiency by installing the stator part inside the casing part and installing the rotor part and magnet part in an abduction type around the outer circumference. do.

Description

External-type permanent magnet synchronous generator {OUTER-ROTOR TYPE PERMANENT MAGNET SYNCHRONOUS GENERATOR}

The present invention relates to an abduction type permanent magnet synchronous generator, and more specifically to an abduction type permanent magnet synchronous generator that generates power by the flow of small force or wave power.

In general, an external rotation type permanent magnet generator is provided with a stator in the center in which at least one coil is wound, and a rotor that rotates with a plurality of permanent magnets installed on the outside of the stator.

In such a conventional external electric permanent magnet generator, harmonics are inevitably generated due to the slot openings installed on the stator and through which the coil is wound, and the pitch spacing of the permanent magnets installed on the rotor.

In this way, when harmonics are generated, cogging torque is also inevitably generated. The cogging torque that occurs at this time not only deteriorates the performance of the generator, but also generates vibration and increases noise.

In addition, it was difficult to assemble the permanent magnets installed in large numbers on the rotor due to the repulsive and attractive forces with the adjacent permanent magnets or the installation surface to which they are attached. Additionally, there was a problem in that the permanent magnet was damaged as an impact occurred on the attachment surface of the permanent magnet.

In particular, these permanent magnet rotors are used in large rotors that require high torque at low speeds, such as permanent magnet generators and ship propulsion rotors. In permanent magnet rotators, the magnetized permanent magnets are directly connected to the electrical steel sheet of the rotor, which has a very high magnetic permeability. assembly method was used.

Conventional permanent magnet rotors have a skew (SKEW) structure to secure required performance such as voltage harmonics and torque ripple. In other words, the skew of the rotor is achieved by stacking at least 2 to 3 permanent magnet blocks at a certain angle in the axial direction of the rotor. At this time, each permanent magnet block is installed on laminated electrical steel sheets.

This conventional permanent magnet coupling structure has a structure in which permanent magnets are assembled while each permanent magnet block is laminated on a 05 mm thick electrical steel plate, so manufacturing is very complicated, and when stacking multiple permanent magnet blocks, it is difficult to manufacture. There was a risk that the permanent magnets would be damaged due to the repulsive force between the blocks.

Republic of Korea Patent No. 10-1718249 (March 22, 2017) Republic of Korea Patent No. 10-1339516 (January 10, 2014) Republic of Korea Patent No. 10-1871248 (June 27, 2018)

The present invention was devised to solve the problems of the prior art as described above. By installing the stator part inside the casing part and installing the rotor part and magnet part in an abduction type around the outer circumference, power generation can be easily generated by the flow of small force or wave force. The purpose is to provide an external rotation type permanent magnet synchronous generator that can improve power generation efficiency at the same time.

In addition, the present invention provides a blade unit with a first blade unit on one side and a second blade unit on the other side, so that cooling efficiency for heat generation between the rotor unit and the stator unit can be improved by blowing inward from both ends of the casing unit. Another purpose is to provide a typical permanent magnet synchronous generator.

In addition, the present invention provides an abduction type permanent magnet synchronous generator capable of rotatably supporting the rotor unit and the magnet unit and improving their rotation performance by providing a fixed shaft unit as a fixed shaft unit and a plurality of bearings at both ends. It is for a different purpose.

In addition, the present invention provides an abduction type permanent magnet synchronous generator that can block leakage of magnetic flux generated from the magnet portion in the direction of the rotor frame by providing a shielding ring between the rotor core and the rotor frame as the rotor portion. It serves another purpose.

In addition, the present invention is an abduction type device in which the installation grooves are formed at steps to install the magnets on the rotor core at equal intervals around the inner circumference, thereby allowing the magnets to adhere closely to the inner surface of the rotor core and improving the holding force. Another purpose is to provide a permanent magnet synchronous generator.

In addition, the present invention provides a magnet piece and a magnet support piece as a magnet portion, so that the magnet pieces are installed at equal intervals around the inner circumference of the rotor portion to improve the rotation performance and power generation performance of the magnet piece and at the same time improve the coupling force and support force of the rotor piece. Another purpose is to provide an abduction type permanent magnet synchronous generator that can be improved.

In addition, the present invention is an abduction type permanent magnet synchronous generator that improves the rotation performance and power generation performance of the turbine section and the rotor section by installing guide sections at the upstream and bottom of the casing section, respectively, and at the same time can efficiently flow small force or wave force. Another purpose is to provide.

The present invention for achieving the above object is a permanent magnet synchronous generator that generates power by the flow of small force or wave power, and the casing part (10) installed inside the passage part 200 to generate power by the flow of small force or wave power. ); A fixed shaft portion (20) fixedly installed in the central portion of the casing portion (10); A stator unit (30) installed around the outer periphery of the fixed shaft unit (20); a rotor unit (40) spaced apart from the outer periphery of the stator unit (30); A magnet unit 50 installed around the inner circumference of the rotor unit 40; A turbine unit 60 installed around the outer periphery of the rotor unit 40; A guide part 70 installed around the outer periphery of the casing part 10; and a blade unit coupled to the rotor unit 40 and installed inside the casing unit 10 to cool the internal space of the casing unit 10 by blowing.

The blade unit of the present invention includes a first blade unit 80 installed at one end of the interior of the casing unit 10 to blow air inward; and a second blade unit 90 installed at the other inner end of the casing unit 10 to blow air inward.

The fixed shaft portion 20 of the present invention includes a fixed shaft fixedly installed in the inner central portion of the casing portion 10; a first bearing installed at one end of the inner part of the casing part 10 and one end of the fixed shaft to support rotation of one side of the blade part; a second bearing installed on an outward portion of the first bearing and supporting one end of the fixed shaft; a third bearing installed on the other inner end of the casing part 10 and on the other end of the fixed shaft to rotationally support the other side of the blade part; and a fourth bearing installed on an outward portion of the second bearing and supporting the other end of the fixed shaft.

The stator portion 30 of the present invention includes a stator core installed around the central portion of the fixed shaft portion 20; and a stator coil installed around the outer periphery of the stator core.

The rotor unit 40 of the present invention includes a rotor core spaced apart from the outer periphery of the stator unit 30; A non-magnetic shielding ring installed around the outer circumference of the rotor core; and a rotor frame installed to cover the outer circumference of the shielding ring.

The rotor core of the present invention is characterized by spaced installation grooves to install the magnet portion 50 at equal intervals around the inner circumference.

The shielding ring of the present invention is characterized by being made of a non-magnetic material to block leakage of magnetic flux generated from the magnet portion 50 in the direction of the rotor frame.

The magnet unit 50 of the present invention includes a plurality of magnet pieces spaced apart from each other around the inner circumference of the rotor unit 40; and magnet support pieces installed on both ends of the magnet piece and around the inner circumference of the rotor unit 40 to support the magnet piece.

The magnet support piece of the present invention includes a fitting piece tightly coupled to both sides of the magnet piece; a first ring piece bent at one end of the insertion piece; and a second ring piece bent at the other end of the fitting piece.

The guide part 70 of the present invention includes a first guide that protrudes around one outer side of the casing part 10 and guides the flow by small force or wave force; And a second guide that protrudes around the other outer side of the casing part 10 and guides the flow by small force or wave force.

As seen above, the present invention installs the stator part inside the casing part and installs the rotor part and magnet part in an abduction type around the outer circumference, so that power generation efficiency can be easily generated by the flow of small power or wave power and at the same time, improve power generation efficiency. Provides effective effects.

In addition, by providing the blade portion with a first blade portion on one side and a second blade portion on the other side, air is blown inward from both ends of the casing portion, providing the effect of improving cooling efficiency for heat generation between the rotor portion and the stator portion. .

In addition, by providing a fixed shaft and a plurality of bearings at both ends as the fixed shaft portion, it provides the effect of rotatably supporting the rotor portion and the magnet portion and improving their rotational performance at the same time.

In addition, by providing a shielding ring between the rotor core and the rotor frame as the rotor part, it provides the effect of blocking leakage of magnetic flux generated from the magnet part in the direction of the rotor frame.

In addition, the installation grooves are formed at steps to install the magnets on the rotor core at equal intervals around the inner circumference, thereby providing the effect of bringing the magnets into close contact with the inner surface of the rotor core and improving the holding force.

In addition, by providing a magnet piece and a magnet support piece as the magnet portion, the rotation performance and power generation performance of the magnet piece can be improved by installing the magnet pieces spaced apart at equal intervals around the inner circumference of the rotor portion, and at the same time, the coupling force and support force of the rotating piece can be improved. Provides effective effects.

In addition, by installing guide parts upstream and below the casing part, the rotation performance and power generation performance of the turbine part and the rotor part are improved, while providing the effect of efficiently flowing small force or wave force.

1 is a configuration diagram showing an abduction type permanent magnet synchronous generator according to an embodiment of the present invention.
Figure 2 is a detailed view showing an abduction type permanent magnet synchronous generator according to an embodiment of the present invention.
Figure 3 is a configuration diagram showing the stator portion and the rotor portion of an abduction type permanent magnet synchronous generator according to an embodiment of the present invention.
Figure 4 is a configuration diagram showing the rotor portion of an abduction type permanent magnet synchronous generator according to an embodiment of the present invention.
Figure 5 is a front cross-sectional view showing the rotor portion of an abduction type permanent magnet synchronous generator according to an embodiment of the present invention.
Figure 6 is a side cross-sectional view showing the rotor portion of an abduction type permanent magnet synchronous generator according to an embodiment of the present invention.
Figure 7 is a front cross-sectional view showing another example of the rotor portion of an abduction type permanent magnet synchronous generator according to an embodiment of the present invention.
Figure 8 is a state diagram sequentially showing the coupling operation of the magnet portion of the abduction type permanent magnet synchronous generator according to an embodiment of the present invention.
Figure 9 is a state diagram showing the state before coupling of the magnet portion of the abduction type permanent magnet synchronous generator according to an embodiment of the present invention.
Figure 10 is a state diagram showing the state after coupling of the magnet portion of the abduction type permanent magnet synchronous generator according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

Figure 1 is a configuration diagram showing an abduction type permanent magnet synchronous generator according to an embodiment of the present invention, Figure 2 is a detailed diagram showing an abduction type permanent magnet synchronous generator according to an embodiment of the present invention, and Figure 3 is a diagram showing the present invention. It is a configuration diagram showing the stator portion and the rotor portion of an abduction type permanent magnet synchronous generator according to an embodiment of the invention, and Figure 4 is a configuration diagram showing the rotor portion of an abduction type permanent magnet synchronous generator according to an embodiment of the present invention. , Figure 5 is a front cross-sectional view showing the rotor part of an abduction type permanent magnet synchronous generator according to an embodiment of the present invention, and Figure 6 is a side view showing the rotor part of an abduction type permanent magnet synchronous generator according to an embodiment of the present invention. It is a cross-sectional view, and Figure 7 is a front cross-sectional view showing another example of the rotor part of an abduction type permanent magnet synchronous generator according to an embodiment of the present invention, and Figure 8 is a front cross-sectional view of an abduction type permanent magnet synchronous generator according to an embodiment of the present invention. It is a state diagram sequentially showing the coupling operation of the magnet part, and Figure 9 is a state diagram showing the state before coupling of the magnet part of the abduction type permanent magnet synchronous generator according to an embodiment of the present invention, and Figure 10 is a state diagram according to an embodiment of the present invention. This is a state diagram showing the state after coupling of the magnet part of an abduction type permanent magnet synchronous generator.

As shown in FIG. 1, the abduction type permanent magnet synchronous generator according to this embodiment includes a casing portion 10, a fixed shaft portion 20, a stator portion 30, a rotor portion 40, a magnet portion 50, It is a permanent magnet synchronous generator such as a small hydro generator or wave power generator that includes a turbine unit 60, a guide unit 70, a blade unit, and a power generation unit 100, and generates power by the flow of small hydro power or wave power.

The casing part 10 is a casing member installed inside the passage part 200 to generate power by the flow of small hydropower or wave force, and is streamlined to smoothly move the flow of small hydropower or wave force within the passage part 200. It consists of a casing formed in a curved shape.

The fixed shaft portion 20 is a shaft member fixedly installed in the central portion of the casing portion 10, and as shown in FIG. 2, it includes a fixed shaft 21, a first bearing 22, a second bearing 23, and a third bearing. It consists of a bearing (24) and a fourth bearing (25).

The fixed shaft 21 is a shaft member fixedly installed in the inner central portion of the casing portion 10, and is installed to extend in the left and right directions in the central portion of the casing portion 10 to rotate and support the rotor portion 40.

The first bearing 22 is a rotation support member installed at one end of the inside of the casing part 10 and one end of the fixed shaft 21 to rotate and support one side of the blade part, and is of the first blade part 80. One end is rotated and supported.

The second bearing 23 is a rotation support member installed on the outward portion of the first bearing 22 and supports one end of the fixed shaft 21, and rotationally supports the other end of the first blade portion 80. .

The third bearing 24 is a rotation support member installed at the other inner end of the casing part 10 and the other end of the fixed shaft 21 to rotationally support the other side of the blade part, and is of the second blade part 90. One end is rotated and supported.

The fourth bearing 25 is a rotation support member installed on the outward portion of the second bearing 23 and supports the other end of the fixed shaft 21, and rotationally supports the other end of the second blade portion 90. .

The stator unit 30 is a fixed member fixed to the outer periphery of the fixed shaft unit 20 and spaced apart from the rotor unit 40. As shown in FIG. 3, it consists of a stator core 31 and a stator coil 32. there is.

The stator core 31 is a core member installed around the central portion of the fixed shaft portion 20, and is made up of a plurality of disc-shaped iron cores fixed to the outer periphery of the fixed shaft 21.

The stator coil 32 is a coil member installed around the outer periphery of the stator core 31, and is made up of a plurality of winding coils wound around the outer periphery of the stator core 31 and is connected to the power generation unit 100.

The rotor unit 40 is a rotating member spaced apart around the outer periphery of the stator unit 30 and includes a rotor core 41, a shielding ring 42, and a rotor frame 43, as shown in FIGS. 4 to 7. It consists of

The rotor core 41 is a rotor core member spaced apart around the outer periphery of the stator unit 30, and has a plurality of magnet units 50 around the inner periphery of the rotor core 41, as shown in FIGS. 8 to 10. ) It is preferable that a plurality of installation grooves (41a) are formed at equal intervals to install them at equal intervals.

In this installation groove (41a), a plurality of magnet parts (50) are in close contact with the inner circumferential part of the rotor core (41) and are provided between the inner circumferential surface of the rotor core (41) and the close contact surface of the magnet part (50) for fixed support. Of course, it is possible to be recessed to form a step d of a predetermined distance.

The shielding ring 42 is a non-magnetic shielding member installed around the outer periphery of the rotor core 41, and is made of stainless steel to block leakage of magnetic flux generated from the magnet portion 50 in the direction of the rotor frame 43. It is preferable that it is made of a non-magnetic material such as the like.

The rotor frame 43 is a rotor frame member installed to cover the outer circumference of the shielding ring 42, and is composed of a cylindrical frame to cover the outside of the rotor unit 40.

The magnet unit 50 is a magnet member installed with a plurality of permanent magnets spaced at equal intervals around the inner circumference of the rotor unit 40, and is composed of a magnet piece 51 and a magnet support piece 52.

The magnet piece 51 is a plurality of magnet members installed spaced apart around the inner circumference of the rotor portion 40, and is preferably made of a magnetic material such as a permanent magnet that is curved upward to adhere closely to the inner circumference of the rotor portion 40. .

The magnet support piece 52 is a support member installed on both ends of the magnet piece to support both sides of the magnet piece 51 around the inner circumference of the rotor portion 40 by close contact at two points. It consists of a first ring piece (52a) and a second ring piece (52b).

The fitting piece is a fitting member that is tightly coupled to both sides of the magnet piece 51, and is bent in an approximately "ㄷ" shape so as to be tightly coupled and supported by fitting to both sides of the magnet piece 51. consist of.

The first ring piece (52a) is a ring member bent inward at one end of the fitting piece, and supports one end of both sides of the magnet piece (51), while also fixing and supporting the inward portion of the magnet piece (51).

The second ring piece 52b is a ring member bent at the other end of the fitting piece and is fitted into the installation groove 41a of the rotor core 41 to support the other ends of both sides of the magnet piece 51. Two magnet pieces 51 are fixed and supported on the inner circumference of the rotor core 41.

The turbine unit 60 is a turbine member installed around the outer periphery of the rotor unit 40, and is formed to protrude around the outer periphery of the rotor unit 40 and is curved in a screw-shaped spiral to be rotated by flow by small force or wave force. It consists of multiple turbine blades.

The guide part 70 is a plurality of guide members spaced apart from each other around the outer circumference of the casing part 10, and consists of a first guide 71 and a second guide part 72 that are curved in a screw-shaped spiral.

The first guide 71 is a guide member that protrudes around one outer periphery of the casing portion 10 and guides the flow by small force or wave force, and is made up of a plurality of guide plates curved in a screw-shaped spiral.

The second guide 72 is a guide member that protrudes around the other outer side of the casing portion 10 and guides the flow by small force or wave force, and is composed of a plurality of guide plates curved in a screw-shaped spiral.

The blade unit is a blade member that is coupled to the rotor unit 40 and installed inside the casing unit 10 to cool the internal space of the casing unit 10 by blowing, and includes a first blade unit 80 and a second blade. It consists of parts (90).

The first blade portion 80 is a blade member installed at one end of the inside of the casing portion 10 to blow inward, and includes a plurality of blades curved in a screw-shaped spiral to blow inward toward the center of the casing portion 10. It is made up of a falcon blade.

The second blade portion 90 is a blade member installed at the other inner end of the casing portion 10 to blow inward, and includes a plurality of blades curved in a screw-shaped spiral to blow inward toward the center of the casing portion 10. It is made up of a falcon blade.

The power generation unit 100 is a power generation means installed at the inner rear end of the casing unit 10 and receives power generated in the stator unit 30 by rotation of the rotor unit 40, and is connected to the stator unit 30. The power generated by the rotation of the rotor unit 40 and the magnet unit 50 is received.

As explained above, according to the present invention, by installing the stator part inside the casing part and installing the rotor part and the magnet part in an abduction type around the outer circumference, it is possible to easily generate power by the flow of small power or wave power and at the same time improve power generation efficiency. Provides effective effects.

In addition, by providing the blade portion with a first blade portion on one side and a second blade portion on the other side, air is blown inward from both ends of the casing portion, providing the effect of improving cooling efficiency for heat generation between the rotor portion and the stator portion. .

In addition, by providing a fixed shaft and a plurality of bearings at both ends as the fixed shaft portion, it provides the effect of rotatably supporting the rotor portion and the magnet portion and improving their rotational performance at the same time.

In addition, by providing a shielding ring between the rotor core and the rotor frame as the rotor part, it provides the effect of blocking leakage of magnetic flux generated from the magnet part in the direction of the rotor frame.

In addition, the installation grooves are formed at steps to install the magnets on the rotor core at equal intervals around the inner circumference, thereby providing the effect of bringing the magnets into close contact with the inner surface of the rotor core and improving the holding force.

In addition, by providing a magnet piece and a magnet support piece as the magnet portion, the rotation performance and power generation performance of the magnet piece can be improved by installing the magnet pieces spaced apart at equal intervals around the inner circumference of the rotor portion, and at the same time, the coupling force and support force of the rotating piece can be improved. Provides effective effects.

In addition, by installing guide parts upstream and below the casing part, the rotation performance and power generation performance of the turbine part and the rotor part are improved, and at the same time, it provides the effect of efficiently flowing small force or wave force.

The present invention described above can be implemented in various other forms without departing from its technical idea or main features. Therefore, the above embodiment is merely an example in all respects and should not be construed as limited.

10: Casing part 20: Fixed shaft part
30: stator part 40: rotor part
50: magnet part 60: turbine part
70: Guide part 80: First blade part
90: second blade unit 100: power generation unit

Claims (10)

It is a permanent magnet synchronous generator generated by the flow of small hydropower or wave power,
A casing part (10) installed inside the passage part (200) to generate power by the flow of small hydropower or wave power;
A fixed shaft portion (20) fixedly installed in the central portion of the casing portion (10);
A stator unit (30) installed around the outer periphery of the fixed shaft unit (20);
a rotor unit (40) spaced apart from the outer periphery of the stator unit (30);
A magnet unit 50 installed around the inner circumference of the rotor unit 40;
A turbine unit 60 installed around the outer periphery of the rotor unit 40;
A guide part 70 installed around the outer periphery of the casing part 10; and
An abduction type permanent magnet synchronous generator comprising a blade unit coupled to the rotor unit 40 and installed inside the casing unit 10 to cool the internal space of the casing unit 10. According to claim 1,
The blade part,
A first blade unit 80 installed at one end of the inside of the casing unit 10 to blow air inward; and
An abduction type permanent magnet synchronous generator comprising a second blade unit (90) installed at the other inner end of the casing unit (10) and blowing air inward. According to claim 1,
The fixed shaft portion 20,
A fixed shaft fixedly installed in the inner central portion of the casing portion 10;
a first bearing installed at one end of the inner part of the casing part 10 and one end of the fixed shaft to support rotation of one side of the blade part;
a second bearing installed on an outward portion of the first bearing and supporting one end of the fixed shaft;
a third bearing installed on the other inner end of the casing part 10 and on the other end of the fixed shaft to rotationally support the other side of the blade part; and
A fourth bearing installed on an outward portion of the second bearing and supporting the other end of the fixed shaft. According to claim 1,
The stator part 30 is,
A stator core installed around the central portion of the fixed shaft portion 20; and
An abduction type permanent magnet synchronous generator comprising a stator coil installed around the outer circumference of the stator core. According to claim 1,
The rotor unit 40,
a rotor core installed spaced apart around the outer circumference of the stator unit 30;
A non-magnetic shielding ring installed around the outer circumference of the rotor core; and
An abduction type permanent magnet synchronous generator comprising a rotor frame installed to cover the outer circumference of the shielding ring. According to claim 5,
The rotor core is an abduction type permanent magnet synchronous generator, characterized in that installation grooves are formed to space the magnet portions 50 at equal intervals around the inner circumference. According to claim 5,
The shielding ring is made of a non-magnetic material to block leakage of magnetic flux generated from the magnet unit 50 in the direction of the rotor frame. According to claim 1,
The magnet portion 50 is,
a plurality of magnet pieces spaced apart from each other around the inner circumference of the rotor unit 40; and
An abduction-type permanent magnet synchronous generator comprising: magnet support pieces installed on both ends of the magnet piece to support the magnet piece around the inner circumference of the rotor unit (40). According to claim 8,
The magnet support piece is,
Fitting pieces tightly coupled to both sides of the magnet piece;
a first ring piece bent at one end of the insertion piece; and
An abduction type permanent magnet synchronous generator comprising a second ring piece bent at the other end of the fitting piece. According to claim 1,
The guide part 70 is,
A first guide that protrudes around one outer side of the casing portion 10 and guides the flow by small force or wave force; and
An abduction type permanent magnet synchronous generator comprising a second guide that protrudes around the other outer side of the casing portion (10) and guides the flow by small force or wave force.

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