KR100965481B1 - Hub of flywheel for energy storage - Google Patents

Abstract

The present invention relates to a hub of an energy storage flywheel that is not only expandable at high speeds but also prevents stress concentration and further has a high resonant frequency compared to the rotational speed. The hub of the energy storage flywheel according to the present invention is provided in the flywheel for energy storage, and has a hub formed with a plurality of grooves spaced apart from each other along the circumferential direction and formed concave with respect to the insertion hole and the outer surface into which the rotating shaft is inserted. main body; And a plurality of hub blades each disposed on an outer surface of the hub body so as to surround the outer surface of the hub body, and having a plurality of hub blades each having a protrusion inserted into the groove, wherein the protrusion is disposed to be inclined with respect to the insertion direction of the protrusion and has a flat inclined surface. The groove portion is configured to have a flat tapered surface in contact with the inclined surface to be relatively slidable relative to the inclined surface of the protrusion.

Energy storage, flywheel, hub, multi-layers type rotor

Description

Hub of the flywheel for energy storage

The present invention relates to a hub of an energy storage flywheel, and more particularly, to a hub provided in an energy storage flywheel and coupled between a rotating shaft and a rotor.

The energy storage device using the flywheel is a device that stores surplus power as inertial energy of a rotating body, which has higher energy storage efficiency, instant charging and discharging than conventional mechanical energy storage and chemical energy storage devices, and performs at low temperature. It is widely used because of its advantage.

1 shows a flywheel used for energy storage. Referring to FIG. 1, the flywheel 300 includes a rotation shaft 310, a hub 320 into which the rotation shaft 310 is inserted, and a multilayer rotor 330 coupled to the hub to surround the hub 320. . The hub 320 is designed to solve a problem of a solid-type hub and is configured in a split-type as well disclosed in Korean Patent No. 10-0644458. That is, as shown in FIG. 2, the plurality of slits 321 are formed long along the circumferential direction of the hub 320, and a wing portion 322 is formed between the pair of slits 321. . Therefore, when the flywheel 300 is rotated, especially at high speed, the wing 332 can be easily expanded in the radial direction.

By the way, when the rotor 320 is rotated at high speed so as to store a large amount of energy, especially when the rotor 320 is rotated, the wing 332 of the hub is shown in FIG. 2 while expanding radially by the centrifugal force. As it is, there is a problem in that stress is concentrated at both ends of the wing portion 332 so that the stress concentration site is easily broken. As a result, the split type hub 320 was limited in durability.

The present invention has been made to solve the above problems, the object of the present invention is not only expandable during high-speed rotation, but also to prevent stress concentration and further improved energy storage structure to have a high resonant frequency compared to the rotational speed To provide the hub of the flywheel.

In order to achieve the above object, the hub of the energy storage flywheel according to the present invention is provided in the flywheel for energy storage, is formed concave with respect to the insertion hole and the outer surface is inserted into the rotating shaft and spaced apart from each other along the circumferential direction A hub body having a plurality of grooves formed therein; And a plurality of hub blades each disposed on an outer surface of the hub body so as to surround the outer surface of the hub body, each of which has a protrusion inserted into the groove, wherein the protrusion is inclined with respect to the insertion direction of the protrusion. The flat inclined surface is disposed, the groove portion is characterized in that the flat tapered surface in contact with the inclined surface to be relatively sliding relative to the inclined surface of the protrusion.

In addition, the hub of another type of energy storage flywheel according to the present invention for achieving the above object is provided in the flywheel for energy storage, is formed to protrude with respect to the insertion hole and the outer surface is inserted into the rotating shaft and along the circumferential direction A hub body having a plurality of protrusions disposed to be spaced apart from each other; And a plurality of hub blades each disposed on an outer side surface of the hub body to surround the outer side surface of the hub body, and each of which has a groove portion into which the protrusions are inserted, wherein the protrusions have an insertion direction of the protrusion portion. An inclined surface disposed to be inclined is formed, and the groove portion is formed with a tapered surface in contact with the inclined surface to be relatively slidable with respect to the inclined surface of the protrusion.

According to the present invention, it is possible to significantly reduce the stress generated in the hub at high speed rotation. In addition, the inclined surface of the hub body and the inclined surface of the hub blade even at high speed rotation Slips occur between them, preventing stress concentrations on the hub and ultimately improving the durability of the hub. do. In addition, it is possible to easily adjust the expansion amount of the hub blade. In addition, the hub may be designed to have a higher resonance frequency than in the prior art.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

Figure 3 is a schematic perspective view of the hub of the energy storage flywheel according to the first embodiment of the present invention, Figures 4 and 5 are respectively a schematic perspective view of the hub body and the hub blade shown in Figure 3, Figure 6 3 is a schematic cross-sectional view for explaining the coupling structure of the hub body and the hub blade shown in FIG.

3 to 6, the hub 100 of the flywheel for energy storage according to the present embodiment includes a hub body 10 and a hub blade 20.

The hub body 10 is formed in a circular plate shape as a whole. The hub body 10 has an insertion hole 11 through which a rotating shaft (not shown) is inserted. Then, the rotating shaft is inserted into the insertion hole 11 to be integral with the hub body 10 through an interference fit method or a separate fixing structure.

The hub body 10 is formed with a plurality of grooves 12 concave with respect to the outer surface of the hub body 10. The plurality of grooves 12 are arranged to be equally spaced from each other along the circumferential direction of the hub body 10. In addition, each of the grooves 12 is formed to be completely open to both sides of the hub body 10 in the thickness direction. In addition, each groove portion 12 has a bottom surface 121, a pair of first side surfaces 122, a pair of tapered surfaces 123, and a pair of second side surfaces formed flat as shown in the drawing. It is formed partitioned by 124.

The hub blades 20 are provided in plural numbers corresponding to the number of the groove portions 12. Each hub blade 20 is formed with a protrusion 21. The protrusion 21 is formed in a shape corresponding to the groove 12 and is inserted into the groove 12. As such, when the protrusions 21 are inserted into the grooves 12, the plurality of hub blades 20 surround the hub body 10 to form a circle. The protrusion 21 includes a bottom surface 211, a pair of first side surfaces 212, a pair of inclined surfaces 213, and a pair of second side surfaces 214 to correspond to the shape of the groove 12. do.

The bottom surface 211 is formed in a flat plane shape disposed perpendicular to the insertion direction of the protrusion. In particular, the insertion direction of the protrusion 21 in the present embodiment is the same as the radial direction of the hub body.

The pair of first side surfaces 212 are respectively disposed at both sides of the bottom surface 211 and are orthogonally connected to the bottom surface 211.

The pair of inclined surfaces 213 are each formed in a flat planar shape that is inclined with respect to the insertion direction of the protrusion 21, and are inclinedly connected to the pair of first side surfaces 212, respectively. In particular, in the present embodiment, the pair of inclined surfaces 213 are disposed on both sides with respect to the imaginary plane P passing through the center line of the protrusion, and are arranged symmetrically about the imaginary plane P. The pair of inclined surfaces 213 are disposed such that the distance therebetween gradually increases as the insertion direction of the protrusion 21 is increased.

The pair of second side surfaces 214 are connected to the pair of inclined surfaces 213, respectively.

The pair of second side surfaces 214 are each disposed in parallel with the first side surface 212, and the distance between the pair of second side surfaces 214 is smaller than the distance between the pair of first side surfaces 212. .

As such, the protrusion 21 may have a dovetail shape to include a bottom surface 211, a pair of first side surfaces 212, a pair of inclined surfaces 213, and a pair of second side surfaces 214. It is formed and inserted into the groove portion 12 in a close-fitting method. When the protrusion 21 is inserted into the groove 12, the bottom surface 211, the pair of first side surfaces 212, the pair of inclined surfaces 213, and the pair of second side surfaces of the protrusion 21 are provided. 214 presses each other in contact with the bottom surface 121 of the groove 12, the pair of first side surfaces 122, the pair of tapered surfaces 123 and the pair of second side surfaces 124, respectively. Done. In addition, the pair of inclined surfaces 213 are in contact with the tapered surface 123 of the groove 12, and relative sliding is possible with respect to the tapered surface 123.

On the other hand, it is shown in the figure that the sharp portions of the grooves 12 and the protrusions 21 are rounded to prevent stress concentration.

In the hub 100 of the energy storage flywheel configured as described above, the tapered surface 123 of the hub body is configured to contact each other in contact with the inclined surface 213 of the hub blade. Therefore, even if the hub blade 20 is moved radially by the centrifugal force during the high speed rotation of the flywheel, sliding or slippage occurs between the tapered surface 123 of the hub body and the inclined surface 213 of the hub blade. Therefore, unlike the related art, it is possible to prevent a phenomenon in which stress is concentrated. That is, since the stress can be dispersed even during the high speed rotation of the flywheel, the durability of the hub 100 can be increased. In addition, unlike the related art, when the flywheel rotates at a high speed, the hub blades 20 can be moved better in the radial direction with respect to the hub body.

In addition, if the degree of inclination of the tapered surface 123, that is, the inclination angle formed by the tapered surface 123 and the first side surface 122, is adjusted, the hub blade 20 moves in the radial direction at high speed. That is, the expansion amount of the hub blade 20 can be easily adjusted. For example, under the same operating conditions, as the angle of inclination decreases, the amount of expansion of the hub blades 20 increases, and as the angle of inclination increases, the amount of expansion of the hub blades 20 can be reduced.

In addition, since the hub 100 is configured to include the hub body 10 and the plurality of hub blades 20, the hub 100 can be easily designed to have a higher resonance frequency than in the prior art.

In conclusion, according to the present invention, it is possible to wisely reduce the stress acting on the hub 100 during high speed rotation, and further, to manufacture the hub 100 having a resonance frequency higher than the operating speed. Then, the hub blade 20 can be moved better in the radial direction.

7 is a schematic cross-sectional view for explaining the coupling structure of the hub body and the hub blade according to the second embodiment of the present invention. The same components as those of the first embodiment of the present invention are indicated with the same reference numerals, and somewhat changed, but corresponding components are indicated with the addition of 'a', and the second embodiment of the present invention is the same as the first embodiment. The descriptions of the parts are duplicated, so the description of the parts is omitted.

Referring to FIG. 7, in the present embodiment, the slot 215 is formed in the protrusion 21a of the hub blade 20a. The slot 215 penetrates one end of the protrusion 21, that is, the bottom surface 211 of the protrusion, and is formed long in the insertion direction of the protrusion 21.

Thus, in the present embodiment, the slot 215 is formed in the protrusion 21, so that the hub blade 20a can be moved more easily in the radial direction during the high speed rotation of the flywheel. Therefore, when the flywheel rotates at the same speed, the hub blade 20a is stretched more than in the first embodiment.

And, due to the slot formed in the protrusion 21, it is possible to relieve the stress acting on the protrusion 21 during high-speed rotation and further increase the amount of interference fit of the protrusion 21.

8 is a schematic cross-sectional view for explaining the coupling structure of the hub body and the hub blade according to the third embodiment of the present invention.

Referring to Fig. 8, in the present embodiment, the shape of the protrusion 21b of the hub blade 20b is formed differently from the protrusion 21a of the second embodiment. That is, the protrusion 21b is connected to the bottom surface 211, a pair of inclined surfaces 213 and each inclined surface 213 disposed on both sides of the bottom surface and inclinedly connected to the bottom surface, respectively. It is configured to include a side 214 disposed orthogonally. The protrusion 21b is formed with a slot 215 penetrating through the bottom surface 211.

Moreover, each groove part of the hub blade | wing 10b is formed so that it may correspond to the shape of the protrusion part 21b. That is, the groove portion is partitioned and formed by the bottom surface 121, the pair of tapered surfaces 123, and the pair of second side surfaces 124.

9 is a schematic cross-sectional view for explaining a coupling structure of the hub body and the hub blade according to the fourth embodiment of the present invention.

Referring to FIG. 9, in the present embodiment, the shape of the protrusion 21c of the hub blade 20c is formed in a two-stage shape so as to be different from the protrusions in the first, second and third embodiments. It is. That is, the inclined surfaces 213 and 217 of the protrusions 21c are disposed on both sides of the protrusion 21c to be spaced apart from each other along the insertion direction of the protrusions 21c. Thus, a total of four inclined surfaces 213 and 217 are disposed symmetrically with respect to the imaginary plane P. Each distance between the pair of symmetrical inclined surfaces 213 and 217, that is, the distance between the inclined surfaces 213 and the inclined surface 217 increases toward the insertion direction of the protrusion 212c.

In addition, the bottom portion 211, the connection surface 216, and the side surface 214 are further formed on the protrusion 21c. The bottom surface 211 is connected to a pair of inclined surfaces 213 that are inserted deepest in the groove portion among the inclined surfaces 213 and 217. The connecting surface 216 interconnects a pair of inclined surfaces 213 and 217 disposed on both sides of the virtual plane P, respectively. The connection surface 216 has a flat planar shape and is disposed in parallel with the bottom surface 211. The side surface 214 is disposed orthogonal to the bottom surface 211 and connected to the pair of inclined surfaces 217, respectively. The protrusion 21c is formed with a slot 215 penetrating through the bottom surface 211.

And each groove part of the hub blade | wing 10c is formed so that it may correspond to the shape of the protrusion part 21c. That is, the groove portion is divided and formed by the bottom surface 121, the four tapered surfaces 123 and 127, the connection surface 126, and the pair of second side surfaces 124c.

In particular, the shape of the protrusion in the present embodiment, for example, the number of stages or the number of inclined surfaces may be variously set by factors such as the size of the hub and the rotational speed of the rotor.

As mentioned above, the present invention has been described in detail with reference to preferred embodiments, but the present invention is not limited to the above embodiments, and various modifications may be made by those skilled in the art within the technical idea of the present invention. It is obvious.

For example, in the first, second, third and fourth embodiments, a plurality of grooves are formed in the hub body, and protrusions inserted into the grooves are formed in the hub blades, but a plurality of protrusions are formed in the hub body. It may be configured to form a groove portion is formed and each protrusion is inserted into each hub blade.

Further, in the first embodiment, the distance between the first side surface of the groove portion is formed larger than the distance between the second side surface, but may be configured to the contrary.

1 is a schematic partial cutaway perspective view of a flywheel for energy storage according to a conventional example.

FIG. 2 is a schematic cutaway perspective view of the hub shown in FIG. 1. FIG.

3 is a schematic perspective view of a hub of an energy storage flywheel according to the first embodiment of the present invention.

4 and 5 are respectively a schematic perspective view of the hub body and the hub blade shown in FIG.

FIG. 6 is a schematic cross-sectional view illustrating the coupling structure of the hub body and the hub blades shown in FIG. 3.

7 is a schematic cross-sectional view for explaining the coupling structure of the hub body and the hub blade according to the second embodiment of the present invention.

8 is a schematic cross-sectional view for explaining the coupling structure of the hub body and the hub blade according to the third embodiment of the present invention.

9 is a schematic cross-sectional view for explaining a coupling structure of the hub body and the hub blade according to the fourth embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10, 10 b, 10 c ... hub body 11 ... inserter

12.groove 20,20a, 20b, 20c ... hub blade

21,21a, 21b, 21c ... protrusion

100.Flywheel hub for energy storage

121,211 ... bottom 122,212 ... first side

123,127,213,217 Slope 124,214 Second side

126,216 ... Connecting surface 215 ... Slot

Claims (10)

As provided in the flywheel for energy storage, A hub body having a plurality of grooves disposed concavely with respect to the insertion hole and the outer surface into which the rotation shaft is inserted and spaced apart from each other along the circumferential direction; And And a plurality of hub blades each disposed on an outer surface of the hub body so as to surround the outer surface of the hub body, and each of which has protrusions inserted into the grooves. The protrusion is disposed to be inclined with respect to the insertion direction of the protrusion and a flat inclined surface is formed, The hub of the energy storage flywheel, characterized in that the groove is formed with a flat tapered surface in contact with the inclined surface so as to be relatively sliding relative to the inclined surface of the protrusion. The method of claim 1, The inclined surface is a pair is formed so as to be symmetrically disposed about the imaginary plane passing through the centerline of the protrusion, The distance between the pair of inclined surface hub of the flywheel for energy storage, characterized in that increases in the direction of insertion of the protrusion. 3. The method of claim 2, The protrusion has a flat bottom surface disposed perpendicular to the insertion direction of the protrusion; A pair of flat first sides disposed on both sides of the bottom surface, respectively connected to the bottom surface at right angles, and connected to the inclined surface; And a pair of flat second side surfaces connected to the inclined surface and disposed in parallel with the first side surface, respectively. 3. The method of claim 2, The protrusion has a flat bottom surface disposed perpendicular to the insertion direction of the protrusion and connected to the inclined surface, respectively; And a side surface disposed at right angles to the bottom surface and connected to the inclined surface, respectively, the hub of the flywheel for energy storage. The method of claim 1, The inclined surface is a hub of the energy storage flywheel, characterized in that formed on the imaginary plane passing through the center line of the projection to be spaced apart from each other along the insertion direction of the projection respectively on both sides of the virtual plane. The method of claim 5, The inclined surfaces are arranged in pairs on both sides of the imaginary plane to be symmetrical with respect to the imaginary plane, The distance between the pair of inclined planes symmetrical with respect to the imaginary plane of the four inclined planes, the hub of the energy storage flywheel, characterized in that increases in the direction of insertion of the protrusion. The method of claim 6, The protrusion has a flat bottom surface disposed perpendicular to the insertion direction of the protrusion and connected to a pair of inclined surfaces disposed farthest from the insertion hole; A connection surface interconnecting a pair of inclined surfaces respectively disposed on both sides of the imaginary plane; And a side surface disposed at right angles to the bottom surface and connected to a pair of inclined surfaces disposed farthest from the insertion hole, respectively, the hub of the flywheel for energy storage. The method according to any one of claims 2 to 7, The hub of the flywheel for energy storage, characterized in that the protrusion is provided with a slot which penetrates one end of the protrusion and is elongated in the insertion direction of the protrusion. The method according to any one of claims 2 to 7, The grooves are formed to be open to both sides of the hub body in the thickness direction, Each of the groove portion is a hub of the energy storage flywheel, characterized in that formed in a shape corresponding to the shape of the protrusion so as to be inserted into each groove portion. As provided in the flywheel for energy storage, A hub body having a plurality of protrusions formed to protrude from the insertion hole and the outer surface into which the rotation shaft is inserted and spaced apart from each other along the circumferential direction; And And a plurality of hub blades each disposed on an outer surface of the hub body so as to surround the outer surface of the hub body, each of which has a groove portion into which the protrusion is inserted. The protrusion is formed with an inclined surface inclined with respect to the insertion direction of the protrusion, The groove portion has a hub of the energy storage flywheel, characterized in that the tapered surface in contact with the inclined surface is formed so as to be relatively sliding relative to the inclined surface of the protrusion.

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