KR101449941B1 - generation apparatus for turning effect - Google Patents

Abstract

The present invention relates to a rotation force generating device, which comprises a shaft, a main body rotatably mounted on the shaft, and a main body provided on the main body, the length of which is variable according to the rotational position of the main body, And an acceleration portion.
Therefore, in the torque generating device according to the present embodiment, the heavy object is linearly moved from the center of the body to the edge by the screw and the guide connected to the rotary gear. The moved weight adds weight to the edge of the body. When a portion where weight is added to the edge of the rotating main body falls down, gravity acts on the heavy object and an acceleration force is generated in the main body.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

The present invention relates to a torque generating device.

Generally, electric energy is produced through large-scale power generation facilities such as hydroelectric power generation, thermal power generation, and nuclear power generation.

In the case of thermal power generation, petroleum or coal energy must be supplied to operate the power generation facilities. However, from the current point of view that oil and coal resources are depleted, thermal power generation is expected to face many difficulties and pollution becomes a big problem.

In the case of hydroelectric power generation, there is a submerged area due to the construction of the tanks and seawalls in order to operate the power generation facilities, and it takes long time to construct and damage the nature.

In addition, in the case of nuclear power generation, radiation leakage and nuclear waste disposal have serious problems.

Japanese Patent Application Laid-Open No. 10-2012-0136742 (December 30, 2012) Open Patent Publication No. 10-2012-0134790 (December 12, 2012)

The present invention provides a torque generating device capable of generating electricity without environmental pollution and natural damage.

The rotation force generating device according to an embodiment of the present invention includes a shaft, a main body rotatably installed on the shaft, and a main body disposed on the main body, the length of which is variable according to the rotational position of the main body, And an accelerating portion for applying an acceleration.

Wherein the acceleration portion includes at least one of a center gear fixed to the center of the body, at least one rotary gear engaged with the center gear and rotatably coupled to the body, one side connected to the rotary gear, As shown in FIG.

Wherein the variable portion includes at least a part of a screw which is angled with the rotary gear and is connected to the inside of the through hole and has a first helical groove and a second helical groove formed in opposite directions to each other, Or a slide groove connected to the second helical groove is formed along the longitudinal direction, and a slide projection which is movably disposed in the guide and which is connected to the slide groove and the first helical groove or the second helical groove, And a weight connected to the other side of the rod.

A bearing is rotatably coupled to the center gear, and one side of the guide extends in the direction of the center gear to be connected to the bearing.

The main body may have a guide groove for guiding the heavy object, and a weight reducing part may be formed by removing at least a part of the surface of the main body to reduce the weight of the main body.

The acceleration part is arranged symmetrically with one surface of the main body, and the heavy materials facing each other on both surfaces of the main body can be connected to each other through the guide groove.

The main body on which the acceleration portions are disposed on both sides may be arranged at intervals along the longitudinal direction of the shaft.

According to the embodiment of the present invention, the heavy object is linearly moved from the center of the body to the edge by the screw and the guide connected to the rotary gear. The moved weight adds weight to the edge of the body. An acceleration force is generated in the main body as gravity acts on the weight of the rotating body, where the weight is added to the edge of the rotating body. Accordingly, the body can smoothly rotate even with a small force due to the movement of the weight of the heavy object. As the weight of the heavy object moves, the main body rotates and the power generator is driven, so that environmental pollutants are not generated.

According to the embodiment of the present invention, the weight of the main body can be minimized by the weight reducing part of the main body. Accordingly, as the weight of the main body decreases, the resistance due to the weight of the main body is minimized, and the main body can rotate smoothly.

1 is a perspective view of a rotational force generating device according to an embodiment of the present invention;
2 is a rear perspective view of the rotational force generating device shown in Fig.
Fig. 3 is an exploded perspective view of the rotation force generating device shown in Fig. 1. Fig.
Fig. 4 is an exploded perspective view of the variable portion shown in Fig. 3; Fig.
Fig. 5 is a view showing the variable portion operating state shown in Fig. 4. Fig.
6 is an operational state diagram of a rotational force generating device according to an embodiment of the present invention;

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Like parts are designated with like reference numerals throughout the specification.

1 to 3, a rotational force generating apparatus according to an embodiment of the present invention will be described.

FIG. 1 is a perspective view of a rotating force generating device according to an embodiment of the present invention, FIG. 2 is a rear perspective view of the rotating force generating device shown in FIG. 1, and FIG. 3 is an exploded perspective view of the rotating force generating device shown in FIG.

Referring to Figs. 1 to 3, the rotational force generating device 1 according to the present embodiment includes a shaft 20, a main body 30, and an accelerating portion 40.
The shaft 20 is installed in a support portion 10 fixed to the ground or the like, and the shaft 20 and the support portion 10 are at right angles.

delete

The main body 30 is formed in a disk shape and is rotatably connected to the shaft 20. A bearing (not shown) is disposed between the main body 30 and the shaft 20 so that the main body 30 can be rotated with respect to the shaft 20 by a bearing.

A guide groove 31 is formed in the main body 30 in a predetermined length from the center to the outside. The guide groove 31 penetrates the main body 30.

On the other hand, at least a part of the surface of the main body 30 is removed in order to reduce the weight of the main body 30. [ Accordingly, the main body 30 is formed with the weight reducing portion 32.

The main body 30 may be made of metal, synthetic resin, or the like. When the main body 30 is made of synthetic resin, the weight of the main body 30 can be minimized.

  A power generator (not shown) for generating electrical energy may be connected to the main body 30.

The acceleration portion 40 includes a center gear 41, a rotary gear 42, and a variable portion 43.

The centripetal gear 41 is located at the center of the main body 30 and is coupled to the shaft 20. The center gear 41 coupled to the shaft 20 does not rotate along the main body 30.

The rotary gear 42 is formed so as to correspond to the center gear 41. The rotary gear 42 is arranged along the circumferential direction about the center gear 41 and is engaged with the center gear 41. [ The rotary gear 42 is coupled to the main body 30 via a central shaft (not shown). A bearing (not shown) is disposed between the central shaft and the main body 30. [ Accordingly, the rotation gear 42 can be rotated while being engaged with the center gear 41 when the main body 30 rotates.

That is, when the main body 30 rotates, the rotary gear 42 rotates about the center axis while revolving around the center gear 41.

One side of the rotary gear 42 is opened, and a ring gear 421 is formed in the opened portion.

Referring to FIGS. 4 and 5, the variable portion 43 has a varying length, and includes a screw 44, a guide 45, a rod 46, and a heavy object 47.

The screw 44 is located on one side of the rotary gear 42. A pinion gear 441 engaging with the ring gear 421 is formed on the outer circumferential surface of the screw 44. The rotational force of the rotary gear 42 is transmitted to the screw 44 through the ring gear 421 and the pinion gear 441 so that the screw 44 can be rotated in one direction.

The inside of the screw 44 penetrates along the longitudinal direction. Spiral grooves are formed in the screw 44. The helical groove includes a first helical groove 442 and a second helical groove 443. The first helical groove 442 and the second helical groove 443 are formed to correspond to each other. The starting points 442a and 443a of the first helical groove 442 and the second helical groove 443 are connected to each other and the end points 442b and 443b of the first helical groove 442 and the second helical groove 443 are connected to each other. They are also connected to each other. Here, the first helical groove 442 and the second helical groove 443 connected to each other are formed as a pair. However, only one of the first helical groove 442 and the second helical groove 443 may be formed.

The guide 45 has a predetermined length, and the inside is penetrated. One side of the guide 45 is located outside the screw 44 and the other side is located inside the screw 44. The other side of the guide 45 is located on one side of the center gear 41. At this time, the other side of the guide 45 is connected to a bearing 411 rotatably coupled to the shaft 20. Accordingly, the guide 45 can maintain a state perpendicular to the center gear 41. Here, the guide 45 does not rotate and remains fixed.

A slide groove 451 is formed in the guide 45 along the longitudinal direction. The slide groove 451 may be connected to the first helical groove 442 or the second helical groove 443 according to the rotation of the screw 44. The slide groove 451 is formed in a pair so as to correspond to the first spiral groove 442 and the second spiral groove 443. Accordingly, the pair of slide grooves 451 can be connected to the pair of first helical grooves 442 or the second helical grooves 443. However, only one slide groove 451 may be formed.

The rod 46 has a predetermined length. The rod (46) is slidably coupled to the inside of the guide (45). A slide protrusion 461 inserted into the slide groove 451 and the first helical groove 442 or the second helical groove 443 is formed on one side of the rod 46. The protrusions 461 may also be formed as a pair and inserted into the pair of first groove 452 and the pair of first groove 442 or the second groove 443.

The weight member 47 has a predetermined weight and is connected to the other side of the rod 46. The heavy object 47 is formed with a guide protrusion 471 to be engaged with the guide groove 31. The heavy object 47 can move along the guide groove 31 within the range of the screw 44. Although the heavy object 47 is shown as a sphere in FIG. 4, the shape of the heavy object 47 can be variously changed.

The variable portion 43 is configured such that the rotating force of the rotating gear 42 that rotates while revolving the center gear 41 is rotated by the rotating main body 30 through the ring gear 421 and the pinion gear 441 44 so that the screw 44 can rotate in one direction.

When the screw 44 rotates, the projection 461 located at the starting point of the first spiral groove 442 can be pressed by the inner surface of the first spiral groove 442, as shown in FIG. At this time, the inner surface of the first helical groove 442 can press the projection 461 in a direction away from the center gear 41.

The protrusion 461 to be pressed can move along the first helical groove 442. Since the projection 461 is located in the first spiral groove 442 through the slide groove 451, the projection 461 can not rotate along the rotation direction of the screw 44 and can linearly move along the slide groove 451 . The protrusion 461 can be gradually moved along the slide groove 451 by the continuous pressing of the first helical groove 442. [ By the progressive movement of the projection 461, the rod 46 can protrude out of the guide 45. At this time, the heavy object 47 can also move along the guide groove 31.

The pressed projection 461 from the starting point of the first helical groove 442 can move to the end point of the first helical groove 442 by the continuous rotation of the screw 44. [ Accordingly, the heavy object 47 can move in the direction of the edge of the main body 30. The projection 461 may be located at the end of the second helical groove 443 connected to the end of the first helical groove 442, as shown in FIG. 5 (b).

The projection 461 located at the end point of the second helical groove 443 can be pressed by the inner surface of the second helical groove 443. The inner surface of the second helical groove 443 can press the projection 461 in the direction of the center gear 41. The projection 461 pressed in the direction of the centripetal gear 41 can move linearly along the slide groove 451. The rod 46 can move into the guide 45 by the direction in which the inner surface of the second helical groove 443 presses the projection 461. [ The heavy object 47 can be moved away from the edge of the main body 30. [

When the projection 461 is pressed by the inner surface of the first spiral groove 442 by the rotation of the screw 44 as described above, the heavy object 47 can move in the direction away from the center gear 41. [ The rod 46 may be pulled out from the inside of the guide 45 and the length of the variable portion 43 may become longer. The weight of the edge of the main body 30 can be increased as the heavy material 47 moves to the edge of the main body 30. [

Conversely, when the projection 461 is pressed by the second helical groove 443, the rod 46 can move in the direction of the center gear 41. The rod 46 is drawn into the guide 45, and the length of the variable portion 43 can be shortened. The heavy object 47 can move toward the center of the main body 30. [ The edge weight of the main body 30 can be reduced.

In addition, since the guide 45 is kept perpendicular to the center gear 41 by the bearing 411, resistance applied to the rotation gear 42 by the variable portion 43 does not occur. Accordingly, rotation of the rotary gear 42 can be smoothly performed. Smooth rotation of the rotary gear 42 can improve the operability of the variable portion 43.

On the other hand, FIG. 5 (b) shows a state in which the rod 46 is drawn out about half from the guide 45.

The rotary gear 42 and the acceleration portion 40 of the rotation-force generating device 1 are arranged along the circumferential direction about the center gear 41. At this time, the guide groove 31 formed in the main body 30 is also formed so as to correspond to the acceleration part 40. Although the guide grooves 31 and the acceleration portions 40 of the rotary gear 42 are shown as being arranged at intervals of 90 degrees in FIGS. 1 to 3, they may be arranged at intervals of 90 degrees or more.

The acceleration portion 40 including the center gear 41, the rotary gear 42 and the variable portion 43 of the rotational force generating device 1 is disposed so as to correspond to one surface and the other surface of the main body 30, respectively . The weight members 47 of the acceleration unit 40 disposed on both sides of the main body 30 are connected to each other by guide projections 471. Accordingly, the acceleration portions 40 disposed on both surfaces of the main body 30 can move in the same direction.

In addition, the main body 30 having the acceleration portions 40 on both sides thereof may be arranged at intervals along the longitudinal direction of the shaft 20 as shown in Fig. When the main body 30 is arranged along the longitudinal direction of the shaft 20, the driving performance of the power generation device can be improved.

Next, the operation of the torque generating device described with reference to Fig. 7 will be described.

First, referring to FIG. 7A, the variable portion 43, the center gear 41, and the rotary gear 42 located in the 90 ° portion of the main body 30 are located on the same line. At this time, the guide 45 is coupled to the bearing 411 of the center gear 41 so that the variable portion 43 can maintain a state perpendicular to the center gear 41. At this time, the variable portion 43 maintains the state shown in Fig. 5 (a).

In this state, when the main body 30 rotates in one direction with respect to the shaft 11, the rotation gear 42 can rotate and rotate while being engaged with the centrifugal gear 30.

The variable portion 43 can be operated as shown in Figs. 5 (b) and 5 (c) by the rotating gear 42 rotating. That is, the screw 44 is rotated by the rotation of the rotary gear 42 so that the first helical groove 442 presses the projection 461. By the movement of the projection 461, the rod 46 is guided by the guide 45, And is drawn out. The weight member 47 can be gradually moved from the center gear 41 toward the edge of the main body 30. [ The weight (47) moved to the edge of the main body (30) can add weight to the edge of the main body (30). An acceleration force may be generated in the main body 30 where the weight is added to the edge.

7 (b), when the main body 30 is rotated by the rotation of the main body 30, the variable portion 43 can be in the state shown in Fig. 5 (c). Accordingly, the projection 461 can be positioned in the second helical groove 443 (see Fig. 5 (c)).

By the rotation of the main body 30, the variable portion 43 can be located at the 270 ° portion as shown in FIG. 7 (c). The projection 461 located in the second helical groove 443 is pressed toward the center gear 41 by the second helical groove 443 so that the rod 46 can be in the state shown in FIG.

By the continuous rotation of the main body 30, the variable portion 43 can be located at the 180 ° portion as shown in Fig. 7 (d). At this time, the projection 461 may be located at the starting point of the first helical groove 442. The rod 46 can be gradually drawn out of the guide 45 while the first helical groove 442 presses the projection 461 in the direction away from the center gear 41 ).

7 (a), when the weight 47 moves in a direction away from the center gear 41 due to a change in length of the variable portion 43, the weight of the weight 47 may increase to the edge of the body 30 have. The main body 30 having the weight added to the edge can be rotated while the acceleration force is increased, and the rotational force can be increased. Accordingly, the main body 30 connected to the power generator can be easily rotated even with a small external force.

When the heavy object 47 of the main body 30 passes through the 0 °, 270 ° and 180 ° portions of the main body 30, the rod 46 is drawn into the guide 45 and moves toward the center gear 41 . At this time, the weight added to the edge of the main body 30 can move toward the center of the main body 30.

That is, the weight 47 passing through the 180 °, 90 °, and 0 ° portions of the main body 30 can add weight to the edge of the main body 30. The weight 47 that has added weight to the edge of the main body 30 can move in the direction of the centripetal gear 41 while passing through the 0 °, 270 °, and 180 ° portions of the main body 30. Accordingly, the weight applied to the edge of the main body 30 can be moved to the center of the main body 30. Since the weight of the edge of the main body 30 is reduced, the weight 47 passing through the 180 °, 90 ° and 0 ° of the main body 30 can be reduced in gravity added to the edge of the main body 30. As a result, the rotational force of the main body 30 is increased, and the main body 30 can be smoothly rotated by a small force to drive the power generation apparatus.

7 and the above description, the main body 30 and the variable portion 43 are rotated in the clockwise direction. However, the main body 30 and the variable portion 43 can be rotated in the counterclockwise direction.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, Of the right.

1: rotational force generating device 10:
20: shaft 30: body
31: Guide groove 40: Acceleration section
41: Center gear 411: Bearing
42: rotary gear 421: ring gear
43: variable portion 44: screw
441: Pinion gear 442: First spiral groove
443: second helical groove 45: guide
451: slide groove 46: rod
461: projection 47: heavy article
471: guide projection

Claims (7)

main body,
A shaft rotatably supporting the main body, and
At least one rotary gear coupled to the main body and meshed with the center gear, at least one variable portion having one side connected to the rotary gear and the other side connected to the shaft, The accelerator portion
Lt; / RTI >
The variable-
A screw connected to the rotary gear and having a first helical groove and a second helical groove formed on an inner circumferential surface thereof,
A guide connected to the shaft and disposed inside the screw, the guide having a slide groove formed along a longitudinal direction thereof,
A rod disposed movably in the guide and having a slide protrusion connected to the slide groove and the first helical groove or the second helical groove,
The weight connected to the rod
Containing
Torque generating device. delete delete The method of claim 1,
And a bearing coupled to the guide and rotatably coupled to the shaft. The method of claim 1,
Wherein the body is provided with a guide groove for guiding the heavy object and a weight reducing part for removing at least a part of the body to reduce the weight of the body. The method of claim 5,
Wherein the acceleration part is symmetrically arranged on one surface and the other surface of the main body, and the heavy objects facing each other on both surfaces of the main body are connected to each other through the guide groove
Torque generating device. The method of claim 6,
Wherein the main body in which the acceleration parts are disposed on both sides is arranged at an interval along the longitudinal direction of the shaft.

Images