KR102065187B1 - Mechanical accelerating power generator - Google Patents

Abstract

The present invention relates to a mechanical generator, the configuration of which is a small motor for supplying rotation when the power is supplied; and is connected to the small motor to receive the rotation from the small motor, the rotational speed of the small motor is reduced Rotation force is increased; and, a worm wheel connected to the reducer through the pulley and the belt is supplied with the rotational power through the reducer to rotate; and is rotated by being supplied with the rotational force is engaged with the worm wheel, the rotational speed is increased A worm shaft that rotates by rotating the worm shaft; and a large-capacity generator that is connected to the worm shaft and receives rotation from the worm shaft and rotates at 1800 rpm or more; and fixes positions of the reducer, the worm wheel, the worm shaft, and the large-capacity generator. As a fixed frame;
By supplying the rotational force supplied from the small motor to the large-capacity generator through the reducer, worm wheel, worm shaft, and power boosting means, it is possible to easily generate and produce power in the large-capacity generator by using the rotational power supplied from the small motor, Compared to conventional solar, wind, and hydro power plants, installation space or installation cost can be greatly reduced, and thus the utility of the generator can be secured.

Description

Mechanical generators {Mechanical accelerating power generator}

The present invention relates to a mechanical generator, and more particularly, by supplying the rotational force supplied from the small motor to the large-capacity generator through the reducer, the worm wheel, the worm shaft, and the increasing means, in the large-capacity generator using the rotational power supplied from the small motor. The present invention relates to a mechanical generator that not only can easily generate power, but also can significantly reduce installation space and installation costs in comparison with conventional solar, wind, and hydro power plants by using mechanical devices. .

In general, electricity is most efficiently produced through power generation using nuclear power, but recently, as fears about the dangers of nuclear power plants are generated, interest in safe and environmentally friendly solar, wind, and hydro power plants is increasing.

However, the photovoltaic, wind, and hydroelectric power plants have unstable electrical power generation due to changes in weather conditions, and there are limitations that are not continuous. There is a problem in that it is difficult to install and operate in large quantities due to the characteristics that require too much installation cost for maintenance.

Therefore, there is an urgent need for the development of a generator that is easy to install, operate and manage and has excellent power generation efficiency.

The present invention has been proposed to solve the above-mentioned problems, the object of which is to supply a small motor by supplying the rotational force supplied from the small motor to the large capacity generator through the reducer, the worm wheel and the worm shaft and the increasing means, By using rotational power, not only power generation can be easily produced and produced in large-capacity generators, but also a mechanical device can significantly reduce installation space and installation costs compared to conventional solar, wind, and hydro power plants, thereby securing the utility of generators. To provide a mechanical generator that can be.

Mechanical generator according to the present invention for achieving the above object is a small motor for supplying rotation when the power is supplied; And, connected to the small motor to receive the rotation from the small motor, the number of revolutions of the small motor A speed reducer but a rotational force is increased; and a worm wheel connected to the speed reducer through a belt connected to a pulley formed on the speed reducer to receive rotational force through the speed reducer; A worm shaft that is rotated by being supplied with a rotational speed, and rotates at an increased speed; and a large-capacity generator that is connected to the worm shaft and receives rotation from the worm shaft and generates power while rotating at 1800 rpm or more; and the reducer and the worm wheel It is configured to include; and a fixed frame for fixing the position of the worm shaft and a large capacity generator,

Rotational force produced by the small motor is supplied to the large-capacity generator so that electricity is produced and produced in the large-capacity generator,
The first power means for supplying a rotational force to the worm shaft is stopped by the operation of the small motor further comprises;
The first power means includes a rotary shaft connected to the worm wheel and rotates together with the worm wheel, pulleys formed at both ends of the rotary shaft, and a first boost shaft rotatably connected to the fixed frame; A first flying wheel formed at both ends of the first reinforcement shaft, and the pulley and the first flying wheel are configured to include a first belt connected thereto;
The second power means for supplying a rotational force to the worm shaft is reduced by the operation of the small motor is further comprises;
The second power means has a second power axis rotatably formed, a second flying wheel formed on the second power axis and rotating together with the second power axis, and formed on the second power axis. And a third pulley, a fourth pulley formed on the worm shaft, and a second belt connecting the third pulley and the fourth pulley.

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According to the mechanical generator according to the present invention as described above, by supplying the rotational force supplied from the small motor to the large-capacity generator through the reducer, the worm wheel, the worm shaft and the increasing means, in the large-capacity generator using the rotational force supplied from the small motor Not only can be easily produced and produced, it is also possible to significantly reduce the installation space or installation cost compared to conventional solar, wind and hydroelectric power plants with a mechanical device has the effect of ensuring the universal use of the generator.

1 is a perspective view of a mechanical generator according to an embodiment of the present invention
FIG. 2 is a cross-sectional view AA of the mechanical generator shown in FIG.
3 is a plan view of the mechanical generator shown in FIG.
4 is a state diagram used in the mechanical generator shown in FIG.

On the basis of the accompanying drawings a mechanical generator according to a preferred embodiment of the present invention will be described in detail. Detailed descriptions of well-known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention will be omitted.

1 to 4 show a mechanical generator according to an embodiment of the present invention, Figure 1 is a perspective view of a mechanical generator according to an embodiment of the present invention, Figure 2 is a cross-sectional view AA of the mechanical generator shown in FIG. 3 is a plan view of the mechanical generator shown in FIG. 1, and FIG. 4 is a state diagram of the mechanical generator shown in FIG. 1, respectively.

As shown in the figure, the mechanical generator 100 according to the embodiment of the present invention is a small motor 10, a reduction gear 20, a worm wheel 30, a worm shaft 40, a large capacity generator 50 and a fixed frame 60 are included.

As shown in Fig. 1 and 3, the small motor 10 is to supply the rotation when the power is supplied, in the mechanical generator 100 of the present invention is used a small capacity motor of 3.7 kW, but limited to such a motor Of course not to use.

As shown in FIG. 1 and FIG. 2, the speed reducer 20 is connected to the small motor 10 to receive rotation from the small motor 10, and the rotation speed of the small motor 10 is reduced. But increase the torque.

That is, as shown in FIG. 4a, the rotational force of the small motor 10 is difficult to rotate the large-capacity generator 50 to be placed behind, and thus the rotation speed supplied from the small motor 10 through the reducer 20. To slow down but increase the torque.

1 and 2, the worm wheel 30 is connected to the speed reducer 20 through a belt 2 connected to a pulley 1 formed on the speed reducer 20 to reduce the speed reducer. The rotation is supplied through the rotation force 20.

Here, the worm wheel 30 is rotatably connected to the fixed frame 60 to be installed later to ensure stable rotation.

As shown in Figure 1 and 2, the worm shaft 40 is engaged with the worm wheel 30 is rotated to receive a rotational force, to increase the rotational speed to rotate.

Here, as shown in Figure 4b, the worm shaft 40 is meshed with the worm wheel 30 so that the screw thread is produced by multiple screws so that the rotation speed is easily increased, the worm in the mechanical generator 100 of the present invention The screw thread is induced to be densely manufactured with a six screw on the shaft 40, but it is not limited to the number thereof.

Since at least 1800 revolutions per minute is required to generate power through a power generation device, when the worm shaft 40 and the large-capacity generator 50 are directly connected, the rpm of the worm shaft 40 is at least 1800. It is preferable to output the above.

On the other hand, when the worm shaft 40 is supplied with rotation from the worm wheel 30 and the rotation speed is increased, the rotational force of the worm shaft 40 is naturally lowered, so that the worm shaft 40 is connected to the worm shaft 40 with the reduced rotational force. It may be difficult to rotate the large-capacity generator 50.

On the other hand, as shown in Figure 1 to 3 to stop the operation of the small motor 10 to supply the rotational force to the worm shaft 40 to compensate for the reduced rotational force of the reduced worm shaft 40 It is preferable to comprise a further comprising; the first power means (70),

The first power means 70 is connected to the worm wheel 30 and the rotating shaft 71 to rotate together with the worm wheel 30 and the first pulley 72 formed on both ends of the rotating shaft 71, respectively. ), A first reinforcement shaft (73) rotatably connected to the fixed frame (60), and are formed at both ends of the first reinforcement shaft (73) together with the first reinforcement shaft (73). The first flying wheel 74 rotates, the second pulley 75 formed at both ends of the first reinforcement shaft 73, and the first pulley 72 and the second pulley 75 are connected to each other. It comprises a first belt (76) for rotating the first flying wheel (74) together with the first strengthening shaft (73) to the rotational force of the rotary shaft (71).

Here, as shown in FIG. 4B, the first flying wheel 74 requires a lot of power for the first rotation, but when the first flying wheel 74 starts to rotate, the first flying wheel 74 is rotated with a small amount of power by the centrifugal force. The operation of the motor 10 may be stopped to compensate for the reduced rotational force of the worm shaft 40, thereby enhancing the structural safety of the device, thereby inducing stable power generation through the mechanical generator 100 of the present invention.

At this time, a bearing (not shown) is formed between the first flying wheel 74 and the first reinforcement shaft 73 to induce smooth rotation of the first flying wheel 74.

In addition, as shown in Figures 1 to 3 the second motor means (80) for supplying rotational force to the worm shaft 40 is reduced by the operation of the small motor 10 is stopped; ,

The second boosting means (80) is a second flying shaft (81) formed to be rotatable, and a second flying shaft formed on the second strengthening shaft (81) to rotate together with the second strengthening shaft (81) A wheel 82, a third pulley 83 formed on the second reinforcement shaft 81, a fourth pulley 84 formed on the worm shaft 40, and the third pulley 83. ) And a second belt 85 connecting the fourth pulley 84.

That is, as shown in Figure 4b while the second flying wheel 84 of the second power means 80 is rotated with a small power by the centrifugal force of the second flying wheel 84, the small motor ( The operation of 10) can be stopped to compensate for the rotational force of the deteriorated worm shaft 40, thereby enhancing the structural safety of the device to induce stable power generation through the mechanical generator 100 of the present invention.

Here, the second flying wheel 84 also requires a lot of power to rotate the first time, but when the second flying wheel 84 starts to rotate with a small power by centrifugal force operation of the small motor 10 is When stopped, the rotational force is supplied to the worm shaft 40.

Therefore, the worm shaft 40 is stopped by the operation of the small motor 10 is reduced by the rotational force is compensated by the first and second power means (70, 80), the number of rotations of the worm shaft (40) (At least 1800 rpm or more) to easily rotate the large-capacity generator 50 to induce efficient power generation through the large-capacity generator (50).

As shown in FIG. 1, the large capacity generator 50 is connected to the worm shaft 40 to receive rotation from the worm shaft 40 to generate power while rotating at 1800 rpm or more.

Here, the large-capacity generator 50 of the mechanical generator 100 of the present invention uses a generator of 29 kA, but is not limited to the generator of this capacity.

As shown in FIG. 1, the fixing frame 60 fixes the positions of the reducer 20, the worm wheel 30, the worm shaft 40, and the large capacity generator 50.

Mechanical generator 100 of the present invention having the configuration as described above the rotation supplied from the small motor 10, the reduction gear 20 and the worm wheel 30 and the worm shaft 40 and the increasing means (70, 80) By increasing and increasing rotation through the large-capacity generator 50, more power can be generated and produced in the large-capacity generator 50 in preparation for the power consumed by the small motor 10. Not only can it be improved, but also a mechanical device can significantly reduce the installation space or installation cost compared to conventional solar, wind, and hydro power plants, thereby ensuring the utility of the generator.

Mechanical generator 100 according to an embodiment of the present invention having the configuration as described above is developed as follows.

First, as shown in FIG. 4A, power is supplied to operate the small motor 10 to rotate the reducer 20 connected to the small motor 10.

At this time, the small-capacity motor 10 of 3.7 kW rotates at 1800 rpm, while the rotation speed decreases to 180 rpm while passing through the reducer 20, and greatly increases the rotational force.

Thereafter, as shown in FIG. 4B, when the worm wheel 30 connected to the reducer 20 is rotated while being supplied with rotation, when the operation of the small motor 10 is stopped, the worm wheel 30 is connected to the worm wheel 30. The rotational force of the worm shaft 40 is supplied to the worm shaft 40. At this time, the rotational force of the worm shaft 40 reduced by the operation of the small motor 10 is compensated through the first and second power means 70 and 80. The worm shaft 40 rotates at a high rotational force while rotating at 1800 rpm or more.

Therefore, the large-capacity generator 50 connected to the worm shaft 40 is an efficient power generation by the high rotational force of the worm shaft 40 and the rotation speed of 1800 rpm or more.

Although the present invention has been described with reference to the embodiments illustrated in the accompanying drawings, this is by way of example and not limited to the above-described embodiments, various modifications and equivalent embodiments are possible from those skilled in the art. You will understand the point. In addition, modifications by those skilled in the art can be made without departing from the scope of the present invention. Therefore, the scope of the claims in the present invention will not be defined within the scope of the detailed description, but will be defined by the following claims and the technical spirit thereof.

1. Pulley 2. Belt
10. Small motor 20. Reducer
30. Worm wheel 40. Worm shaft
50. Large capacity generator 60. Fixed frame
70. First means of power 71. Rotating shaft
72. 1st pulley 73. 1st reinforcement shaft
74. First Flying Wheel 75. Second Pulley
76. First belt 80. Second reinforcement means
81. Second reinforcement shaft 82. Second flying wheel
83. Third Pulley 84. Fourth Pulley
85. Second belt
100. Mechanical Generator

Claims (3)

A small motor 10 for supplying rotation when power is supplied;
A reducer 20 connected to the small motor 10 to receive rotation from the small motor 10, wherein the speed of the small motor 10 is reduced while the rotational force is increased;
A worm wheel 30 connected to the speed reducer 20 through a belt 2 connected to the pulley 1 formed on the speed reducer 20 to receive a rotational force through the speed reducer 20 to rotate;
A worm shaft 40 engaged with the worm wheel 30 to be supplied with rotational force and rotated to increase rotational speed;
A large-capacity generator 50 connected to the worm shaft 40 and receiving power from the worm shaft 40 to generate power while rotating at 1800 rpm or more; And
And a fixed frame 60 for fixing the positions of the reducer 20, the worm wheel 30, the worm shaft 40, and the large-capacity generator 50.
By supplying the rotational force produced in the small motor 10 to the large-capacity generator 50 to generate electricity in the large-capacity generator 50,
The first power means 70 for supplying a rotational force to the worm shaft 40 is stopped by the operation of the small motor 10; further comprising,
The first power means 70 is connected to the worm wheel 30 and the rotating shaft 71 to rotate together with the worm wheel 30 and the first pulley 72 formed on both ends of the rotating shaft 71, respectively. ), A first reinforcement shaft (73) rotatably connected to the fixed frame (60), and are formed at both ends of the first reinforcement shaft (73) together with the first reinforcement shaft (73). The first flying wheel 74 rotates, the second pulley 75 formed at both ends of the first reinforcement shaft 73, and the first pulley 72 and the second pulley 75 are connected to each other. It comprises a first belt (76) for rotating the first flying wheel 74 with the first strengthening shaft (73) to the rotational force of the rotary shaft (71),
The second power means (80) for supplying rotational force to the worm shaft (40) is stopped by the operation of the small motor (10); further comprises,
The second boosting means (80) is a second flying shaft (81) formed to be rotatable, and a second flying shaft formed on the second strengthening shaft (81) to rotate together with the second strengthening shaft (81) A wheel 82, a third pulley 83 formed on the second reinforcement shaft 81, a fourth pulley 84 formed on the worm shaft 40, and the third pulley 83. And a second belt (85) connecting the fourth pulley (84) to the mechanical generator.


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