JPS6255472A - Power doubling generating machine - Google Patents

Abstract

PURPOSE:To utilize the generated electric energy in various purpose by generating the electricity by the motive force which is taken out after the inputted motive force has been increased by combining the inertia force of fly wheels with gears. CONSTITUTION:A rotor 6 is rotated by motors 2 and 2 by way of gears 3 and 3A and the like. In addition, the rotor 6 is accelerated by a motive force exerted by a mechanism which allows a torque of fly wheels 7 and 7 driven by motors 14 and 14, to be transmitted only to one way. The rotating shaft 6 drives fly wheels 22 and 22 to rotate by way of gears of various kinds. These fly wheels 22 and 22 are furthermore accelerated because the inertia force of a rotating fly wheel 40 driven by motors 33 and 33 is applied to them. And then a generator 30 is designed to rotate by the rotating shaft 27 of those fly wheels 22 and 22 by way of chains 24 and 28 and the like.

Description

[Detailed description of the invention] A1 Purpose of the invention B. Industrial application field The present invention relates to a power multiplier generator.

Previous technology and its problems There has never been anything similar to this type.

B1 Structure of the Invention A8 Means for Solving Problems The present application attempts to solve the above-mentioned problems with the following structure.

That is, the present application has a gear mechanism that interlocks with each other between a motor disposed at one end of the frame and a motor disposed at the other end of the frame, in which a gear mechanism is provided at both ends of a rotating shaft that supports some of the gears. The flywheel is attached via a freewheel, and spring claws are attached to the outer circumference of the flywheel at appropriate pitches using fixing screws, while the output of the motor is placed in correspondence with the flywheel. This is a power multiplier generator with a gear fixed to the shaft that engages and disengages from the spring claw.

Two embodiments of the invention are provided, and the output shaft of the motor 2 is provided with a gear 2Aft. It is configured so that the first rotation shaft 4 is rotated by meshing with the gear 2A and rotating the gear 6ft. A gear 3Aff is provided at the center of the first rotating shaft 4, and is configured to mesh with a large gear 5 provided at the center of the rotating shaft 6 to rotate the second rotating shaft 6. At this time, the large gear 5 meshes with a gear 8 provided at the center of the sixth rotating shaft 10 to rotate the third rotating shaft 10, and a gear 9 is provided on the sixth rotating shaft 10 in parallel with the gear 8, It is configured to mesh with a gear 11 provided on the fourth rotation shaft 16 to rotate the fourth rotation shaft 16. Next, the gear 12 provided at the center of the fourth rotating shaft 13 meshes with the gear 15 provided at the center of the fifth rotating shaft 17, and another 16-karat gold gear is provided on the fifth rotating shaft 17. meshes with a gear 18 provided at the center of the sixth rotating shaft 19 to rotate the sixth rotating shaft 19. Further, the gear 18 provided at the center of the sixth rotating shaft 19 meshes with the gear 20 provided at the center of the seventh rotating shaft 21 to rotate the seventh rotating shaft 21, and a primary fly is provided at both ends of the seventh rotating shaft 210. One wheel 22 is provided, and the configuration is such that the continuous rotational force of the machine is further increased by the rotational force due to the inertial force of the flywheel. A sprocket 26 is provided on the seventh rotating shaft 21 next to the gear 20, and a chain 24 is connected to this sprocket 23 to connect it to a sprocket 25 provided at the center of the eighth rotating shaft 27. Further, a chain 28 is hung around a sprocket 26 provided at the center of the eighth rotating shaft 27, and the chain 28 is carried on a sprocket 29 provided on a drive shaft of a generator 30. Therefore, the secondary flywheel 7 is attached to both ends of the second rotating shaft 6 via the freewheel 34. Spring claws 7A are attached to the outer periphery of the secondary flywheel 7 over the entire circumference using fixed nails Bk at appropriate pitches. The direction of the top of the spring claw 7A is opposite to the rotation direction.

On the other hand, it is fixed in correspondence with the secondary flywheel 7. A gear 14A is fixed to the output shaft of the motor 14. gear 14
A is arranged so as to be in line with the secondary flywheel 7 when viewed from the top, and when viewed from the side, the teeth of the gear 14A engage with the tops of the spring pawls 7A provided on the outer periphery of the secondary flywheel 7. Place it in the desired position. When the motor 14 is rotated, the gear 17LA rotates in the direction of the arrow, and when the top of the spring claw 7A hits the teeth of the gear 1dA, the secondary flywheel 7 is driven in the direction of the arrow by pushing the spring claw 7A. be done. As a result, the secondary flywheel 7 starts to rotate, and while the gear 14A and the secondary flywheel 7 mutually rotate, each time the teeth of the gear 14A and the top of the spring pawl 7A come into contact, the secondary flywheel 7 Power is transmitted to the secondary flywheel 7, increasing the rotational force of the secondary flywheel 7. Note that when the tooth tips of the gear 14A are in a positional relationship that presses the upper side of the spring pawl 7A, the spring pawl 7A is bent by elasticity and escapes inward, so that rotation is not hindered. Reference numeral 35 refers to a spring hook, which represents another embodiment in place of the spring hook 7A. A rigid hook 35A is swingably attached to a groove on the outer periphery of the secondary flywheel 7 using a pin 65B. The upper side of the hook 65A limits the swinging range with a stopper 35C, and the lower side is supported by a spring 35D attached to the secondary flywheel 7 with a screw 35E. The action of the spring set lift 650 is similar to that of the spring claw 7A described above. The secondary flywheel 7 is attached to the second rotating shaft 6 via a freewheel 34tl provided on the boss portion thereof, and the secondary flywheel 7 is attached to the second rotating shaft 6 through a freewheel 34tl provided on the boss portion thereof. The rotational force is transmitted to the rotating shaft 6. 34A is an inner ring, which fits into the second rotating shaft 6 and which is connected to the key 6.
It is fixed at 4G.

34B is an outer ring, which is integrated with the secondary flywheel 7. The inner ring 34A and the outer ring 34B are bearings 3.
Assembled via ice.

A pawl 34E is pivotally attached to the outer periphery of the inner ring 34A, and the lower side of the pawl 34E is made resilient by a spring 34F.

On the other hand, saw blade-shaped teeth 640 are carved on the inner periphery of the outer ring 34B,
It has a structure in which it engages with the tip of the claw 34E, and transmits rotational force in only one direction. On the other hand, a small sprocket 41 is fixed to both ends of the seventh rotating shaft 21, and a large-diameter tertiary flywheel fLOk, which has a gear on its outer periphery, is attached next to it via a bearing 42. A tertiary flywheel is arranged and fixed to the frame 61, and a small gear 3 is attached to its output shaft.
3A'! and mesh with the gear of the tertiary flywheel 40. Further, power is distributed to a rotating shaft 391 at another position facing the outer periphery of the tertiary flywheel 40, and the small gear 38 and small sprocket 37 are fixed thereto. The small gear 38 meshes with the gear of the tertiary flywheel 40, and is connected to the small sprocket 37 and the small sprocket 41e through a chain 66.

In this structure, when the motor 66 is rotated, the rotational force is transmitted from the small gear 35A to the small gear 38 via the tertiary flywheel 40, and further from the small sprocket 37 to the small sprocket 41 via the chain 66. The seventh rotating shaft 21° is driven. By driving the seventh rotating shaft 21 in the manner described above, the motor 33 provides additional driving force to the generator 30 as a sixth power in addition to the power of the motor 2 and the motor 14. In the transmission system from the motor 63, the purpose of equipping the large-diameter tertiary flywheel 40 is to increase the rotational force of the motor 66; however, since the rotational speed will decrease if left as is, The power is once transmitted to the small gear 38 to increase the rotational speed, and then transmitted to the seventh rotating shaft 21 at the required rotational speed via the small sprocket 37, the chain 66, and the small sprocket 41. In the drawing, 62 is a rotating bearing box, and 1 is a changeover switch.

In addition, the large gear 5u26OB and the secondary flywheel 7 have a capacity of 700 fl, and are lifted by springs on their outer peripheries so that they can be moved and removed.

Gear 8 is 150n, gear 9 is 210m, and gear 11 is 80Il! l, Gigya 15 is 150 dragons, Gear 16 is 10
0 Tsuru, gear 18 is 250xiK, gear 20 is 100m,
The first 170fi, the generator 30 is a 2,000 rpm 6.7 centimeter.

C1 action I will explain it along with the effects.

C0 Effects of the Invention A1 In the book of the present invention, six pairs of flywheels are installed before the final generator, and the inertia of the rotation is utilized. By meshing several of them, it is possible to finally rotate a generator about five times as many times.

Initially, commercially available electricity was used to start the machine, but if 2KW of power was supplied to the electric motor of the present application from the battery of electricity obtained from the activities of this machine, the energy cost of the claimed machine would be completely reduced to nothing. Therefore, if two or more of these machines are connected and installed, an extremely cheap power source can be obtained.Using this cheap energy, first, the hydrogen obtained by electrolyzing water can be used to power automobiles. If used as a fuel, it would be possible to completely prevent air pollution that has plagued all mankind this century.

Furthermore, if the pollution of industrial wastewater is decomposed using this inexpensive electricity, the water will be dehydrated, and if the residual waste is incinerated, this will also help prevent pollution. Furthermore, if this low-cost electricity is widely used in ordinary households, there will be no need to import natural oil, natural gas, or uranium, which will improve the foreign currency situation and be extremely helpful in revitalizing the Japanese economy. This machine also generates power at a very low cost, so if you use that power to operate a compressor and compress the air to the extreme, you can raise the temperature up to 170 degrees Celsius. Utilizing high temperatures equivalent to this heat value, it is also possible to thaw hydroelectric power plants frozen at minus 40 degrees Celsius. Furthermore, it can be applied to snow melting in areas with heavy snowfall to remove snow damage very easily. In addition, the temperature of the hotbed can be maintained at a moderate temperature, and it is possible to obtain heating at an extremely low price, which previously required expensive items such as oil and gas. It is thought that the contribution to the national economy by greatly reducing the cost of people's energy lifestyles will be enormous.

[Brief explanation of drawings]

Fig. 1 is a plan view, Fig. 2 is a side sectional view, Fig. 6 is a side view showing the flywheel section and gear section, Fig. 4 is a front sectional view showing the freewheel section, and Fig. 5 is a side view of the same as above. 6 is a side view showing the spring claw portion, FIG. 7 is a plan view of the same as above, FIG. 8 is a side view showing the spring insertion lift, and FIG. 9 is a plan view of the same. Eel, 14. ,,Motor, 14A,,,Gear, 30
, , Generator , 40 , , Tertiary flywheel.

Claims (1)

[Claims] Two 1/2 HP motors 2 are provided on the left end of the frame 31, a gear 2A is provided on the output shaft of the motor 2, and a gear 3 is meshed with the gear 2A to rotate the first rotating shaft 4. A gear 3A is provided at the center of the first rotating shaft 4, and this gear 3A is configured to mesh with a large gear 5 provided at the center of the second rotating shaft 6 to rotate the second rotating shaft 6. The sixth rotating shaft 10 is configured to rotate by meshing with a gear 8 provided at the center of the third rotating shaft 10, and a gear 9 is provided on the fifth rotating shaft 10 in parallel with the gear 8, and the fourth rotating shaft 13 The gear 12 provided at the center of the fourth rotation shaft 13 meshes with the gear 11 provided at the center of the fifth rotation shaft 17 to rotate the fourth rotation shaft 13.
5, another gear 16 is provided on the fifth rotating shaft 17, and this gear 16 is configured to mesh with a gear 18 provided at the center of the sixth rotating shaft 19 to rotate the sixth rotating shaft 19. A gear 18 provided at the center of the sixth rotating shaft 19
is configured to rotate the seventh rotating shaft 21 by meshing with a gear 20 provided at the center of the seventh rotating shaft 21.
A primary flywheel 22 is provided at each end of the 7th rotating shaft 21, and a sprocket 23 is provided next to the gear 20 on the 7th rotating shaft 21. A chain 28 is connected to a sprocket 25 provided at the center of the eighth rotating shaft 27, and a chain 28 is connected to a sprocket 26 provided at the center of the eighth rotating shaft 27.
This is carried on a sprocket 29 provided on the drive shaft of the generator 30, and the freewheel 3 is mounted on both ends of the second rotating shaft 6.
4, and a spring pawl 7 is attached to the outer periphery of the secondary flywheel 7 over the entire circumference.
A is installed at appropriate pitches using fixing screws 7B, while 1/A is installed corresponding to the secondary flywheel 7.
A gear 14A that engages and disengages from the spring pawl 7A is fixed to the output shaft of the 4HP motor 14, and a small sprocket 41 is fixed to both ends of the seventh rotating shaft 21, and a small sprocket 41 is attached to the outer periphery via a bearing 42 next to it. A large-diameter tertiary flywheel 40 equipped with gears is installed, and a 1/2 HP motor 33 is arranged and fixed to the frame 31 in correspondence with the position of the tertiary flywheel 40, and the output shaft is Small gear 3
3A is fixed and meshed with the gear of the tertiary flywheel 40, the rotating shaft 39 is placed at another position facing the outer periphery of the tertiary flywheel 40, and the small gear 38 and the small sprocket 37 are connected to this. The power doubling generator is characterized in that the small gear 38 is fixed to the gear of the tertiary flywheel 40, and the small sprocket 37 and the small sprocket 41 are connected by a chain 36.