JPH09158825A - Gravitated rotary power unit rotated utilizing action of gravity and lever principle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain automatic rotary motion utilizing the gravitation force for the princile of a lever by using a chain motion device and a lever receptacle acting as a lever in a rotating wheel device of elliptic motion and elliptic one side elliptic motion. SOLUTION: Two rotary gears 7 and two idle pulleys 8 are fitted to the upper and lower sides of a strut 15 each one on both sides with a width deciding pipe in the center by a rotating shaft 9, and a bearing pipe 16 with a bolt is fitted to the lower rotating shaft 9. An assembled chain motion device is seated on the rotary gears 7 and the idle pulley 8, and the width deciding pipe is put on both sides with the lever receptacle 1 in the center to be fitted to the chain motion device by a lever receptacle receiving rod 14.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention utilizes an gravitational force, an attractive force, and an action force based on the principle of leverage to make an elliptical chain elliptical motion device for rotary motion and a lever container acting as a lever up and down. The present invention relates to a self-weighted rotary power plant that makes a rotary motion via a certain rotary gear.

[0002]

2. Description of the Related Art It has been written in textbooks and the like that it has been proven by modern science that a power plant utilizing gravity is impossible. I think it's about the circular movement. Then, when the weight is lowered on the circular rotating wheel, the lever principle is utilized only when it is on the horizon line about the rotation axis, and when it is above and below the horizon line, the lever action is weakened. Gravity is acting only in the vertical direction where the object is located.

In order to make the most of the leverage of the lever on the horizontal line at the center of the circle, it is possible to consider an elliptic or elliptical movement, which requires a longer time interval. Fig. 14 shows an inward bending prevention chain link that prevents the inward bending due to the weight. A chain is attached to one chain, and a protruding plate is attached to the tip of the chain. It is the number of kg measured. The distance of the weight is twice that of the scale. The numbers in parentheses are the weights measured by attaching the rotating wheel to the rotating wheel support plate attached to the column and making one side oval and measuring it.
Is a number.

In the case of an ellipse, the magnification is slightly increased only in the part where the chain is in contact with the rotating wheel, but the part that is not in contact is 1 kg as it is. In the case of an ellipse, the contact portion with the rotating wheel in the middle rises by a factor of 1.5 or more, but this is a little. Therefore, one chain cannot utilize the lever principle. Then how about two rows?

FIG. 5 shows a chain motion device in which an outer turning chain having a radius of 300 mm and an inner turning chain having a radius of 150 mm are arranged in two rows and laterally connected to each other.
This device is attached to the rotating wheel device of FIG. 14, a hanging scale is attached to the inner chain, and the outer chain on the opposite side is
If the weight is lowered, the weight of 1 kg will be 2 kg for the hanging scale.
It appears as Both the contacting part and the non-contacting part of the rotating wheel appear as 2 kg. Therefore, it indicates that the weight was at a position twice the distance from the scale. With this oval and elliptical chain movement device, the lever principle exerts a force on the opposite side only by gravity. FIG.
No. 4 rotating wheel device is fixed to the shaft by attaching the rotating chain receiving rotating gear 7 to the rotating shaft. The inside rotating receiving vehicle is not fixed to the rotating shaft, but the two rows of chain motion devices are seated on the rotating gear 7 and the same 1 kg as before. If you measure it with the weight of the
It appears as g.

[0006]

SUMMARY OF THE INVENTION The present invention uses a chain motion device for elliptical and elliptical motions and a lever container 1 that functions as a lever to extend the rotation in time and distance. The purpose is to make possible.

[0007]

In order to achieve the above object, in the self-weighted rotary power plant of the present invention, two units are mounted on the table.
Two bearing columns (15) are installed symmetrically, two rotating gears (7) and two idler wheels (8) are installed on the top, and two rotating gears (7) and two idler wheels (8) are also installed on the bottom. Attach.
The rotary gear (7) is fixed to the rotary shaft (9). The lever assembly 1 which is a hollow body in which the previously assembled oval and elliptical motion chain motion devices are seated on both sides and connected by joint pins is attached to the chain motion device using the lever container support rod 14.

In order to determine the length (pitch) of the chain link of the above-mentioned chain motion device, the rotating gear 7 for receiving the outer chain link is divided into a number of equal parts, and the points where the outer peripheries intersect are connected by a straight line. Determine the length (pitch) of the chain link. With several lengths of this chain link, the distance between the upper rotary gear 7 and the lower rotary gear 7 does not come into contact, and the distance between the upper and lower rotary shafts 9 is determined. The sum of the number of chain links above and below the circumference and the number on each side between the axes is the number of outer chain links divided into equal parts.

Next, the length (pitch) of the inward chain link is obtained. The number of lengths obtained by multiplying the diameter of the idler wheel 8 by the pi, and the number of lengths obtained by doubling the length between the upper and lower shafts are summed. The length of the inner chain link is obtained by dividing this number of lengths by the number of outer chain links. It is also the same as the number of chain links that go around. Although it depends on the length of the chain link, there is a difference between the circle and the straight line of the chain link, which must be subtracted. Chain link 1
It is about 0.5 mm to 1 mm for each piece. This depends on the actual size. The idler wheel 8 is attached with the chain link being slightly smaller than the obtained diameter.

On the contrary, the length of the inner chain link may be determined first, and the length of the outer chain link may be determined by the method of obtaining the length of the inner chain link. After that, the horizontal connecting plate 6 is used for horizontal connection. The width between chains can be widened at one time and many rows of chain links can be installed in the middle. Therefore, the distance between the rotary gear and the rotary shaft can be increased without limit. As for the chain link assembled in the middle and the chain link that rotates inward, every other chain link 5 with stopper that rotates inward is used. Since it is in a stretched state around the circular movement, it is relaxed by using the lateral connecting plate 30.

Although not shown in the chain movement device of FIG. 5, when the lever plate 1 and the lever plate 1 are attached by mounting the protruding plate 11 and the lever-supporting plate 10 for auxiliary levers for receiving the chain link. It becomes a self-rotating power unit. In this case, the outer chain link 34 is in the contracted state, but is not ready for the rotational movement. By using the inner chain link 38 shown in FIG. 7 on the inner side, the contracted state of the outer circumference can be alleviated.

The hollow lever container 1 is shown in FIGS.
There are three types of containers, 0 and FIG. Liquid reservoirs are provided above and below both ends of the container. It is natural for the liquid to flow toward the lower reservoir due to the rotational movement. As the liquid heavy material, a liquid material having good fluidity and large specific gravity should be used. For example, mercury, salt water, and the like.
Although the width of the lever container can be wide, the length must be clarified by relating the drop velocity to the liquid flow velocity, and an appropriate length must be obtained.

[0013]

As described above, the self-rotating rotary power unit configured as described above can maintain the lever container 1 in a horizontal state for a long time by the chain motion device for elliptic and elliptic motions, and the principle of lever motion to the opposite side can be maintained. Can be given.

[0014]

EXAMPLE An example will be described with reference to the drawings. In FIGS. 1, 2, and 3, two support columns 15 for bearings are mounted on a stand and fixed on both sides and welded. Insert the rotating shaft 9 into the bearing hole of the column 15, and insert one rotating gear 7 and one idler wheel 8. Further, the width-determining pipe 27, the idler wheel 8 and the rotary gear 7 are inserted in this order up and down, the bearing pipe 16 with a bolt is attached to the lower rotary shaft 9 and fixed by the nut 25. The rotary gear 7 is fixed to the key groove of the shaft with the key at the top and bottom. An elastic body 21 is fixed to the play vehicle 8 to prevent noise and idling.

The outer chain link 3 of the chain motion device for elliptical and elliptic motions, which rotates outward, has the roller 20 outward, and the inner chain link 2 which rotates outward, and the lateral connecting plate 6 further.
To the inside of the inner chain link 2 that rotates outward, and stop with the pin 12. Next, similarly connect the opposite side with the chain connecting rod 13 on both sides. Connect the chain links alternately with the pins 12 and the connecting rods 13 on both sides of the chain.

Further, the inner chain link 4 is outwardly
The chain link 5 with a stopper that goes inward is made inside, and the lateral connecting plate 6 is fixed to this inside by a pin 12. The whole is assembled by the above method, and the final end is not stopped, but is seated on the rotary gear 7 and the idler wheel 8 and stopped. Next, the lever container receiving assisting plate 10 is attached to the lateral connecting plate 6 every other chain link. Overhanging board 11
Is carefully attached to the position where the lever container 1 fits. Attach it on the other side in the same position. Next, the lever container 1 is attached with the lever container receiving rod 14 by inserting the width determining tubes 27 into both sides. The lever container support plate 10 is slightly stretchable depending on the position during exercise, and the plate is attached with a long length.

With reference to the embodiment shown in FIG. 4 and FIG. 2, one rotary gear 29 is provided on each side, one idle wheel 8 is provided on both sides of the rotary gear 29, and a width determining pipe 27 is provided inside. The support shaft 15 is attached above and below the support shaft 15 by the rotating shaft 9. A bearing tube 16 with a bolt is attached to the lower rotating shaft 9. With the outer outer chain link 3 and the roller 20 in the middle, the outer inner chain link 2 is viewed from the side and assembled in two rows on one side. In the middle, there is a chain in which the inward turning chain link 4 and the inward turning chain link 5 with a stopper are assembled alternately, and the chain in which the inward turning chain link 31 and the inward turning chain link 32 with a stopper are alternately assembled is long on one side. The holes are connected by the horizontal connecting plate 30 so as to be integrated. This is because the use of the long holes relieves expansion and contraction around the circular movement. Although not shown in the drawing, the lever container support plate 10 is attached between the lateral connecting plates 30 of the middle chain and the inner chain, the lever container 1 is attached by the chain side connecting rods 13 and the outer side is attached to the outer chain. As a result, it becomes a self-rotating power unit.

With reference to the embodiment shown in FIG. 5 and FIG. 2, one rotary gear 33 is attached to each side, and the width determining pipe 27 is placed inside the rotary shaft 9 so as to be mounted above and below the column 15. The gear is fixed to the shaft. A bearing tube 16 with a bolt is attached to the lower rotating shaft 9. Roll the inner chain link 35 to the outside (20)
With the chain link 35 with the stopper inwardly turning inward, the chain with the chain link 35 alternately placed inside, the horizontal connecting plate 6 aligned with the inside, and connected with the pin 12 to connect the rotary gear 33. Install on each side. Then, the outer chain link 34 and the lateral connecting plate 6 are set to the inner side, fixed by the pin 12, and then the chain is connected alternately with the chain connecting rods 13 on the opposite side. The outer chain link 34 of the chain motion device performs a contracted motion on the circumference. To alleviate this condition, the curved chain link 38 with a stopper shown in FIG. 7 is used. This is because the lateral connection plate 6 is opened by functioning to push it outward. Although not shown in the drawing, the chain movement device is provided with a lever container 1
It becomes a self-rotating power unit by attaching.

The embodiment shown in FIG. 9 is a lever body container 1 having a hollow body.
Liquid reservoirs are provided at the top and bottom at both ends. The inlet is provided either above or below, and the liquid heavy object 43 is put in the inlet cover 4
Screw in 2. The lighter the container body, the better.

The embodiment shown in FIG. 10 is a hollow body lever container 4
Liquid reservoirs are vertically provided at both ends of 4. The liquid weight 43 is injected from the injection port and screwed with the injection port lid 42.
The top of the container is rounded. The top and bottom may be round.
The resistance is eased when the liquid flows.

The embodiment shown in FIG. 11 is a hollow body lever container 1.
Liquid reservoirs are provided at the top and bottom at both ends. Liquid weight 43
Then, the weight roller 47 is further used in the container to increase the weight. In order to mitigate the collision when the weight roller 47 moves, the elastic body 50 is stretched over the roller guide plate 48 and the container.
Although not shown, an elastic material is fixed to the wall of the contact portion at the end. An entrance of a weight roller 47 is provided on one side of the side surface of the container, and the weight roller 47 is accommodated and a lid is used to weld a weldable material and a non-weldable material with a bolt. A liquid heavy object is put in through the inlet and screwed with the inlet lid 42.

In the embodiment shown in FIG. 12, a roller guide lever is used in which roller receiving plates are welded to the periphery of an elliptical plate on both sides and a weight roller 47 is housed therein and welded and joined by a joint plate 54. 53. To alleviate the collision of the movement of the weight roller 47, the elastic body 50 is stretched above and below the joint plates 54 at both ends.
Further, an elastic object is fixed to the contact portion of the weight roller 47 by utilizing the joint plate 54.

In the embodiment shown in FIG. 13, a solid heavy object 56 is put in a roller tube 55. The weight roller 47 has a rotating shaft 51 passing through the center thereof. Weight roller 47
The elastic body 21 is fixed to the outer periphery of the. This weight roller 4
2 pieces of 7 are attached with the roller bearing plate 46, and it is 25 with the nut.
Stop with the small vehicle bracket bracket 52 and the small vehicle 49
Is attached by the rotary shaft 45. The weight roller 47 sometimes becomes slanted during the movement to hit the lateral wall and cannot move. It can be prevented by installing small cars on both sides and attaching them. Alternatively, a ball may be used by putting a heavy object in the ball.

[0024]

Since the present invention is configured as described above, the effects will be described below.

A perfect circular movement has been difficult. Elliptical movement is also 1
Although it was not possible with a chain of books, the lever container 1 is attached to the chain motion device for elliptic and elliptic motions in which two or more rows are formed by integrating the chain around the outer circumference and the chain around the inner circumference by the horizontal connecting plate 6. As a result, the acting force of the heavy object of the lever container 1 can be directly applied to the opposite side. Further, the larger the rotary gear 7, the longer the distance between the upper and lower rotary shafts 9 can be, and the larger the number of lever containers 1 can be attached, the greater the force applied to the opposite side.

Further, it is possible to maintain the horizontal state of the lever container 1 for a long time, which was not possible with the perfect circular motion, and it is possible to effectively exert the action force of the lever on the opposite side. A large force can be obtained by arranging the self-weighted rotary power units for elliptical and elliptical motions in several rows and connecting the rotary shafts respectively.

In the elliptic motion, the rotary gear 7 and the idler wheel 8 are held up and down, and the large rotary gear and idler wheel are provided in the middle. The length (pitch) of the chain link for the movement of the ellipse and the one-sided ellipse is obtained by the method obtained by the ellipse. The lever container 1 is attached to a chain motion device that can be formed in two or more rows like an ellipse. Similar to the ellipse, the rotary gear 7 and the intermediate rotary gear can be enlarged to attach a large number of lever containers. The horizontal state is not as long as an ellipse, but it can be maintained for a long time, and the leverage of the lever can be exerted on the opposite side.

A chain motion device which moves the outer and inner circumferences of the upper and lower rotary gears in two or more rows is shown in FIG. 1. The chain connecting device is on the left side of the upper rotary gear 7 and on the horizontal line of the rotary shaft. 6
The outermost chain is the most inclined and the inner chain is pulled up. In the lower rotary gear 7, the inner rotating chain is pulled down by the force applied to the outer rotating chain on the right side below the horizontal line of the shaft. The other horizontal connecting plates 6 have little influence on the rotation of the inner chain. Why is it exerting the leverage of the lever while being pulled by the outer chain? Taking into consideration the fact that it goes up by 1.4 times when it comes into contact with the rotating wheel in FIG. 14, the outer turning chain is pulled up with the inner turning chain together with the rotating gear. It is considered that the lower outer chain on the opposite side is also integrated with the rotary gear to pull down the inner chain. It is also considered that the outer rotating chain, which does not change even when the idler wheel 8 is removed, is integrated with the rotary gear 7 and is pulled up and down at the position of the inner rotating chain through the lateral connecting plate 6.

Further, on the circumference where the width between the chains cannot be widened, the difference between the lengths of the chains inside and outside becomes large, and the lateral connection becomes unreasonable. However, it is possible to widen the width at a time and incorporate several rows of chain links in the middle. Length (pitch) of chain link inserted in the middle
Can be calculated in the same way as the inner chain. It can be used for any large rotating wheel by making it a few rows. The inner chain can be located near the axis of rotation.

In FIG. 5, in the double-row chain moving device that moves by the inner rotating chain receiving rotary gear 33, it is considered that the inner rotating chain is integrated with the rotating gear 33 to be 1.4 times. Further, it is considered that the force applied to the outer rotating chain 34 is added and the rotating gear 33 and the outer rotating chain 34 are also integrated around the circumference to give a force to the opposite side.

In the lever container, the container should be as light as possible. The longer the container, the greater the leverage as a lever. There is air in the container, which resists the flow of heavy liquids. A vacuum can be used, but the container becomes heavy. Increase the flow port of the container or install a pipe between the upper part of the liquid reservoir and the upper part of the container. It is also good to install it on the opposite side to provide an air flow path.

Also, by rounding the upper side of the container of FIG. 10, when the upper side is downward, the liquid flows well along the roundness and the resistance is reduced. It may be rounded up and down.

Further, in FIG. 11, the weight can be increased by using both the liquid weight 43 and the solid weight 56 to increase the effectiveness of the lever.

Further, in FIG. 12, lead or the like having a large specific gravity is used for the weight roller 47 to increase the effectiveness of the lever, so that the entire apparatus can be downsized.

[Brief description of the drawings]

FIG. 1 is a partial sectional front view showing an embodiment of a self-rotating power unit.

FIG. 2 is a cross-sectional view taken along the line AA showing the embodiment of the self-rotating power unit, which is seen by raising the lever container without dividing it.

FIG. 3 is a cross-sectional view showing a main part of the chain link of the embodiment of the self-rotating power unit.

FIG. 4 is a partial sectional front view showing an embodiment of a rotary gear and a chain motion device.

FIG. 5 is a partial sectional front view showing an embodiment of a rotary gear and a chain motion device.

FIG. 6 is a detailed view showing a main part of a chain link with a stopper that rotates inward in an embodiment of a chain motion device.

FIG. 7 is a detailed view showing an essential part of a bent chain link with an inward stopper of an embodiment of a chain motion device.

FIG. 8 is a plan view showing a main part of a long hole holding horizontal connecting plate of an embodiment of a chain motion device.

FIG. 9 is a partial cross-sectional perspective view showing an embodiment of a lever container.

FIG. 10 is a partial cross-sectional perspective view showing an example of a lever container.

FIG. 11 is a sectional perspective view showing an example of a lever container.

FIG. 12 is a sectional perspective view showing an embodiment of a roller guide lever.

FIG. 13 is a partial cross-sectional plan view showing an example of the weight roller.

FIG. 14 is a front view showing a part of the experimental device in which the force exerted on the opposite side by the weight is measured and investigated.

[Explanation of symbols]

1, 44 Lever container 2 Outer inner chain link 3, 34 Outer outer chain link 4, 31, 35 Inner chain link 5, 32, 36, 38 Inner stopper chain link 6, 30 Horizontal connecting plate 7, 29 , 33 Rotating gear 8 Idler 9, 45, 51 Rotating shaft 10 Lever container receiving support plate 11 Overhanging plate 12 Pin 13 Chain both side connecting rod 14 Lever container receiving rod 15 Strut 16 Bearing tube with bolt 17 Adjusting nut 18, 28, 52 Bracket 19 Spring 20 Roller 21, 50 Resilient body 22 Arm 23, 24 Long hole 25 Nut 26 Flange 27 Width determining pipe 37 Stopper protrusion 39 Hit plate 40 Long hole 41 Pin hole 42 Pouring lid 43 Liquid weight 46 Roller bearing Plate 47 Weight roller 48 Roller guide plate 49 Small car 53 Roller guide lever 54 Joint plate 55 Roller Tubes 56 Solid heavy

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[Procedure amendment]

[Submission date] July 17, 1996

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction contents]

[Document Name] Statement

[Title of Invention] Self-rotating rotary power plant that rotates by utilizing the principle action of gravity and lever

[Claims]

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention utilizes an gravitational force, an attractive force, and an action force based on the principle of leverage to make an elliptical chain elliptical motion device for rotary motion and a lever container acting as a lever up and down. The present invention relates to a self-weighted rotary power plant that makes a rotary motion via a certain rotary gear.

[0002]

2. Description of the Related Art It has been written in textbooks and the like that it has been proven by modern science that a power plant utilizing gravity is impossible. I think it's about the circular movement. Then, when the weight is lowered on the circular rotating wheel, the lever principle is utilized only when it is on the horizon line about the rotation axis, and when it is above and below the horizon line, the lever action is weakened. Gravity is acting only in the vertical direction where the object is located.

In order to make the most of the leverage of the lever on the horizontal line at the center of the circle, it is possible to consider an elliptic or elliptical movement, which requires a longer time interval. Fig. 14 shows an inward bending prevention chain link that prevents the inward bending due to the weight. A chain is attached to one chain, and a protruding plate is attached to the tip of the chain. It is the number of kg measured. The distance of the weight is twice that of the scale. The numbers in parentheses are the weights measured by attaching the rotating wheel to the rotating wheel support plate attached to the column and making one side oval and measuring it.
Is a number.

In the case of an ellipse, the magnification is slightly increased only in the part where the chain is in contact with the rotating wheel, but the part that is not in contact is 1 kg as it is. In the case of an ellipse, the contact portion with the rotating wheel in the middle rises by a factor of 1.5 or more, but this is a little. Therefore, one chain cannot utilize the lever principle. Then how about two rows?

FIG. 5 shows a chain motion device in which an outer turning chain having a radius of 300 mm and an inner turning chain having a radius of 150 mm are arranged in two rows and laterally connected to each other.
This device is attached to the rotating wheel device of FIG. 14, a hanging scale is attached to the inner chain, and the outer chain on the opposite side is
If the weight is lowered, the weight of 1 kg will be 2 kg for the hanging scale.
It appears as Both the contacting part and the non-contacting part of the rotating wheel appear as 2 kg. Therefore, it indicates that the weight was at a position twice the distance from the scale. With this oval and elliptical chain movement device, the lever principle exerts a force on the opposite side only by gravity. FIG.
No. 4 rotating wheel device is fixed to the shaft by attaching the rotating chain receiving rotating gear 7 to the rotating shaft. The inside rotating receiving vehicle is not fixed to the rotating shaft, but the two rows of chain motion devices are seated on the rotating gear 7 and the same 1 kg as before. If you measure it with the weight of the
It appears as g.

[0006]

SUMMARY OF THE INVENTION The present invention uses a chain motion device for elliptical and elliptical motions and a lever container 1 that functions as a lever to extend the rotation in time and distance. The purpose is to make possible.

[0007]

In order to achieve the above object, in the self-weighted rotary power plant of the present invention, two units are mounted on the table.
Two bearing columns (15) are installed symmetrically, two rotating gears (7) and two idler wheels (8) are installed on the top, and two rotating gears (7) and two idler wheels (8) are also installed on the bottom. Attach.
The rotary gear (7) is fixed to the rotary shaft (9). The lever assembly 1 which is a hollow body in which the previously assembled oval and elliptical motion chain motion devices are seated on both sides and connected by joint pins is attached to the chain motion device using the lever container support rod 14.

In order to determine the length (pitch) of the chain link of the above-mentioned chain motion device, the rotating gear 7 for receiving the outer chain link is divided into a number of equal parts, and the points where the outer peripheries intersect are connected by a straight line. Determine the length (pitch) of the chain link. With several lengths of this chain link, the distance between the upper rotary gear 7 and the lower rotary gear 7 does not come into contact, and the distance between the upper and lower rotary shafts 9 is determined. The sum of the number of chain links above and below the circumference and the number on each side between the axes is the number of outer chain links divided into equal parts.

Next, the length (pitch) of the inward chain link is obtained. The number of lengths obtained by multiplying the diameter of the idler wheel 8 by the pi, and the number of lengths obtained by doubling the length between the upper and lower shafts are summed. The length of the inner chain link is obtained by dividing this number of lengths by the number of outer chain links. It is also the same as the number of chain links that go around. Although it depends on the length of the chain link, there is a difference between the circle and the straight line of the chain link, which must be subtracted. Chain link 1
It is about 0.5 mm to 1 mm for each piece. This depends on the actual size. The idler wheel 8 is attached with the chain link being slightly smaller than the obtained diameter.

On the contrary, the length of the inner chain link may be determined first, and the length of the outer chain link may be determined by the method of obtaining the length of the inner chain link. After that, the horizontal connecting plate 6 is used for horizontal connection. The width between chains can be widened at one time and many rows of chain links can be installed in the middle. Therefore, the distance between the rotary gear and the axis of the rotary shaft can be increased without limit. As for the chain link assembled in the middle and the chain link that rotates inward, every other chain link 5 with stopper that rotates inward is used. Since it is in a stretched state around the circular movement, it is relaxed by using the lateral connecting plate 30.

Although not shown in the chain movement device of FIG. 5, when the lever plate 1 and the lever plate 1 are attached by mounting the protruding plate 11 and the lever-supporting plate 10 for auxiliary levers for receiving the chain link. It becomes a self-rotating power unit. In this case, the outer chain link 34 is in the contracted state, but is not ready for the rotational movement. By using the inner chain link 38 shown in FIG. 7 on the inner side, the contracted state of the outer circumference can be alleviated.

The hollow lever container 1 is shown in FIGS.
There are three types of containers, 0 and FIG. Liquid reservoirs are provided above and below both ends of the container. It is natural for the liquid to flow toward the lower reservoir due to the rotational movement. As the liquid heavy material, a liquid material having good fluidity and large specific gravity should be used. For example, mercury, salt water, and the like.
Although the width of the lever container can be wide, the length must be clarified by relating the drop velocity to the liquid flow velocity, and an appropriate length must be obtained.

[0013]

As described above, the self-rotating rotary power unit configured as described above can maintain the lever container 1 in a horizontal state for a long time by the chain motion device for elliptic and elliptic motions, and the principle of lever motion to the opposite side can be maintained. Can be given.

[0014]

EXAMPLE An example will be described with reference to the drawings. In FIGS. 1, 2, and 3, two support columns 15 for bearings are mounted on a stand and fixed on both sides and welded. Insert the rotating shaft 9 into the bearing hole of the column 15, and insert one rotating gear 7 and one idler wheel 8. Further, the width-determining pipe 27, the idler wheel 8 and the rotary gear 7 are inserted in this order up and down, the bearing pipe 16 with a bolt is attached to the lower rotary shaft 9 and fixed by the nut 25. The rotary gear 7 is fixed to the key groove of the shaft with the key at the top and bottom. An elastic body 21 is fixed to the play vehicle 8 to prevent noise and idling.

The outer chain link 3 of the chain motion device for elliptical and elliptic motions, which rotates outward, has the roller 20 outward, and the inner chain link 2 which rotates outward, and the lateral connecting plate 6 further.
To the inside of the inner chain link 2 that rotates outward, and stop with the pin 12. Next, the chain is connected on both sides by the chain connecting rods 13 on the opposite side.
Alternate chain links with pin 12 and connecting rod 13 on both sides of the chain
To build up.

Further, the inner chain link 4 is outwardly
The chain link 5 with a stopper that goes inward is made inside, and the lateral connecting plate 6 is fixed to this inside by a pin 12. The whole is assembled by the above method, and the final end is not stopped, but is seated on the rotary gear 7 and the idler wheel 8 and stopped. Next, the lever container receiving assisting plate 10 is attached to the lateral connecting plate 6 every other chain link. Overhanging board 11
Is carefully attached to the position where the lever container 1 fits. Attach it on the other side in the same position. Next, the lever container 1 is attached with the lever container receiving rod 14 by inserting the width determining tubes 27 into both sides. The lever container support plate 10 is slightly stretchable depending on the position during exercise, and the plate is attached with a long length.

With reference to the embodiment shown in FIG. 4 and FIG. 2, one rotary gear 29 is provided on each side, one idle wheel 8 is provided on both sides of the rotary gear 29, and a width determining pipe 27 is provided inside. The support shaft 15 is attached above and below the support shaft 15 by the rotating shaft 9. A bearing tube 16 with a bolt is attached to the lower rotating shaft 9. With the outer outer chain link 3 and the roller 20 in the middle, the outer inner chain link 2 is viewed from the side and assembled in two rows on one side. In the middle, there is a chain in which the inward turning chain link 4 and the inward turning chain link 5 with a stopper are assembled alternately, and the chain in which the inward turning chain link 31 and the inward turning chain link 32 with a stopper are alternately assembled is long on one side. The holes are connected by the horizontal connecting plate 30 so as to be integrated. This is because the use of the long holes relieves expansion and contraction around the circular movement. Although not shown in the drawing, the lever container support plate 10 is attached between the lateral connecting plates 30 of the middle chain and the inner chain, the lever container 1 is attached by the chain side connecting rods 13 and the outer side is attached to the outer chain. As a result, it becomes a self-rotating power unit.

With reference to the embodiment shown in FIG. 5 and FIG. 2, one rotary gear 33 is attached to each side, and the width determining pipe 27 is placed inside the rotary shaft 9 so as to be mounted above and below the column 15. The gear is fixed to the shaft. A bearing tube 16 with a bolt is attached to the lower rotating shaft 9. Roll the inner chain link 35 to the outside (20)
With the chain link 35 with the stopper inwardly turning inward, the chain with the chain link 35 alternately placed inside, the horizontal connecting plate 6 aligned with the inside, and connected with the pin 12 to connect the rotary gear 33. Install on each side. Then, the outer chain link 34 and the lateral connecting plate 6 are set to the inner side, fixed by the pin 12, and then the chain is connected alternately with the chain connecting rods 13 on the opposite side. The outer chain link 34 of the chain motion device performs a contracted motion on the circumference. To alleviate this condition, the curved chain link 38 with a stopper shown in FIG. 7 is used. This is because the lateral connection plate 6 is opened by functioning to push it outward. Although not shown in the drawing, the chain movement device is provided with a lever container 1
It becomes a self-rotating power unit by attaching.

The embodiment shown in FIG. 9 is a lever body container 1 having a hollow body.
Liquid reservoirs are provided at the top and bottom at both ends. The inlet is provided either above or below, and the liquid heavy object 43 is put in the inlet cover 4
Screw in 2. The lighter the container body, the better.

The embodiment shown in FIG. 10 is a hollow body lever container 4
Liquid reservoirs are vertically provided at both ends of 4. The liquid weight 43 is injected from the injection port and screwed with the injection port lid 42.
The top of the container is rounded. The top and bottom may be round.
The resistance is eased when the liquid flows.

The embodiment shown in FIG. 11 is a hollow body lever container 1.
Liquid reservoirs are provided at the top and bottom at both ends. Liquid weight 43
Then, the weight roller 47 is further used in the container to increase the weight. In order to mitigate the collision when the weight roller 47 moves, the elastic body 50 is stretched over the roller guide plate 48 and the container.
Although not shown, an elastic material is fixed to the wall of the contact portion at the end. An entrance of a weight roller 47 is provided on one side of the side surface of the container, and the weight roller 47 is accommodated and a lid is used to weld a weldable material and a non-weldable material with a bolt. A liquid heavy object is put in through the inlet and screwed with the inlet lid 42.

In the embodiment shown in FIG. 12, a roller guide lever is used in which roller receiving plates are welded to the periphery of an elliptical plate on both sides and a weight roller 47 is housed therein and welded and joined by a joint plate 54. 53. To alleviate the collision of the movement of the weight roller 47, the elastic body 50 is stretched above and below the joint plates 54 at both ends.
Further, an elastic object is fixed to the contact portion of the weight roller 47 by utilizing the joint plate 54.

In the embodiment shown in FIG. 13, a solid heavy object 56 is put in a roller tube 55. The weight roller 47 has a rotating shaft 51 passing through the center thereof. Weight roller 47
The elastic body 21 is fixed to the outer periphery of the. This weight roller 4
2 pieces of 7 are attached with the roller bearing plate 46, and 25 pieces with the nut.
Stop with the small vehicle bracket bracket 52 and the small vehicle 49
Is attached by the rotary shaft 45. The weight roller 47 sometimes becomes slanted during the movement to hit the lateral wall and cannot move. It can be prevented by installing small cars on both sides and attaching them. Alternatively, a ball may be used by putting a heavy object in the ball.

[0024]

Since the present invention is configured as described above, the effects will be described below.

A perfect circular movement has been difficult. Elliptical movement is also 1
Although it was not possible with a chain of books, the lever container 1 is attached to the chain motion device for elliptic and elliptic motions in which two or more rows are formed by integrating the chain around the outer circumference and the chain around the inner circumference by the horizontal connecting plate 6. As a result, the acting force of the heavy object of the lever container 1 can be directly applied to the opposite side. Further, the larger the rotary gear 7, the longer the distance between the upper and lower rotary shafts 9 can be, and the larger the number of lever containers 1 can be attached, the greater the force applied to the opposite side.

Further, it is possible to maintain the horizontal state of the lever container 1 for a long time, which was not possible with the perfect circular motion, and it is possible to effectively exert the action force of the lever on the opposite side. A large force can be obtained by arranging the self-weighted rotary power units for elliptical and elliptical motions in several rows and connecting the rotary shafts respectively.

In the elliptic motion, the rotary gear 7 and the idler wheel 8 are held up and down, and the large rotary gear and idler wheel are provided in the middle. The length (pitch) of the chain link for the movement of the ellipse and the one-sided ellipse is obtained by the method obtained by the ellipse. The lever container 1 is attached to a chain motion device that can be formed in two or more rows like an ellipse. Similar to the ellipse, the rotary gear 7 and the intermediate rotary gear can be enlarged to attach a large number of lever containers. The horizontal state is not as long as an ellipse, but it can be maintained for a long time, and the leverage of the lever can be exerted on the opposite side.

A chain motion device which moves the outer and inner circumferences of the upper and lower rotary gears in two or more rows is shown in FIG. 1. The chain connecting device is on the left side of the upper rotary gear 7 and on the horizontal line of the rotary shaft. 6
The outermost chain is the most inclined and the inner chain is pulled up. In the lower rotary gear 7, the inner rotating chain is pulled down by the force applied to the outer rotating chain on the right side below the horizontal line of the shaft. The other horizontal connecting plates 6 have little influence on the rotation of the inner chain. Why is it exerting the leverage of the lever while being pulled by the outer chain? Taking into consideration the fact that it goes up by 1.4 times when it comes into contact with the rotating wheel in FIG. 14, the outer turning chain is pulled up with the inner turning chain together with the rotating gear. It is considered that the lower outer chain on the opposite side is also integrated with the rotary gear to pull down the inner chain. It is also considered that the outer rotating chain, which does not change even when the idler wheel 8 is removed, is integrated with the rotary gear 7 and is pulled up and down at the position of the inner rotating chain through the lateral connecting plate 6.

The width of the outer turning chain and the inner turning chain
On the circumference that cannot be widened at a time, the difference in chain length between the outer and inner chains becomes large, and it becomes impossible to connect horizontally. However, it is possible to widen the width at a time and incorporate several rows of chain links in the middle. The length (pitch) of the chain link inserted in the middle may be determined in the same way as the inner chain. It can be used for any large rotating wheel by making it a few rows. The inner chain can be located near the axis of rotation.

[0030] Figure 5 two rows Chen movement device that moves in rotary gear 33 of the chain down link BEARING orbiting inner in sees that the inner turn Chen has a 1.4 times together with rotary gear 33. Further, it is considered that the force applied to the outer rotating chain 34 is added and the rotating gear 33 and the outer rotating chain 34 are also integrated around the circumference to give a force to the opposite side.

In the lever container, the container should be as light as possible. The longer the container, the greater the leverage as a lever. There is air in the container, which resists the flow of heavy liquids. A vacuum can be used, but the container becomes heavy. Increase the flow port of the container or install a pipe between the upper part of the liquid reservoir and the upper part of the container. It is also good to install it on the opposite side to provide an air flow path.

Also, by rounding the upper side of the container of FIG. 10, when the upper side is downward, the liquid flows well along the roundness and the resistance is reduced. It may be rounded up and down.

Further, in FIG. 11, the weight can be increased by using both the liquid weight 43 and the solid weight 56 to increase the effectiveness of the lever.

Further, in FIG. 12, lead or the like having a large specific gravity is used for the weight roller 47 to increase the effectiveness of the lever, so that the entire apparatus can be downsized.

[Brief description of the drawings]

FIG. 1 is a partial sectional front view showing an embodiment of a self-rotating power unit.

FIG. 2 is a cross-sectional view taken along the line AA showing the embodiment of the self-rotating power unit, which is seen by raising the lever container without dividing it.

FIG. 3 is a cross-sectional view showing a main part of the chain link of the embodiment of the self-rotating power unit.

FIG. 4 is a partial sectional front view showing an embodiment of a rotary gear and a chain motion device.

FIG. 5 is a partial sectional front view showing an embodiment of a rotary gear and a chain motion device.

FIG. 6 is a detailed view showing a main part of a chain link with a stopper that rotates inward in an embodiment of a chain motion device.

FIG. 7 is a detailed view showing an essential part of a bent chain link with an inward stopper of an embodiment of a chain motion device.

FIG. 8 is a plan view showing a main part of a long hole holding horizontal connecting plate of an embodiment of a chain motion device.

FIG. 9 is a partial cross-sectional perspective view showing an embodiment of a lever container.

FIG. 10 is a partial cross-sectional perspective view showing an example of a lever container.

FIG. 11 is a sectional perspective view showing an example of a lever container.

FIG. 12 is a sectional perspective view showing an embodiment of a roller guide lever.

FIG. 13 is a partial cross-sectional plan view showing an example of the weight roller.

FIG. 14 is a front view showing a part of the experimental device in which the force exerted on the opposite side by the weight is measured and investigated.

[Explanation of symbols] 1,44 Lever container 2 Outer inner chain link 3,34 Outer outer chain link 4,31,35 Inner chain link 5,32,36,38 Inner stopper chain link 6,30 Horizontal Connecting plate 7, 29, 33 Rotating gear 8 Idler 9, 45, 51 Rotating shaft 10 Lever container receiving auxiliary plate 11 Overhanging plate 12 Pin 13 Chain both side connecting rod 14 Lever container receiving rod 15 Strut 16 Bolt bearing tube 17 Adjusting nut 18, 28, 52 Bracket 19 Spring 20 Roller 21, 50 Resilient body 22 Arm 23, 24 Long hole 25 Nut 26 Collar 27 Width determining pipe 37 Stopper convex portion 39 Plate 40 Long hole 41 Pin hole 42 Pouring lid 43 Liquid Heavy items 46 Roller bearing plates 47 Weight rollers 48 Roller guide plates 49 Small cars 53 Roller guide levers 54 Joints Plate 55 Roller tube 56 Solid heavy object

[Procedure amendment 2]

[Document name to be amended] Drawing

[Correction target item name] Fig. 1

[Correction method] Change

[Correction contents]

FIG.

Claims (13)

[Claims] 1. A rotating gear (7, 29, 3) attached to a column (15).
3) Put two and two idle cars (8), one on each side,
The width-determining pipe (27) is placed in the middle with the rotating shaft (9) mounted on the upper side and also mounted on the lower side, and the bolted bearing pipe (16) is mounted on the lower rotating shaft (9) to form an ellipse, an ellipse, or one side. A chain movement device for elliptical movement (FIGS. 1, 4, and 5) is attached to the rotary gears (7, 29, 33) and the idler wheel (8), and the lever container (1) is attached to the lever container (1). , 44) attached to the chain motion device (FIGS. 1, 4, and 5). 2. A rotating gear (7, 29) 2 on the column (15).
The bearing tube (16) with bolts is attached to the upper part of the rotating shaft (9) with the width determining pipe (27) inside and the idler car (2) with one idler car and two idler cars (1) on each side. Rotating wheel device for elliptical movement according to claim 1, mounted on the lower rotating shaft (9). 3. The support shaft (15) is provided with two rotary gears (33), one on each side, with the width determining tube (27) in the middle, and mounted on the rotary shaft (9) at the top and also at the bottom. The bearing tube (16) with bolts is attached to the lower rotating shaft (9).
A rotating wheel device for elliptical movement as described. 4. A rotating gear (7, 29) 2 on the column (15).
Bearing pipe (16) with bolts, with one and two idler wheels (8) on each side, with the width-determining pipe (27) inside, and the rotary shaft (9) mounted above and below Is attached to the lower rotary shaft (9), and two large rotary gears (7, 29) and two idlers (8) are provided between the upper rotary shaft (9) and the lower rotary shaft (9). Width-determining tube (2
The rotating wheel device for elliptic and one-sided elliptical movement according to claim 1, which is mounted with a rotating shaft (9) with 7) in the middle. 5. Inward chain link (4, 31, 35)
Chain link with stopper (5, 32, 36,
38) one by one, and the lateral connecting plates (6, 30) are assembled together with pins (12), the lateral connecting plates (6, 30), the inner chain link (2) and the roller (2) which rotate around. Outside chain link (3, 34) with 20) inside
And pin them together with a pin (12), and then connect them to the oppositely assembled outer chains with chain connecting rods (13) on the opposite side and assemble them alternately with pins (12) and chain connecting rods (13). , Lever container support plate (10) and protruding plate (1
The chain motion device for oval, elliptical, or one-sided elliptic motion according to claim 1, wherein 1) is attached to both sides, and the lever containers (1, 44) are attached by lever levers (14). 6. An outer chain link (3) which rotates outward and an inner chain link (2) which rotates with a roller (20) in between are alternately assembled by a pin (12) and a chain connecting rod (13) on both sides of the chain. Connected to the other side with a rod (13), in the middle, an inner chain link (4) and an inner chain link with stopper (5) are stopped together with a horizontal connecting plate (30) with a pin (12) and assembled alternately. The chain, the further inner chain link (31) and the inner chain link with stopper (32) together with the horizontal connecting plate (30) are fastened together with the pin (12), and the horizontal connecting plate (30) is assembled alternately. A chain movement device for elliptical, elliptical, and one-sided movement according to claim 1 or 5, which can be attached to the chain link in several rows. 7. The inward turning chain link (35) and the inward turning chain link (35) are outside, and the inward turning chain link (36, 38) and the inward turning chain link (3).
Pin (12) with horizontal connecting plate (6) with 5) inside
The outer chain link (34) with the horizontal connecting plate (6).
6. The ellipse, ellipse and one-sided elliptical motions according to claim 1 and 5, wherein the pin (12) and the chain double-sided connecting rod (13) are alternately assembled together and the opposite side and the chain double-sided connecting rod (13) are connected together. Chain exercise equipment. 8. A liquid container is provided vertically at both ends of a hollow lever container (1, 44), and a liquid heavy object (43) is put in through an inlet and screwed with an inlet lid (42). The described lever container. 9. A liquid container is vertically provided at both ends of a hollow lever container (44) to make the upper part of the container round, and a liquid heavy object (43) is put in from an inlet and screwed with an inlet lid (42). The lever container according to claim 1, which is combined. 10. A hollow body lever container (1) is provided with liquid reservoirs vertically at both ends thereof, and a weight roller (47) is placed in the lever container (1) to provide a roller guide plate (48) and an elastic body (5).
The lever container according to claim 1 or 8, wherein an elastic material is fixed to the walls at the ends of which (0) is attached, a liquid heavy material (43) is put in through the inlet, and screwed with the inlet lid (42). 11. A roller receiving plate is welded to the periphery of an elliptical plate, the weight roller (47) is housed in both sides, and the joint plate (54) is welded to the elastic body (50). Roller guide lever with elastic material fixed at each end. 12. A solid heavy object (56) is put in a weight roller (47), a rotary shaft (51) is attached to a hole penetrating through the center, and an elastic body (21) is fixed to the outer periphery of the weight roller (47). 47) A weight roller in which two roller bearing plates (46) are integrally attached to attach the small wheel (49) to the rotary shaft (45). 13. A ball for weighting, in which lead is melted into a metal ball having an outer periphery.