JP2001241375A - Energy generating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To generate energy by letting an automobile depress a step (running plate) of a pump installed on a road or the like to discharge liquid or air from the pump, and rotate an impeller blade of a power generator connected to the pump for generating power. SOLUTION: A piston 1 is installed on a sealed container having a discharge port 10 and a suction port 11 on which a discharge check valve 22 and an intake valve 23 are installed, a pump having a piston and a container fixed by a spring 9 is provided, and pipes 24a, 24b inserted into the discharge port 10 and the suction port are connected to an impeller housing box 27 on the power generator side.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION The present invention relates to a bag-shaped or box-shaped pump, which is made of a stretchable material, has a stretchable structure, or has a piston mounted with a spring. When a person or a car steps on, the liquid or air, such as water or oil, entering the pump is discharged through a pipe, the blades of a generator are turned, and an energy generating device and a person, etc., for generating electric power are discharged. The present invention relates to an energy generation device that can move water or the like to a destination by stepping on the energy generation device.

[0002]

2. Description of the Related Art Conventionally, wind power generation using wind has a high utility value as eco-energy, but the wind is not always blowing, and the drawback is that the power generation efficiency is low compared to the cost of the apparatus. Also, when the windmill is turned by the wind, the sound of the wind cutting the blades makes the person feel uncomfortable.

[0003] Solar systems using sunlight are one of the eco-energy, but the equipment cost is high.
Power generation is not possible in cloudy or rainy days or at night, which is inconvenient.

Further, in order to move water, a pump or the like must be usually used, which consumes energy. Like a dam, storing rainwater and river water, storing water at a high place, and using the energy of the location to generate electricity, etc., requires enormous funds and labor, and requires remote Because of the location, huge transmission costs and losses were incurred.

[0005]

SUMMARY OF THE INVENTION The problem to be solved by the present invention is to generate energy by using the exercise that does not produce energy conventionally, that is, the waste of energy, that is, the walking of a person or the running of a car. Trying to make it happen. The aim is to create a generator that converts sleeping giant energy, such as the huge running weight of a car that consumes a large amount of energy or the weight of a large number of humans, that has not been noticed before, into eco-energy such as power generation.

[0006]

In order to solve the above problems, when a person or a vehicle is loaded, a traveling plate (stepping plate) serves as a piston to remove air, water, oil, etc. in a sealed container. The purpose is to create a mechanism for discharging electricity, turning the blades of the generator with the discharged air, water, oil, etc., rotating the impeller, and generating electricity. Energy consisting of a pump that discharges air, water, oil, etc., and a generator that turns the blades connected to the motor and turns the motor of the generator to generate electricity by the air, water, oil, etc., discharged from the pump. Generator. The basic shape of the pump is a piston portion including a flat plate or a wing-shaped plate (step plate), a body protruding from the step plate, and a flange (pressing plate) attached to the body portion. This is a pump consisting of a compression box fitted with a piston. In the compression box,
An outlet with a check valve and an inlet with a check valve are also provided. Pipes are inserted into the outlet and inlet respectively. A spring is interposed between the pressing plate of the piston and the compression box. This is because the piston is pushed down by a person or a vehicle, and the air, water, oil, and the like in the compression box are discharged to the outside through a discharge pipe, and then automatically returned to the original state. When air is discharged, the blades of the generator are wind turbines having blades attached to the outer periphery of the impeller, and one or more such wind turbines are connected to the motor of the generator coaxially. When discharging the liquid such as water or oil from the pump and rotating the impeller of the generator, it is necessary to devise an impeller and an impeller storage box. The discharged liquid is transported to the impeller by a pipe, and the impeller needs to be rotated in a certain direction. The discharged liquid hits the blade, pushes the blade to rotate the impeller, and rotates the motor of the generator to generate power. The structure of the blade, the impeller, and the impeller storage box will be described in detail in the following embodiments. A sealed storage tank (regulating pump) that temporarily stores air, water, oil, etc. between the pump and the generator (in order to rotate the impeller blades at the same speed as possible and without interruption) ) Can also be provided. This adjustment pump has a movable compression plate fixed to a sealed container with a spring inside, and has a suction port with a suction valve for backflow prevention and a discharge port with a discharge valve for backflow prevention. . The discharge pipe of the main body pump is inserted into the inlet of the adjusting pump, the pipe is inserted into the outlet of the adjusting pump, and the pipe is inserted into one opening of the impeller housing of the generator. A pipe is inserted into another opening of the impeller storage box, and this pipe is inserted into the suction port of the main body pump. The elastic force of the spring attached to the pressing plate of the piston of the main body pump is made stronger than the elastic force of the spring attached to the movable compression plate of the adjusting pump. This is because the pumping pressure of the main body pump is stronger than the pressure of the adjusting pump, so that the liquid and the like discharged from the main body pump enter the adjusting pump, and a part of the liquid is discharged from the outlet of the adjusting pump to store the impeller of the generator. After entering the box, a part pushes up the movable compression plate of the adjusting pump to store liquid and the like in the adjusting pump. When the pump of the main body pump returns to the original position and the liquid is not discharged from the main body pump, the movable compression plate is lowered by the spring interposed in the movable compression plate of the adjustment pump, and the liquid in the adjustment pump is discharged from the generator through the discharge port. Is discharged toward the impeller storage box. By providing the adjusting pump in this way, air and liquid can be sent to the impeller of the generator more constantly,
Power generation efficiency can be increased.

[0007]

BEST MODE FOR CARRYING OUT THE INVENTION
The basic combination is the same when using air and when using a liquid such as water.However, the method for rotating the generator blades is slightly different. Structural differences occur. The basic combination is
A pump for discharging air, water, oil, or the like, and a generator for generating electricity are connected via a pipe.

FIG. 1 shows a piston 1 in a sealed container (compression box 5).
FIG. 2 is a cross-sectional view showing a cross-section of a side surface of the main body pump of the first embodiment equipped with. The main body pump has a piston 1 mounted on a compression box 5, and the piston 1 is composed of a flat tread plate 2 and a body 3 projecting from the tread plate. If the body 3 is not in close contact with the inner wall of the compression box, a flange (pressing plate 4) that is in close contact with the inner peripheral surface of the compression box is attached to the body 3. When the piston is slid in the compression box (when it is moved up and down), the pressure plate of the piston is pressed to give enough pressure to discharge air, water, oil, etc. Must be in close contact with the inner peripheral wall of the vehicle. The compression box 5 is a hollow sealed container having a rectangular body or an arbitrary shape, and has a slot (opening) in the upper surface (top plate 6) into which the body 3 of the piston 1 fits. A flat guide plate 7 may be attached along the slot and perpendicular to the slot. The compression box 5 is provided with a discharge port 10 having a backflow prevention discharge valve (not shown) and a suction port 11 having a backflow prevention suction valve (not shown). Pipes (a discharge pipe 24a and a suction pipe 24b) are inserted into the discharge port and the suction port, respectively. The body 3 of the piston 1 is fitted into a slot (opening) of the top plate 6 of the compression box, and the pressing plate 4 is fixed to the body. A guide or a sliding bearing or the like can be attached to the slot (opening) so that the body fits in the slot and moves up and down smoothly. Guides with air and water leak seals are optimal. A spring 9a (coil spring or leaf spring) is mounted between the pressing plate 4 and the bottom plate 8 of the compression box 5. A spring 9b having an elastic force weaker than the spring 9a is attached between the pressing plate and the top plate 6. (As in Figure 1,
If one pump chamber is used, the spring 9b may be omitted). It is a main body pump having such a structure.

FIG. 2 shows a cross section of the main body pump of the second embodiment in which the inside of the compression box 5 of the main body pump is divided into upper and lower chambers by the pressing plate 4 of the piston 1. A stopper 13 for stopping the pressing plate at a predetermined position is provided inside the compression box. 2, the upper pump chamber 19 and the lower pump chamber 20 are respectively provided with a discharge port 10 having a backflow prevention discharge valve (not shown) and a backflow prevention suction valve (not shown). A suction port 11 is provided, and pipes 24a and 24b (not shown) are inserted into the discharge port and the suction port, respectively. Press plate 4
A spring 9a is interposed between the compression box and the bottom plate 8 of the compression box. A spring 9b is also mounted between the pressing plate and the top plate 6. Instead of providing the discharge port 10 and the suction port 11 directly in the compression box 5, it is made of a stretchable material having a discharge port and a suction port with a check valve, or a box-like structure having a flexible structure such as a bellows structure. Alternatively, a bag-shaped container (elastic body 16) may be provided inside the compression box, the piston 1 may be lowered, the elastic body may be contracted by the pressing plate 4, and air or water may be discharged.

An elastic material 12, such as hard sponge or rubber, is provided between the top plate 6 of the compression box and the tread plate 2 of the piston 1 of the main body pump shown in FIGS. Prevents the treadle from suddenly falling when stepped on. An elastic material is attached on the top plate 6 of the compression box 5 or on the back surface of the tread plate 2 to reduce impact. FIG. 3 is a partially cutaway perspective view of the main body pump of the second embodiment having an upper pump chamber 19 and a lower pump chamber 20 separated by the pressing plate 4 of the piston 1. When the piston is pushed down, the pressure in the lower pump chamber 20 is increased, and the air or liquid in the lower pump chamber is discharged from the discharge port 10. Conversely, the pressure in the upper pump chamber 19 is weakened, and air or liquid is sucked into the upper pump chamber from the outside through the suction port. When the vehicle or the like disappears on the tread plate, the piston is pushed up by the repulsive force of the spring 9a, and air or liquid is sucked into the lower pump chamber from the outside, and the air or liquid entering the upper pump chamber is discharged from the outlet. It is discharged outside.

As shown in FIG. 4, the third embodiment of the main body pump has a simpler structure than the main body pumps of the first and second embodiments, and has a top plate (also serves as the step plate 2; hereinafter referred to as a step plate). And a bottom plate 8 connected by a spring 9 to form a frame of the main body pump. A plurality of suitable legs 14 are hung on the framed tread plate 2, and two plate-like members, rod-like members, or square members (hereinafter referred to as “X plates”) are pivotally mounted on the legs 14. The two X plates 15 are stacked so as to form an X shape, and the leg 1
4 is slidably mounted on the shaft. Two X boards 1 assembled in X shape
A groove or a guide rail is provided at a position where the tip of the step 5 comes into contact with the tread plate 2, a ball or a wheel is attached to the tip of the X plate, and the slide plate slides in the groove or the guide rail. Similarly, the lower end of the X plate is slidably attached to the bottom plate 8. The ratio of the length from the point where the X plate 15 is pivotally mounted to the leg 14 (the fulcrum) to the upper end and the length from the fulcrum to the lower end,
It is possible to amplify the length by which the step board 2 is lowered. A box-shaped or bag-shaped elastic body 16 made of a stretchable material or having a stretchable structure, for example, a bellows structure is provided in the skeleton configured as described above. The expansion and contraction body is provided with a discharge port 10 with a check valve and a suction port 11 with a check valve, and pipes are respectively inserted into the discharge port and the suction port. When the discharge target is air, it is not necessary to insert a pipe into the suction port. When air enters the inside of the elastic body 16, when the treadle 2 is pushed down,
When the telescopic body is compressed, the air inside is exhausted, and the tread returns to its original state with the force of the spring, the pressure inside the telescopic body decreases,
Air is sucked through the inlet. Air can be sucked in with or without a pipe inserted into the suction port. FIG. 4 is a front sectional view of a skeleton in which an elastic body is provided, and FIG. 5 is a side sectional view of the skeleton.

Further, as a fourth embodiment, as shown in FIG. 6, instead of the frame shown in FIG. 4, two plate-like members (top plate 6 and bottom plate 8) are connected to side plate 17 or an appropriate number of columns. And connect
A hollow box is formed, and this is used as a main frame. The tread 2 is fixed or mounted on the top plate 6 of the main body frame via the elastic material 12. An appropriate number of legs 14 are hung on the tread plate 2, and the X plate 15 described above is pivotally mounted on the legs 14. X board 15
And a flat movable partition plate 17 provided inside the main frame.
Hold. A handle or a guide for holding the movable partition plate is provided at or near the upper end of the X plate. (See FIG. 7). The movable partition plate 17 is sandwiched by the X plate 15 and is provided inside the main body skeleton so as to move up and down freely in the main body skeleton. Springs 9a and 9b are interposed between the movable partition plate 17 and the bottom plate 8 and between the movable partition plate 17 and the top plate 6. Whether the space between the movable partition plate 17 and the top plate 6 (upper pump chamber 19) and the space between the movable partition plate and the bottom plate (lower pump chamber 20) are made of a stretchable material. A telescopic body 16 having a telescopic structure, for example, a bellows-like structure, is provided inside. In each elastic body 16,
A discharge port 10 having a check valve and a suction port 11 also having a check valve are provided, and pipes 24a and 24b are respectively inserted into the discharge port and the suction port. FIG. 6 is a front sectional view showing the main body pump in which the step plate 2 on which the X plate 15 is mounted is attached to the main body skeleton having the movable partition plate 18. FIG. 7 is a cross-sectional view of the main body pump of FIG. By changing the ratio of the length (the length from the fulcrum to the upper end and the length from the fulcrum to the lower end) from where the X-plate 15 is pivoted, the length (distance) by which the tread plate is lowered is amplified. The movable partition plate can be lowered. For example, the ratio of the length from the fulcrum to the upper end and the length from the fulcrum to the lower end is 2:
If it is set to 1, when the step board is lowered by 1, the movable partition plate is lowered by 2. The elastic body of the lower pump chamber 20 can be largely compressed by a slight movement (expansion and contraction) of the tread plate, and the discharge amount from the lower pump chamber increases accordingly.

Amplifying structure for greatly expanding and contracting the expandable body 16 with a slight vertical movement of the tread plate 2 to increase the amount of discharge of air, water, etc. In addition to the above-mentioned X-plate structure, FIG.
As shown in FIG. 3, a leg 14 is hung on the tread plate 2, and a lever 33 pivotally mounted on the leg 14 with an arbitrary point as a fulcrum 34. A string or a chain 35 (hereinafter referred to as a “string”) is connected to the other end of or near the lever 33, and is fixed to the movable partition plate 18 through a gap or a string passing tool provided below the lever 33. In this manner, the fulcrum 34 is
When the distance that the tread plate 2 descends is determined by the ratio of the length of the tread plate 2 to the point where the cord 35 is fixed, the distance that the movable partition plate 18 descends is determined. For example, when the ratio is 1: 2, if the stepping plate is lowered by 1, the movable partition plate is lowered by 2. Even with a slight vertical movement of the tread plate, the movable partition plate can be largely moved, and the discharge from the pump can be increased.

Further, a pump using a hook-shaped swinging rod 21 as shown in FIG. 8 is used to amplify the lowered width of the step plate. A strong spring is fixed to the base plate (bottom plate 8), and the spring is attached to the tread plate 2. The spring is also a substitute for the column supporting the tread. One spring may be used, but it is better to use a plurality of springs to stabilize the tread. A suitable leg 14 is attached to a tread connected to the bottom plate by a spring. The key-shaped swinging rod 21 is pivotally mounted on a column or side plate fixed to the bottom plate. The axle is located at the intersection of the hooks (where two straight lines intersect). One end of the swinging rod or the vicinity thereof, which is pivotally attached to the column or the side plate, is pivotally attached to the leg 14. A piston 1 mounted on a sealed container (compression box 5) is mounted on the other end or in the vicinity of the other end. With this configuration, when the tread plate is stepped down by an automobile or the like, the leg fixed to the tread plate is lowered (position A in FIG. 8), and the hook-shaped swinging rod is fixed at position B. Therefore, the position C is pushed forward and upward, and the piston 1 is pushed, the piston is pushed into the compression box, and the air, water, oil, or the like in the compression box is discharged from the discharge port. AB and B
The ratio of the length of C determines the ratio of the distance of the tread plate lowered and the distance (length) of the piston pushing into the compression box.
For example, if the length ratio of AB and BC is 1: 3, the piston will enter the 6 cm compression box when the tread is lowered 2 cm. FIG. 8 is an explanatory diagram explaining these principles.
FIG. 9 is an explanatory view of a state where the tread plate is lowered.

FIG. 11 is a sectional view showing a pump having a simple structure. The flat tread plate 2 is placed on a hollow container having an open surface, and the tread plate 2 and the hollow container are fixed by a spring 9 to support the tread plate. Outlet 1 with check valve in hollow container
A telescopic body 16 having a zero and a suction port 11 is provided. Insert pipes into the outlet and inlet of the telescopic body respectively. When the discharge body is air, it is not necessary to insert a pipe into the suction port.
Instead of providing the elastic body internally, the hollow container may be sealed, and the hollow container may be provided with a discharge port 10 and a suction port 11 having a check valve. The above is the basic shape of the main body pump for discharging air, water, oil, and the like. The above main body pump is mainly installed on the road, and when the car runs on the tread, the tread descends due to the weight of the car, and the piston compresses the air or water etc. in the compression box or telescopic body and the pump inside the pump It discharges air, water, oil, etc. and turns the generator blades. The shape of the cross section of the tread may be rectangular, but the shape of the wing of an airplane or the cross section of the upper surface may be curved or triangular. When the vehicle travels on the tread, it is desirable that the vehicle be shaped so that the vehicle can travel smoothly with as little step as possible. A shape in which the front part is rounded and swells is good.

Next, the structure of the generator blade (impeller) and the impeller storage box and the connection between the generator (impeller storage box) and the main body pump will be described in detail. When the object to be discharged is air, the discharge port at the end of the discharge pipe 24a of the main body pump is installed so as to hit the blade of the generator. Discharge pipe 24a
One or more holes are made near the tip of the generator, and a discharge pipe is mounted near the generator so that air discharged from each hole hits a plurality of blades mounted on the impeller of the generator. When the object to be discharged is air, the suction port 11 of the main body pump is used.
A pipe (suction pipe 24b) may or may not be attached to the pipe.

When the object to be discharged is a liquid such as water or oil, it is important how the liquid discharged from the main body pump through the discharge pipe can efficiently rotate the blades of the generator. An impeller 30 having a blade 29 is axially mounted on an impeller storage box 27 of a sealed hollow container which is open at two places, with a drive shaft 31 connected to a motor of a generator. A discharge pipe 24a and a suction pipe 24b of the main body pump are inserted into two openings of the impeller storage box.
Although the structure of the impeller and the impeller storage box may be conventional,
The structure as shown in FIG. 12 can rotate the impeller without reverse rotation. The impeller of FIG. 12 has the following structure. The disk-shaped impeller 30 has a plurality of blades 29 mounted on or near the outer periphery. The blades 29 are mounted on a rotating plate of a disk with a shaft or a pin so that the blades 29 can be moved forward. A spring 32 is attached to the blade, and the spring is fixed to a disk. When the force is applied, the blades 29 move forward, and when the force is released, the blades 29 return to their original positions by the force of the spring (stand almost at right angles to the disk). Such an impeller 30 is mounted on a hollow container (impeller storage box) having an annular inner peripheral wall with a drive shaft connected to a motor of a generator. At this time, the position where the impeller is axially attached is slightly shifted from the center of the impeller storage box. With this mounting, when the impeller rotates, a wide area and a narrow area between the impeller and the inner peripheral wall of the impeller storage box are formed. In a narrow place, the blades 29 of the impeller are pushed forward by the inner peripheral wall. Then, when it comes to a wide place, the blade is raised by the repulsive force of the spring 32. The impeller storage box 27 has two openings, and the opening is provided in a place where the width between the impeller and the inner peripheral wall is wide. The discharge pipe 24a is inserted into one of the openings, and the suction pipe 24b is inserted into the other opening. One or a plurality of such impeller storage boxes 27 are coaxially connected in a row to a motor of a generator. The liquid flowing through the discharge pipe 24a collides with the vertical position of the impeller blades 29, and pushes the blades in one direction by the force of the liquid to rotate the impellers. Impeller 30
Rotates, the blades 29 of the impeller are pressed against the inner peripheral wall of the impeller storage box 27 and fall forward, where the space between the inner peripheral wall of the impeller storage box 27 and the rotating body of the impeller is narrow. At a wide place, the spring 32 returns to the original position. The liquid 33 discharged from the discharge pipe hits the blades 29 of the impeller, and rotates the impeller by the flowing force of the liquid. The liquid flowing in the discharge pipe mainly flows in a direction for rotating the impeller. In the opposite direction, the blades are in close contact with the inner peripheral wall of the impeller housing and serve to stop the flow of liquid. In addition, since the cross-sectional area is large in the direction in which the blade is rotated (forward direction, the direction of the arrow) and small in the opposite direction (reverse direction, the direction of the dotted arrow), the pressure at which the liquid flows is small, and the impeller is rotated. Rotates forward. The main body pump and the generator are connected by inserting the discharge pipe and the suction pipe into the impeller storage box of the generator. The main body pump composed of the main body pump and the generator connected by the above connection method may be any of the main body pumps described above.

The shape of the blade of the impeller is, besides the structure shown in FIG.
As shown in FIG. 13, two plate-like bodies or hemispheres (hinges 2) that can be opened and closed like hinges are provided on the outer periphery of the rotating body of the impeller.
Attach 9). Attach a spring to this blade. Attach the spring so that the blades are opened by the force of the spring. An impeller 30 having such blades. The hollow impeller storage box 27 having two openings has an annular inner peripheral wall whose wall height is partially higher (wider), and is connected to the motor of the generator at the center. The drive shaft 31 is passed through and the impeller is mounted on the drive shaft. A discharge pipe 24a and a suction pipe 24b of the main body pump are inserted into openings of an impeller storage box in which the impeller is mounted on a drive shaft. An energy generating device including the main body pump and the generator in which the main body pump and the generator are connected as described above.

As for the method of connecting the main body pump and the generator, in addition to the above-described connecting method, as shown in FIG. 14, a discharge pipe 24a and a suction pipe 24b of the main body pump are provided.
And an impeller storage box 27 storing the generator impeller
a, 27b between the adjusting pumps 25a, 25b, 25
c, 25d are provided, and the discharge pipe and the suction pipe of the main body pump are respectively connected to the suction port or the discharge port of the adjusting pump.
The pipe inserted into the other outlet and inlet of the adjusting pump is inserted into the opening of the impeller storage box. The pipe inserted into the other opening of the impeller storage box is connected to the outlet or the inlet of the adjusting pump. Each regulating pump is
This is a sealed container having a movable compression plate 26 with a spring interposed therein, a discharge port having a backflow prevention discharge valve, and a suction port having a backflow prevention suction valve. Adjusting pumps 25a, 25
The elastic force of the spring 9c attached to the movable compression plate 26 of b, 25c, 25d is weaker than the elastic force of the spring 9a attached to the pressing plate 4 of the piston of the main body pump. With this configuration, the pressure of the liquid discharged from the main body pump is stronger than the elastic force of the spring of the adjustment pump, and thus the amount of liquid discharged from the main body pump is smaller than the amount discharged from the discharge port of the adjustment pump. Also increase. For this reason, when the liquid discharged from the main body pump flows into the adjusting pump, the liquid is stored in the adjusting pump. Of course, the liquid is discharged from the regulating pump. Next, when the discharge pump of the main body pump is closed and the liquid stops flowing from the main body pump to the adjustment pump, the movable compression plate 26 in the adjustment pump is lowered by the force of the spring of the adjustment pump, and Drain the liquid. The main body pump repeats the vertical movement of the piston,
Although the liquid is repeatedly discharged, stopped, and discharged from the discharge port, the adjustment pump can discharge the liquid even when the discharge of the liquid from the main body pump is stopped. Therefore, the liquid always flows into the impeller storage box, and the impeller can be constantly rotated. Each liquid discharged from the upper and lower pump chambers of the main body pump is supplied to two adjusting pumps 25a and 25c.
And flows into two impeller storage boxes 27a and 27b coaxially connected to one generator 28 to rotate the impeller. From the other opening of the impeller housing boxes 27a, 27b, the liquid is recirculated through the pipes to the adjusting pumps 25b, 25d different from the adjusting pumps 25a, 25c. Further, pipes are connected from these adjusting pumps 25b and 25d to respective suction ports of the main body pump, and the liquid is recirculated. FIG. 14 is an explanatory diagram illustrating the relationship of the reflux of these liquids using the main body pump, the adjusting pump, and the generator (impeller storage box).

The pressure applied to the tread varies depending on the size (weight) and speed of the vehicle passing over the tread of the main body pump. In the case of a large vehicle, a large pressure is applied to the tread, and the amount of liquid (mainly oil) discharged from the main body pump increases due to the pushing force of the piston, and the flow velocity also increases. Also,
In the case of a small car, the pushing force is weakened, and the amount of the discharged liquid is also reduced. In order to make the discharge amount and the flow rate as constant as possible, a regulating valve as shown in FIGS. 15 and 16 can be attached to the main body pump.

In addition to the energy generating device including the main body pump and the generator, there is an energy generating device for transferring liquid as shown in FIG. A plurality of compression pumps 37 each having a lid 38 in which a spring or an elastic material is attached to a partially opened sealed container and further having an insertion opening (hereinafter referred to as “insertion port”) 39 at a plurality of locations. This is an energy generating device for moving liquid connected by a connecting pipe 40. At least one of the insertion ports 39 of the compression pump 37 has a backflow prevention discharge valve, and one has a backflow prevention suction valve. If the outlet does not have a discharge valve or a suction valve, attach a check valve to the connecting pipe. FIG. 18 is an explanatory plan view showing an example in which the compression pumps are connected by the connection pipe 40. For example, when moving water from one place to another, when a person steps on the compression pump, the water in the compression pump is discharged to an adjacent compression pump connected by a connecting pipe. The original compression pump draws water from the inlet because the pressure inside is reduced. Thus, every time the compression pump is stepped on, water moves one after another to the next compression pump and is carried to the destination.

[0022]

Since the present invention is constituted by the main body pump and the generator having the above-described structures, the following effects can be obtained. 1. Normally, power generation requires the use of fossil fuels such as oil, gas, and coal, or nuclear power, but the energy generator of the present invention utilizes the power that consumes energy, such as running people and cars. Can generate electricity,
No fuel is required and power can be generated for almost 24 hours, which is economical. 2. Because it does not consume fuel to generate electricity, there is no need to worry about environmental pollution, and it is the same eco-energy as wind and solar power. In particular, it is clean energy that does not emit CO2. 3. The equipment for power generation is simple, and the cost of the equipment is very low compared to other eco-energy. 4. Because the structure is simple, just by replacing some parts,
It is very easy to maintain and can generate electricity semi-permanently. 5. Since power is generated by running a car or the like, the cost of power transmission is very low because the place where power is generated and the place where power is consumed are the same or close. 6. Automobiles are a great invention of modern civilization, and while useful as a means of transportation, are beneficial to human life, but the emissions from automobiles,
Considering the emission of harmful substances such as CO2, NOx, SOx, soot, and noise pollution, it can be said that it is in the middle of the tribunal. Moreover,
It is wonderful for humanity to consume at least some precious energy and to contribute at least in some way to producing pollution-free energy. It is very important for car drivers, who are the polluters, to think about how to prevent environmental pollution and to be conscious of the generation of energy that does not cause pollution. The energy generating device of the present invention is also a tool for enlightening such an idea.

[Brief description of the drawings]

FIG. 1 is a side sectional view of a main body pump.

FIG. 2 is a side sectional view of a main body pump having upper and lower pump chambers.

FIG. 3 is a partially cut perspective view of a main body pump having upper and lower pump chambers.

FIG. 4 is a front sectional view of a main body pump having an X plate according to a third embodiment.

FIG. 5 is a side sectional view of a main body pump having an X plate according to a third embodiment.

FIG. 6 is a front sectional view of a main body pump having an X plate according to a fourth embodiment.

FIG. 7 is a side sectional view of a main body pump having an X plate according to a fourth embodiment.

FIG. 8 is an explanatory view of a device of a main body pump that amplifies a reduction width.

FIG. 9 is an explanatory diagram of a device of a main body pump that amplifies a reduction width.

FIG. 10 is an explanatory diagram of an apparatus for amplifying a reduction width.

FIG. 11 is a sectional view of a main body pump having a simple structure.

FIG. 12 is a cross-sectional view of an impeller storage box and an impeller to which pipes are connected.

FIG. 13 is a perspective view of an impeller storage box and an impeller to which pipes are connected.

FIG. 14 is an explanatory diagram of a relationship among a main body pump, an adjustment pump, and an impeller of a generator.

FIG. 15 is an explanatory view in which a regulating valve is attached to a main body pump.

FIG. 16 is an explanatory view in which an adjustment valve is attached to a main body pump.

FIG. 17 is a sectional view of a compression pump of the liquid transfer energy generating device.

FIG. 18 is a plan view of a connected compression pump.

[Explanation of symbols]

1: piston 2: stepping plate 3: body 4: press plate 5: compression box 6: top plate 7: guide plate 8: bottom plate 9a, 9b: spring 10: discharge port 11: suction port 12: elastic material 13: stopper 14 : Leg 15: X plate 16: Elastic body 17: Side plate 18: Movable partition plate 19: Upper pump chamber 20: Lower pump chamber 21: Swinging rod 22: Discharge valve 23: Suction valve 24 a: Discharge pipe 24 b: Suction pipe 25a, 25b, 25c, 2
5d: adjustment pump 26: movable compression plate 27, 27a, 27
b: impeller storage box 28: generator 29: blade 30: impeller 31: drive shaft 32: spring 33: leverage 34: fulcrum 35: string-like body 36: regulating valve 37: compression pump 38: lid 39: plug-in Mouth 40: Connecting pipe

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Claims (13)

[Claims] 1. An energy generator comprising the following structure and the structure. 1. A sealed container of any shape having at least one discharge port with a check valve and at least one suction port with a check valve, all or part of which is open on the top surface (hereinafter referred to as the "top plate"). (Hereinafter referred to as "compression box"). 2. A compression body or a tread plate comprising a head of a plate-like body (hereinafter referred to as a "tread plate") and a body portion protruding from the tread plate and fitted into an opening of a top plate of the first compression box; A compressed body (hereinafter, referred to as a "piston") including a protruding body portion and a flat flange (hereinafter, referred to as a "pressing plate") attached to a tip portion of the body portion. 3. Leaving the step plate of the piston outside the compression box, fitting the body of the piston into the opening of the top plate of the compression box, mounting the piston on the compression box, and attaching the piston to the body or the body of the piston; A pump in which a spring is fixed between a bottom plate or an inner peripheral wall of a compression box (hereinafter, referred to as a “body pump”). 4. A generator having one or more blades mounted on a drive shaft connected to a motor of the generator, or a generator having such blades coaxially mounted on multiple shafts, or a rotating device having a plurality of blades. A generator that is mounted on a drive shaft that connects the body to a motor, or a commonly used wind generator (hereinafter “generator”). 5. A pipe (hereinafter, referred to as “discharge pipe”) is attached to the discharge port of the compression box, and gas (hereinafter, referred to as “air”) discharged from a hole provided at or near the end of the discharge pipe is
According to the length of the discharge pipe, the generator is installed close to the main body pump so as to directly hit one or more impeller blades of the four generators provided separately from the main body pump. Install a generator at an appropriate place. An energy generating device composed of a main body pump and a generator configured as described above. 2. An energy generator comprising the following structure and the structure. 1. In the main body pump according to claim 1, the piston is mounted on the compression box so that the inside of the compression box is divided into two chambers by the pressing plate of the body of the piston. 2. Each of the upper chamber (hereinafter referred to as “upper pump chamber”) and the lower chamber (hereinafter referred to as “lower pump chamber”) of the compression box divided by the piston is equipped with a discharge port with a check valve and a check valve. At least one attached suction port is provided, and a discharge pipe is inserted into each discharge port. 3. A spring is interposed between the body of the piston or the pressing plate and the top plate of the compression box, or a spring is interposed between the pressing plate and the bottom or inner peripheral wall of the compression box, or both. Body pump with spring interposed in it. 4. The generator according to claim 1. 5. One or more holes are provided at or near the tip of a discharge pipe attached to the discharge port of the upper pump chamber and the discharge port of the lower pump chamber of the main body pump, and air discharged from the holes is separated from the main body pump. The generator is installed close to the main body pump or at an appropriate place according to the length of the discharge pipe so as to directly hit one or more impeller blades of the provided generator. An energy generating device composed of a main body pump and a generator configured as described above. 3. An energy generator comprising the following structure and the structure. 1. A spring is interposed between the flat plate and the bottom plate. 2. A leg of a plate-like body or a column-like body is suspended vertically or substantially perpendicularly to the tread plate, and the X plate according to claim 3 is pivotally attached to the leg. 3. The upper end of the X plate is slidably attached to the tread plate, and the lower end of the X plate is slidably attached to the bottom plate. 4. It is made of stretchable material or has the structure of a telescopic member, which has a discharge port with a check valve and a suction port with a check valve, between the tread and the bottom plate. An elastic body of any shape in a sealed shape is installed inside. 5. A main body pump composed of the above items 1 to 4. 6. The generator according to claim 1. 7. A discharge pipe is attached to a discharge port of the telescopic body according to the above item 4, so that air discharged from a hole provided at the end of the discharge pipe or in the vicinity thereof directly hits a blade of a generator provided separately from the main body pump. Install the discharge pipe close to the generator. An energy generating device composed of a main body pump and a generator configured as described above. 4. An energy generator comprising the following structure and the structure. 1. On the top plate of a box-like body (hereinafter referred to as "body frame") in which the top plate and the bottom plate are connected by side plates, a wide tread plate with a top plate and a spring interposed is attached. 2. One or a plurality of legs are hung on a tread plate, and a plurality of plate-like bodies or rod-like bodies (hereinafter referred to as “X-plates”) are pivotally mounted on the legs. 3. A flat plate (hereinafter, referred to as a “movable partition plate”) is provided between the top plate and the bottom plate of the main body frame.
The upper end of the plate is slidably mounted, and the lower end of the X plate is slidably mounted on the bottom plate of the main frame. 4. A spring is mounted between the movable partition plate and the top plate of the main frame, between the movable partition plate and the bottom plate, or between the movable partition plate and the top plate and between the movable partition plate and the bottom plate. 5. A space separated by a top plate and a movable partition plate (hereinafter referred to as “upper pump chamber B”) has a discharge port having a check valve mounted thereon, and a suction port also having a check valve mounted therein.
A sealed arbitrary-shaped body (hereinafter referred to as an “upper elastic body”) that is made of an elastic material or has the structure of an elastic material is provided inside. 6. A space that is separated by a bottom plate and a movable partition plate (hereinafter referred to as “lower pump chamber B”), which has a discharge port with a check valve and a suction port with a check valve. A hermetically sealed body (hereinafter referred to as “lower elastic body”) made of a material or having the structure of an elastic self-material will be provided inside. 7. A main body pump composed of the above items 1 to 7. 8. The generator according to claim 1. 9. A discharge pipe is attached to each of the outlets of the upper elastic body and the lower elastic body, and air discharged from a hole provided at the tip of or near the discharge pipe is provided separately from the main body pump. The exhaust pipe is mounted close to the generator so as to directly hit one or more blades. An energy generating device composed of a main body pump and a generator configured as described above. 5. An energy generator comprising the following structure and the structure. 1. The compression box according to claim 1, wherein the compression box has a liquid therein, has a discharge pipe attached to a discharge port, and has a pipe attached to a suction port (hereinafter, “suction pipe”).
A liquid is poured into a main body pump equipped with the piston according to claim 1 or a telescopic body provided inside the main body pump according to claim 3, and a discharge pipe and a suction pipe are respectively provided at a discharge port and a suction port of the telescopic body. Body pump inserted. 2. In a hollow container of an arbitrary shape having an annular inner peripheral wall that is open at two places (hereinafter referred to as an “impeller storage box”),
A disk-shaped rotating body (hereinafter referred to as an "impeller") having a plurality of blades on or near its outer circumference is mounted on a drive shaft connected to a motor of a generator. A generator in which one or more are mounted on a coaxial drive shaft. 3. Insert the discharge pipe into one opening of the impeller storage box so that the liquid discharged from the discharge pipe of the main body pump directly hits the blades of the impeller, and insert the main body pump into the other opening of the impeller storage box. Insert the suction pipe. An energy generating device composed of a main body pump and a generator configured as described above. 6. An energy generator comprising the following structure and the structure. 1. 3. The main body pump according to claim 2, wherein the upper pump chamber and the lower pump chamber each have a liquid, and the upper pump chamber and the lower pump chamber have a discharge pipe at each discharge port, and a suction pipe at the suction port. 5. The upper telescopic body of the main body pump or the upper telescopic body and the lower telescopic body of the main body pump according to claim 4, wherein a discharge pipe and a suction pipe are inserted into respective discharge ports and suction ports, and a liquid is contained therein. And a main body pump having a lower elastic body. 2. An impeller having a plurality of blades on the outer periphery or in the vicinity thereof is connected to a generator motor in a hollow impeller storage box having an annular inner peripheral wall that is open at two places. A generator in which one or more of the impeller storage boxes mounted on a drive shaft is mounted on a coaxial drive shaft. 3. A discharge pipe so that the liquid discharged from the lower pump chamber of the main body pump according to claim 2 or the discharge pipe attached to the discharge port of the lower telescopic body of the main body pump according to claim 4 directly hits the blades of the impeller. And the suction pipe attached to the lower pump chamber of the main body pump according to claim 2 or the suction port of the lower telescopic body according to claim 4. Insert into the other opening of. 4. The liquid discharged from the upper pump chamber of the main body pump according to claim 2 or the discharge pipe attached to the discharge port of the upper expandable body of the main body pump according to claim 4 is driven by a drive shaft coaxial with the second impeller. The discharge pipe is inserted into one opening of an impeller storage box separate from the second impeller storage box so as to directly hit the impeller of another impeller connected to the generator. The upper pump chamber of the main body pump according to claim 2 or the suction pipe attached to the suction port of the upper telescopic body of the main body pump according to claim 4 is inserted into another opening of the storage box. An energy generating device composed of a main body pump and a generator configured as described above. 7. An energy generator comprising the following structure and the structure. 1. The main body pump according to claim 5. 2. In the impeller and the impeller storage box of the generator according to claim 5 or 6, instead of the blade attached to the disk-shaped rotating body, a plurality of the blades are provided on the outer periphery of the disk-shaped rotating body or on a peripheral portion of the outer circumference. The blades are rotatably mounted, and an impeller with springs interposed between each blade and the rotating body so that the blades stand almost vertically with respect to the rotating body by the force of the spring. A drive shaft connected to the motor of the machine, and one or more of the hollow impeller storage boxes having an annular inner peripheral wall, which is axially mounted at a position eccentric from the center of the impeller storage box, is driven by a coaxial drive shaft. Generator worn. 3. The discharge pipe and the suction pipe according to claim 5 or 6 are respectively inserted into openings of the impeller storage boxes. An energy generating device composed of a main body pump and a generator configured as described above. 8. An energy generator comprising the following structure and the structure. 1. The main body pump according to claim 5. 2. On the outer periphery of the disk-shaped rotating body, two plate-shaped bodies are attached to the rotating body so as to be openable and closable, and a plurality of blades with springs interposed so that the two plate-shaped bodies open up and down by the force of the spring. One or more of the hollow impeller storage boxes with two openings, with the height of a part of the annular inner peripheral wall being low, on which the mounted impeller of the rotating body is pivotally mounted. A generator mounted on the drive shaft. 3. The discharge pipe and the suction pipe according to claim 5 or 6 are inserted into respective openings of each impeller storage box. An energy generating device composed of a main body pump and a generator configured as described above. 9. The generator according to claim 5, 6 or 7, wherein a drive shaft connected to a motor of the generator is provided with a claw or a gear for preventing reverse rotation. An energy generator comprising a main body pump and a generator according to claim 5 or claim 6 or claim 7 or claim 8. 10. An energy generator comprising the following structure and the structure. 1. It has at least one discharge port with a check valve and at least one suction port with a check valve,
All or part of one side is open, all or part of the side is made of stretchable elastic material, or
A main body pump in which a tread plate is fixed or detachably attached to a box-like body of any shape having an elastic structure like a bellows. 2. A discharge pipe is inserted into the discharge port of the main body pump, and a suction pipe is inserted into the suction port. 3. The generator according to claim 5, claim 6, claim 7, or claim 8. 4. Insert the discharge pipe into one opening of the impeller storage box so that the liquid discharged from the discharge pipe of the main body pump directly hits the blades of the impeller, and insert the main body pump into the other opening of the impeller storage box. Insert the suction pipe. An energy generating device composed of a main body pump and a generator configured as described above. 11. An energy generator comprising the following structure and the structure. 1. Attach the support or side plate to the bottom plate to make the main body frame. 2. Attach the tread on the side plate directly or via an elastic material. 3. A flat leg is hung on the tread plate, and an L-shaped swinging rod is pivotally mounted on the leg. A piston of the main body pump is axially mounted on or near the other end of the swinging rod. 4. A spring is fixed to the leg suspended from the tread plate, and the other end of the spring is fixed to the bottom plate of the main frame. 5. A spring is attached to the piston of the main body pump, and the spring is fixed to the bottom plate of the main body pump. 6. A discharge port and a suction port with a check valve attached to the main body pump are provided, and a discharge pipe and a suction pipe are inserted and fitted respectively. 7. The generator according to claim 5, claim 6, claim 7, or claim 8. 8. Insert the discharge pipe into one opening of the impeller storage box so that the liquid discharged from the discharge pipe of the main body pump directly hits the blades of the impeller, and insert the main body pump into the other opening of the impeller storage box. Insert the suction pipe. An energy generating device composed of a main body pump and a generator configured as described above. 12. An energy generator comprising the following structure and the structure. 1. The main body pump according to claim 5. 2. The generator according to claim 5. 3. An energy generating device comprising the main body pump and the generator according to the first and second aspects, wherein a movable compression plate with a spring mounted therein is provided between the main body pump and the impeller storage box of the generator, and an outlet and an inlet are provided. One or a plurality of sealed containers (hereinafter referred to as “regulating pumps”) having the following are provided: a discharge pipe of the main body pump is inserted into a suction port of the adjusting pump; a pipe is inserted into a discharging port of the adjusting pump; It is inserted into one opening of the impeller storage box of the generator, and a pipe connected to the suction port of the main unit pump or the adjustment pump is inserted into the other opening of the impeller storage box. An energy generating apparatus comprising the main body pump and the generator according to claim 5 or claim 6 or claim 7 or claim 8 or claim 9 or claim 10 or claim 11. 13. An energy generator comprising the following structure. 1. A hollow container made of a stretchable material or having a stretchable structure, having at least one suction port with a check valve for suction and at least one discharge port with a check valve for discharge. (Hereinafter referred to as “compression pump”). 2. A connecting pipe having a shape in which one fits into the suction port of the compression pump and the other fits into the discharge port of the compression pump. 3. An energy generator in which a plurality of compression pumps are connected by the two connection pipes.