CN117167224A

CN117167224A - Cylinder circumference engine

Info

Publication number: CN117167224A
Application number: CN202210611998.3A
Authority: CN
Inventors: 任文林
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-05-27
Filing date: 2022-05-27
Publication date: 2023-12-05

Abstract

The invention relates to an engine. Provides a plurality of new methods and devices for obtaining the solid potential energy natural energy of the circumference. The power transmission device comprises a shaft circumference body and a suspension circumference body, wherein the circumference body can be stably operated, and power is effectively transmitted. The potential energy force is infinitely increased by the counterweight circumference body, the external force circumference body and the magnetic force circumference body. Overcomes the prejudice and the shortages of the known technology. The invention is simpler and more practical than the known technology. Provides sufficient clean and low-cost new energy for human beings. The defects of limited fossil energy source quantity, high cost and serious pollution are avoided. Can replace fossil energy to become the main energy source of human beings. Makes a contribution to the human walking out of the energy crisis and the environment crisis. Natural energy is ubiquitous, never exhausted, more convenient than hydropower and wind power, and the cost is lower. With enough clean and low-cost energy, everything is done.

Description

Cylinder circumference engine

1. Technical field: the invention belongs to the field of energy, in particular to a zero-pollution engine.

2. Technical background: all is owned by the energy source. Ancient vegetation energy almost destroys the earth vegetation. Today's fossil energy almost destroys the human environment. Including hydroenergy, wind energy and solar energy, the known energy sources are limited and have high cost, and the development requirements of human beings cannot be met. Humans are continually looking for clean and inexpensive energy sources and for an infinitely rich, zero-consumption, zero-emission, zero-pollution engine.

In a gravitational field, a uniform mass of a circumferential body (herein referred to as a sphere or cylinder) is in contact with a point or line where a solid, horizontal bearing surface is ideal, and gravity divides the mass of the circumferential body from the middle into two parts, the interface of which is the gravitational plane. Due to the structure, the gravity on two sides of the gravity surface is equal in size, and the two forces are balanced and are resistance or power; the direction of movement caused by gravity is opposite. Its stationary inertia is independent of mass. Regardless of the mass, the stationary inertia is zero, the mass is equal to zero, and the force against the stationary inertia is greater than zero. The following conditions may exist: when in motion, half of gravity always becomes resistance or power, and the force overcoming the motion inertia is larger than the external force applied to the device.

The uniform mass refers to uniform mass distribution. The phenomenon described is also present to a different extent in a circumferential body with an uneven mass distribution. The circumference body refers to an object with a gravity surface and comprises a sphere, a cylinder and a non-circular body. The cylinder comprises a wheel-like object. Non-circular body refers to a body with circular motion outside a sphere or a cylinder. All the objects with circular motion are circular bodies. The non-circular body is only a circular body when circular motion occurs. Rolling, turning, swaying, swinging and swaying are all circular motions. The rolling and rotation may be without a shaft and may be displaced. The rotation of the shaft cannot be displaced. The roller of the ball mill rotates, and the wheels have both rolling and rotating functions, so that the ball mill is in compound motion. The tumbler is swayed, the swing is swayed, and the teeterboard is swayed. Walking is the alternate swinging of two legs and the shaking of the whole human body. The fulcrum is used for fixing a circumferential lever which cannot roll and simultaneously follows the lever principle. The term "solid, horizontal bearing surface" refers to a bearing surface that is in a non-deformed, horizontal state. The ideal state means that the bearing surface is not concave, and the grounding radius of the circumference body is not shortened. The grounding radius refers to the radius from the circle center to the bearing surface; the grounding radius is relative to the primitive radius, which refers to the primitive radius itself. For example, the wheel is a cylinder-like circumference, and ideally the wheel is in line contact with the ground. The gas wheel tends to have a shorter contact radius than the original radius, and is in contact with the ground surface instead of being in contact with an ideal line, so that rolling resistance is high. The gravity plane is also called as a gravity interface, and refers to an interface of two parts of gravity with opposite movement directions on the circumference body. The gravity surface is always positioned on the extension line of the connecting line of the fulcrum of the circumferential body and the earth center. The gravitational plane is invisible but objectively present. Although the gravity direction is downward, due to the structure, the gravity on both sides of the gravity surface of the circumferential body is equal in magnitude and opposite in movement direction. Such as: when the sphere or cylinder is in point or line contact with the bearing surface, the two sides of the fulcrum are suspended, and the gravity on the two sides of the gravity surface causes the opposite movement direction. The static circumference body has zero gravity resultant force and zero inertia force, which is equal to zero mass. The circumference body in motion can automatically adjust the gravity on two sides of the gravity surface to make the two forces equal in size and balance. The application range of the gravity surface is wide, and physical phenomena such as non-falling, acrobatic top bowl, labor saving in rolling and the like can be explained.

The circumference body on the inclined plane in the ascending trend has the gravity surface not in the position passing through the center of the circle, the gravity on the two sides of the gravity surface is unequal, more than half of the gravity is changed into resistance, the acceleration generated by the stress is directly proportional to the force applied by the circumference body and inversely proportional to the mass;

the circumference body which is in a descending trend on the inclined plane, the gravity surface of the circumference body is not positioned at the position passing through the center of the circle, the gravity on two sides of the gravity surface is unequal, more than half of the gravity is changed into power, and the magnitude of acceleration generated by stress is in direct proportion to the force born by the circumference body and in direct proportion to the mass;

the gravity surface of the circumference body on the inclined plane, no matter the circumference body is up and down, is on the extension line of the connecting line of the fulcrum and the earth center;

the force of the circumferential body rotating around the shaft, no matter the mass, against the static inertia is larger than the friction force of the bearing, and the force against the motion inertia is larger than the external force. The circumferential body rotating around the shaft has an energy storage function during rotation. The circumferential body moves at a high speed or moves linearly in rolling and is in compound motion, the circumferential body rotating at a high speed has centrifugal weightlessness phenomenon, and the higher the speed is, the larger the centrifugal force is, and the more weightlessness is; the force against the static inertia of the mass is larger than the friction force of the bearing point, and the force against the motion inertia of the mass is larger than the external force.

In connection with specific practice, the following conditions may exist when rolling the circumferential body:

when the force is applied to the fulcrum at the bottom of the circumference body, the center of the circle is emphasized, the force point is at the top of the circumference body, and the power arm is one time longer than the resistance arm, half of the force can be saved, and the obtained gravity is two times of the applied force. Like a traveling block. Well known rim driven wheels belong to this class.

When the force is applied to the fulcrum at the bottom of the circumference body and the center of the circle is lower, the force point is at the top of the circumference body, and the power arm is longer than the resistance arm by more than one time, more than half of the force can be saved, the force is saved, and the obtained gravity is more than two times of the applied force. Known large wheel drive methods belong to this category. When the wheel (circumference body) bears the weight through the pendulum structure, the weight can swing relative to the wheel, and the gravity surface of the wheel can be changed along with the pendulum, more than half of the gravity becomes resistance or power, and the force for overcoming the static inertia of the wheel is larger than the friction force of the pendulum shaft. The wheel is driven to roll, so that gravity which is more than twice of the acting force can be obtained.

The circumference body has a fixed high-position gravitational potential energy. The circumference body can always keep the high-position gravitational potential energy of the fixed body in horizontal rolling. The circumference body is provided with a fixed high-position gravitational potential energy area. The suspended area below the circumference (including the surrounding of the grounding point or the two sides of the grounding wire) is a solid high-level gravitational potential energy area, which is called a potential energy area for short. The gravitational energy of the circumferential body may be collected on the circumferential body or in a potential energy zone of the circumferential body. The solid high-level gravitational potential energy of the circumference body is higher than the high-level gravitational potential energy density of the fluid, and the circumference body is wide in distribution, environment-friendly and easy to collect.

The gravitational potential energy of the moving circular body can be obtained. More than half of the force can be saved by rolling the circumference body along a proper inclined plane, and the rolling circumference body can generate the same gravity and gravitational potential energy for each point or each line along the rolling path. The gravity on the two sides of the gravity surface of the rolling circumference body is continuously changed, and the more the gravity is changed into power, the more labor is saved. The rolling circumference body can obtain the solid high-position gravitational potential energy.

The gravity converting device converts the gravitational potential energy of the circumferential body in a mode of continuously recovering and releasing the gravitational potential energy of the circumferential body. Comprises a salient point arranged in a potential energy area of the circumferential body. The protruding points receive and transmit the gravity of the circumference body, and the gravity is converted into power. The protruding points can be higher than the bearing surface of the circumference body, and form resistance to the rolling of the circumference body. The force required to roll the circumferential body increases with the increase in the bump. The higher the bump, the more laborious. The lower the bump is, the more labor-saving. As long as the convex points are positioned in the potential energy area of the circumference body, gravity can be changed into power. The gravity can be collected as long as the force of rolling the circumference body to press the convex point is smaller than the gravity of the circumference body. The manner in which the circumferential body outputs gravity can vary. The structural form of the convex points can be changed, and the convex points can be changed into gears or connecting rods or levers or push rods. For example, the convex point can be changed into a connecting rod which is connected with a potential energy area of the circumference body to drive the crankshaft. The energy comes from solid gravitational potential energy of the circumferential body, namely the gravitational force of the earth to the circumferential body continuously.

Examples: a cylinder (circumference) of 500 kg is driven by a circle center of 50 kg acting force to roll up and down along an inclined plane of about 5 degrees, and the stroke is 1 decimeter. The cylinder can generate potential energy force of more than 500 kg, which is far greater than 50 kg. Potential energy force refers to the power generated by the circumference in motion. Potential energy force is converted from acting force, circumferential body gravity and motion inertia force. Proof of fact: the potential energy force is far greater than the acting force, and the force for recovering the potential energy is far less than the potential energy force. The potential energy force of more than 500 kg can be converted into acting force of more than 500 kg by using the equal arm lever conversion device. The formula is as follows: force 50 kg X stroke 1 dm = cylinder 500 kg X stroke 1 dm. I.e. 50=500, i.e. 1=50, i.e. 1=n. By repeating the action, more than 500 kg of potential energy force can be obtained continuously. Thus obtaining continuous power. This is a very realistic fact. This fact is evolved into a machine that continuously outputs power, called: a circumferential engine. And a larger potential energy force can be obtained by adjusting the size ratio between the inclined plane or the acting force and the weight of the circumference body. Virtually we can get unlimited energy.

The force to recover the potential energy of the circumferential body on a suitable slope is much smaller than its potential energy force. This is the basis for the facts of the present invention.

The circumferential potential energy force is circumferential power. The force according to the invention may be a motive force.

A reasonable circumferential body can be used as an energy source, and clean and low-cost energy sources can be obtained.

Almost all objects can be a circular body and can perform circular motion, and the key is the structure and the motion mode of the circular body. A circumferential body with a rational structure comprising: the circumference of the shaft or fulcrum, the circumference of the roller or suspension or counterweight, the circumference of the external force or the circumference of the lever or the circumference of the large wheel or the elasticity or the circumference of the magnetic force or the circumference of the wheel shaft or the circumference of the crankshaft or the combination circumference.

1. The circumferential body with the shaft means that the circumferential body with the shaft. The shaft comprises a mandrel or an off-axis or a mandrel off-axis combination; the spindle refers to a round spindle. Comprises a circumference body formed by a gear, wheels and a belt pulley. The eccentric shaft refers to the shaft which is positioned outside the circle center and comprises an eccentric wheel. The mandrel off-axis combination refers to a circumference body with a mandrel and an off-axis. The mandrel can move up and down and left and right in the shaft hole or/and elastically contact with the shaft hole, and the mandrel can vibrate slightly up and down relative to the shaft hole, namely, vibrate regularly with small amplitude. Or vice versa, the shaft hole is movable relative to the mandrel or/and elastically connected with the mandrel. The axial circumferential body is a controlled circumferential body, and the axial circumferential body is more stable and efficient in operation and easier to implement than the shaftless circumferential body.

2. The fulcrum circumference body means that the circumference body has reasonable fulcrum. The fulcrum refers to the position of the bearing circumference body. On a reasonable fulcrum, the weights of two sides of the gravity surface of the circumference body are equal or similar or tend to be equal, and the force overcoming the static inertia is larger than zero or tends to zero. A reasonable fulcrum may have a relatively longest power arm or a relatively shortest resistance arm; the reasonable pivot point can release the potential energy force of the circumference body to the maximum extent. All movements should and can establish reasonable fulcrums, can establish reasonable gravity planes and can be fulcrum circumferences.

3. The suspension circumference body refers to a circumference body belt suspension. The suspension is a mechanism for installing the circumference body, and is movably connected with the machine base. The suspension can be in a flat plate shape, a grid shape and a frame shape and can have elasticity; the elasticity can help the suspension to return or act as an external force on the suspension; the elasticity may be from an elastic material or a spring or/and an elastic means; the elastic device comprises a pneumatic or hydraulic elastic device. The movable connection comprises a gap or/and elasticity at the joint, and the moving circumferential body can move back and forth and down in a certain range relative to the stand by taking the suspension. Limiting devices such as a top dead center or/and a lower pivot or/and a limiting spring can be arranged to limit the range of the front-back and lower movement of the cylinder or the suspension. The circumference body is arranged on the suspension, can be in a suspended state in movement, and can stably and efficiently transfer potential energy force. The potential energy force refers to power generated by the circular body in motion, and the potential energy force is converted from the gravity of the circular body and the inertia force of the circular body in motion. The suspension comprises a cantilever, an inclined frame, a vertical frame, a suspension arm, an upper seat or a car lever; the suspension circumference may be provided with weights or/and external forces. The weight of the suspension can also be used as a counterweight; the potential energy force which is larger than the power can be obtained by driving a suspension circumferential body positioned on a reasonable fulcrum, and the potential energy restoring force is far smaller than the potential energy force. The potential energy force is the power of the circumference; the circumference body can also move up and down relative to the suspension.

4. The circumference of the roller is the roller, which is located on the fulcrum wheel and has a reasonable gravity surface. The reasonable method includes that the gravity values of the two sides of the gravity surface are equal or similar or tend to be equal, and the force overcoming the static inertia is larger than zero or tends to be zero. The roller of the known ball mill, dryer and stirrer can be provided with a reasonable fulcrum wheel, so that the roller becomes a circumference body of the roller, and energy is saved. The fulcrum wheel is positioned below the roller near the vertical center line. The fulcrum wheel may be a gear or friction wheel or a hole wheel or a sprocket. The roller and/or the fulcrum wheel can be matched with the generator to generate electricity, so that energy is not consumed, and energy is output.

5. The counterweight circumference body means that the circumference body is provided with a counterweight. The counterweight is used for arranging the weight, so that the weight and potential energy of the circumference body are increased. The counterweight can change the gravity of the two sides of the gravity surface of the circumference body, so that the circumference body is easy to move, and the power is saved. The counterweight comprises a movable counterweight, a static counterweight, a movable counterweight and a fixed counterweight. The movable weight means that the weight moves together with the circumferential body, and the static weight means that the weight does not move together. The movable counterweight refers to a counterweight movably connected with the circumferential body, such as a counterweight hung on the circumferential body or a circumferential body shaft. The fixed counterweight means that the counterweight is fixedly connected to the circumferential body or a related device. The counterweight may be provided on the circumferential body or on the circumferential body shaft or on the suspension. The hanging counterweight arranged along the front lower direction of the circumference body can not influence the downward movement of the circumference body and the transmission potential energy force of the circumference body; the weight may be greater than the resistance, and sufficient weight may overcome all of the resistance.

6. The external force circumference body refers to the circumference body with external force; the external force refers to a force other than the motive force. The external force comprises a tensile force or/and a compressive force or/and a magnetic force or/and an elastic force; the external force can increase the potential energy force of the circumference body; the external force can change the gravity of the two sides of the gravity surface of the circumference body, so that the circumference body is easier to drive, and the power is saved; the external force and the power act on the circumference together; the external force can be arranged on the circumference body or the circumference body shaft or the related device of the circumference body; the external force can rotate with the circumference body or not; gravity and external force can be mutually converted. The external force can be larger than the resistance, and enough external force can overcome all resistance.

7. The lever circumference body is a circumference body lever, and can be cylindrical, round basin-shaped, circular ring-shaped, disc-shaped and cylindrical. The potential energy force is transmitted by adopting a known transmission method.

8. The large wheel circumference body refers to a circumference body adopting a known large wheel transmission method. The large wheel transmission structure is changed into a circumference body.

9. The elastic circumference body means that the circumference body has elasticity, and comprises an elastic material or a spring or an elastic device; the device comprises a gap or/and elasticity between a circumferential body shaft and a shaft hole, wherein the circumferential body can move up and down and left and right slightly relative to the shaft hole; the purpose of the gap or/and the elasticity is to increase the potential energy force of the circumferential body or/and release the potential energy force of the circumferential body more effectively.

10. The magnetic force circumference body means that the circumference body has magnetic force and can be driven by the magnetic force. The power may be assisted or used as the power.

11. The wheel axle circumference means that the circumference is provided with a wheel axle mechanism. Including known pulleys or gears or sprockets or flywheels.

12. The crankshaft circumference means that the circumference is a crankshaft or is provided with a crankshaft. The crankshaft is connected with the connecting rod and outputs potential energy force of the circumference body.

13. The combined circumference body refers to a plurality of circumference body combinations or a plurality of stamping part combined circumference bodies. The combination of the circumferences is force superposition. The potential energy force point of the last circumferential body is the power of the next circumferential body. A plurality of small circumferential bodies are combined into a large circumferential body. For example, a plurality of belt pulley devices are combined, the potential energy force of the last belt pulley is the power of the next belt pulley, and the power is superposed; for example, a plurality of magnetic force circumferential bodies are combined with a large wheel circumferential body and an inner gear circumferential body, and potential energy force of the upper one is taken as a power source to infinitely amplify the potential energy force. The combination includes inventive combination and also includes simple superposition, including horizontal arrangement combination, up-down arrangement combination, radial or/and axial combination. For example, a plurality of inner gear circumferences or a large wheel circumference may be axially combined. The stamping part combination is a circumference body structure and a processing method. The processing and maintenance can be facilitated, the damage and rejection are reduced, the cost is reduced, and the variety of the circumference body is increased. For example, a gear is axially or radially disassembled and processed into a plurality of stamping parts, and the stamping parts are axially or radially combined into the gear. A spherical or cylindrical or round basin-shaped circumference body is axially or radially decomposed and processed into a plurality of stamping parts, and the stamping parts are axially or radially combined into the circumference body. Various different configurations of the circumferential body may be used in combination.

The transmission mode of the circumference body can comprise: A. spindle drive, i.e. centre drive. Such as the propeller shaft drive of a known automobile. B. And (5) wheel axle transmission. Such as a steering wheel. C. And (5) off-axis transmission. Such as an eccentric. D. Dome drive. Is driven at the top of the circumference. Dome drives may be used for both the shafted and shaftless circumferences. The force arm of the dome transmission is the longest and saves more force.

The circle body is an abstract upper concept which is created for summarizing the natural law of circular motion and explaining the natural law of propagation. The circumference body in the application of the invention is a concrete object, and the concrete object is different from the abstract concept. The circumferential body must be interpreted and identified as the case may be. Objects or devices for converting potential energy forces, such as gears or wheels, may be circumferential. It should be apparent that this abstract and generic terms are not used to stringent requirements or limitations on the practice of the invention. The concept of a circumferential body should be used to help propagate the scientific, correct interpretation of the claims as the case may be. It is apparent that: explaining a discovered nature rule is quite different from explaining the constructional features of an invention.

Almost all power can be used as power, almost all objects can be used as circumferential bodies, almost all movements can be used as circumferential movements, and all movements can be used as circumferential engines. The motive force and the circumferential body are ready, widely available and readily available. Unfortunately, for 16 years, humans have not been aware. The circumferential engine may have seven different configurations. The first generation was reciprocating engines. The second generation is a rotary engine. The power is used to drive a circular body to reciprocate or rotate, and gravity is converted to do work. Can be used for generating electricity or as an engine of a train or a ship. The third generation is a counterweight and external force engine, which converts the counterweight and external force to do work. Small volume and large specific energy. Can generate electricity or be used as an engine of an automobile, a train, a ship or an airplane. The fourth generation is a multiple pulley device combined axle engine. The fifth generation is a crankshaft engine. The sixth generation is a concentric engine. The seventh-generation circle center engine can be used for a space plane and can fly at the speed of light. The theoretical basis is as follows: first, the mass of the object may become zero. The mass of the object can be stationary to zero, thereby inventing a three-generation circumferential engine. The object mass may also be moved to zero. The moving mass of the object is zero, namely the light speed. And secondly, the circumferential engine can provide infinitely large clean and low-cost energy sources in space, and creates necessary energy conditions for infinitely approaching and finally reaching the speed of light. Thirdly, a method for transplanting and applying the principle is found according to the principle of the universe light speed, an accelerator and a light speed aircraft which can approach the light speed infinitely or finally reach the light speed are designed, and the light speed can be approaching the light speed infinitely or realizing the light speed by applying space conditions.

Example 1: the cylinder with shaft (a circumference) is installed on the suspension, one or more concave-convex parts are arranged on the surface of the circumference, and the concave-convex parts comprise convex ribs or saw teeth or rotating wheels. The power drives the shaft circumference body to reciprocate or roll or rotate, and the concave-convex pair connecting rod or lever or driving bar transmits pressure to do work. Pressure, i.e. potential energy force. The height of the concave-convex determines the stroke of the circumference body to do work.

Example 2: the upper gear, the middle gear and the lower gear are driven by a power to sequentially drive, and the upper gear and the middle gear are arranged on the suspension and are movably connected with the machine base and can be provided with a counterweight or/and an external force. The external force comprises pressure force or/and tensile force or/and elastic force or/and magnetic force. The balance weight and external force on the middle gear and the pivot position of the balance weight and the external force on the lower gear determine the potential energy force of the middle gear except the power. That is, the potential energy force of the middle gear is mainly determined by the balance weight or/and the external force on the middle gear and the fulcrum position of the external force on the lower gear. The middle gear is positioned above the lower gear and near the vertical center line. The meshing point of the middle gear and the lower gear is the fulcrum of the middle gear on the lower gear. The weight and/or external force on the middle gear and its fulcrum determine the gravity difference between the two sides of the gravity surface of the middle gear. Therefore, the upper gear can easily overcome the resistance of the middle gear. The mid gear resistance refers to the stationary inertial force of the mid gear. Therefore, the upper gear can easily drive the middle gear to rotate, the middle gear rolls forward and upward on the inclined plane of the lower gear together with the suspension and the counterweight, and potential energy force is transmitted to the lower gear. Thus obtaining infinite natural energy. The gear can also be a perforated wheel or a chain wheel or a friction wheel or a magnetic wheel.

Example 3: the suspension circumference body can adopt belt transmission to transfer potential energy force upwards. The suspension circumference body driven by the upward belt is a suspension movable pulley, so that the labor can be saved by half. The circumference of the suspension adopts dome transmission, and the position and angle of the force point of the circumference of the suspension and the belt can be changed by using the tension wheel, so that the force point is at the optimal position of the potential energy area of the circumference of the suspension, becomes roller transmission on an inclined plane, and can save more than half of force. The fulcrum of the suspension circumference body on the belt is also a resistance point, and the two points are combined. Rope drive or chain sprocket drive or friction drive or magnetic drive can also be used to transfer potential energy force of the suspension circumference.

Examples which are not exhaustive. Almost all objects are circular bodies, almost all movements can be circular movements, clean and low-cost new energy sources can be created, and the circular engine can be realized.

The potential energy force greater than the power force can be obtained by driving a shaft circumference body or a suspension circumference body or a counterweight circumference body or an external force circumference body which are positioned on reasonable supporting points by the power force. The potential energy restoring force is far smaller than the potential energy force, and the potential energy restoring force becomes a source of force, and is continuous and huge.

Facts 2: the force of potential energy recovery by rolling the cylinder on a 5 degree incline can be much less than the weight of the cylinder. The gravity and rolling potential energy of the cylinder can be converted into acting force by using a lever and other devices. The force is greater than the force to recover the potential energy of the cylinder.

According to the principle and the embodiment of the circumferential engine disclosed in the specification and the attached drawings, the circumferential engine can be manufactured, and new energy sources can be created. The application thus has practical value and practicality. The present application will be further described with reference to the following specific embodiments.

The above background of the application is intended to explain and support the claims of the application.

3. The application comprises the following steps: the application aims to provide a zero-pollution circumferential engine. The specific contents are as follows.

1. An engine is characterized in that a power is provided for driving at least one circumferential body to perform circumferential motion and outputting potential energy force of the circumferential body, and the power is power for driving the circumferential body; the circumference body is an object which moves circularly; the potential energy force is the power generated by the circumference body in the motion; the circumferential body is a roller 40 mounted on a suspension.

2. The engine or the motive force or the circumferential body or the circumferential motion or the potential energy force is one of the following:

the circumference body is provided with a shaft and is arranged on the stand or the suspension; or, the shaft comprises a mandrel 2 or a deflection shaft 7 or a combination of the mandrel 2 and the deflection shaft 7; the mandrel refers to a round mandrel and comprises a gear shaft or a belt wheel shaft or a chain wheel shaft; the off-axis refers to an axis outside the circle center and comprises an off-axis 7; the mandrel off-axis combination means that a circumference body is provided with a mandrel and an off-axis; or, a gap or/and elasticity is arranged between the shaft and the shaft hole, and the circumference body can move up and down and left and right in small amplitude relative to the fixed shaft hole; or, a gap or/and elasticity is arranged between the shaft and the shaft hole, and the shaft hole can move up and down, left and right slightly; or alternatively, the first and second heat exchangers may be,

the circumference body is provided with a reasonable fulcrum; or, the weights of the two sides of the gravity surface of the moving circumferential body are equal or similar, and the force for overcoming the static inertia of the circumferential body is equal to or close to zero; or a moving circumferential body, wherein the power arm is longer than the resistance arm; or the circumference body is positioned at the reasonable fulcrum position, the moment arm is longest, and the moment is greatest; or alternatively, the first and second heat exchangers may be,

the circumference body is arranged on the suspension, and the suspension is a mechanism for installing the circumference body and is movably connected with the machine base; the suspension can be in a flat plate shape or a grid shape or a frame shape or a tubular shape or a rod shape; or, the suspension is elastic; the elasticity comprises pneumatic or hydraulic elasticity; or, a gap or/and elasticity is arranged between the suspension and the stand; or the moving circumferential body and the suspension frame move back and forth and down slightly in a certain range relative to the base; or, the upper dead point or/and the lower dead point or/and the limit spring limit the movable range of the circumference body or/and the suspension; or, the suspension is provided with a counterweight and/or an external force; or the suspension comprises a cantilever, a inclined frame, a vertical frame, a suspension arm, an upper seat or a car lever; or, the circumferential body can move relative to the suspension; or alternatively, the first and second heat exchangers may be,

The two ends of the roller 40 are in clearance or elastic connection with the machine seat 43 or are movably connected with the machine seat 43; or, a gap or elasticity is formed between the bearing seats at the two ends of the roller 40 and the machine seat 43 or is movably connected with the machine seat 43; alternatively, the roller 40 is located at or near the vertical centerline above or over the fulcrum wheel 41; or, the fulcrum wheel 41 is installed on the stand or on the ground, is in the same axial direction as the roller 40, and rotates together with the roller 40; alternatively, one or more seats 43 are located on either side of or around the drum 40; or, there are auxiliary wheels 42 mounted on the frame 43; alternatively, one or more auxiliary wheels 42 are positioned around or below the drum 40 or near or below the horizontal centerline or near the fulcrum wheel 41; alternatively, the driving wheel 44 is mounted on the frame 43, and the dome drives the drum 40; or, the suspension is movably connected with the stand 43; or, the driving wheel 44 is mounted on a suspension with a counterweight and/or external force, and the suspension is mounted on the stand 43 or on the ground foundation; alternatively, the fulcrum wheel 41 is located at or near the vertical centerline below or beneath the drum 40; or, the fulcrum wheel 41 is positioned below the roller 40 outside the vertical center line or is 5 mm or more or 10 mm or more or 15 mm or more from the vertical center line; or, the roller 40 is positioned above the fulcrum wheel 41 outside the vertical center line or is 5 mm or more or 10 mm or more or 15 mm or more from the vertical center line; or, the gravity of the two sides of the gravity surface of the roller 40 is equal, similar or unequal; or, the gravity in front of the movement of the drum 40 is greater than that in the rear or the gravity in front of the movement is less than that in the rear; or, the plurality of fulcrum wheels 41 are distributed along the drum 40; or, a plurality of stands 43 are distributed along the drum 40; or, the base 43 is provided with a limiting device of the roller 40; alternatively, the motive force drives the drum 40 at the upper or dome or periphery of the drum 40; alternatively, the weight of the drum 40 falls mainly on the fulcrum wheel 41; or, the auxiliary wheel 42 assists the fulcrum wheel 41 to bear the weight or/and the limit roller 40; or, the fulcrum wheel 41 is a gear or friction wheel or a gear hole wheel or a magnetic wheel or a chain wheel; alternatively, the drum 40 is a ball mill or dryer or agitator drum; or, the roller of the ball mill or dryer or stirrer is positioned on the suspension or/and the fulcrum wheel 41 and is provided with a power generation device; or, the fulcrum wheel 41 is provided with a belt pulley or a friction wheel or a gear or a coupling on a shaft, and the power generator is driven to generate power; or, the roller 40 is provided with a gear, a belt pulley, a chain wheel or a friction wheel, and drives a generator to generate electricity; or alternatively, the first and second heat exchangers may be,

The circumference body is provided with a counterweight; or the circumferential body shaft or the suspension for mounting the circumferential body is provided with a counterweight; or the balance weight comprises a movable balance weight, a static balance weight, a movable balance weight and a fixed balance weight; the movable counterweight means that the counterweight moves together with the circumferential body; the static balance weight means that the balance weight does not move with the circumference body; the movable counterweight refers to that the counterweight is movably connected with the circumference body; the fixed counterweight is fixed on the circumference body or related devices; or, the counterweight is hung on the circumference body or the circumference body shaft or the suspension; or, the hanging counterweight means to connect the counterweight with the circumference body or the circumference body shaft or the suspension by using ropes or/and connecting rods or/and suspension arms; or, a counterweight is arranged along the front lower direction of the motion of the circular body, and comprises a hanging counterweight; or alternatively, the first and second heat exchangers may be,

the circumference body is provided with an external force; or the external force and the power act on the circumference together; the external force comprises a tensile force or/and a compressive force or/and a magnetic force or/and an elastic force; the external force is arranged on the circumference body or the circumference body shaft or the circumference body related device; the external force can rotate together with the circumference body or not rotate together with the circumference body; or the circumference body is provided with a counterweight and an external force; or alternatively, the first and second heat exchangers may be,

the circumference body is cylindrical or round cake-shaped or circular or disc-shaped or round basin-shaped or cylindrical or wheel-shaped; the input structure receives the driving force and the output structure outputs the potential energy of the circumferential body; or a limiting structure is arranged to limit the circumference body; alternatively, the input structure comprises an input shaft 19 or gear 9 or gear 10; the output structure comprises an output shaft 18 or a gear 9 or a gear 10 or a central shaft 12; the limiting structure comprises a limiting shaft 16 or a central shaft 12 or a gear 9 or a gear 10; or alternatively, the first and second heat exchangers may be,

The circumference body is provided with a large wheel structure, and a small wheel is movably matched with the large wheel in the large wheel; or alternatively, the first and second heat exchangers may be,

the circumference body has elasticity; or, the elasticity is from elastic materials or springs or/and elastic devices; or, the elastic circumferential body generates regular vibration; or, a vibration damper and/or a limiting device are/is matched with the elastic circumference body; or, a gap or/and elasticity is arranged between the shaft of the circumferential body and the shaft hole, and the circumferential body can move up and down, left and right slightly relative to the shaft hole; or alternatively, the first and second heat exchangers may be,

the circumference body is a magnetic flywheel or a magnetic device; or the circumference body with the magnetic device receives magnetic force drive and power-assisted power or is used as power; or a magnetic force circumference body is arranged between the power generation body and the energy utilization body; or the magnetic force circumference body is arranged on the motor shaft or the generator shaft or the belt pulley shaft or the gear shaft; or, the magnetic force circumference body is arranged on the stand or/and the suspension; or, one or more known electromagnets or magnets are arranged on the circumference of the flywheel and the engine base, and the two electromagnets or magnets are mutually induced; when the flywheel rotates, the electromagnet on the base generates attractive and repulsive force to the electromagnet on the flywheel, so as to drive the flywheel; or the magnet on the machine base generates attractive and repulsive force to the magnet on the flywheel; or when the magnetic induction point on the flywheel passes through the magnetic induction point on the machine base, the magnetic induction point on the machine base and the magnetic induction point on the flywheel generate repulsive force to drive the flywheel; or alternatively, the first and second heat exchangers may be,

The circumference body is provided with a wheel axle structure; the wheel axle structure comprises a belt pulley or a gear or a chain wheel or a flywheel; or, at least one pulley shaft and a plurality of pulley groups with different diameters form a pulley device which is driven by power; or, a plurality of belt pulley sets are combined into a belt pulley device; or, at least one belt pulley shaft is arranged on the belt pulley device, and a gap or elasticity is arranged between the belt pulley shaft and the machine base; or the belt wheel shaft can move up and down, left and right slightly relative to the machine base; or, the belt wheel shaft is provided with a counterweight or/and an external force; or alternatively, the first and second heat exchangers may be,

the circumference body is a crankshaft or is provided with a crankshaft; the crankshaft is connected with the connecting rod and outputs potential energy force of the circumference body; or, the eccentric wheel or the cam replaces the crankshaft to drive the connecting rod capable of automatically returning; or, the connecting rod is provided with an upper crankshaft and a lower crankshaft; or alternatively, the first and second heat exchangers may be,

the circumference body combination or a plurality of stamping parts are combined into a circumference body; or a plurality of circumference body combinations, the potential energy force of the last circumference body is the power of the next circumference body; or, a plurality of circumferential body combinations of different structures or different functions; or, a plurality of stamping parts are axially or/and radially combined into the belt pulley; or, a plurality of stamping parts are axially or/and radially combined into a gear; or, a plurality of stamping parts are axially or/and radially combined with a circumferential body which is spherical or cylindrical or in a circular basin shape; or, the power drive is provided with a suspension or/and a counterweight or/and a combined circumference body of external force; or a plurality of magnetic flywheels are combined into a magnetic circumference body; or a plurality of gears or chain wheels or belt pulleys or chain wheels or magnetic force wheel combinations, wherein the potential energy force of the previous one is the next power; or, a suspension or/and a flywheel or/and a magnetic circumferential body or/and an energy storage device or/and a frequency conversion device are arranged between the power generation force and the energy utilization body; or, the belt pulley shaft is provided with a magnetic force circumference body; or, the circumferential body combination comprises creative combination or simple superposition; or, a plurality of circumferential bodies are horizontally arranged and combined or combined up and down or combined radially or/and axially; or, a plurality of circumferential bodies 8 or/and circumferential bodies 13 or/and circumferential bodies 17 are axially combined; the potential energy force of the last is the next power; or, the circumference body is composed of a plurality of stamping parts; the circumference body is a gear, and the gear 64 is formed by axially combining 3 stamping parts 66; 4 bolts 65 are used for fixing 3 stamping parts 66 together; or the gear is radially decomposed into a plurality of stamping parts, and the plurality of stamping parts are combined into the gear; or, a plurality of stamping parts are axially or/and radially combined into a gear; or, a plurality of stamping parts axially or/and radially combine the belt pulleys; or, a plurality of stamping parts are axially or/and radially combined into a circumference body, and the circumference body is spherical or cylindrical or round basin-shaped; the stamping parts are fixed together by bolts; or a plurality of circumferential body combinations, wherein the potential energy force of the previous one is the next power; or, a plurality of engine combinations; the potential energy force of the last is the next power; or, the combination comprises a horizontal arrangement combination, an up-down arrangement combination and a radial or/and axial combination; or, a plurality of circumferential bodies 8 or/and circumferential bodies 13 are axially combined; or alternatively, the first and second heat exchangers may be,

The circumference body is a cylinder, the cylinder is arranged on the stand or the suspension, one or more concave-convex parts are arranged on the circumference surface of the cylinder, and the concave-convex parts comprise convex points or/and convex ribs or/and saw teeth or/and rotating wheels; the saw teeth refer to saw-tooth-shaped concave-convex parts; the rotating wheel can roll and is arranged on the surface of the cylinder; the power drives the cylinder to reciprocate or roll or rotate, and the concave-convex pair has an automatic return function to the connecting rod or the lever or the transmission bar, transmits pressure and outputs potential energy force of the cylinder; or, the automatic return comprises a connecting rod or a lever or a transmission bar, and a spring is arranged on the connecting rod or the lever or the transmission bar; or, the cylinder is arranged on the suspension, the power is used for driving the cylinder to reciprocate or/and rotate or/and roll, and the gravity and torsion of the cylinder or/and the counterweight or external force arranged on the cylinder are converted into circumferential body power which is output outwards; or, elastic devices with positioning function or/and vibration reduction function or/and reinforcement function are arranged around the cylinder, and the elastic devices comprise elastic materials or/and springs or/and pneumatic or hydraulic devices; in the potential energy area of the cylinder, a lever device receives the concave-convex drive and outputs the power of the cylinder; or the lever device is a connecting rod crankshaft device, and the connecting rod receives the concave-convex driving and outputs cylinder power; or the lever device is a chain sprocket device, the chain receives the concave-convex drive and outputs cylinder power; or the lever device is a fluid pressure device, and the connecting rod piston receives the concave-convex driving and outputs cylinder power; or the cylinder power, namely the cylinder potential energy force, comprises the gravity and torsion of the cylinder or the external force arranged on the cylinder; or, the reciprocating motion comprises a reciprocating motion device, the reciprocating motion device comprises a one-way wheel, the one-way wheel can accept the wheel of the transmission by rotating in only one direction, the one-way wheel comprises a ratchet wheel or a one-way bearing or a check wheel, the one-way wheel can accept the transmission from the power, and the reverse rotation is idle; or, the check wheel is provided with a saw-tooth wheel at the finger edge, and an elastic check rod is matched with the check wheel to rotate the check wheel in one direction; the check rod is a rod-shaped object which is elastic and can return automatically; or, the check wheel adopts a check structure of a winding cable turntable of a known ship; or, the concave-convex height is the stroke of doing work; or, the cylinder can also be a sphere, a hexagonal body, an octagon body or a round cake body; or the circumference body is an eccentric wheel or a cam, the eccentric wheel or the cam is arranged on the suspension, a counterweight and/or an external force can be provided, and the potential energy force of the cylinder is output by transmitting pressure to a connecting rod or a lever or a transmission bar capable of automatically resetting; or the circumference body is a crankshaft, and the pressure is transmitted to a connecting rod or a lever or a transmission bar which can return automatically to output potential energy force of the cylinder; or the circumference body is a crankshaft, the crankshaft is provided with a connecting rod, the connecting rod transmits pressure to the connecting rod or the lever or the transmission bar which can return automatically, and potential energy of the cylinder is output; or, the cylinder can also be a round tube body or a roller; or alternatively, the first and second heat exchangers may be,

The circumference body is a chain wheel, the chain wheel is arranged on the machine base or the suspension through a chain wheel shaft, the chain wheel is driven by power, and potential energy force of the chain wheel is output; or the chain wheel is positioned below the generator, the power is generated to drive the chain wheel, the chain is driven, and the chain drives the generator chain wheel above to generate electricity; or, the chain wheel shaft is provided with a belt pulley or a coupling, the power is used for driving the chain wheel through the belt pulley or the coupling, and potential energy force of the chain wheel is output; or, the chain wheel is a chain wheel; the chain wheel is cylindrical or disc-shaped or ring-shaped or gear-shaped; the chain is arranged on the circumference of the chain wheel, and the chain wheel are mutually driven; the power is generated to drive a chain wheel or a chain wheel to output power; or the chain is linearly arranged on the flat plate, and the power is transmitted to the driving chain wheel to drive the flat plate to reciprocate so as to output power; or, the potential energy force refers to the total force of the movement of the chain wheel, and the total force comprises a power force and the gravity force or/and torsion force or/and the magnetic force or/and elastic force arranged on the chain wheel and the suspension; the gravity comprises the gravity of the chain wheel or/and the gravity arranged on the chain wheel, and the torsion comprises the motion torsion of the chain wheel and the torsion of the self material; the magnetic force comprises electromagnetic force or attraction and repulsion force of a magnet; the electromagnetic force comprises the repulsive force of an electromagnet; the elastic force comprises the elastic force of an elastic material or/and the elastic force of a spring or/and the elastic force of an elastic device; or alternatively, the first and second heat exchangers may be,

The circumference body is a circumference body 8, the circumference body 8 is an internal gear, and the inner periphery of the circumference body is provided with a plurality of gears 9; the gear 9 is connected with the engine base or the power generation or the energy or the transmission shaft through a shaft; the gear 9 can be driven by a power transmission or a circumferential body 8, or the circumferential body 8 and/or a limiting circumferential body 8 are/is driven; the power-driven circumferential body 8 drives the gear 9 to output power; or, the power driving gear 9 drives the circumference body 8 to drive the other gears 9 to output power; or, the circumference body 8 is an internal gear with external teeth, and the inner circumference and the outer circumference of the circumference body are provided with a plurality of gears 9 and/or a plurality of gears 10; the gear 9 and/or the gear 10 are/is connected with the engine base or the power generation or the energy or the transmission shaft through a shaft; the gear 9 and/or the gear 10 can be driven by a power transmission or a circumferential body 8, or the circumferential body 8 and/or a limiting circumferential body 8 are driven; the power-driven circumferential body 8 drives the gear 9 or/and the gear 10 to output power; alternatively, both the inner periphery and the outer periphery of the circumferential body 8 are toothed; or, the inner periphery or/and the outer periphery of the circumference body 8 is provided with one or more gears 9 or/and gears 10; or, the power is driven to drive one gear 9 or gear 10, and the transmission circumference body 8 drives the other gear 9 or/and gear 10 to output power; or, a gap or/and elasticity is arranged between the circumference body 8 and the gear 9 or/and the gear 10; or the circumference body 8 can move up and down, left and right slightly relative to the gear 9 or/and the gear 10; or, the circumference body 8 or/and the gear 9 or/and the gear 10 are arranged on the suspension; or the circumference body 8 is an outer ring and rotates around the gear 9, an inner ring gear 11 is arranged, and the gear 9 is positioned between the inner ring and the outer ring; the inner ring gear 11 is provided with a central shaft 12, one end of the central shaft 12 is connected with the inner ring gear 11, and the other end is connected with an energy body; the power is generated to drive the circumference body 8 or the gear 9 or the gear 10 to drive the central shaft 12 to output power; alternatively, the gear 9 and/or the gear 10 may change the position on the circumferential body 8; or friction transmission or gear hole wheel transmission or chain wheel transmission or magnetic force wheel transmission is adopted between the circumference body 8 and the gears 9 and 10; or, chains are installed on the inner periphery and the outer periphery of the circumference body 8, so that the chain wheel can be used for replacing gears; or, the magnetic wheel comprises a magnetic flywheel; or, a plurality of circumferential bodies 8 are axially combined with the gear 9 or/and the gear 10, and the potential energy force of the former is the next power; or alternatively, the first and second heat exchangers may be,

The circumference body is a circumference body 13, and the circumference body 13 can be cylindrical or circular or annular or cylindrical; a plurality of small wheels 15 are clamped in grooves on one side or two sides of the circumference body 13, the small wheels 15 have limiting or/and transmission functions, and the small wheels 15 and the circumference body 13 are in friction transmission; the small wheel 15 is connected with the stand or the power or/and energy; the power-driven circumferential body 13 drives a plurality of small wheels 15 to rotate, at least one small wheel is connected with the energy-using body, and power is output; or, the power is used for driving at least one small wheel 15 to rotate, driving the circumference body 13 to drive other small wheels 15, and at least one small wheel 15 is connected with the energy utilization body to output power; or, the inner periphery or/and the outer periphery of the circumference body 13 is provided with one or more small wheels 15; or, the power is driven by magnetic force or gear or chain wheel; or, the power is used for driving at least one small wheel 15 or driving a circumference body 13, the circumference body 13 drives the other small wheel or wheels 15 to rotate, and at least one small wheel 15 is connected with the energy utilization body to output power; or, the spindle 14 passes through the center shaft hole of the circumference body 13 and is arranged on the suspension or the stand, so that the circumference body 13 is limited and supported; the circumferential body 13 rotates around the spindle 14; the power is generated to drive at least one small wheel 15 to rotate, and at least one small wheel 15 is connected with an energy utilization body shaft to output power; or, the mandrel 14 is fixedly connected with the circumference body 13 and the energy utilization body, and the power is output by driving the small wheel 15 by the power; or, the circumference body 13 is fixed on the suspension or the stand, and a gap or elasticity is formed between the circumference body and the mandrel 14; or the mandrel 14 can move slightly up and down, left and right in the shaft hole of the circle center of the circumference body 13; alternatively, the small wheel 15 may change position on the circumferential body 13; or, the circumference body 13 or the small wheel 15 is arranged on a suspension; or alternatively, the first and second heat exchangers may be,

The circumference body is a circumference body 17, and the circumference body 17 is in a circular basin shape; the inner periphery of the circumference body 17 is provided with a limiting shaft 16 which is fixedly connected with the stand 21; the limiting shaft 16 can limit the circumferential body 17; the limiting shaft 16 is provided with a movable friction wheel; the output shaft 18 is provided with a fixed friction wheel, and the output shaft 18 is connected with an energy utilization body; the input shaft 19 is provided with a fixed friction wheel, the output shaft 19 is connected with a power generation force, and the three shafts are used for jointly positioning the circumferential body 17; the power drives the input shaft 19, the friction wheel on the input shaft 19 rubs the inner periphery of the circumference body 17, and the circumference body 17 rotates relative to the stand 21; the friction wheel of the limiting shaft 16 and the output shaft 18 is driven by the friction of the inner periphery of the circumferential body 17, the friction wheel of the limiting shaft 16 idles along with the friction wheel, and the output shaft 18 drives an energy body to output power; or, the inner periphery or/and the outer periphery of the circumferential body 17 is/are provided with one or more limiting shafts or/and one or more input shafts or/and one or more output shafts; or, the limiting shaft 16 or/and the output shaft 18 or/and the input shaft 19 are elastic; or, a gap or/and elasticity is arranged between the circumferential body 17 and the limiting shaft 16 or/and the output shaft 18 or/and the input shaft 19; the elasticity is from elastic materials or springs or elastic devices; or the circumference body 17 can move up and down, left and right slightly; or, the center of the circumference body 17 is provided with a mandrel 20 which is movably connected with the circumference body 17 and the stand 21, and the mandrel 20 and the limiting shaft 16 are used for jointly positioning the circumference body 17; alternatively, the circumferential body 17 may be spaced from the spindle 20 or/and resilient; or, the circumference 17 can move up and down, left and right slightly relative to the mandrel 20; or, the mandrel 20 is fixedly connected with the circumference body 17 and the energy body, and the power driving input shaft 19 drives the circumference body 17 to output power; or, the position of the limiting shaft or/and the output shaft or/and the input shaft can be changed on the circumference body 17; or, the friction transmission can also be gear transmission or magnetic transmission or gear hole wheel transmission or chain wheel transmission; or, a chain is arranged on the inner periphery or/and the outer periphery of the circumference body 17 to form a chain wheel which is matched with a plurality of chain wheels for transmission; or alternatively, the first and second heat exchangers may be,

The circumference body is a gear, an upper gear 25 is arranged on a car lever 23, a middle gear 26 is arranged on a car lever 28, a motive power drives the upper gear 25, drives the middle gear 26 and a lower gear 27, and outputs potential energy force of the middle gear 26; or, the upper gear 25 or/and the car lever 23 are provided with a counterweight or/and an external force; or, the middle gear 26 or/and the car lever 28 are provided with a counterweight or/and an external force; or, the external force comprises pressure force or/and tensile force or/and elastic force or/and magnetic force; or, the upper gear 25 or/and the middle gear 26 are arranged on the suspension and are movably connected with the machine base; or, the intermediate gear 26 is located near the vertical center line above the lower gear 27; or, the meshing point of the intermediate gear 26 and the lower gear 27 is the fulcrum of the intermediate gear 26 when moving on the lower gear 27; or, the upper gear 25 is located near the vertical center line above the middle gear 26; or, the meshing point of the upper gear 25 and the intermediate gear 26 is the fulcrum of the upper gear 25 when moving on the intermediate gear 26; or, the middle gear 26 rolls obliquely upward on the inclined surface of the lower gear 27 with the car bar 28; or, the upper gear 25 rolls obliquely upward on the inclined surface of the middle gear 26 with the car bar 23; or, the rotating intermediate gear 26 generates small movements back and forth and up and down; or, the rotating upper gear 25 generates a small movement back and forth and down; or, there are two or more upper gears 25 or middle gears 26 or lower gears 27 on one gear shaft, i.e., a plurality of gears are juxtaposed on one gear shaft; or, the intermediate gear 26 is provided with a suspension or/and a counterweight or/and an external force; the power generation drives the middle gear 26 to rotate, and potential energy force of the middle gear 26 is converted into output power; or, the middle gear shaft 31 is provided with a driven gear or a driven belt pulley or a coupling, and directly receives power for transmission; alternatively, the potential force refers to the force generated by the intermediate gear 26 during movement; or, the potential force comprises potential force generated by the middle gear 26 in movement or/and gravity or/and torsion or/and tension or/and pressure or/and external force configured on the middle gear 26; the gravity includes the gravity of the middle gear 26 and the suspension and the gravity arranged on the middle gear 26; the torsion force comprises a motion torsion force generated by the middle gear 26 in motion and an elastic torsion force generated by the self material of the middle gear 26; the external force refers to magnetic force or/and elastic force or/and tensile force or/and compressive force arranged on the middle gear 26; the magnetic force comprises electromagnetic force or attraction and repulsion force of a magnet; the electromagnetic force comprises the repulsive force of an electromagnet; the elastic force comprises the elastic force of an elastic material or/and the elastic force of a spring or/and the elastic force of an elastic device; or, the diameter of the upper gear 25 is smaller than that of the middle gear 26; or, the diameter of the middle gear 26 is smaller than that of the lower gear 27; or, the car lever is provided with a sliding sleeve, the sliding sleeve is a vertical sleeve 61, and the vertical sleeve 61 is provided with a vertical hole 62 and a vertical hole 63 which are mutually vertical; or the gear is a gear hole wheel or a friction wheel or a chain wheel or a magnetic wheel; or alternatively, the first and second heat exchangers may be,

The circumference body is a belt pulley, and the belt pulley is arranged on a motor shaft or a generator shaft or a belt pulley shaft, or the belt pulley device comprises a machine seat, at least one belt pulley shaft arranged on the machine seat, and a driven belt pulley and a driving belt pulley which are arranged on the same belt pulley shaft; a plurality of belt pulleys with different diameters are combined with a high-speed motor and a low-speed generator, and the high-speed motor drives the plurality of belt pulleys with different diameters to drive the low-speed generator to generate power; or, the high-speed motor, the belt pulley device and the low-speed generator are combined to generate electricity; within the same time; or the power is used for driving the high-speed motor to drive the low-speed generator to generate electricity; or the motor is combined with the belt pulley device to drive the low-speed generator to generate electricity, or the belt pulley on the high-speed motor drives the driven belt pulley and the driving belt pulley on the belt pulley shaft, and the driving belt pulley drives the belt pulley on the low-speed generator shaft to generate electricity; or, the motor is combined with a plurality of belt pulley devices and a low-speed generator to generate electricity; or, the plurality of belt pulley devices are horizontally arranged or vertically arranged or overlapped and combined with the motor, and the motor drives the belt pulleys of the plurality of belt pulley devices to output power; or, the diameter of the pulley on the high-speed motor shaft is smaller than the diameter of the driven pulley; or, the driven belt pulley refers to a belt pulley which receives the transmission of the other belt pulley; the driving belt pulley points to the belt pulley which transmits the transmission to the other side; or the diameter of the driving pulley is smaller than that of the pulley of the low-speed generator; or the belt pulley is arranged on the suspension frame and positioned below the generator, and the belt drives the belt pulley of the generator upwards to generate electricity; or the belt pulley is arranged on the suspension, is positioned under the low-speed generator, is provided with a counterweight or/and external force, and drives the generator above to generate electricity; or, a belt pulley is arranged on the motor shaft and is arranged on the suspension to drive the belt pulley on the generator shaft to generate electricity; or, the belt pulley shaft is arranged on the suspension or/and provided with a counterweight or/and provided with an external force; or the transmission direction of the driving belt pulley is above the horizontal line; or the two belt pulleys are arranged obliquely above; or, the driven pulley is positioned above or higher than the driving pulley; or, a flywheel or a magnetic flywheel is arranged on the motor shaft or the belt pulley shaft or the generator shaft; or, the belt pulley on the belt pulley shaft or/and the motor shaft or the generator shaft is provided with a flywheel structure, and the belt pulley has the energy storage function; or the diameter of the belt pulley on the shaft of the high-speed motor is smaller than that of the belt pulley on the shaft of the low-speed generator, or is one time or more smaller than that of the belt pulley on the shaft of the low-speed generator; or, the diameter of the belt pulley on the shaft of the high-speed motor is smaller than that of the driven belt pulley, or is one time or more smaller than that of the driven belt pulley; or the diameter of the driving pulley on the pulley shaft is smaller than that of the pulley on the low-speed generator shaft, or is one time or more smaller than that of the driving pulley on the pulley shaft; or, the diameter of the driving pulley is smaller than that of the driven pulley, or is one time or more smaller than that of the driven pulley; or the diameter of the driving pulley on one pulley shaft is smaller than that of the driven pulley, or is one time or more smaller than that of the driven pulley; or, the rotating speed of the high-speed motor is 600 or more than 900 or more than 1400 or more than 2000 or more than 2800; or, the rotating speed of the low-speed generator is 600 or less or 300 or less or 200 or less or 100 or less or 50 or 30 or less; or, the power of the motor is 2 times or more or 3 times or more than that of the generator, or, the belt pulley is arranged on the suspension, and the rotating speed of the motor is the same as or similar to that of the generator; or the rotating speeds of the motor and the generator are the same or similar; or, at least one belt pulley on the belt pulley device is a magnetic circumference body; or, the belt pulley is provided with magnetic force and is a magnetic force circumference body; or, a gap or/and elasticity is arranged between the belt pulley shaft and the shaft hole, and the belt pulley shaft can move up and down and left and right slightly relative to the shaft hole; or the shaft hole can move up and down, left and right slightly relative to the belt pulley shaft; or, the belt is a synchronous belt; or alternatively, the first and second heat exchangers may be,

The magnetic circumferential body is a magnetic flywheel; the magnetic flywheel 52 is provided with a plurality of magnetic induction points 53; the base 54 of the magnetic flywheel 52 is provided with a magnetic induction point 55 corresponding to the magnetic induction point 53; or, one or more electromagnets or magnet sensing devices, namely the magnetic force sensing points, are arranged on the circumference of the flywheel 52 and the base 54 and are mutually sensed; when a magnetic induction point 53 on the flywheel 52 passes through a magnetic induction point 55 on the stand 54, the magnetic induction point 55 on the stand 54 is controlled by known techniques including a relay or a commutator, and generates attraction or repulsion to the magnetic induction point 53 of the flywheel 52 to drive the flywheel; the repulsive force is absorbed and driven to rotate just like the stator and the rotor of the known motor; flywheel 52 corresponds to the rotor of the motor and frame 54 corresponds to the stator of the motor; or a magnetic force circumferential body is arranged on the motor shaft or the belt pulley shaft or the gear shaft or the generator shaft; or, a flywheel or a magnetic flywheel is arranged between the power generation force and the energy utilization body; or, the circumferential body shaft is provided with a flywheel or a magnetic flywheel; or the circumference body is provided with magnetic force, receives magnetic force drive, and assists the power or is used as the power; or the magnetic force circumference body is arranged on the stand or the suspension; or alternatively, the first and second heat exchangers may be,

The circumference body is a chain wheel; the chain wheel can be cylindrical or circular plate-shaped or circular ring-shaped or gear-shaped; the chain wheel is formed by clamping a chain 59 by two clamping plates 56; a plurality of pins 57 secure a chain 59 between the two clamping plates 56; a plurality of bolts 60 are provided to connect the two clamping plates 56 together; the chain wheel is driven by the chain wheel; or the chain is linearly arranged on the flat plate, and the power is transmitted to drive the chain wheel to drive the chain and the flat plate to reciprocate so as to output power; or alternatively, the first and second heat exchangers may be,

the circumference body is arranged on a car bar, the car bar is provided with a vertical sleeve 61, and vertical holes 62 and 63 which are mutually vertical are formed in the vertical sleeve; the car bar 23 or the car bar 28 is made of round tubes, two ends of the car bar are provided with vertical sleeves 61, and the car bar can slide back and forth after being inserted into the vertical holes 62; the vertical hole 63 is sleeved on a vertical hole shaft on the base and can move up and down; the circumference body with the car lever can move up and down relative to the machine seat; the vertical sleeve 61 can also be used as a sliding sleeve of a suspension; or alternatively, the first and second heat exchangers may be,

the power drives the circumferential body to perform the circumferential motion, and potential energy force of the circumferential body is converted into output power; the power comprises well-known electric power or/and battery power or/and magnetic force or manpower or animal power or hydraulic power or wind power or clockwork power; or the power can be an electric motor or an internal combustion engine or a steam engine or a hydrogen engine or a magnetic machine or a pneumatic machine or a spring device; or the power is the power from an electric motor or an internal combustion engine or a steam engine or a hydrogen engine or a magnetic machine or a pneumatic machine or a spiral spring; or the power is driven by a well-known shaft or friction drive or gear drive or belt pulley drive or universal coupling drive or magnetic drive or chain wheel drive of the invention; or, the power refers to the power for driving the circumference body; or, the circumferential potential energy force is circumferential power; the force may be a motive force; or alternatively, the first and second heat exchangers may be,

The circumference body refers to an object with circular motion; the object comprises a device; the object refers to a tangible individual and comprises a sphere or a cylinder or a belt pulley or a friction wheel or a tooth hole wheel or a chain wheel or a flywheel or a roller; or, the circumference body can amplify the power in the circular motion; the circular motion is radial motion; the circular motion refers to the motion with a circle center and a radius, and comprises rotation, rolling, swinging, shaking or swaying or simultaneous rotation and rolling; or alternatively, the first and second heat exchangers may be,

the potential energy force is from the movement potential energy of the circumference body and comprises potential force or/and gravity or/and torsion or/and tension or/and pressure or/and external force configured on the circumference body; the gravity comprises the gravity of the circumference body and the suspension or/and the gravity arranged on the circumference body, and the torsion comprises the motion torsion generated by the circumference body in motion and the elastic torsion generated by the circumference body material; the external force refers to magnetic force or/and elastic force or/and tensile force or/and pressure arranged on the circumference body; the magnetic force comprises electromagnetic force or magnetic force of a magnet, and the elastic force comprises the elastic force of an elastic material or/and the elastic force of a spring or/and the elastic force of an elastic device; or, the driven belt pulley or the driven gear refers to a belt pulley or a gear which receives the driving of the other party; the driving belt pulley or the driving gear points to the belt pulley or the gear which transmits transmission to the other side; or alternatively, the first and second heat exchangers may be,

The motor may also be: an internal combustion engine or a steam engine or a hydrogen engine or a magnetic engine or a pneumatic engine or a spring device; or, the plurality of fingers are two or more; or a tensioning wheel is arranged between the pulleys; or, a plurality of pulley shafts and a plurality of pulley combinations are arranged on one machine seat; or the engine is used for an oil field pumping unit or a dryer or a stirrer or a ball mill; or, the pulley shaft is provided with a plurality of pulleys, the pulleys are arranged on the suspension, and the power is output by driving the pulleys on the suspension; or, on the belt between two pulleys, at least one pulley with a suspension is engaged in the transmission; or the rotation speed of the motor is the same as or similar to that of the generator; or the circumference body is arranged on a suspension, a counterweight or/and an external force are arranged on the suspension, the suspension is movably connected with the machine base, and a motor is used for driving the circumference body to move so as to output potential energy force to the generator; or, the energy-using body refers to an object using energy, and comprises a lathe, a water pump, a generator, a ball mill, a coupler or a transmission shaft; or, the magnetic force comprises a known electromagnet or a repulsive force of the magnet; the magnetic transmission structure comprises a magnetic transmission structure adopting a motor; or the belt pulley device comprises at least one machine seat, at least one belt pulley shaft arranged on the machine seat, and a driven belt pulley and a driving belt pulley which are arranged on the same belt pulley shaft; or, the mounting includes mounting with a known bearing or bushing or shaft bowl or machine component; the bearing installation or shaft sleeve installation or shaft bowl installation refers to that a shaft of a component or a mechanism is installed on a stand or a suspension or an energy-using body through a bearing or a shaft sleeve or a shaft bowl; the shaft comprises a gear shaft or a pulley shaft sprocket shaft; the shaft sleeve is characterized in that a sliding sleeve is arranged on the shaft, and the shaft slides or rotates in the sliding sleeve; the shaft bowl refers to a steel bowl on the shaft, steel balls are arranged in the steel bowl, and the shaft rotates in the steel balls; or, a gap or/and elasticity is arranged between the circumferential body shaft and the shaft hole, and the circumferential body shaft can move up and down and left and right slightly relative to the shaft hole. The circumference body shaft comprises a belt wheel shaft or a gear shaft or a chain wheel shaft; or, the elasticity is from elastic material or spring or elastic device; or, the gap or/and elasticity is used for small movements between the components, or other methods or devices can be used for small movements between the components, up and down, left and right; or, the automatic return comprises arranging a spring on a connecting rod or a lever or a transmission bar.

2. The manufacturing approach of a kind of engine, characterized by that there is a motive force to drive at least one circumference body to take place the circular motion, output the potential energy force of the circumference body, the said motive force is the motive force to drive circumference body; the circumference body is an object which moves circularly; the potential energy force is the power generated by the circumference body in the motion; the circumference is a roller 40 mounted on a suspension; or (iii).

3. The engine or the motive force or the circumferential body or the circumferential motion or the potential energy force is one of the following:

The circumference body is a belt pulley, and the belt pulley is arranged on a motor shaft or a generator shaft or a belt pulley shaft, or the belt pulley device comprises a machine seat, at least one belt pulley shaft arranged on the machine seat, and a driven belt pulley and a driving belt pulley which are arranged on the same belt pulley shaft; the high-speed motor drives the plurality of belt pulleys with different diameters to drive the low-speed generator to generate power, or the high-speed motor, the belt pulley device and the low-speed generator are combined to generate power; or the power generation force drives the high-speed motor to drive the low-speed generator to generate power, or the motor is combined with the belt pulley device to drive the low-speed generator to generate power, or the belt pulley on the high-speed motor drives the driven belt pulley and the driving belt pulley on the belt pulley shaft, and the driving belt pulley drives the belt pulley on the low-speed generator shaft to generate power; or, the motor is combined with a plurality of belt pulley devices and a low-speed generator to generate electricity; or, the plurality of belt pulley devices are horizontally arranged or vertically arranged or overlapped and combined with the motor, and the motor drives the belt pulleys of the plurality of belt pulley devices to output power; or, the diameter of the pulley on the high-speed motor shaft is smaller than the diameter of the driven pulley; or, the driven belt pulley refers to a belt pulley which receives the transmission of the other belt pulley; the driving belt pulley points to the belt pulley which transmits the transmission to the other side; or the diameter of the driving pulley is smaller than that of the pulley of the low-speed generator; or the belt pulley is arranged on the suspension frame and positioned below the generator, and the belt drives the belt pulley of the generator upwards to generate electricity; or the belt pulley is arranged on the suspension, is positioned under the low-speed generator, is provided with a counterweight or/and external force, and drives the generator above to generate electricity; or, a belt pulley is arranged on the motor shaft and is arranged on the suspension to drive the belt pulley on the generator shaft to generate electricity; or, the belt pulley shaft is arranged on the suspension or/and provided with a counterweight or/and provided with an external force; or the transmission direction of the driving belt pulley is above the horizontal line; or the two belt pulleys are arranged obliquely above; or, the driven pulley is positioned above or higher than the driving pulley; or, a flywheel or a magnetic flywheel is arranged on the motor shaft or the belt pulley shaft or the generator shaft; or, the belt pulley on the belt pulley shaft or/and the motor shaft or the generator shaft is provided with a flywheel structure, and the belt pulley has the energy storage function; or the diameter of the belt pulley on the shaft of the high-speed motor is smaller than that of the belt pulley on the shaft of the low-speed generator, or is one time or more smaller than that of the belt pulley on the shaft of the low-speed generator; or, the diameter of the belt pulley on the shaft of the high-speed motor is smaller than that of the driven belt pulley, or is one time or more smaller than that of the driven belt pulley; or the diameter of the driving pulley on the pulley shaft is smaller than that of the pulley on the low-speed generator shaft, or is one time or more smaller than that of the driving pulley on the pulley shaft; the method comprises the steps of carrying out a first treatment on the surface of the Or, the diameter of the driving pulley is smaller than that of the driven pulley, or is one time or more smaller than that of the driven pulley; or the diameter of the driving pulley on one pulley shaft is smaller than that of the driven pulley, or is one time or more smaller than that of the driven pulley; or, the rotating speed of the high-speed motor is 600 or more than 900 or more than 1400 or more than 2000 or more than 2800; or, the rotating speed of the low-speed generator is 600 or less or 300 or less or 200 or less or 100 or less or 50 or 30 or less; or, the power of the motor is 2 times or more or 3 times or more than that of the generator, or, the belt pulley is arranged on the suspension, and the rotating speed of the motor is the same as or similar to that of the generator; or the rotating speeds of the motor and the generator are the same or similar; or, at least one belt pulley on the belt pulley device is a magnetic circumference body; or, the belt pulley is provided with magnetic force and is a magnetic force circumference body; or, a gap or/and elasticity is arranged between the belt pulley shaft and the shaft hole, and the belt pulley shaft can move up and down and left and right slightly relative to the shaft hole; or the shaft hole can move up and down, left and right slightly relative to the belt pulley shaft; or, the belt is a synchronous belt; or alternatively, the first and second heat exchangers may be,

The engine is used for a mobile phone, a watch, an airplane, a generator or human body equipment; or the engine replaces a battery or an internal combustion engine or a steam engine or water energy or wind energy or solar energy or fossil fuel; or, the engine is used for a spacecraft or an outer planet.

The invention has the advantages that: on the one hand, the energy crisis is huge, and on the other hand, the natural energy is huge and incomparable. The invention makes a contribution to the method and provides a plurality of novel methods and novel devices for acquiring the solid potential energy natural energy of the circumference. The circumferential body with the shaft and the circumferential body with the suspension can make the circumferential body stably run, and the power is effectively transmitted. The potential energy force can be infinitely increased by the counterweight circumference body and the external force circumference body. Overcoming the prejudice of the known technology. Provides sufficient clean and low-cost new energy for human beings. The defects of limited fossil energy source quantity, high cost and serious pollution are avoided. The carbon emission target of human beings is achieved. The natural energy is ubiquitous, is never exhausted, is more convenient and simpler than the traditional energy, is more practical, and has lower cost.

4. The accompanying drawings illustrate and examples. The invention is further described below with reference to the drawings and examples.

FIGS. 1-12 are schematic axial circumferential views; FIGS. 13-16 are schematic views of the structure of the suspension and the upper, middle and lower gears;

FIGS. 17-18 are schematic views of the circumference of a cylinder; FIGS. 19-24 are schematic views of three relief structures;

FIGS. 25-26 are schematic views of magnetic flywheel structures; FIGS. 27-28 are schematic illustrations of sprocket constructions;

FIGS. 29-30 are schematic views of a vertical sleeve configuration; fig. 31-32 are schematic illustrations of the structure of the stamping gears.

Fig. 1 is a right side view of fig. 2. The center of the gear 1 is provided with a shaft, which is a circumference body with a shaft, and 2 is a shaft. The centers of the gears, the wheels and the belt pulleys are all provided with shafts, and the gears, the wheels and the belt pulleys can be all the circumference bodies with shafts. The intermediate gear 26 of the present invention is an axially circumferential body. The mandrel circumferential body runs stably, and accessories such as a suspension, a counterweight or external force are easy to set.

Fig. 3 is a right side view of fig. 4, the circumferential body with the shaft is a well-known cam, and the cam 3 is centered on the shaft 4. The cam mounted on the suspension is driven by the power to press down the elastic lever or pedal which can be automatically returned to reciprocate up and down, so that potential energy force can be output. The pedal is a plate-like object. The cam 3 is a one-tooth gear. The cam 3 may instead be a plurality of teeth, concave-convex, which like a gear wheel moves on a lever with a suspension.

Fig. 5 is a right side view of fig. 6, and the eccentric may be an off-axis circumferential body. 5 is a wheel, 6 is a spindle, and 7 is an off-axis. The eccentric wheel arranged on the suspension can be driven by a power generation force, and the other circumference body is driven to reciprocate by the connecting rod to output potential energy force. The eccentric wheel arranged on the suspension can be driven by a power to press down the elastic lever or pedal which can automatically return to reciprocate up and down.

Fig. 7 is a right side view of fig. 8. The circumference body 8 is an internal gear, and the inner circumference of the circumference body is provided with 4 gears 9; the gear 9 is connected with the engine base or the power generation or the energy or the transmission shaft through a shaft; the gear 9 can be driven by a power transmission or a circumferential body 8, or the circumferential body 8 and/or a limiting circumferential body 8 are/is driven; the power-driven circumferential body 8 drives the gear 9 to output power. Or, the gear 9 and/or the gear 10 are/is connected with the engine base or the power generation or the energy body or the transmission shaft or the transmission device through a shaft; the energy-using body refers to an object using energy, and comprises a lathe, a water pump, a generator, a ball mill, a coupling or a transmission shaft. The machine base and the energy consuming body are omitted in the figure. The gear 9 or the gear 10 can be driven by power or the circumference body 8, and can drive the circumference body 8 and/or the limit circumference body 8. The gear 9 and the gear 10 can have a gap or/and elasticity with the circumference body 8, the circumference body 8 can move up and down and left and right slightly relative to the gear 9 and the gear 10, and the moving range can be set to be about one millimeter. Other methods or devices can be used to move the circumferential body 8 slightly up and down, left and right relative to the gears 9 and 10. The power is transmitted to the circumference body 8 through the gear 9 or the gear 10, the circumference body 8 drives the other gear 9 or/and the gear 10, and the power is output. Or the power is driven to drive one gear 9 or gear 10 to drive the circumference body 8, and the circumference body 8 drives the other gear or gears 9 or gear 10 to output power. Alternatively, the circumferential body 8 has internal or/and external teeth, and has one or more gears 9 on its inner periphery and one or more gears 10 on its outer periphery. In fig. 7, 4 gears 10 are distributed on the outer periphery of the circumferential body 8. One or more gears 9 and/or 10 may be provided on the inner periphery or/and outer periphery of the circumferential body 8. Or the power is driven to drive one of the gears 9 or the gears 10 to drive the circumference body 8, and the circumference body 8 drives the other one or more gears 9 and the gears 10 to output power to the energy utilization body. Or, an inner ring gear 11 is arranged in a similar known bearing structure, and a center shaft 12 is arranged at the center of the inner ring gear 11. The gear wheel 9 is located between the inner ring gear 11 and the circumferential body 8. The circumference body 8 is similar to an outer ring of a bearing and rotates around the gear 9, an inner ring gear 11 is further arranged, and the gear 9 is positioned between the inner ring and the outer ring; or, the inner ring gear 11 is provided with a central shaft 12, one end of the central shaft 12 is connected with the inner ring gear 11, and the other end is connected with an energy body; the power is generated to drive the circumference body 8 or the gear 9 or the gear 10 to drive the central shaft 12 to output power; alternatively, a plurality of circumferential bodies 8 are axially combined with the gear 9 or/and the gear 10, and the potential energy force of the former is the next motive force. Alternatively, the transmission structure of the circumferential body 8, the gear 9 and the gear 10 may be a well-known gear transmission structure or a friction wheel transmission structure or a magnetic transmission structure. Or, friction wheel transmission is combined with gear transmission. For example, the outer periphery of the circumferential body 8 is friction-driven and the inner periphery is gear-driven. The inner or outer periphery refers to the inner and outer vicinity of the periphery of the circumferential body 8. Alternatively, the gear 9 and/or the gear 10 may change position on the circumferential body 8.

Fig. 10 is a cross-sectional view A-A of fig. 9. The circumferential body 13 is in the shape of a circular cake. The circumferential body 13 may have a cylindrical shape or a circular ring shape or a cylindrical shape. Three small wheels 15 are clamped in grooves on one side of the circumference body 13 and are in friction transmission with the circumference body 13. The small wheel 15 has limiting or/and transmission function, and the small wheel 15 is connected with a stand or a suspension or power generation or energy utilization; the frame, suspension, motive force and energy consuming structure are omitted from the figure. The power is generated to drive one or more small wheels 15 to rotate, at least one small wheel 15 is connected with the energy utilization body, and power is output; alternatively, the inner periphery or/and the outer periphery of the circumferential body 13 has one or more small wheels 15; or, the power is driven by a known friction transmission or magnetic transmission or gear transmission or chain wheel transmission to drive the circumference body 13, the circumference body 13 drives the other small wheel or wheels 15 to rotate, at least one small wheel 15 is connected with the energy utilization body, and power is output; or, the power is generated to drive at least one small wheel 15, the small wheel 15 drives the circumference body 13, the circumference body 13 drives the other small wheels 15, and power is output; or, the spindle 14 passes through the center shaft hole of the circumference body 13 and is arranged on the suspension or the stand, so that the circumference body 13 is limited and supported; the circumferential body 13 rotates around the spindle 14; the power is generated to drive one or more small wheels 15 to rotate, at least one small wheel 15 is connected with an energy utilization body shaft, and power is output; or, the mandrel 14 is fixedly connected with the circumference body 13 and the energy utilization body, and the power is output by driving the small wheel 15 by the power; or the circumference body 13 is fixed on a suspension or a stand, a gap or elasticity is formed between the circumference body and the mandrel 14, and the mandrel 14 can move up and down and left and right in the shaft hole in a small way; the range of motion can be set to about one millimeter. Or conversely, the spindle 14 is fixed on the suspension or the stand with a gap or elasticity between the spindle and the stand, and the circumference body 13 can move slightly up and down, left and right relative to the spindle 14. Or, the small wheel 15 and the mandrel 14 limit the circumference body 13 together; alternatively, the small wheel 15 may change position on the circumferential body 13; or, the circumference body 13 or the small wheel 15 is arranged on a suspension; alternatively, a well known internal gear drive or a hole wheel drive or a sprocket drive may be employed.

Various transmission structures and methods may be used in combination. For example, the outer periphery of the circumferential body 13 is in friction wheel transmission, and the inner periphery of the circumferential body 13 is in gear transmission. Or vice versa, the outer periphery of the circumferential body 13 is geared, and the inner periphery of the circumferential body 13 is friction-wheel-driven.

Fig. 12 is a cross-sectional view A-A of fig. 11. Fig. 11 omits the housing 21. The circumference body 17 is in a shape of a circular basin, and is provided with a limiting shaft 16 which is fixedly connected with the stand 21 to play a role in positioning. The limiting shaft 16 is movably connected with a friction wheel. The output shaft 18 is fixedly connected with a friction wheel. The output shaft 18 is connected to the power utilization body. The input shaft 19 is fixedly connected with a friction wheel. The power drives the input shaft 19, and friction wheels on the input shaft 19 rub against the peripheral inner wall of the peripheral body 17, and the peripheral body 17 rotates relative to the stand 21. The peripheral inner wall of the circumferential body 17 rubs against the friction wheel on the limit shaft 16 and the output shaft 18, and the friction wheel of the limit shaft 16 rotates along with the friction wheel to idle. The friction wheel of the output shaft 18 drives the energy body to output power. All friction wheels are omitted from the figure. Or, the center of the circumference body 17 is provided with a mandrel 20 which is movably connected with the circumference body 17 and the stand 21. The spindle may be provided with bearings. The spindle 20 and the limiting shaft 16 may co-locate the circumferential body 17. The circumference 17 and the mandrel 20 may have a gap or elasticity, and the circumference 17 may be movable up and down, left and right with respect to the mandrel 20. The elasticity is from elastic materials or springs or elastic devices. Or the spindle 20 is fixedly connected with the circumferential body 17 to replace the output shaft 18 outputting power. The action of the limiting shaft and/or the output shaft and/or the input shaft and/or the position on the circumferential body 17 can be varied as desired. Such as changing the limiter shaft 16, the output shaft 18, and the input shaft 19 to the limiter shaft 19, the output shaft 16, and the input shaft 18. Or, the position of the limiting shaft 16 or/and the output shaft 18 or/and the input shaft 19 is/are changed at the inner periphery of the circumference body 17; or, the position of the limiting shaft or/and the output shaft or/and the input shaft is changed at the outer periphery of the circumferential body 17; or, the inner periphery or/and the outer periphery of the circumferential body 17 is/are provided with one or more limiting shafts or/and output shafts or/and input shafts; alternatively, the friction wheel transmission can be a known gear transmission or a tooth hole wheel transmission or a magnetic transmission chain wheel transmission. The chain, namely a chain wheel, is arranged on the inner periphery of the circumference body 17 and is driven by the chain wheel.

Fig. 13 is a plan view of fig. 15, in which the intermediate gear 26, the lower gear 27, the motor 33, and other components are omitted. This is a three gear engine with upper gear 25 and pulley 34 mounted on upper gear shaft 24. An upper gear shaft 24 is mounted on the car bar 23. The car bar 23 is mounted on the frame 22. Pulley 34 receives the motive power transmission. Four cable-stayed springs 35 with limiting function or/and reinforcing function or/and vibration damping function are arranged between the upper gear shaft 24 and four corners of the stand 22.

Fig. 14 shows a left side view of the upper gear, upper gear shaft and pulley 34 in fig. 13, with the remaining components omitted.

In fig. 15, the stand 22 may be divided into an upper stand and a lower stand. The upper and lower seats together form a housing 22. The upper seat can be a suspension. Figure 15 shows an upper seat to lower seat interface 29. The bottom edge of the upper seat may also extend downwards, for example up to the ground. The upper gear 25, the middle gear 26 and the lower gear 27 are arranged up and down to sequentially drive. The lower gear 27 is mounted on a lower gear seat 30. The motor 33 drives the upper gear 25 to drive the middle gear 26 and the lower gear 27 through the belt 32 to drive the belt pulley 34 and the upper gear shaft 24 to output power. There are 4 oblique tension springs 35 and a lower tension spring 36. The oblique tension spring 35 does not affect the downward gravity release of the upper gear 25 and the middle gear 26. A diagonal spring 35 having a limiting effect or/and a reinforcing effect or/and a vibration damping effect is installed between the upper gear shaft 24 or the middle gear shaft 31 and the frame of the machine base 22. The oblique tension spring 35 and the lower tension spring 36 may be installed between the suspension and the stand. The upper gear 25 is located near the vertical center line above the middle gear 26; the intermediate gear 26 is located near the vertical centerline above the lower gear 27. Or, the upper gear 25 is located above the middle gear 26 to deviate from the vertical center line by 10 mm or more; the intermediate gear 26 is located 10 mm or more above the lower gear 27 from the vertical center line. A reasonable fulcrum position is important. A reasonable fulcrum position need not be on or near the vertical center line, and needs to be determined according to the specific situation. The engagement point of the upper gear 25 with the intermediate gear 26 is the fulcrum of the upper gear 25 as it moves over the intermediate gear 26. The point of engagement of the intermediate gear 26 with the lower gear 27 is the fulcrum of the intermediate gear 26 as it moves over the lower gear 27. An upper gear 25 dome drive middle gear 26; the intermediate gear 26 dome drives the lower gear 27. The upper gear 25 can roll obliquely upward with the car bar 23 on the inclined surface of the middle gear 26. The middle gear 26 can roll obliquely upwards on the inclined surface of the lower gear 27 with the car bar 28; the rotating upper gear 25 can move slightly back and forth and down relative to the middle gear 26 and/or the housing. The rotating intermediate gear 26 can move slightly back and forth and back and forth relative to the lower gear 27 and/or the housing. An iron block counterweight 38 is suspended from the intermediate gear shaft 31 by a wire rope 37. A fixed sheave 39 changes the direction or position of the hanging weight. The counterweight 38 is a movable counterweight that is movably connected and is also a hanging counterweight. There may also be stationary weights fixedly connected, i.e. weights fixed on the suspension or the circumferential body shaft. The weight 38 is disposed along the horizontal or forward-downward direction of the body without affecting the downward gravity release of the body. The upper gear 25, the middle gear 26 and the suspension may be provided with weights and/or external forces. The potential force of the upper gear 25 is the motive force of the intermediate gear 26. The force of the upper gear 25 driving the middle gear 26 is much less than the potential energy force of the middle gear 26 in motion; the potential energy force generated by the gravity and the external force of the middle gear 26 in the motion is far greater than the resistance of the lower gear 27. The potential energy force which is larger than the power can be obtained by driving a suspension circumferential body or a counterweight circumferential body or an external force circumferential body which is positioned on a reasonable fulcrum, and the potential energy restoring force is far smaller than the potential energy force. The circumference body or the suspension can be provided with a spring or/and an elastic device with a positioning function or/and a vibration reduction function or/and a reinforcement function, and the elasticity comprises the elasticity of the component material; the elastic device comprises an elastic device or an air pressure or hydraulic device which is made of elastic materials. The weight on the intermediate gear 26 and the external force and the fulcrum position on the lower gear 27 determine the magnitude of the potential energy force of the intermediate gear 26 without taking account of the motive force. Namely: the potential energy force of the intermediate gear 26 is mainly determined by the balance weight on the intermediate gear 26 and the external force and the fulcrum position of the external force on the lower gear 27. Weights and external forces on the intermediate gear 26 may be provided as desired. The weight and external force on the intermediate gear 26 and the location of its fulcrum determine how much the weight on both sides of the gravitational plane of the intermediate gear 26 is different. Therefore, the upper gear 25 can easily overcome the resistance of the middle gear 26. The drag of the intermediate gear 26 includes the static inertial force of the intermediate gear 26, such as the gravitational force. The upper gear 25 can easily drive the middle gear 26 to roll obliquely upwards on the inclined surface of the lower gear 27 together with the car bar and the counterweight, and power is transmitted to the lower gear 27 to output potential energy force of the middle gear 26. Therefore, the force with which the upper gear 25 drives the middle gear 26 (i.e., the force with which the upper gear 25 recovers the potential energy of the middle gear 26) is much smaller than the potential energy force generated by the middle gear 26 in motion. Since the potential force generated by the dead weight of the middle gear 26 and the counterweight and the external force in the motion is far greater than the resistance of the lower gear 27, the reaction force (i.e., resistance) of the lower gear 27 is instantaneously and easily overcome (i.e., depressed) by the potential force of the middle gear 26 as soon as one tooth on the middle gear 26 is in contact with one tooth on the lower gear 27. The last tooth has just been depressed to turn, the next tooth is again attached, and the cycle repeats. The intermediate gear 26 is thus constantly alternating in turn the fulcrum and the resistance point on the lower gear 27. Before the movement, the middle gear 26 takes the engagement point as a fulcrum, and the car bar is a resistance point. When one or several teeth of the intermediate gear 26 are pressed down (driven) by one or several teeth of the lower gear 27 during movement, the car bar is a fulcrum and the engagement point is a resistance point. The engagement point is a resistance point and also a fulcrum, and the two points are coincident. The car bar and the engaging point are continuously and angularly exchanged during movement, and the engaging point is a fulcrum at the moment when the upper tooth and the lower tooth are just contacted and then becomes a resistance point. In the transmission, the middle gear 26 moves slightly up and down in front of and behind each other between the adjacent two teeth along with the contact and separation of the upper and lower teeth; i.e. the rotating intermediate gear 26 produces small movements, i.e. regular vibrations, up and down on the lower gear 27. The amplitude can be controlled within 1 mm. Vibration damping means such as vibration damping springs may be provided to prevent and reduce unwanted vibrations. The upper gear 25 is dome-driven at the middle gear 26, and the middle gear 26 is most labor-saving dome-driven at the lower gear 27. The force imparted by the intermediate gear 26 to the lower gear 27 is greater than the force imparted by the upper gear 25 to the intermediate gear 26. Or, the intermediate gear shaft 31 is provided with a driven gear, a driven pulley or a coupling, and directly receives the power transmission. This eliminates the need for the upper gear 25 and its components. The driven gear refers to the gear that receives the transmission. Or, the diameter of the upper gear 25 is smaller than that of the middle gear 26; alternatively, the diameter of the intermediate gear 26 is smaller than the diameter of the lower gear 27. The gear may also be a sprocket or friction wheel or a sprocket.

Fig. 16 is a schematic diagram of a frame structure of the upper gear car bar 23 or the middle gear car bar 28, in which two square tubes with two lengths and four lengths are connected in a frame shape. The car bar 23 can also be made of round tubes or channel steel or steel bars. The car bar 23 is a type of suspension. The upper gear shaft 24 or the middle gear shaft 31 may be mounted to the car bar using known bearings and bearing blocks. The two ends of the car bar can be provided with sliding sleeves or sliding grooves or vertical sleeves 61 which are movably connected with the machine base 22 and can move slightly up and down relative to the machine base 22. The middle gear car bar 28 has the same structure as the upper gear car bar 23, and the use method can be the same. Or, a gap or/and elasticity is arranged between the suspension and the stand, and the moving circumferential body can move back and forth and down slightly in a certain range relative to the stand by the suspension; or, the upper dead point or/and the lower dead point or/and the limit spring limit the movable range of the circumference body or/and the suspension.

The suspension is a mechanism for installing the circumference body, and is movably connected with the machine base. The suspension can be flat, grid, frame or tubular or bar, and has elasticity. The elasticity can help the suspension to return or act as an external force on the suspension; the elasticity may come from springs or/and elastic means; the elastic device comprises a pneumatic or hydraulic elastic device. The movable connection comprises a gap or/and elasticity at the joint, and the moving circumferential body can move up and down in a certain range relative to the stand by taking the suspension. Limiting devices such as an upper dead point or/and a lower pivot point or/and a limiting spring can be arranged to limit the front-back and lower movable range of the cylinder or the suspension. The circumference body is arranged on the suspension, is in a suspended state in motion, and stably and efficiently transmits potential energy force. The flat plate is a flat plate, and the circumference body is arranged on the flat plate. The tubular shape is a round tube, a square tube or a flat tube. The rod shape is a round rod or a square rod flat rod. Alternatively, the suspension may be provided with a counterweight or/and an external force; or the suspension comprises a cantilever, a inclined frame, a vertical frame, a suspension arm, an upper seat or a car lever; the cantilever is similar to an arm of a person, one end of the cantilever is provided with a circumference body, and the other end of the cantilever is movably connected with the machine base. The inclined frame refers to the non-horizontal and non-vertical installation of the suspension on the stand. The vertical frame refers to the suspension frame which is vertically arranged. The suspension arm is hung on the machine base. The upper seat refers to the machine seat which is divided into an upper part and a lower part or multiple parts, and the upper seat is positioned above the machine seat. The cantilever or the inclined frame or the vertical frame or the suspension arm can be directly changed by adopting the frame structure of the car bar 23. Alternatively, the circumferential body may be movable relative to the suspension.

The potential energy force of the circumferential body refers to the power generated by the circumferential body in the motion. The potential energy force of the circumference is the circumference power. Potential energy force of the circumference body is the motion inertia force of the circumference body; the potential energy force of the circumferential body refers to the total force of the movement of the circumferential body, and the total force comprises a power force and the gravity force or/and the torsion force of the circumferential body or/and the magnetic force or/and the elastic force arranged on the circumferential body and the suspension; the gravity comprises the gravity of the circumference body or/and the gravity arranged on the circumference body, and the torsion comprises the movement torsion and the material torsion of the circumference body; the magnetic force comprises electromagnetic force or magnet repulsive force. The electromagnetic force comprises the attractive and repulsive force of an electromagnet. The elastic force comprises the elastic force of an elastic material or/and the elastic force of a spring or/and the elastic force of an elastic device; the gear can also be a chain wheel, and the chain wheel are driven to replace two gears.

The application has a plurality of different explanations and definitions for the circumference body from different angles, and is not contradictory. The circumference is an upper concept, an abstract concept and a specific object in application. The circumferential body is to be set or identified according to the specific circumstances. Such as gears or wheels or cylinders, may be circumferential. All the objects or devices capable of amplifying the power are circumferential bodies. Or, the reasonable pivot comprises a reasonable gravity plane, a relatively longest power arm or a relatively shortest resistance arm; or, all objects with reasonable supporting points are the circumference body of the application; or alternatively, the first and second heat exchangers may be,

The movable connection comprises well-known shaft hole connection or buckle connection or sliding sleeve connection or sliding groove connection. The shaft hole connecting finger member is provided with a hole and a shaft, and the shaft can move in the shaft hole. Or vice versa, the holes may be movable about an axis. The scissors and the pliers are movably connected with each other through shaft holes. The clamping finger mechanism is provided with a clamp or a buckle, and the clamp and the buckle can move relatively. The rear box plate of the automobile can be conveniently taken down, namely, the automobile is movably connected by a buckle. The sliding sleeve connecting finger shaft can rotate or slide in the sleeve, and the sleeve can also rotate or slide on the shaft. The hinge on the door is a movable connection of the shaft sleeve. The shaft sleeve can be axially movably connected. The bolt is axially movably connected when being pushed and pulled in the gun chamber. The sliding groove is connected with the finger ribs and slides in the grooves. The sliding door of the automobile is connected with the sliding groove. The movable connection can also be that the connection part has a gap or/and elasticity, and the upper gear 25 or the middle gear 26 or the suspensions 23 and 28 can slightly move up and down relative to the stand 22.

Fig. 17 is a right side view of fig. 18. The roller 40 is near the vertical centerline above the fulcrum wheel 41. Below the drum 40 there may be one or more fulcrum wheels 41, the fulcrum wheels 41 being co-axial with the drum and rotating with the drum. Alternatively, the fulcrum wheel 41 is located at or near the vertical centerline below or beneath the drum 40; the fulcrum wheel 41 may be mounted on a ground base. A plurality of auxiliary wheels 42 are mounted on the frame 43 near the horizontal center line of the drum 40, and the auxiliary wheels 42 assist the drum 40 in smoothly rotating or restraining the drum 40. The auxiliary wheel 42 may also be located below the horizontal centerline of the drum 40 or near the fulcrum wheel 41. There may be one or more auxiliary wheels 42 distributed around or under the drum 40, the weight of the drum 40 mainly falling on the fulcrum wheel 41, the auxiliary wheels 42 assisting the fulcrum wheel 41 in bearing the weight; a drive wheel 44 is mounted on the housing 43 for rotation of the dome drive roller 40. The gravity on both sides of the gravity surface of the drum 40 is equal or similar. The drum 40 is mounted on a suspension, and may be provided with a weight and/or an external force. The suspension is mounted on the foundation 43 or on a ground base. Or, the suspension is movably connected with the stand 43; one or more housings 43 are mounted downstream on either side or the circumference of the drum 40. A cross brace 45 is provided to connect two or more frames 43 together. The machine base 43 can be provided with a roller limiting device; or, the motive force drives the drum at the dome or upper or peripheral portion of the drum; or, a gap or elasticity is formed between the two ends of the roller 40 and the machine base 43 or the roller is movably connected with the machine base 43; or, a gap or elasticity is formed between the bearing seats at the two ends of the roller 40 and the machine seat 43 or is movably connected with the machine seat 43; or, the fulcrum wheel 41 is mounted on the stand or on the ground foundation; alternatively, the drive wheel 44 is mounted on a suspension with a weight and/or external force thereon; alternatively, the roller 40 is located at or near the vertical centerline above or over the fulcrum wheel 41; or, this may occur; the fulcrum wheel 41 is positioned below or below the roller 40 at a position outside the vertical center line or 5 mm or more or 10 mm or more or 15 mm or more from the vertical center line; or, the roller 40 is located at a position above or above the fulcrum wheel 41, outside the vertical center line or 5 mm or more or 10 mm or more or 15 mm or more from the vertical center line; or, this may occur; the gravity of the two sides of the gravity surface of the roller 40 is equal or similar; or the gravity on both sides of the gravity surface of the roller 40 is not equal; or the gravity on both sides of the gravitational plane of the drum 40 is not equal, the gravity in front of the movement is greater than the gravity in back or the gravity in front of the movement is less than the gravity in back. Or, the fulcrum wheel 41 is a gear or a friction wheel or a gear hole wheel or a magnetic wheel chain wheel; alternatively, the drum 40 is a ball mill or dryer or agitator drum; or, the drum of the ball mill or dryer or mixer is located on the suspension or/and on the fulcrum wheel 41 or with a power generation device; or, the fulcrum wheel 41 is provided with a belt pulley or a friction wheel or a gear or a coupling on a shaft, and the power generator is driven to generate power; or the fulcrum wheel 41 drives the generator to generate electricity through a belt pulley, a friction wheel, a gear or a coupling; or, the roller 40 is provided with a gear, a belt pulley, a chain wheel or a friction wheel, and drives a generator to generate electricity; alternatively, the amount of power output by the drum 40 may far exceed the amount of power input. Or, the circumference is a roller 40 mounted on a hanger; alternatively, the drum 40 may be a cylinder. The fulcrum position of the drum 40 on the fulcrum wheel 41 can be appropriately adjusted according to the gravity distribution condition of the drum 40 and the moment arm condition of the drum 40 on the fulcrum wheel. A reasonable fulcrum position should be one that can maximize the moment arm of the circumferential body or create a reasonable plane of gravity or maximally release the potential energy of the circumferential body, so a reasonable fulcrum position need not be on or near the vertical center line and needs to be determined according to the particular situation.

Fig. 19 is a right side view of fig. 20. The circumference of the cylinder 46 carries 4 bumps 47. The bump 47 is a kind of concave-convex. The bump 47 pushes a lever or a link or a piston or a pedal having a return function to reciprocate and output power.

Fig. 21 is a right side view of fig. 22. The circumference of the cylinder 48 is provided with 4 ribs 49. The bead 49 is a kind of concavity and convexity. The rib 49 pushes a lever or a connecting rod or a piston or a pedal with a return function to make the lever or the connecting rod or the piston or the pedal reciprocate, and power is output. The ribs 49 may also be wheels. The turning wheel is a kind of concave-convex rotatable, and is mounted on the circumferential surface of the cylinder 48.

Fig. 23 is a right side view of fig. 24. The cylinder 50 has 4 serrations 51 around its circumference. The saw tooth 51 is a kind of concave-convex. The concave-convex push lever or connecting rod or driving bar with return function can also act on the top end of piston or pedal panel to make it reciprocate and output power. The height of the concave-convex is the stroke of the cylinder doing work.

The circumference body can be a cylinder, one or more concave-convex parts can be arranged on the circumference surface of the cylinder, and the concave-convex parts comprise convex points or/and convex ribs or/and saw teeth or rotating wheels; the saw teeth refer to saw-tooth-shaped concave-convex parts; the rotating wheel can rotate and is arranged on the circumferential surface of the cylinder; the power drives the cylinder to reciprocate or roll or rotate, the concave-convex part transmits pressure to a stress point of a connecting rod or a lever or a transmission bar with an automatic return function, and potential energy force of the cylinder is output; or the cylinder is arranged on the suspension, and the power is used for driving the cylinder to reciprocate or/and rotate or/and roll, so that the gravity and torsion of the cylinder or/and the external force arranged on the cylinder are converted into circumferential body power; or, elastic means for positioning or/and vibration reduction or/and reinforcement are arranged around the cylinder, and the elastic means comprise elastic materials or/and springs or/and pneumatic or hydraulic means. The automatic return comprises a spring arranged on a connecting rod or a lever or a transmission bar. Or at least one lever or crankshaft or connecting rod in the potential energy area of the cylinder receives the drive of the concave-convex. The cylinder may be mounted on a stand or a suspension.

Fig. 26 is a left side view and a 1/4 angle section view of fig. 25. The magnetic flywheel 52 has a plurality of magnetic sensing points 53 around its circumference. The outer ring of the magnetic flywheel 52 is a stand 54, and the stand 54 is provided with a plurality of magnetic induction points 55 corresponding to the magnetic induction points 53 of the magnetic flywheel 52. Alternatively, one or more known electromagnets or magnet sensing devices, i.e., magnetic sensing points, may be provided on the circumference of the magnetic flywheel 52 and the housing 54. The two are mutually induced; when the magnetic flywheel 52 rotates, a magnetic induction point 53 on the magnetic flywheel 52 passes through a magnetic induction point 55 on the stand 54, and the magnetic induction point 55 on the stand 54 is controlled by a known relay or a commutator, so as to generate attraction or repulsion to the magnetic induction point 53 on the magnetic flywheel 52, and drive the magnetic flywheel 52 to rotate. Like the known motor stator and rotor, the repulsive force drives the rotor to rotate. The magnetic flywheel 52 corresponds to the rotor of the motor and the housing 54 corresponds to the stator of the motor. The magnetic flywheel 52 may be mounted on a frame or suspension and may assist or be powered. Or, the magnetic force circumference body is arranged on the motor shaft or the belt pulley shaft or the gear shaft or the generator shaft. Or, a flywheel or a magnetic flywheel is arranged between the power generation force and the energy utilization body; or the circumferential body shaft is provided with a flywheel or a magnetic flywheel.

Fig. 28 is a top view of fig. 27. The sprocket 58 is formed by two sheaves 56 sandwiching a chain 59. A plurality of pins 57 secure a chain 59 between the two cleats 56. A plurality of bolts 60 are provided to connect the two clamping plates 56 together. The circumference body can be a chain wheel, and the chain wheel can be cylindrical or circular plate-shaped or circular ring-shaped or gear-shaped; the transmission mode of the chain wheel and the chain wheel is similar to the gear transmission mode. The chain wheel has the characteristics of simple structure, easy processing and maintenance and low cost. Or the chain is linearly arranged on the flat plate, and the power is transmitted to drive the chain and the flat plate to reciprocate so as to output power.

Fig. 29 is a left side view of fig. 30. The vertical sleeve 61 has vertical holes 62 and 63 perpendicular to each other. The vertical sleeve 61 may act as a sliding sleeve for the suspension. For example, the car bar 23 or 28 is made of a circular tube, and two ends of the car bar are provided with 4 vertical sleeves 61, and the car bar is inserted into the vertical holes 62 and can slide back and forth. The vertical hole 63 is sleeved on a vertical hole shaft on the machine base and can move up and down. Therefore, the circumference body with the car bar can move up and down relative to the machine seat. The vertical bore axis is omitted from the figure.

Fig. 31 is a bottom view of fig. 32. The gear 64 is formed by axially combining 3 stampings 66. There are 4 bolts 65 securing 3 stampings 66 together. The gears can be radially decomposed and combined into the gears in a stamping part superposition mode. Or, a plurality of stamping parts axially or/and radially combine the belt pulleys; or, a plurality of stamping parts are axially or/and radially combined into a gear; or, a plurality of stamping parts are axially or/and radially combined into a circumference body, and the circumference body is spherical or cylindrical or round basin-shaped; alternatively, bolts 65 may be provided to secure the stampings together.

Claims

2. An engine or said motive force or said circumferential body or said circumferential movement or said potential energy force as claimed in claim 1, characterized by one of the following:

The circumference body is a belt pulley, and the belt pulley is arranged on a motor shaft or a generator shaft or a belt pulley shaft, or the belt pulley device comprises a machine seat, at least one belt pulley shaft arranged on the machine seat, and a driven belt pulley and a driving belt pulley which are arranged on the same belt pulley shaft; a plurality of belt pulleys with different diameters are combined with a high-speed motor and a low-speed generator, and the high-speed motor drives the plurality of belt pulleys with different diameters to drive the low-speed generator to generate power; or, the high-speed motor, the belt pulley device and the low-speed generator are combined to generate electricity; within the same time; or the power is used for driving the high-speed motor to drive the low-speed generator to generate electricity; or the motor is combined with the belt pulley device to drive the low-speed generator to generate electricity, or the belt pulley on the high-speed motor drives the driven belt pulley and the driving belt pulley on the belt pulley shaft, and the driving belt pulley drives the belt pulley on the low-speed generator shaft to generate electricity; or, the motor is combined with a plurality of belt pulley devices and a low-speed generator to generate electricity; or, the plurality of belt pulley devices are horizontally arranged or vertically arranged or overlapped and combined with the motor, and the motor drives the belt pulleys of the plurality of belt pulley devices to output power; or, the diameter of the pulley on the high-speed motor shaft is smaller than the diameter of the driven pulley; or, the driven belt pulley refers to a belt pulley which receives the transmission of the other belt pulley; the driving belt pulley points to the belt pulley which transmits the transmission to the other side; or the diameter of the driving pulley is smaller than that of the pulley of the low-speed generator; or the belt pulley is arranged on the suspension frame and positioned below the generator, and the belt drives the belt pulley of the generator upwards to generate electricity; or the belt pulley is arranged on the suspension, is positioned under the low-speed generator, is provided with a counterweight or/and external force, and drives the generator above to generate electricity; or, a belt pulley is arranged on the motor shaft and is arranged on the suspension to drive the belt pulley on the generator shaft to generate electricity; or, the belt pulley shaft is arranged on the suspension or/and provided with a counterweight or/and provided with an external force; or the transmission direction of the driving belt pulley is above the horizontal line; or the two belt pulleys are arranged obliquely above; or, the driven pulley is positioned above or higher than the driving pulley; or, a flywheel or a magnetic flywheel is arranged on the motor shaft or the belt pulley shaft or the generator shaft; or, the belt pulley on the belt pulley shaft or/and the motor shaft or the generator shaft is provided with a flywheel structure, and the belt pulley has the energy storage function; or, the diameter of the belt pulley on the shaft of the high-speed motor is larger than that of the belt pulley on the shaft of the low-speed generator, or is one time or more larger than that of the belt pulley; or, the diameter of the belt pulley on the shaft of the high-speed motor is larger than that of the driven belt pulley, or is one time or more larger than that of the driven belt pulley; or the diameter of the driving pulley on the pulley shaft is larger than that of the pulley on the low-speed generator shaft, or is one time or more larger than that of the driving pulley on the pulley shaft; the method comprises the steps of carrying out a first treatment on the surface of the Or, the diameter of the driving pulley is larger than that of the driven pulley, or is larger than that of the driven pulley by one time or more; or the diameter of the driving pulley on one pulley shaft is larger than that of the driven pulley, or is one time or more than one time larger than that of the driven pulley; or, the rotating speed of the high-speed motor is 600 or more than 900 or more than 1400 or more than 2000 or more than 2800; or, the rotating speed of the low-speed generator is 600 or less or 300 or less or 200 or less or 100 or less or 50 or 30 or less; or, the power of the motor is 2 times or more or 3 times or more than that of the generator, or, the belt pulley is arranged on the suspension, and the rotating speed of the motor is the same as or similar to that of the generator; or the rotating speeds of the motor and the generator are the same or similar; or, at least one belt pulley on the belt pulley device is a magnetic circumference body; or, the belt pulley is provided with magnetic force and is a magnetic force circumference body; or, a gap or/and elasticity is arranged between the belt pulley shaft and the shaft hole, and the belt pulley shaft can move up and down and left and right slightly relative to the shaft hole; or the shaft hole can move up and down, left and right slightly relative to the belt pulley shaft; or, the belt is a synchronous belt; or alternatively, the first and second heat exchangers may be,

3. The manufacturing approach of a kind of engine, characterized by that there is a motive force to drive at least one circumference body to take place the circular motion, output the potential energy force of the circumference body, the said motive force is the motive force to drive circumference body; the circumference body is an object which moves circularly; the potential energy force is the power generated by the circumference body in the motion; the circumferential body is a roller 40 mounted on a suspension.

4. A method of manufacturing as claimed in claim 3, wherein said engine or said motive force or said circumferential body or said circumferential movement or said potential energy force is one of:

The circumference body is a belt pulley, and the belt pulley is arranged on a motor shaft or a generator shaft or a belt pulley shaft, or the belt pulley device comprises a machine seat, at least one belt pulley shaft arranged on the machine seat, and a driven belt pulley and a driving belt pulley which are arranged on the same belt pulley shaft; the high-speed motor drives the plurality of belt pulleys with different diameters to drive the low-speed generator to generate power, or the high-speed motor, the belt pulley device and the low-speed generator are combined to generate power; or the power generation force drives the high-speed motor to drive the low-speed generator to generate power, or the motor is combined with the belt pulley device to drive the low-speed generator to generate power, or the belt pulley on the high-speed motor drives the driven belt pulley and the driving belt pulley on the belt pulley shaft, and the driving belt pulley drives the belt pulley on the low-speed generator shaft to generate power; or, the motor is combined with a plurality of belt pulley devices and a low-speed generator to generate electricity; or, the plurality of belt pulley devices are horizontally arranged or vertically arranged or overlapped and combined with the motor, and the motor drives the belt pulleys of the plurality of belt pulley devices to output power; or, the diameter of the pulley on the high-speed motor shaft is smaller than the diameter of the driven pulley; or, the driven belt pulley refers to a belt pulley which receives the transmission of the other belt pulley; the driving belt pulley points to the belt pulley which transmits the transmission to the other side; or the diameter of the driving pulley is smaller than that of the pulley of the low-speed generator; or the belt pulley is arranged on the suspension frame and positioned below the generator, and the belt drives the belt pulley of the generator upwards to generate electricity; or the belt pulley is arranged on the suspension, is positioned under the low-speed generator, is provided with a counterweight or/and external force, and drives the generator above to generate electricity; or, a belt pulley is arranged on the motor shaft and is arranged on the suspension to drive the belt pulley on the generator shaft to generate electricity; or, the belt pulley shaft is arranged on the suspension or/and provided with a counterweight or/and provided with an external force; or the transmission direction of the driving belt pulley is above the horizontal line; or the two belt pulleys are arranged obliquely above; or, the driven pulley is positioned above or higher than the driving pulley; or, a flywheel or a magnetic flywheel is arranged on the motor shaft or the belt pulley shaft or the generator shaft; or, the belt pulley on the belt pulley shaft or/and the motor shaft or the generator shaft is provided with a flywheel structure, and the belt pulley has the energy storage function; or, the diameter of the belt pulley on the shaft of the high-speed motor is larger than that of the belt pulley on the shaft of the low-speed generator, or is one time or more larger than that of the belt pulley; or, the diameter of the belt pulley on the shaft of the high-speed motor is larger than that of the driven belt pulley, or is one time or more larger than that of the driven belt pulley; or the diameter of the driving pulley on the pulley shaft is larger than that of the pulley on the low-speed generator shaft, or is one time or more larger than that of the driving pulley on the pulley shaft; the method comprises the steps of carrying out a first treatment on the surface of the Or, the diameter of the driving pulley is larger than that of the driven pulley, or is larger than that of the driven pulley by one time or more; or the diameter of the driving pulley on one pulley shaft is larger than that of the driven pulley, or is one time or more than one time larger than that of the driven pulley; or, the rotating speed of the high-speed motor is 600 or more than 900 or more than 1400 or more than 2000 or more than 2800; or, the rotating speed of the low-speed generator is 600 or less or 300 or less or 200 or less or 100 or less or 50 or 30 or less; or, the power of the motor is 2 times or more or 3 times or more than that of the generator, or, the belt pulley is arranged on the suspension, and the rotating speed of the motor is the same as or similar to that of the generator; or the rotating speeds of the motor and the generator are the same or similar; or, at least one belt pulley on the belt pulley device is a magnetic circumference body; or, the belt pulley is provided with magnetic force and is a magnetic force circumference body; or, a gap or/and elasticity is arranged between the belt pulley shaft and the shaft hole, and the belt pulley shaft can move up and down and left and right slightly relative to the shaft hole; or the shaft hole can move up and down, left and right slightly relative to the belt pulley shaft; or, the belt is a synchronous belt; or alternatively, the first and second heat exchangers may be,