阅读说明：本技术 一种惯性动力循环转换发动机 (Inertial power cycle conversion engine ) 是由 张斗三 于 2020-07-25 设计创作，主要内容包括：一种惯性动力循环转换发动机包括电动机、第一转动轴、第一曲轴、第二曲轴、第一水罐、第二水罐、发电机及至少一个甩块；电动机通过第一转动轴与第一曲轴及第二曲轴传动连接,第一曲轴与第二曲轴的中心轴线重合设置,电动机用于驱动第一曲轴及第二曲轴做旋转运动,第一曲轴的旋转方向与第二曲轴的旋转方向相反；第一水罐及第二水罐各设置有密闭容置腔,密闭容置腔内装盛有流动液体,密闭容置腔的腔壁上设置有导流绕叶片,第一水罐与第一曲轴远离第二曲轴的一端相连接,第二水罐与第二曲轴远离第一曲轴的一端相连接,第一曲轴或第二曲轴上的连杆轴颈通过连接件与至少一个甩块相铰接；发电机与第一转动轴传动连接,发电机与电动机电连接。(An inertial power cycle conversion engine comprises a motor, a first rotating shaft, a first crankshaft, a second crankshaft, a first water tank, a second water tank, a generator and at least one throwing block; the motor is in transmission connection with the first crankshaft and the second crankshaft through a first rotating shaft, the central axes of the first crankshaft and the second crankshaft are overlapped, the motor is used for driving the first crankshaft and the second crankshaft to rotate, and the rotating direction of the first crankshaft is opposite to that of the second crankshaft; the first water tank and the second water tank are respectively provided with a closed containing cavity, flowing liquid is contained in the closed containing cavity, a diversion wound blade is arranged on the wall of the closed containing cavity, the first water tank is connected with one end, far away from the second crankshaft, of the first crankshaft, the second water tank is connected with one end, far away from the first crankshaft, of the second crankshaft, and a connecting rod journal on the first crankshaft or the second crankshaft is hinged with at least one throwing block through a connecting piece; the generator is in transmission connection with the first rotating shaft and is electrically connected with the motor.)

1. An inertial power cycle conversion engine, comprising: the water pump comprises a motor, a first rotating shaft, a first crankshaft, a second crankshaft, a first water tank, a second water tank, a generator and at least one throwing block;

the motor is in transmission connection with the first crankshaft and the second crankshaft through the first rotating shaft, the central axis of the first crankshaft is overlapped with the central axis of the second crankshaft, the motor is used for driving the first crankshaft and the second crankshaft to rotate, and the rotating direction of the first crankshaft is opposite to that of the second crankshaft;

the first water tank and the second water tank are respectively provided with a closed accommodating cavity, flowing liquid is filled in the closed accommodating cavity, a diversion winding blade is arranged on the wall of the closed accommodating cavity, the first water tank is connected with one end, far away from the second crankshaft, of the first crankshaft, the second water tank is connected with one end, far away from the first crankshaft, of the second crankshaft, a connecting rod journal on the first crankshaft or the second crankshaft is connected with a force arm, and the force arm is hinged with at least one throwing block through a connecting piece;

the generator is in transmission connection with the first rotating shaft and is electrically connected with the motor.

2. The inertial power cycle conversion engine of claim 1 wherein the linkage includes two oppositely disposed clamp blocks, one end of the thrower block is hingedly connected between the two clamp blocks by a pivot, and the end of the two clamp blocks remote from the thrower block is connected to the moment arm.

3. The inertial power cycle conversion engine of claim 2, further comprising a fixing rod disposed at one side of the throwing block, wherein two ends of the fixing rod are connected to the two clamping blocks, respectively, and the fixing rod abuts against the throwing block when the throwing block rotates in a direction approaching the fixing rod.

4. The inertial power cycle conversion engine of claim 1 wherein each of said throws are connected in series.

5. The inertial power cycle conversion engine of claim 1 wherein the thrower is spherical.

6. The inertial power cycle conversion engine of claim 1, wherein the cross-section of the first water tank and the second water tank is a rotationally symmetric pattern.

7. The inertial power cycle conversion engine of claim 6, wherein the number of the flow guide vanes is multiple, and each flow guide vane is rotationally symmetrically arranged in the sealed accommodating cavity around a geometric axis of the sealed accommodating cavity.

8. The inertial power cycle conversion engine of claim 1, wherein a pulley is connected to the first rotating shaft, and the electric motor and the generator are each drivingly connected to the pulley by a belt.

9. The inertial power cycle conversion engine of claim 1, wherein the first and second water tanks are hollow cones or cylinders.

10. The inertial power cycle conversion engine of claim 1, wherein the number of said first water tanks and said second water tanks is plural, each of said first water tanks being disposed at intervals, and each of said second water tanks being disposed at intervals.

Technical Field

The invention relates to the technical field of power conversion, in particular to an inertial power cycle conversion engine.

Background

The conventional motor needs to input electric energy continuously from the outside to maintain a working state. The traditional motor has a plurality of short plates, and after the electric energy is converted into other forms of energy by the motor, the other forms of energy are difficult to recycle, so that the electric energy consumption is large; secondly, under the condition that the motor is suddenly powered off, the motor can immediately stop rotating, and production and operation are affected.

Disclosure of Invention

Based on this, it is necessary to provide an inertia power cycle conversion engine to solve the above technical problems.

An inertial power cycle conversion engine comprising: the water pump comprises a motor, a first rotating shaft, a first crankshaft, a second crankshaft, a first water tank, a second water tank, a generator and at least one throwing block;

the motor is in transmission connection with the first crankshaft and the second crankshaft through the first rotating shaft, the central axis of the first crankshaft is overlapped with the central axis of the second crankshaft, the motor is used for driving the first crankshaft and the second crankshaft to rotate, and the rotating direction of the first crankshaft is opposite to that of the second crankshaft;

the first water tank and the second water tank are respectively provided with a closed accommodating cavity, flowing liquid is filled in the closed accommodating cavity, a diversion winding blade is arranged on the wall of the closed accommodating cavity, the first water tank is connected with one end, far away from the second crankshaft, of the first crankshaft, the second water tank is connected with one end, far away from the first crankshaft, of the second crankshaft, a connecting rod journal on the first crankshaft or the second crankshaft is connected with a force arm, and the force arm is hinged with at least one throwing block through a connecting piece;

the generator is in transmission connection with the first rotating shaft and is electrically connected with the motor.

In one embodiment, the connecting piece comprises two oppositely arranged clamping blocks, one end of the swinging block is hinged between the two clamping blocks through a pivoting piece, and one end, far away from the swinging block, of the two clamping blocks is connected with the force arm.

In one embodiment, the centrifugal pump further comprises a fixing rod, the fixing rod is arranged on one side of the throwing block, two ends of the fixing rod are respectively connected with the two clamping blocks, and when the throwing block rotates towards the direction close to the fixing rod, the fixing rod is abutted to the throwing block.

In one embodiment, each of the flail blocks is connected in sequence.

In one embodiment, the slinger is spherical.

In one embodiment, the cross-section of the first water tank and the second water tank is a rotationally symmetric pattern.

In one embodiment, the number of the flow guiding surrounding blades is multiple, and each flow guiding surrounding blade is rotationally and symmetrically arranged in the closed accommodating cavity around the geometric axis of the closed accommodating cavity.

In one embodiment, a pulley is connected to the first rotating shaft, and the motor and the generator are respectively in transmission connection with the pulley through a belt.

In one embodiment, the first and second water tanks are hollow cones or cylinders.

In one embodiment, the number of the first water tanks and the second water tanks is multiple, each of the first water tanks is arranged at intervals, and each of the second water tanks is arranged at intervals.

The beneficial effect of this application is:

the motor drives the first rotating shaft to rotate the first crankshaft and the second crankshaft, the first crankshaft and the second crankshaft are arranged on the same central axis, the rotating directions of the first crankshaft and the second crankshaft are opposite, and then torques generated when the first crankshaft and the second crankshaft rotate can be mutually offset, so that the first crankshaft and the second crankshaft can keep balance when rotating;

the first crankshaft and the connecting rod journal of the first crankshaft are hinged with the throwing block, and the first crankshaft and the second crankshaft can drive the throwing block to rotate together when rotating; the first water tank is driven to rotate when the first crankshaft rotates, the second water tank is driven to rotate when the second crankshaft rotates, when the first water tank and the second water tank rotate, the flowing liquid in the closed accommodating cavity rotates to form a spiral water vortex, when the input electric quantity of the motor is reduced or stopped, the swinging block can continue to rotate under the action of inertia, the flowing liquid pushes the guide flow to wind the blades under the action of inertia, thereby pushing the water tank to rotate and further driving the first crankshaft and the second crankshaft to rotate, thereby driving the first rotating shaft to rotate, the first rotating shaft driving the generator to generate power, the generator transmits the generated electric quantity to the motor, and the motor continues to do work so as to further continue to drive the first crankshaft and the second crankshaft to rotate; therefore, the motor drives the throwing block to do work in a rotating mode, and meanwhile the throwing block drives the generator to generate electricity under the action of inertia, so that the motor provides electric energy, and the consumption of the electric energy is greatly reduced.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

FIG. 1 is a schematic illustration of an embodiment of an inertial power cycle conversion engine;

FIG. 2 is a schematic illustration of another embodiment of an inertial power cycle conversion engine;

fig. 3 is a schematic diagram of a first water tank of an inertial power cycle conversion engine.

Reference numerals:

10. an inertial power cycle conversion engine motor; 100. an electric motor; 200. a first rotating shaft; 300. a first crankshaft; 400. a second crankshaft; 500. a first water tank; 600. a second water tank; 700. a generator; 800. throwing blocks; 510. sealing the accommodating cavity; 520. guiding around the blades; 310. a force arm; 320. a connecting member.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, fig. 2 and fig. 3, an inertia power cycle conversion engine according to an embodiment of the present invention includes: the water pump comprises a motor 100, a first rotating shaft 200, a first crankshaft 300, a second crankshaft 400, a first water tank 500, a second water tank 600, a generator 700 and at least one throwing block 800;

the motor 100 is in transmission connection with the first crankshaft 300 and the second crankshaft 400 through the first rotating shaft 200, a central axis of the first crankshaft 300 is overlapped with a central axis of the second crankshaft 400, the motor 100 is used for driving the first crankshaft 300 and the second crankshaft 400 to rotate, a rotating direction of the first crankshaft 300 is opposite to a rotating direction of the second crankshaft 400, and rotating directions of the first water tank 500 and the second water tank are opposite;

specifically, the motor 100 and the first rotating shaft 200 may be driven by a belt or a gear, the motor 100 may drive the first rotating shaft 200 to rotate the first crankshaft 300 and the second crankshaft 400, in order to rotate the first crankshaft 300 in the opposite direction to the second crankshaft 400, in one embodiment, a first bevel gear may be provided on the first rotating shaft 200, the first crankshaft 300 and the second crankshaft 400 may be provided on opposite sides of the first rotating shaft 200, respectively, a second bevel gear may be provided on one end of the first crankshaft 300 close to the second crankshaft 400, a third bevel gear may be provided on one end of the second crankshaft 400 close to the first crankshaft 300, and the first bevel gear may be engaged with the second bevel gear and the third bevel gear, respectively, when the first bevel gear drives the second bevel gear and the third bevel gear to rotate, the second bevel gear and the third bevel gear have opposite rotation directions, that is, the first crankshaft 300 and the second crankshaft 400 have opposite rotation directions. Of course, there are many ways to use one rotating shaft to drive the other two rotating shafts to rotate in opposite directions, and this application is not limited thereto.

It should be noted that, a single or multiple first crankshafts 300 and multiple second crankshafts 400 may be selectively installed according to the required power, the multiple first crankshafts 300 or the multiple second crankshafts 400 are respectively installed in a connected manner on the same central axis, each first crankshaft 300 or each second crankshaft 400 may be installed with multiple throwers 800, or may be installed with a metal steel ball as a movable thrower 800. Meanwhile, according to the size of required power, a plurality of movable throwing blocks 800 are connected to each movable throwing block 800.

In order to reduce the vibration when the first crankshaft 300 and the second crankshaft 400 drive the thrower 800 to rotate, in an embodiment, a gear box may be further included, in this embodiment, a gear box may be installed between the first crankshaft 300 and the second crankshaft 400, when a plurality of first crankshafts 300 and second crankshafts 400 are installed, a gear box may be installed at each of upper and lower ends of each of the first crankshafts 300 or the second crankshafts 400, a plurality of first rotating shafts 200 may be connected between each of the first crankshafts 300 and the second crankshafts 400, a plurality of first rotating shafts 200 may be connected by a belt, and the first rotating shafts 200 are in transmission connection with the first crankshafts 300 and the second crankshafts 400 in the gear box.

It should be noted that, in the use state, the first crankshaft 300 and the second crankshaft 400 are in the vertical state, and since the rotation directions of the first crankshaft 300 and the second crankshaft 400 are opposite, the torques generated by the first crankshaft 300 and the second crankshaft 400 during the rotation can be mutually offset, that is, since the rotation directions of the first crankshaft 300 and the second crankshaft 400 are opposite, the inertia forces of the first crankshaft 300 and the second crankshaft 400 are mutually offset, and further the first crankshaft 300 and the second crankshaft 400 can keep a balanced state during the rotation, so that the inertia power cycle conversion engine is in a balanced operation state as a whole, and meanwhile, the effects of shock absorption and silence can be achieved.

It should be understood that first rotating shaft 200 is drivingly connected to first crankshaft 300 and second crankshaft 400, respectively, and first rotating shaft 200 is used to drive first crankshaft 300 and second crankshaft 400 to rotate in different directions, and the driving connection of first rotating shaft 200 to first crankshaft 300 and second crankshaft 400 can be realized by using the prior art, such as driving through gears.

The first water tank and the second water tank are respectively provided with a closed containing cavity, flowing liquid is contained in the closed containing cavity, a diversion winding blade is arranged on the wall of the closed containing cavity, the first water tank 500 is connected with one end, far away from the second crankshaft 400, of the first crankshaft 300, the second water tank 600 is connected with one end, far away from the first crankshaft 300, of the second crankshaft 400, a force arm 310 is connected to a connecting rod journal on the first crankshaft 300 or the second crankshaft 400, and the force arm 310 is hinged to at least one throwing block 800 through a connecting piece 320.

Specifically, the first crankshaft 300 drives the first water tank 500 to rotate when rotating, the second crankshaft 400 drives the second water tank 600 to rotate when rotating, when the first water tank 500 and the second water tank 600 rotate, the flowing liquid in the sealed accommodating cavity 510 rotates to form a spiral water vortex, when the input electric quantity of the motor 100 is reduced or stopped, the throwing block 800 can continue to rotate under the action of inertia, the flowing liquid pushes the diversion to wind the blades 520 under the action of inertia, and further pushes the water tank to rotate, and further drives the first crankshaft 300 and the second crankshaft 400 to rotate, and further drives the first rotating shaft 200 to rotate, the first rotating shaft 200 drives the generator 700 to generate electricity, the generator 700 transmits the generated electric quantity to the motor 100, and the motor 100 continues to do work, thereby continuously driving the first crankshaft 300 and the second crankshaft 400 to rotate; therefore, when the motor 100 drives the throwing block 800 to do work in a rotating manner, the throwing block 800 drives the generator 700 to generate electricity under the action of inertia, so that the motor 100 provides electric energy, and the consumption of the electric energy is greatly saved. It should be noted that the guide vanes 520 are disposed to cross the rotation direction of the flowing liquid, for example, the guide vanes 520 are disposed along the longitudinal section of the first water tank 500 or the second water tank 600, so that the flowing liquid can impact the guide vanes 520, and then the first water tank 500 or the second water tank 600 is rotated.

Since the rotation directions of the first crankshaft 300 and the second crankshaft 400 are opposite, and the rotation directions of the water vortexes in the first water tank 500 and the second water tank 600 are also opposite, the torques generated by the first crankshaft 300 and the second crankshaft 400 during rotation can be offset, that is, the rotation directions of the first crankshaft 300 and the second crankshaft 400 are opposite, so that the inertia forces of the first crankshaft 300 and the second crankshaft 400 are offset, and further the first crankshaft 300 and the second crankshaft 400 can keep a balanced state during rotation, so that the entire inertia power cycle conversion engine is in a balanced operation state.

In order to increase the stability of the device, the device further comprises a rack, the first water tank and the second water tank are rotationally fixed on the rack, and one end of the first crankshaft close to the second crankshaft or one end of the second crankshaft close to the first crankshaft is rotationally fixed on the rack.

In one embodiment, in order to increase the inertia utilization efficiency of the flowing liquid, the number of the flow guiding surrounding blades 520 is multiple, each flow guiding surrounding blade is rotationally and symmetrically arranged in the closed accommodating cavity 510 around the geometric axis of the closed accommodating cavity 510, and the multiple flow guiding surrounding blades 520 are arranged in the closed accommodating cavity 510 in a single-layer surrounding manner or in multiple-layer surrounding manner.

In one embodiment, in order to increase the inertia power of the first water tank 500 or the second water tank 600 after rotating, a plurality of throwing blocks 800 are hinged around the first water tank 500 or the second water tank 600, so that when the input power of the motor 100 is reduced or stopped, the throwing blocks 800 can continue to rotate under the action of inertia, and further continue to drive the first water tank 500 and the second water tank 600 to rotate, and further drive the first crankshaft 300 and the second crankshaft 400 to rotate.

The generator 700 is in transmission connection with the first rotating shaft 200, and the generator 700 is electrically connected with the motor 100.

Specifically, when the motor 100 drives the first rotating shaft 200 to rotate, the first rotating shaft can drive the generator 700 to generate electricity, and the electricity generated by the generator 700 can be supplied to the motor 100, so that a power circulation system is formed. In addition, when the motor 100 suddenly stops operating, the throwing block 800 can continue to rotate under the action of inertia, and further drives the first crankshaft 300 and the second crankshaft 400 to rotate, and further drives the first rotating shaft 200 to rotate, the first rotating shaft 200 drives the generator 700 to generate power, the generator 700 transmits the generated power to the motor 100, the motor 100 continues to do work, and further continues to drive the first crankshaft 300, the first water tank 500, the second crankshaft 400 and the second water tank 600 to rotate; therefore, when the motor 100 drives the throwing block 800 to do work in a rotating manner, the throwing block 800 drives the generator 700 to generate electricity under the action of inertia, so that the motor 100 provides electric energy, and the consumption of the electric energy is greatly saved. In addition, the first crankshaft 300 and the second crankshaft 400 of the present application may be connected to other driven components, so that the power cycle conversion engine using inertia of the present application can not only generate power, but also transmit power, for example, convert electric energy of the electric motor 100 into mechanical energy for rotating the first crankshaft 300 and the second crankshaft 400, and transmit the mechanical energy to other components needing to rotate, so as to drive the components.

In one embodiment, the connecting member 320 comprises two oppositely arranged clamping blocks, one end of the slinger 800 is hinged between the two clamping blocks through a pivoting member, and one ends of the two clamping blocks far away from the slinger 800 are connected with the force arm 310.

Specifically, the connecting member 320 is configured to connect the thrower 800 and the arm 310, one end of the connecting member 320 is fixed to an edge of the arm 310, the other end of the connecting member 320 is hinged to the thrower 800 through the pivot, when the first crankshaft 300 or the second crankshaft 400 rotates, the arm 310, the connecting member 320, and the thrower 800 perform synchronous rotational motion with the first crankshaft 300 or the second crankshaft 400, and when the rotational speed of the first crankshaft 300 or the second crankshaft 400 decreases, the thrower 800 continues to maintain the original rotational speed under the action of inertia to rotate, so as to drive the first crankshaft 300 and the second crankshaft 400 to rotate. Get rid of piece 800 set up in two between the clamp splice, two the restraint that the clamp splice can be fine get rid of piece 800's rotation plane for get rid of piece 800's rotation steadily. In order to reduce the friction force of the swinging block 800 rotating around the pivot, one end of the swinging block 800 is provided with a through hole, a bearing is arranged in the through hole, the pivot penetrates through the bearing, and at least one end of the pivot is fixed on the connecting piece 320.

In one embodiment, a pulley is connected to the first rotating shaft, and the motor and the generator are respectively in transmission connection with the pulley through a belt.

Specifically, in order to protect the motor, a one-way bearing is installed between the first rotating shaft and the belt pulley, the rotating direction of the one-way bearing is the rotating direction of the power output shaft of the motor, when the rotating direction of the first rotating shaft is opposite to that of the one-way bearing, when the first rotating shaft rotates, the belt pulley does not rotate, and the first rotating shaft does not drive the power output shaft of the motor to rotate in the reverse direction, so that the one-way bearing can play a role in reducing kinetic energy loss and motor wear effects; the first rotating shaft transmits power to the generator by rotating the belt to cause the generator to generate electricity.

In one embodiment, the centrifugal pump further comprises a fixing rod, the fixing rod is disposed on one side of the centrifugal pump 800, two ends of the fixing rod are respectively connected with the two clamping blocks, and when the centrifugal pump 800 rotates in a direction close to the fixing rod, the fixing rod is abutted to the centrifugal pump 800.

Specifically, get rid of piece 800 and have great degree of freedom when rotatory, through one increase in one side of getting rid of piece 800 the dead lever, the both ends of dead lever are connected respectively on the connecting piece 320, the dead lever is in the card is put in a direction of rotation of getting rid of piece 800 get rid of piece 800 makes get rid of piece 800 can only rotate in a direction after starting, has increased the stability of this device.

In one embodiment, the slinger blocks 800 are connected in series. That is, each dump block 800 is connected with one or more other dump blocks 800 in sequence.

Specifically, one end of the connecting member 320 is fixed to one of the throwing blocks 800, and the other end of the connecting member 320 is hinged to the other throwing block 800, so that when the first crankshaft 300 or the second crankshaft 400 decelerates or stops rotating, the throwing block 800 at the far end from the axial lead of the first crankshaft 300 sequentially drives the other throwing blocks 800 to throw in the direction from far to near from the axial lead of the first crankshaft 300, and then drives the first crankshaft 300 or the second crankshaft 400 to rotate.

In one embodiment, the slinger 800 is spherical.

The throwing block can be a metal throwing block 800 or a metal ball, and in order to increase the stability of the throwing block 800 during rotation, the weight increasing block is preferably a spherical metal block.

In one embodiment, in order to ensure the smoothness of the rotation of the first water tank 500 and the second water tank 600, the cross-sections of the first water tank 500 and the second water tank 600 are in a rotational symmetric pattern.

In one embodiment, a pulley is connected to the first rotating shaft 200, and the motor 100 and the generator 700 are respectively connected to the pulley through a belt.

Specifically, in order to protect the motor 100, a one-way bearing is installed between the first rotating shaft 200 and the belt pulley, the rotating direction of the one-way bearing is the rotating direction of the power output shaft of the motor 100, when the rotating direction of the first rotating shaft 200 is opposite to that of the one-way bearing, when the first rotating shaft 200 rotates, the belt pulley does not rotate, and the first rotating shaft 200 does not drive the power output shaft of the motor 100 to rotate in the reverse direction, so that the one-way bearing can play a role in reducing the loss of kinetic energy and the wear effect of the motor 100; the first rotating shaft 200 transmits power to the generator 700 through the rotation of the belt to cause the generator 700 to generate electricity.

In one embodiment, the first and second water tanks 500 and 600 are hollow cones or cylinders.

Specifically, the first water tank 500 and the second water tank 600 have circular cross sections, that is, the cross sections of the first water tank 500 and the second water tank 600 are circular, and the closed accommodating cavity 510 has good rotational symmetry by using a cone or a cylinder, so that the flowing liquid can form a complete and large spiral water vortex, and inertia generated when the flowing liquid rotates can be fully utilized.

In one embodiment, the number of the first water tanks 500 or the second water tanks 600 is adjusted according to the required kinetic energy, that is, the number of the first water tanks 500 and the second water tanks 600 is multiple, each of the first water tanks 500 is arranged at intervals, and each of the second water tanks 600 is arranged at intervals. That is, the plurality of first water tanks 500 are stacked one on another and connected to the first crankshaft 300, and the plurality of second water tanks 600 are stacked one on another and connected to the second crankshaft 400, so that the power generated by the inertia power cycle conversion engine is increased by increasing the number of the first water tanks 500 and the number of the second water tanks 600.

In one embodiment, the electric motor 100 is a dc motor or an ac motor, and the mobile power source is electrically connected to the dc motor or the ac motor.

Specifically, in order to simplify the driving method of the present apparatus, the dc motor may be used to start the apparatus, the generator 700 may be a dc generator or an ac generator, when the generator 700 is a dc generator, a transformer needs to be disposed in a circuit between the generator 700 and the motor 100 to adjust the voltage output by the generator 700, and when the generator 700 is an ac generator, a rectifier needs to be disposed in a circuit between the generator 700 and the motor 100 to convert the ac output by the generator 700 into dc for the motor 100 to use.

In addition, the generator 700 can also be started by a small-sized fuel engine, and after the current generated by the engine is inverted by voltage regulation, counter pressure, voltage transformation and the like, the high-voltage high-power alternating-current motor rotates to continuously drive the generator 700 to generate electricity, and the mutual conversion achieves the effect of circular rotation.

In one embodiment, an end of the second crankshaft 400 remote from the first crankshaft 300 is drivingly connected to another first rotating shaft 200, and the first rotating shaft is drivingly connected to the motor 100 and the generator 700.

In an embodiment, the first crankshaft 300 and the second crankshaft 400 are vertically installed and connected, the first crankshaft 300 and the second crankshaft 400 may also be straight shafts, a plurality of movable throws 800 may be installed on the first crankshaft 300 and the second crankshaft 400 to increase inertia power, and a plurality of movable throws 800 may also be connected to one movable throws 800 to increase inertia power. In order to increase the stability of the device, a force arm 310 is arranged at the position of the connecting rod journal, and one or more movable swinging blocks 800 are connected to the force arm 310. In order to start the device, the storage battery and the speed regulator can be used for starting the direct current motor 100 to rotate, and then the direct current generator 700 is driven to generate electricity, one part of electricity generated by the direct current generator 700 is charged into the storage battery, and the other part of electricity is supplied to the direct current motor 100 to continue to operate and do work, so that the direct current generator 700 is driven to generate electricity, and an electric power self-circulation supply system is formed. After the direct current motor 100 is started, the alternating current generator 700 is driven to generate electricity, and the alternating current generator 700 and the alternating current motor 100 can form power cycle conversion.

The movable throwing block 800 can rotate freely or rotate in a limited way on the force arm 310, and the metal steel can be used as a movable inertia throwing ball to be connected with the force arm 310 to rotate.

The first bent axle 300 and the second bent axle 400 of both ends are just reversing rotation about gear glass box rotates the drive, is installing many first bent axle 300 with during the second bent axle 400, can be at each first bent axle 300 or a gear change case is respectively installed at the upper and lower both ends of second bent axle 400, each first bent axle 300 with be connected with a plurality ofly between the second bent axle 400 first axis of rotation 200 is a plurality of connect through belt transmission between the first axis of rotation 200.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.