阅读说明：本技术 一种新型稀土能源动力机 (Novel rare earth energy power machine ) 是由 顾杰雄 于 2021-01-12 设计创作，主要内容包括：本发明公开了一种新型稀土能源动力机。机座固定置于外壳底部,外壳的两端均置有端盖,端盖中间位置和外壳内部均设置有双锁轴承座,动力输出轴置于外壳内,且动力输出轴的两端从外壳两端的双锁轴承座向外穿出,双锁轴承座的两端内均置有油封,油封通过卡簧和双锁轴承座连接固定,双锁轴承座的中间位置内置有两个推力圆柱滚子轴承,推力圆柱滚子轴承外侧置有推力圆柱滚子轴承挡圈,油封和相邻的推力圆柱滚子轴承挡圈之间置有两个调心圆柱滚子轴承,且两个调心圆柱滚子轴承间置有调心圆柱滚子轴承挡圈。运行时间长,运行中不添加任何燃料；制造成本低；相对无费用成本运行；应用范围广；运行使用寿命长；无论是停放还是做功,皆无任何有害物质释放。(The invention discloses a novel rare earth energy power machine. The frame is fixed and is arranged in the shell bottom, the end cover has all been put at the both ends of shell, end cover intermediate position and the inside double-lock bearing frame that all is provided with of shell, power output shaft arranges in the shell, and power output shaft's both ends are outwards worn out from the double-lock bearing frame at shell both ends, the oil blanket has all been put in the both ends of double-lock bearing frame, the oil blanket passes through jump ring and double-lock bearing frame connection fixed, the intermediate position of double-lock bearing frame embeds there are two thrust cylindrical roller bearings, thrust cylindrical roller bearing retaining ring has been put in the thrust cylindrical roller bearing outside, two aligning cylindrical roller bearings have been put between oil blanket and the adjacent thrust cylindrical roller bearing retaining ring, and aligning cylindrical roller bearing retaining. The running time is long, and no fuel is added in the running process; the manufacturing cost is low; relatively no cost to operate; the application range is wide; the service life is long; no harmful substance is released whether the vehicle is parked or does work.)

1. A novel rare earth energy power machine is characterized by comprising a shell, a linear bearing seat, a No. 2 positioning ring, a No. 1 supporting disk, a linear sliding shaft, a rotor, a mover, a subsidiary mover, a mover locking block, a No. 3 positioning ring, a No. 2 supporting disk, a double-body cutting and matching mover group, a timing device, a No. 4 positioning ring, a No. 3 supporting disk, a single-body cutting and matching mover group, a sliding gear hub, a driven gear hub, an electromagnetic clutch device, a driving gear hub, a flywheel group, a starter, a double-locking bearing seat, a power output shaft, a self-aligning cylindrical roller bearing, a thrust cylindrical roller bearing retainer ring, a thrust cylindrical roller bearing, an end cover, a self-aligning cylindrical roller bearing retainer ring, an oil seal, a snap spring, a No. 1 positioning ring, a lubricating oil filling cup, an instrument control box, a machine seat, a cutting and matching body fixing and supporting seats and an, the middle position of the end cover and the inside of the shell are both provided with double-locking bearing seats, the power output shaft is arranged in the shell, and two ends of the power output shaft penetrate out of the double-locking bearing seats at the two ends of the shell, oil seals are arranged in the two ends of the double-locking bearing seats, the oil seal is fixedly connected with the double-lock bearing seat through a clamp spring, two thrust cylindrical roller bearings are arranged in the middle position of the double-lock bearing seat, a thrust cylindrical roller bearing retainer ring is arranged on the outer side of the thrust cylindrical roller bearing, two aligning cylindrical roller bearings are arranged between the oil seal and the adjacent thrust cylindrical roller bearing retainer ring, a self-aligning cylindrical roller bearing retainer ring is arranged between the two self-aligning cylindrical roller bearings, the self-aligning cylindrical roller bearing retainer ring is arranged between the oil seal and the adjacent self-aligning cylindrical roller bearing, and the inner ring of the self-aligning cylindrical roller bearing is tightly connected with the power output shaft through a clamp spring; four groups of linear bearing seats are arranged on the inner wall of the shell, one group of linear bearing seats are distributed in a row, a linear sliding shaft is arranged on each group of linear bearing seats, a No. 1 positioning ring is fixedly arranged on the inner wall of one end of the shell, the No. 1 positioning ring is connected with the adjacent linear bearing seat, a No. 1 supporting disk is arranged on each linear sliding shaft and is limited and fixed through a No. 2 positioning ring, a pair of moving body groups and a moving body locking block group which are distributed at intervals are arranged on the first supporting disk, a rotor is arranged on the power output shaft and is fixed through the No. 2 positioning ring, the rotor is positioned in a sliding chute formed by the No. 1 supporting disks on the four linear sliding shafts, and a moving body group is arranged on the; the cutting body fixing supporting seat is arranged on the power output shaft, thrust cylindrical roller bearings are arranged in two ends of the cutting body fixing supporting seat, the No. 3 supporting disc is arranged on the outer side surface of the cutting body fixing supporting seat and is distributed in an annular shape, the No. three supporting discs are provided with double-body cutting body groups, and the cathodes and the anodes of the double-body cutting body groups are arranged in a crossed manner; the two sides of each third supporting disk are respectively provided with a No. 2 supporting disk, the No. 2 supporting disk is connected with a linear sliding shaft through a No. 3 positioning ring, the No. 2 supporting disk is provided with a corresponding monomer cutting and matching body group, the cathode of the double-body cutting and matching body group and the anode of the adjacent monomer cutting and matching body group are arranged in a crossed manner, the anode of the double-body cutting and matching body group is opposite to the anode of the adjacent monomer cutting and matching body group, the linear sliding shaft is provided with a timing device, one end of the cutting and matching body fixing supporting seat is provided with a driven gear hub, the power output shaft is provided with an active gear hub which corresponds to the driven gear hub, the sliding gear hubs are arranged on the outer sides of the active gear hub and the driven gear hub, and the electromagnetic clutch device is arranged; the starter is arranged in the other end of the shell, and the flywheel set is arranged on the power output shaft and matched with the starter; the automobile engine lubricating oil control device is characterized in that lubricating oil filling cups are arranged at the tops of two ends of the shell, an instrument control box is arranged on the outer side face of the other end of the shell and is electrically connected with a starter, a timing device, an electromagnetic clutch device and an external 12V or 24V automobile storage battery.

2. The novel rare earth energy power machine as claimed in claim 1, wherein a main power switch, a 12V or 24V dc current meter, a tachometer, a starter start button, an electromagnetic clutch, an automatic clutch button, a battery wire connection post with a shield and an operation recorder are arranged in the instrument control box.

Technical Field

The invention relates to the technical field of new energy power machines, in particular to a novel rare earth energy power machine.

Background

The magnitude of the magnetic force between the "magnet" and the iron-based element substance is determined by three parameters, namely the "maximum energy product", "coercive force" and "residual energy product". The maximum magnetic energy product represents the maximum magnetic energy obtained by magnetizing the magnetic block, but is not invariable; "coercivity" refers to the ability of a "magnetic block" to resist demagnetization; the residual magnetic energy product refers to the residual magnetic energy product of the magnetic block after demagnetization. This means that the magnetic force of the magnet will decrease with time and use environment. This is the biggest reason why the "magnetic" type of motivation is difficult to produce.

The rare earth kinetic energy body is a new energy body developed by utilizing the physical characteristics of rare earth elements. The "animal" itself does not exhibit any release of antibiotics, harmful substances to other substances and to people and living beings. It belongs to a 'forward' potential energy body of elements and comprises a cathode and an anode. Somewhat similar to a "magnet", like poles repel and unlike poles attract. However, it has no "energy product" or even no fading phenomenon, and it has only "forward" and "reverse" components. The magnetic power machine is fundamentally different from the conventional magnetic power machine, and is a revolution of the conventional magnetic power machine, so that the magnetic power machine provides an energy trend for the development of the power machine.

The rare earth originally is a mineral resource (world science and technology) is proved at present, and the rare earth totally contains 17 elements, namely scandium (Sc); yttrium (Y); lanthanum (La); cerium (Ce); praseodymium (Pr); neodymium (Nd); promethium (Pm); samarium (Sm); europium (Eu); gadolinium (Gd) dysprosium (Dy); holmium (Ho); erbium (Er); lutetium (Lu); thulium (Tm); ytterbium (Yb); terbium (Tb). And … … in these 17 middle elements. Except praseodymium (Pr) element, which is not readily available, most elements (by their nature) have the potential to be developed as "energy sources".

Disclosure of Invention

Aiming at the technical defects, the invention aims to provide a novel rare earth energy power machine which utilizes rare earth as power energy, is more energy-saving and environment-friendly and greatly reduces the use cost of the power machine.

In order to solve the technical problems, the invention adopts the following technical scheme:

a novel rare earth energy power machine is characterized by comprising a shell, a linear bearing seat, a No. 2 positioning ring, a No. 1 supporting disk, a linear sliding shaft, a rotor, a mover, a subsidiary mover, a mover locking block, a No. 3 positioning ring, a No. 2 supporting disk, a double-body cutting and matching mover group, a timing device, a No. 4 positioning ring, a No. 3 supporting disk, a single-body cutting and matching mover group, a sliding gear hub, a driven gear hub, an electromagnetic clutch device, a driving gear hub, a flywheel group, a starter, a double-locking bearing seat, a power output shaft, a self-aligning cylindrical roller bearing, a thrust cylindrical roller bearing retainer ring, a thrust cylindrical roller bearing, an end cover, a self-aligning cylindrical roller bearing retainer ring, an oil seal, a snap spring, a No. 1 positioning ring, a lubricating oil filling cup, an instrument control box, a machine seat, a cutting and matching body fixing and supporting seats and an, the middle position of the end cover and the inside of the shell are both provided with double-locking bearing seats, the power output shaft is arranged in the shell, and two ends of the power output shaft penetrate out of the double-locking bearing seats at the two ends of the shell, oil seals are arranged in the two ends of the double-locking bearing seats, the oil seal is fixedly connected with the double-lock bearing seat through a clamp spring, two thrust cylindrical roller bearings are arranged in the middle position of the double-lock bearing seat, a thrust cylindrical roller bearing retainer ring is arranged on the outer side of the thrust cylindrical roller bearing, two self-aligning cylindrical roller bearings are arranged between the oil seal and the adjacent thrust cylindrical roller bearing retainer ring at an angle, a self-aligning cylindrical roller bearing retainer ring is arranged between the two self-aligning cylindrical roller bearings, the self-aligning cylindrical roller bearing retainer ring is arranged between the oil seal and the adjacent self-aligning cylindrical roller bearing, and the inner ring of the self-aligning cylindrical roller bearing is tightly connected with the power output shaft through a clamp spring; four groups of linear bearing seats are arranged on the inner wall of the shell, one group of linear bearing seats are distributed in a row, a linear sliding shaft is arranged on each group of linear bearing seats, a No. 1 positioning ring is fixedly arranged on the inner wall of one end of the shell, the No. 1 positioning ring is connected with the adjacent linear bearing seat, a No. 1 supporting disk is arranged on each linear sliding shaft and is limited and fixed through a No. 2 positioning ring, a pair of moving body groups and a moving body locking block group which are distributed at intervals are arranged on the first supporting disk, a rotor is arranged on the power output shaft and is fixed through the No. 2 positioning ring, the rotor is positioned in a sliding chute formed by the No. 1 supporting disks on the four linear sliding shafts, and a moving body group is arranged on the; the cutting body fixing supporting seat is arranged on the power output shaft, thrust cylindrical roller bearings are arranged in two ends of the cutting body fixing supporting seat, the No. 3 supporting disc is arranged on the outer side surface of the cutting body fixing supporting seat and is distributed in an annular shape, the No. three supporting discs are provided with double-body cutting body groups, and the cathodes and the anodes of the double-body cutting body groups are arranged in a crossed manner; the two sides of each third supporting disk are respectively provided with a No. 2 supporting disk, the No. 2 supporting disk is connected with a linear sliding shaft through a No. 3 positioning ring, the No. 2 supporting disk is provided with a corresponding monomer cutting and matching body group, the cathode of the double-body cutting and matching body group and the anode of the adjacent monomer cutting and matching body group are arranged in a crossed manner, the anode of the double-body cutting and matching body group is opposite to the anode of the adjacent monomer cutting and matching body group, the linear sliding shaft is provided with a timing device, one end of the cutting and matching body fixing supporting seat is provided with a driven gear hub, the power output shaft is provided with an active gear hub which corresponds to the driven gear hub, the sliding gear hubs are arranged on the outer sides of the active gear hub and the driven gear hub, and the electromagnetic clutch device is arranged; the starter is arranged in the other end of the shell, and the flywheel set is arranged on the power output shaft and matched with the starter; the automobile engine lubricating oil control device is characterized in that lubricating oil filling cups are arranged at the tops of two ends of the shell, an instrument control box is arranged on the outer side face of the other end of the shell and is electrically connected with a starter, a timing device, an electromagnetic clutch device and an external 12V or 24V automobile storage battery.

Preferably, a main power switch, a 12V or 24V direct current ammeter, a revolution meter, a starter starting button, an electromagnetic clutch, an automatic clutch button, a storage battery wire wiring pile with a shield and an operation recorder are arranged in the instrument control box.

The invention has the advantages that in the process of operating power output, only a small amount of lubricating grease needs to be injected once, which is unnecessary, the operation time is long, and no fossil or other fuels are added in the operation; can be stopped/started at any time according to various different power requirements; compared with the power cost of various energy engines used at present, the manufacturing cost is low; relatively no cost to operate; the application range is wide; the service life is long; no matter the vehicle is parked or does work, no harmful substance is released; the noise is low in the operation process, fossil and other types of energy and fuel do not need to be added, and the input and injection of energy and resources such as electric power, water and the like are not needed.

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, 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 the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of a novel rare earth energy power machine provided by the invention;

FIG. 2 is a schematic structural diagram of the front half part of a novel rare earth energy power machine provided by the invention;

FIG. 3 is a schematic structural diagram of the rear half part of a novel rare earth energy power machine provided by the invention;

FIG. 4 is an enlarged view of a double-lock bearing seat of the novel rare earth energy power machine provided by the invention;

FIG. 5 is a schematic structural diagram of a tangential phase position of a novel rare earth energy power machine provided by the invention;

FIG. 6 is a schematic structural diagram of the exterior of a novel rare earth energy power machine provided by the invention;

FIG. 7 is a phase diagram of the novel rare earth energy power machine;

description of reference numerals:

a shell 1, a linear bearing seat 2, a No. 2 positioning ring 3, a No. 1 supporting disk 4, a linear sliding shaft 5, a rotor 6, a moving body 7, a driven body 8, a moving body locking block 9, a No. 3 positioning ring 11, a No. 2 supporting disk 12, a double-body cutting matching body group 13, a timing device 14, a No. 4 positioning ring 15, a No. 3 supporting disk 16, a single-body cutting matching body group 18, a sliding gear hub 19, a driven gear hub 20 and an electromagnetic clutch device 21, the device comprises a driving gear hub 22, a flywheel set 23, a starter 24, a double-lock bearing seat 25, a power output shaft 26, a self-aligning cylindrical roller bearing 27, a thrust cylindrical roller bearing retainer ring 28, a thrust cylindrical roller bearing 29, an end cover 30, a self-aligning cylindrical roller bearing retainer ring 31, an oil seal 32, a clamp spring 33, a No. 1 positioning ring 34, a lubricating oil filling cup 35, an instrument control box 36, a machine base 37, a cutting body fixing support seat 38 and an external 12V or 24V storage battery 39 for the automobile.

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.

It should be noted that in the description of the present invention, the terms "in", "upper", "lower", "lateral", "inner", etc. indicate directions or positional relationships based on those shown in the drawings, which are merely for convenience of description, and do not indicate or imply that the device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Furthermore, it should be noted that, in the description of the present invention, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally connected; may be a mechanical connection; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

As shown in figures 1-7, a novel rare earth energy power machine comprises a shell 1, a linear bearing seat 2, a No. 2 positioning ring 3, a No. 1 supporting disk 4, a linear sliding shaft 5, a rotor 6, a dynamic body 7, a secondary dynamic body 8, a dynamic body locking block 9, a No. 3 positioning ring 11, a No. 2 supporting disk 12, a double-body cutting matching dynamic body group 13, a timing device 14, a No. 4 positioning ring 15, a No. 3 supporting disk 16, a single-body cutting matching dynamic body group 18, a sliding gear hub 19, a driven gear hub 20, an electromagnetic clutch device 21, a driving gear hub 22, a flywheel group 23, a starter 24, a double-locking bearing seat 25, a power output shaft 26, a self-aligning cylindrical roller bearing 27, a thrust cylindrical roller bearing retainer ring 28, a thrust cylindrical roller bearing 29, an end cover 30, a self-aligning cylindrical roller bearing retainer ring 31, an oil seal 32, a clamp spring 33, a No. 1, A cutting body fixing support 38 and an external 12V or 24V storage battery 39 for an automobile, wherein a base 37 is fixedly arranged at the bottom of a shell 1, end covers 30 are respectively arranged at two ends of the shell 1, double-lock bearing seats 25 are respectively arranged at the middle position of each end cover 30 and inside the shell 1, a power output shaft 26 is arranged in the shell 1, two ends of the power output shaft 26 penetrate out of the double-lock bearing seats 25 at the two ends of the shell 1, oil seals 32 are respectively arranged at two ends of each double-lock bearing seat 25, the oil seals 32 are fixedly connected with the double-lock bearing seats 25 through clamp springs 33, two cylindrical thrust roller bearings 29 are arranged in the middle positions of the double-lock bearing seats 25, cylindrical thrust roller bearing retainer rings 28 are arranged outside the cylindrical thrust roller bearings 29, two self-aligning cylindrical roller bearings 27 are arranged between each oil seal 32 and the adjacent cylindrical thrust bearing retainer rings 28, and a cylindrical self-aligning roller bearing retainer ring 31, a self-aligning cylindrical roller bearing retainer ring 31 is arranged between the oil seal 32 and the adjacent self-aligning cylindrical roller bearing 27, and the inner ring of the roller self-aligning bearing 27 is tightly connected with the power output shaft 26 through a clamp spring 33; four groups of linear bearing seats 2 are arranged on the inner wall of the shell 1, one group of linear bearing seats 2 is distributed in a row, a linear sliding shaft 5 is arranged on each group of linear bearing seats 2, a No. 1 positioning ring 34 is fixedly arranged on the inner wall of one end of the shell 1, the No. 1 positioning ring 34 is connected with the adjacent linear bearing seat 2, a No. 1 supporting disk 4 is arranged on the linear sliding shaft 5, and is limited and fixed by a No. 2 positioning ring 3, a pair of moving bodies 8 and a moving body locking block 9 which are distributed at intervals are arranged on the first supporting disk, a rotor 6 is arranged on a power output shaft 26, the rotor 6 is positioned in a sliding groove formed by a No. 1 supporting disk 4 on four linear sliding shafts 5, the sliding groove slides once in each orientation (linear vector), the sliding groove pair moving body group and the corresponding rotor moving body group work once, and the rotor rotates for 90 degrees; the outer side surface of the rotor 6 is provided with a moving body 7 group which corresponds to a fixed moving body 8 group; the cutting and matching body fixing supporting seat 38 is arranged on the power output shaft 26, thrust cylindrical roller bearings 29 are arranged in two ends of the cutting and matching body fixing supporting seat 38, the No. 3 supporting discs 16 are arranged on the outer side surface of the cutting and matching body fixing supporting seat 38 and are distributed annularly, the three supporting discs are provided with the double-body cutting and matching body group 13, and the cathodes and the anodes of the double-body cutting and matching body group 13 are arranged in a crossed manner; two sides of each third supporting disk are respectively provided with a No. 2 supporting disk 12, the No. 2 supporting disk 12 is connected with the linear sliding shaft 5 through a No. 3 positioning ring 11, the No. 2 supporting disc 12 is provided with a corresponding monomer cutting and matching body group 18, the cathode of the double-body cutting and matching body group 13 and the anode of the adjacent monomer cutting and matching body group 18 are arranged in a crossing way, the anode of the double-body cutting match body group 13 is opposite to the anode of the adjacent single-body cutting match body group 18, the linear sliding shaft 5 is provided with a timing device 14 which is a device for controlling the cutting advance angle and the delay angle of the cutting phase, a passive gear hub 20 is arranged at one end of the cutting element fixing and supporting seat 38, an active gear hub 22 is arranged on the power output shaft 26, the sliding gear hub 19 is arranged outside the driving gear hub and the driven gear hub 20, and the electromagnetic clutch device 21 is arranged outside the sliding gear hub 19; the starter 24 is arranged in the other end of the shell 1, the flywheel set 23 is arranged on the power output shaft 26 and is matched with the starter 24; the lubricating oil filling cups 35 are arranged at the tops of two ends of the shell 1, the instrument control box 36 is arranged on the outer side face of the other end of the shell 1 and is electrically connected with the starter 24, the timing device 14, the electromagnetic clutch device 21 and an external 12V or 24V automobile storage battery (determined according to the size of the automobile model).

Further, a main power switch, a 12V or 24V dc ammeter, a tachometer, a starter 24 start button, an electromagnetic clutch, an automatic clutch button, a battery wire connection post with a shield, and an operation recorder are arranged in the instrument control box 36.

When the instrument is used, the instrument control box 36 is opened, and the external power main switch is opened by using a special key; the electromagnetic clutch button (automatic type) is started to lead the 'double-body cutting matching body' of the 'cutting matching phase' to be integrated with the power output shaft 26 (moving corner); pressing a starting button of a starter 24 to start and operate the power machine;

when the double-body cutting matching body is operated at a certain angle (less than or equal to 90 degrees), the double-body cutting matching body generates pulling force and pushing force with the single-body cutting matching body on the left side and the right side, because the kinetic energy bodies on the cutting matching body are assembled in a 90-degree staggered mode, a linear sliding shaft (orientation) 5 is instantaneously moved in parallel (and the parallel movement is less than or equal to 90 mm stroke), and meanwhile, the moving body 7 and the auxiliary moving body 8 are enabled to move according to the characteristics of the rare earth kinetic energy bodies, the ratio of the vertical acting force of the moving body to the parallel acting force: the kinetic potential energy (experiment) parameter of beta ≈ 1.33 … … generates great kinetic potential energy, and the rotor 6 is directionally rotated due to the design of the differential angle (tangential phase) between the moving body 7 and the auxiliary moving body 8. The moving body 7 on the rotor 6 and the auxiliary moving body 8 on the parallel sliding shaft are mutually assembled in a corresponding male-female staggered way, so that the angle of 45 degrees before cutting is the pushing potential energy; then, the angle of 45 degrees is matched in a cutting mode to pull the kinetic potential energy, and the power output shaft 26 can rotate by 90 degrees through one-time matching in a cutting mode;

when the power output shaft 26 rotates (less than or equal to 90 degrees) for a certain angle, and the double-body cutting matching body also rotates (less than or equal to 90 degrees), the double-body cutting matching body and the single-body cutting matching bodies on the left side and the right side generate cutting matching of reverse parallel movement (cutting matching with the single-body cutting matching body), and in the same way, the power output shaft 26 rotates (less than or equal to 90 degrees) in the original rotating direction, so that the conversion of cutting matching and kinetic energy is realized, the power output shaft 26 is enabled to rotate directionally, and in order to balance the power output, the flywheel set 23 mechanism is designed to solve the problem of balance of output power;

during the cutting process of the cutting phase (designed according to the cutting phase diagram), the two-body cutting match body and the left and right single-body cutting match bodies operate relatively without resistance. Because one side of the two (left and right) is pushed and the other side is pulled, and the pushing force F is approximately equal to F pulling resistance between the opposite parallel acting surfaces;

one set of shearing energy drives the five moving components 7 to operate, which is designed due to the characteristics of the rare earth kinetic energy body. Between the rare earth kinetic energy bodies with the same volume and the cross section area, the vertical force is about three times of the parallel force, namely (potential energy difference of a moving body 7) e is approximately equal to 0.33 … …, and the power machine is designed according to a (conventional) mechanical power factor mu which is approximately equal to 80.33%;

when the power machine needs to stop running, the electromagnetic clutch button (automatic type) is started, and the driven gear hub 20 of the cut double-body cutting matching body is connected with the driving gear hub 22 of the power output shaft 26. The external storage battery is the configuration of the power machine starting and the instrument, but not used for the power machine starting and the instrument, and the external storage battery is charged to the storage battery (a general generator of an automobile) under the normal running state of the power machine, so that the next starting of the power machine and the normal running of the instrument are ensured.

FIG. 7 shows the direction of the arrow as the rotation direction, and a is the cut-off passing angle, i.e. the relative sliding interval between the passive block and the passive block, which is the inactive zone; b is a cutting matching delay angle, in order to prevent the rotor from rotating left and right in the cutting matching process and ensure the design of directional rotation; and c is the working rotation angle of the rotor.

According to the cutting phase diagram, the cutting camera mechanism, the timing mechanism, the rotation direction of the power output shaft and the like of the energy power machine can be designed and researched.

In the design of the invention, in the process of operating power output, only a small amount of lubricating grease needs to be injected once, which is unnecessary, the operation time is long, and no fuel is added in the operation; can be stopped/started at any time according to the power demand; compared with the power cost of various energy engines used at present, the manufacturing cost is low; relatively no cost to operate; the application range is wide; the service life is long; no matter the vehicle is parked or does work, no harmful substance is released; the noise is low in the operation process, fossil and other types of energy and fuel do not need to be added, and the input and injection of energy and resources such as electric power, water and the like are not needed.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.