阅读说明：本技术 一种用于旋转的组件 (Component for rotation ) 是由 尹继桃 于 2021-02-05 设计创作，主要内容包括：本发明涉及一种组件,尤其涉及一种用于旋转的组件,包括第一物件、第三物件、第四物件、第五物件,其特征在于,在所述第三物件上至少设置一个所述第一物件,在所述第一物件上设置第四物件,所述第四物件与所述第一物件连接或一体成型,所述第四物件为所述第一物件传递动力,所述动力位于所述第一物件之外,所述动力的反作用力作用在所述第三物件上或作用在与所述第三物件直接或间接连接的可旋转的物体上,本发明的有益效果是：在第一物件之外施加作用力使得旋转体动能不会随力矩的成倍增加而成倍增加旋转方向相反的旋转体通过电机组件相互作用将动能转换为电能,从而回收利用。(The invention relates to an assembly, in particular to an assembly for rotation, which comprises a first object, a third object, a fourth object and a fifth object, and is characterized in that at least one first object is arranged on the third object, the fourth object is arranged on the first object, the fourth object is connected with or integrally formed with the first object, the fourth object transmits power to the first object, the power is positioned outside the first object, and the reaction force of the power acts on the third object or a rotatable object directly or indirectly connected with the third object, so that the assembly has the advantages that: the acting force is applied outside the first object, so that the kinetic energy of the rotating body cannot be multiplied along with the multiplied increase of the moment and the rotating bodies with opposite rotating directions convert the kinetic energy into electric energy through the interaction of the motor components, and the electric energy is recycled.)

1. An assembly for rotation, comprising a first object, a third object, a fourth object and a fifth object, wherein at least one first object is arranged on the third object, the first object is rotatably connected with the third object, and an axial center point or a mass center point of a body of the first object and an axial center point of the third object are not on the same axial line;

arranging a fourth object on the first object, wherein the mass of the fourth object is smaller than that of the first object, the fourth object is connected with or integrally formed with the first object, the fourth object transmits power to the first object, the power is positioned outside the first object, and the reaction force of the power acts on the third object or a rotatable object directly or indirectly connected with the third object;

the rotary power of the first object is interacted with the rotary power of a rotary body with the opposite rotary direction of the first object through the fifth object;

the fifth object is connected to an object within or rotatable component connected to the one component for rotation.

2. An assembly according to claim 1, wherein the radius of the first article is smaller than the radius of the third article or a second article is provided on the third article, the second article and the first article are rotatably connected to the third article, the axis of the second article is coaxial with or between the axis of the first article, the first article and the second article receive power from a power source, and the first article and the second article receive power in opposite directions.

3. An assembly for rotation according to claim 1 or 2, wherein the power source is provided within or on the assembly to which it is connected.

4. An assembly for rotation according to claim 1, wherein the reaction force of the power provided by the power source to the first article acts on the third article, the ratio of the sum of the masses to the number of the first article being greater than the mass of the third article.

5. An assembly for rotation according to claim 2, wherein the third article receives a difference in kinetic energy of the first and second articles or a reaction force to the power provided by the power source.

6. An assembly for rotation according to claim 2, wherein the ratio of the sum of the masses to the number of the first articles provided on the third article is greater than the ratio of the sum of the masses to the number of the second articles.

7. An assembly for rotation according to claim 1 or 2, wherein the third and first and second objects are circular bodies or bodies of rotation connected by bodies to rings or bearings, the fourth object is a rod-shaped or circular body or a magnetic material, and the fifth object is a brake assembly.

8. An assembly for rotation according to claim 7, wherein the braking assembly comprises a first braking member and a second braking member, the first braking member is a motor stator, the second braking member is a motor rotor, the motor stator is connected with the second object, and the motor rotor is connected with the first object or in intermittent contact with the first object or integrally formed with the first object.

9. An assembly for rotation according to claim 1 or claim 2, wherein the first article is spaced to receive the power from the power source, or the braking assembly is spaced to provide the first article with a resistance greater than the power.

10. An assembly for rotation according to claim 5, wherein the power source is a human body or a magnetic assembly or air pressure.

Technical Field

The present invention relates to an assembly, and more particularly to an assembly for rotation.

Background

The reaction force can not be well coexisted with the acting force all the time, and can not be well utilized at the same time, which is a bottleneck of the prior art. The reaction force sometimes causes inconvenience to people, for example, it is very difficult for several people to stand on a turntable and want to rotate the turntable in the same direction, which is very inconvenient for people, and countless scientists and inventors have been troubled about how to solve the technical problem.

Disclosure of Invention

It is an object of the present invention to provide an assembly for rotation that solves or at least mitigates at least one of the problems of the background art.

The technical scheme of the invention is as follows: an assembly for rotation, comprising a first object, a third object, a fourth object and a fifth object, wherein at least one first object is arranged on the third object, the first object is rotatably connected with the third object, and an axial center point or a mass center point of a body of the first object and an axial center point of the third object are not on the same axial line;

arranging a fourth object on the first object, wherein the mass of the fourth object is less than that of the first object, the fourth object is connected with or integrally formed with the first object, the fourth object transmits power to the first object, and the power is positioned outside the first object; the reaction force of the motive force acts on the third member or on a rotatable object directly or indirectly connected to the third member;

the rotary power of the first object is interacted with the rotary power of a rotary body with the opposite rotary direction of the first object through the fifth object;

the fifth object is connected to an object within or rotatable component connected to the one component for rotation.

Further, the radius of the first object is smaller than that of the third object or the third object is provided with a second object, the second object and the first object are rotatably connected with the third object, the axis of the second object and the axis of the first object are on the same axis or between the axis of the first object and the axis of the third object, the first object and the second object receive power provided by a power source, and the power directions received by the first object and the second object are opposite.

Further, the power source is disposed within or on a component connected to the one component for rotation.

Further, the reaction force of the power provided by the power source for the first object acts on the third object, and the ratio of the sum of the masses to the number of the first object is greater than the mass of the third object.

Further, the third object receives a kinetic energy difference of the first and second objects or a reaction force of the power provided by the power source.

Further, the ratio of the sum of the masses to the number of the first objects arranged on the third object is larger than the ratio of the sum of the masses to the number of the second objects.

Further, the third object and the first and second objects are round bodies or rotating bodies connected to a ring or a bearing by an object, the fourth object is a rod-shaped object or a round body or a magnetic material, and the fifth object is a brake assembly.

Further, the braking part comprises a first braking part and a second braking part, the first braking part is a motor stator, the second braking part is a motor rotor, the motor stator is connected with the second object, and the motor rotor is connected with the first object or is in discontinuous contact with the first object or is integrally formed with the first object.

Further, the first object intermittently receives the power of the power source, or the braking component intermittently provides a resistance force greater than the power for the first object.

Further, the power source is a human body or a magnetic component or air pressure.

The invention has the beneficial effects that: the acting force is applied outside the first object, so that the kinetic energy of the rotating body cannot be multiplied along with the multiplication of the moment, and the rotating bodies with opposite rotating directions convert the kinetic energy into electric energy through the interaction of the motor components, thereby recycling and achieving the purpose of saving energy. Meanwhile, the power device or the power source can be arranged in the rotating assembly or the rotating device connected with the rotating assembly, so that the power device or the power source is not limited by reaction force.

Drawings

Fig. 1 to 4 are schematic exploded views of different connection modes of a rotating component according to an embodiment of the present invention;

FIGS. 5, 7, 9 and 11 are preview reference views of a component for rotation in an embodiment of the invention;

fig. 6, 8, 10 and 12 are exploded views of the components of an assembly for rotation according to an embodiment of the present invention.

The correspondence between the components and the reference numbers in the above figures is as follows:

in the drawings: the motor comprises a first circular body 1, a second circular body 2, a motor stator 3, a motor rotor 4, a force arm part 5, a rotating shaft 6, a third circular body 7, a bearing 8, a magnetic body 11, an electromagnetic assembly 12, a screw 13, a fan blade 14, a sleeve 15 and an electronic clutch assembly 66.

Detailed Description

An embodiment of an assembly for rotation according to the present invention is described below with reference to the accompanying drawings.

In the present invention, it should be understood that the terms "outer", "outer ring", "inner ring", and the like are used in a directional or positional relationship based on the orientation or positional relationship shown in the drawings, which is for convenience of description only, and do not indicate or imply that the device relationship referred to has a particular orientation.

Please refer to fig. 1 to 4, which is a component for rotation, including a first object, a third object, a fourth object, and a fifth object, wherein at least one of the first object and the third object is disposed on the third object, the first object is rotatably connected to the third object, and an axial center point or a mass center point of a body of the first object and an axial center point of the third object are not on the same axial line;

arranging a fourth object on the first object, wherein the mass of the fourth object is less than that of the first object, the fourth object is connected with or integrally formed with the first object, the fourth object transmits power to the first object, and the power is positioned outside the first object; a first reaction force of the motive force acts on the third member or on a rotatable object directly or indirectly connected to the third member;

the rotary power of the first object is interacted with the rotary power of a rotary body with the opposite rotary direction of the first object through the fifth object;

the fifth object is connected to an object within or rotatable component connected to the one component for rotation.

FIG. 1 shows the connection of a first circular body 1 and a second circular body 2 by sleeving the same rotating shaft 6 and connecting the same rotating shaft 6 with a third circular body 7;

fig. 2 shows the second circular body connected to the third circular body 7 through the bearing 8, and the first circular body 1 is connected to the third circular body 7 through the rotating shaft 6, and the axes of the first circular body 1 and the second circular body 2 are on the same straight line; figure 4 shows the first circular body 1 connected to the second circular body 2 by means of a bearing 8 and the second circular body 2 in turn connected to the third circular body 7 by means of a large bearing, in the above described embodiment four items are chosen as arm members 5, rod-shaped or circular-shaped, and a first item is chosen as a motor assembly: motor electronics 3 and motor rotor 4

As shown in fig. 4, in the present embodiment, the connection mode of the first circular body 1 and the motor rotor 4 is further improved, and the first circular body 1 is integrally formed with the core of the motor rotor 4. Fig. 1 to 4 show the parts lifted upwards for reference, the connected motor rotor 4 being inside the motor stator 3, the remaining parts being connected in the described manner.

Fig. 3 shows the connection of the first circular body 1 and the third circular body 7 in different axial centers, as a further improvement, the diameter of the first circular body is smaller than that of the third circular body.

Fig. 5, 7, 9 and 11 only show that a plurality of first circular bodies can be arranged on the third circular body, and only the number is shown.

As shown in fig. 6, 8, 10, 12, which also show the parts lifted upwards for reference, the connected motor rotor 4 is inside the motor stator 3, and the rest parts are connected in a connection manner, and the scheme that the power source can be arranged on the rotating assembly is also exemplified.

An alternative to the fourth article in the embodiment of fig. 5 to 12 is a rod-shaped or circular object as the moment arm 5, and an alternative to the fifth article is a motor assembly: a motor electronics 3 and a motor rotor 4.

As shown in fig. 6, the first circular body 1 is connected with the motor rotor 4, the motor stator 3 is connected with the second circular body 2, the inner ring of the motor rotor 4 and the inner ring of the second circular body are provided with bearings 8, and the first circular body 1 and the second circular body 2 are connected with the third circular body 7 through the bearings 8.

In this embodiment, the rotation power of the first circular body 1 and the second circular body 2 is generated by the magnetic body 11 and the electromagnetic assembly 12, and the magnetic body 11 is disposed at the outer end of the arm member 5 and the outer ring of the second circular body 2 and connected to the outer ring of the second circular body 2 and the outer end of the arm member 5, respectively. The electromagnet assembly 12 is provided in the range of the radius surface of the third circular body 7, the center of the electromagnet assembly 12 is on the same line with the axial centers of the first circular body 1 and the second circular body 2, and a plurality of first circular bodies are provided on the third circular body 7 as shown in fig. 5.

After the above arrangement and connection, when the electromagnetic assembly 12 is energized, a magnetic field is generated, which is opposite to the magnetic field direction of the magnetic body 11, and the magnetic body 11 pushes the first circular body 1 and the second circular body 2 to rotate through the force arm 5. After the power is cut off, the first circular body 1 and the second circular body 2 continue to rotate, and after the motor components of the motor components are electrified on the two rotating bodies, the power of the first circular body 1 and the power of the second circular body 2 are gradually reduced by the braking of the motor components, and the mechanical energy of the rotating bodies is converted into electric energy to be recovered. And the electromagnetic assembly 12 side pushes the third circular rotating body to rotate.

The general working principle of the invention is as follows: the working principle is explained by taking a column which is easy to understand as the book formula is directly used for generating divergence, for example, two identical rotating bodies are arranged on the same rotating shaft which is fixed outside the shaft center of the same object, acting forces with the same size and opposite directions are respectively arranged on the outer rings of the two rotating bodies, the reaction force of the two acting forces acts on the object, the sum of the kinetic energy and the angular momentum of a mass element of the two identical rotating bodies is completely identical after the acting forces are opened for a short time, the kinetic energy difference is zero after the two rotating bodies are contacted through a braking component, and the resultant force of the reaction force of the acting forces is also zero. Now, a force arm is connected with the outer ring of one rotating body, the force arm is not needed to be considered, the mass of the force arm keeps the force acting on the force arm at a certain distance from the outer ring of the rotating body, and the position of the force acting on the other rotating body is kept unchanged. Because the reaction force moves along with the movement of the acting force, the resultant force difference of the two reaction forces to the object is obtained, the resultant force difference is the power for pushing the object, the force arm is connected at the outer side of the mass element of the rotating body, the force arm is multiplied, the kinetic energy of the rotating body and the angular momentum of the mass element are not multiplied, when the two rotating bodies are contacted through the braking component after the acting force is cut off, the difference of the kinetic energy of the two rotating bodies with opposite rotating directions is not multiplied, and the difference of the reaction forces of the two acting forces can be multiplied. So that the whole rotating system will generate kinetic energy. For example, the force arm is extended by 1000 meters, the acting force is kept unchanged, the kinetic energy of the rotating body does not become 1000 times in unit time, the difference side of the kinetic energy generated by the two reaction forces on the object can be increased by 1000 times in unit time, the force arm added to the outer ring of the rotating body only increases the work done by the acting force in unit time, the mass of the rotating body added with the force arm can be added to ensure that the work done by the two acting forces with equal magnitude and opposite directions in unit time is the same, the work done by the two acting forces in unit time is the same, the lost impulse is also the same, and therefore, the difference value of the two rotating bodies is not 1000 times as before, which goes against the conventional principle. The added mass only can increase the moment of inertia of the rotating body, and simultaneously reduces the angular speed of the rotating body, the angular momentum of the mass element of the rotating body cannot be multiplied, and the total angular momentum of the mass elements of the rotating body cannot be multiplied, so that the difference of the kinetic energies of the two rotating bodies can be smaller than the kinetic energy difference of the reacting force of the two acting forces to the object.

If the kinetic energy of the object is increased in the same time, only the moment arm of the rotating body with the moment arm needs to be extended, the radius of the object is increased, the increased radius of the object certainly has a mass element, and meanwhile, the most convenient method for saving the work is to increase the mass of the rotating body with the moment arm so that the two acting forces can perform the same work in unit time. When the acting force is cut off, the two rotating bodies interact with each other through the braking assembly to convert kinetic energy into electric energy. Because the two rotating bodies are connected with the object through the rotating shaft, the difference value of the reaction force of the two acting forces to the object pushes the object and the two rotating bodies to rotate.

When the diameters of the two rotating bodies are equal, the force arm acting force can be arranged on one rotating body and acts on the force arm to keep a certain distance with the rotating body, so that different moments can be generated when the reaction forces of the two acting forces act on an object. Therefore, the object has certain kinetic energy, the kinetic energy is in direct proportion to the force arm, the kinetic energy difference of the two rotating bodies is smaller than the kinetic energy of the object after the acting force is short, and the kinetic energy of the object is the power for pushing the rotating assembly to rotate. The mass is added to the rotating body provided with the force arm member due to the resistance and the friction force, and the mass added to the rotating body provided with the force arm member can be determined according to actual conditions, or the mass of the rotating body without the force arm member can be reduced.

It should be noted that the mass is added to illustrate the principle of the rotating body, and the mass is not necessarily added, and the mass ratio of the two rotating bodies under the condition of performing the same work can be measured by the mass addition, so as to determine the size of the rotating body. But can of course also be calculated according to a formula.

When the two rotating bodies are coaxially connected and have unequal diameters, a force arm can be arranged on the outer ring of any one rotating body, when the force arm is arranged on the outer ring of the rotating body with the small diameter, the reaction force of the acting force can act in the diameter range of the large rotating body, and similarly, the two rotating bodies can also generate power difference; when the force arm is arranged on the rotator with large diameter, the force arm can be randomly extended or preset until power is generated, when the rotator with the force arm is directly connected with an object in a non-coaxial manner, kinetic energy can be generated, large kinetic energy can be obtained by presetting the force arm or presetting a radius, increasing the force arm or increasing the radius of one rotator or decreasing the radius of one rotator, and the axis of the rotator without the force arm can be arranged between the axis of the rotator with the force arm and the axis of the object, so long as the range of the difference value of the preset kinetic energy is within the range.

The above is the working principle of an assembly for rotation of the present invention.

The block diagram shown in fig. 6 is also based on the principle that the electromagnetic assembly pushes the entire assembly to rotate.

In the embodiment shown in fig. 8, the first circular body 1 is connected to the third circular body 7 through the rotating shaft 6 in a staggered manner, the first circular body 1 is a hollow body, the force arm 5 is a hollow pipe connected to the first circular body, two ends of the hollow pipe are penetrated, the power assembly is also the magnetic body 11 and the electromagnetic assembly 12, the upper end of the rotating shaft 6 is provided with a sleeve 15, a hole sleeve penetrating through the inner wall of the sleeve is arranged at the hollow part of the first circular body, a fixed end is arranged on the outer ring of the sleeve, the magnetic body is arranged in the sleeve, and the electromagnetic assembly is connected to the fixed end of the sleeve through a screw 13. The third circular body is provided with fan blades 14 which are used for blocking the speed of air so as to generate reaction force, after the connection is completed, the electromagnetic assembly 12 is electrified to generate a magnetic field opposite to the magnetic body 11, so that the magnetic body is pushed to do piston motion, the compressed air generates the reaction force and the reaction force, and the output end of the force arm piece 5 at the outer end of the first circular body can generate rotation kinetic energy difference with the third circular body, and the difference value is the power for pushing the rotation of the assembly. Fig. 7 shows that a plurality of first circular bodies may be provided to facilitate stable rotation. Fig. 9 also shows that a plurality of one circular bodies and a plurality of second circular bodies can be arranged on the third circular body 7.

Referring to fig. 10, the working process of the embodiment of fig. 10 is the same as that of fig. 8, and the structural difference is that the rotating shaft 6 is a hollow pipe, a hole penetrating through the inner wall is formed in the hollow pipe, the position of the rotating shaft 6 with the hole is in the second circular body, the circular bodies 1 and 2 are arranged on the same rotating shaft 6 and are connected with the third circular body 7 through the rotating shaft, the hollow pipe is also arranged on the outer ring of the second circular body, and the length of the hollow pipe of the first circular body is longer than that of the hollow pipe of the second circular body, so that the kinetic energy difference of the reaction force is obtained.

FIGS. 12 and 11 show the embodiment of the structure of the first circular body 1 having a smaller radius than the second circular body 2

In fig. 12 and 11, a force arm 5 is arranged on the outer side of a first circular body 1, a motor stator 3 is connected with a second circular body 2, a motor rotor 4 is connected with the first circular body 1, a bearing 8 is arranged on the inner ring of the motor rotor 4, the first circular body 1 is connected with a third circular body 7 through a rotating shaft 6, a magnetic body 11 is connected with the outer end of the force arm, an electromagnetic assembly 12 is arranged on the outer ring of the second circular body and connected with the second circular body, the second circular body is rotatably connected with the third circular body 7, an assembly 66 of an electronic clutch is arranged on the outer side of the second circular body so as to facilitate the third circular body to receive the kinetic energy difference of the first circular body and the second circular body, in the embodiment, a reaction force is arranged on the second circular body so that the kinetic energy difference only depends on the two rotating bodies, and the radius of the third circular body can be changed freely; of course, the reaction force can also be provided on the third circular body, and when provided on the third circular body, the clutch can be eliminated, since the difference of the third circular body can be greater than the difference of the two rotating bodies, the contact of the two rotating bodies being always power consuming.

When the electromagnetic assembly 12 is energized, a magnetic field generated by the magnetic field is opposite to the magnetism of the magnetic body 11 to generate thrust, the first circular body 1 and the second circular body 2 rotate in opposite directions, and a moment arm part is arranged on the outer ring of the first circular body to generate a difference value because the radius of the first circular body is smaller than that of the second circular body. When the power supply is switched on for a short time, the kinetic energy of the two rotating bodies is converted into electric energy through the motor assembly, and the electronic clutch transmits the residual kinetic energy to the third circular body, so that the whole assembly is driven to rotate.

It should be noted here that the resistance generated by the motor assembly is actually a pair of balance forces that ultimately only transmit, and that when the resistance experienced by the first circular body is greater than the power, the same difference will be true as the remaining rotational power of the inertial first circular body will interact with the remaining rotational power of the second circular body, with intermittent power being an alternative to intermittent power or allowing the circular bodies to receive power intermittently.

Through the above-mentioned embodiments, it can be obtained that the power source can be a power source arranged on one rotating body to provide power for the rotating device, and the power source can be a pair of balance forces or a plurality of pairs of balance forces, and the first rotating body intermittently receives power to accelerate the rotating device to rotate. Convenience is brought to the daily life of people by applying power to the outside of one rotating body so that the whole assembly or a rotating device comprising the assembly can rotate, for example, two human bodies can rotate on the rotating assembly as shown in fig. 3 when the human body pushes the power arm rod to rotate, and the feet provide reverse acting force for the third round body, so that the whole assembly can rotate by intermittently providing power, thereby better solving the problem of non-rotation.

The above are only examples of the present invention and are not intended to limit the scope of the present invention, and it should be understood by those skilled in the art that the present invention is not limited by the description of the present invention and the accompanying drawings.