TWM512853U - Electromagnetic device - Google Patents

Description

Electromagnetic device

This creation belongs to the field of electromagnetic technology, specifically refers to an electromagnetic device that can quickly destroy the magnetic balance of proliferation, so as to enhance the magnetic assistance in the forward direction, and reduce the kinetic energy loss caused by the proliferative magnetic attraction under load, thereby improving its energy. Conversion efficiency.

Generally, the electromagnetic device is made according to Fleming's right-hand rule, which is generally constituted by a set of relative motion and magnetic lines of force, the electromagnetic device comprising at least one magnetic group and at least one induction coil group. They are defined as a rotor and a stator, respectively, so that the induction coil group generates a voltage due to magnetic line cutting, and achieves the purpose of power generation.

Since the induction coil assembly is connected to the load, the right hand of the ampere will generate current and electromagnetic, and the induction coil group will be magnetic. Since the magnetic field lines of the induction coil group are vertically staggered with respect to the relative movement direction, the magnetic field is proliferated. The suction system has a single suction point vertical shape, and its hyperplastic magnetic attraction tends to cause a strong suction state, so its vertical vector component is large, which is not conducive to the horizontal movement direction, but has the effect of blocking the forward movement, and further it has a single suction. Point, therefore, under the load, there will be kinetic energy loss caused by more hyperplastic magnetic attraction; when the kinetic energy loss occurs, the input kinetic energy of the actuating rotor in the electromagnetic device must be increased, and the requirement of micro-power generation cannot be achieved, and the second is Proliferated magnetic The effect of kinetic energy loss will also reduce the rate at which it operates, thus affecting the efficiency of energy conversion.

In other words, if it can quickly destroy the equilibrium state of its hyperplastic magnetic attraction and enhance the forward magnetic assistance of its moving direction, it is believed that the kinetic energy loss of the hyperplastic magnetic attraction can be reduced, thereby increasing the energy conversion rate. This purpose is believed to be urgently developed by the industry. By.

In view of this, the creator has in-depth discussion on the problems faced by the above-mentioned existing electromagnetic devices, and has actively pursued solutions through years of research and development experience in related industries, and has succeeded in research and trials. Developed an electromagnetic device that can increase the energy conversion rate, thereby overcoming the inconvenience and trouble caused by the kinetic energy loss of the existing hyperplastic magnetic attraction.

Therefore, the main purpose of this creation is to provide an electromagnetic device that can quickly destroy the magnetic balance of the proliferation, thereby generating the effect of the micro force drive, thereby reducing the kinetic energy loss, thereby increasing the energy conversion rate.

Moreover, another main object of the present invention is to provide an electromagnetic device capable of enhancing the forward magnetic assistance in relative motion, so that it can utilize the double magnetic attraction point to amplify the vector component of the moving direction, improve its kinetic energy, and further enhance its Energy conversion rate.

Based on this, the present invention mainly achieves the foregoing objects and functions by the following technical means, which are composed of a magnetic group and at least one induction coil group, and the magnetic groups can be respectively defined as a rotor or a stator. And the induction coil groups can be respectively defined as a stator or a rotor, so that the magnetic group and the induction coil group can generate a relative motion of rotation or linearity, and the present invention is characterized in that the magnetic group has at least one magnetic member and is adjacent to each other. The magnetic members are arranged in series in the same polarity, and the magnetic poles of each magnetic member are parallel with the moving direction. Furthermore, each of the induction coil groups has a magnetizer, and a coil having a direction parallel to the direction of motion is disposed around the magnetizer, and the magnets of each of the induction coil groups can generate magnetic assistance for the direction of motion. One end is provided with a yoke of a larger diameter.

Thereby, through the display of the foregoing technical means, the magnetic field lines of the magnetic component of the magnetic group and the coils of the induction coil group are arranged in parallel with the moving direction to generate a double magnetic attraction point, and at the same time, the induction coil group is One end of the magnet is provided with a design of a large diameter yoke, and the yoke of the larger diameter can be used to break the balance of the magnetic attraction at both ends, thereby making it possible to enlarge the horizontal vector component and effectively reduce the dynamic loss rate. Therefore, the effect of the micro-force drive can be generated, and the vector component of the motion direction can be amplified to improve the kinetic energy, and under the inertial acceleration, the large current can be effectively generated, the power generation capacity can be increased, and the energy conversion rate can be further enhanced, thereby improving power generation. Efficiency, so it can greatly increase its added value and improve its economic efficiency.

In order to enable the review board to further understand the composition, characteristics and other purposes of the creation, the following are some of the preferred embodiments of the creation, and the detailed description of the creation is as follows, and the person familiar with the technical field can be implemented. .

(10) ‧‧‧Magnetic Group

(11)‧‧‧Magnetic parts

(20)‧‧‧ coil group

(21)‧‧‧ Magnets

(22)‧‧‧ coil

(25) ‧ ‧ yoke

The first picture is a schematic diagram of the structure of the electromagnetic device of the present creation.

The second figure is a schematic diagram of the operation of the electromagnetic device of the present invention with the magnetic group as the rotor, for explaining the state of the magnetic group from the S pole to the N pole.

The third figure is a schematic diagram of the action of the magnetic device of the present invention with the magnetic group as the rotor, for explaining the state of the magnetic group from the N pole to the S pole.

The fourth figure is a schematic diagram of the action of the electromagnetic device of the present invention with the induction coil group as the rotor, for explaining the state of the magnetic pole N pole to the S pole.

Fig. 5 is a schematic view showing the operation of the electromagnetic device of the present invention with the induction coil group as a rotor for explaining the state of the magnetic group S to the N pole.

The present invention is an electromagnetic device, and the specific embodiments of the present invention and its components, as illustrated in the accompanying drawings, all references to front and rear, left and right, top and bottom, upper and lower, and horizontal and vertical, only For convenience of description, it is not intended to limit the creation of the invention, nor to limit its components to any position or space. The drawings and the dimensions specified in the specification may be varied according to the design and needs of the specific embodiments of the present invention, without departing from the scope of the invention.

The electromagnetic device of the present invention is constructed as shown in the first figure, and the electromagnetic device is composed of a magnetic group (10) and at least one induction coil group (20), and the magnetic groups (10) can be respectively Defined as a rotor or a stator, and the induction coil groups (20) can be defined as a stator or a rotor, respectively, so that the magnetic group (10) and the induction coil group (20) can generate rotational or linear relative motion; The magnetic group (10) is composed of at least one magnetic member (11), and the adjacent magnetic members (11) are arranged in series in the same polarity, and the magnetic poles (N poles) of each magnetic member (11) And the S pole) is parallel with the moving direction of the magnetic group (10) or the induction coil group (20) as a rotor, and each of the induction coil groups (20) has a magnet (21) and a magnetizer (21) A coil (22) is disposed around the coil, and the coil (22) extends in a direction of a winding on the magnetizer (21) and is parallel to a moving direction of the magnetic group (10) or the induction coil group (20) as a rotor. Further, each of the magnets (21) of the induction coil group (20) is provided with a larger diameter yoke (25) at an end that can generate a magnetic assistance force in the moving direction, for example, when the magnetic group (10) is used. When the rotor and the induction coil group (20) function as a stator, the yoke ( 25) is disposed at one end of the magnetizer (21) different from the direction of movement of the magnetic group (10) (as shown in the second and third figures), and the fixed induction coil group (20) can increase the displacement of the suction magnetic group (10) The force. Conversely, when the induction coil group (20) is used as the rotor and the magnetic group (10) is used as the stator, the yoke (25) is disposed at one end of the magnetizer (21) relative to the direction of movement of the induction coil group (20) (such as the fourth And the magnetic group (10) for fixing can increase the force of the displacement of the suction induction coil group (20); thereby, the group constitutes an electromagnetic device capable of increasing the forward magnetic assistance and reducing the kinetic energy loss. By.

As for the actual operation of the electromagnetic device of the present invention, first, the magnetic group (10) is used as the rotor, and the induction coil group (20) is used as the stator. For example, please refer to the second and third figures, when the magnetic group (10) is relatively inductive. When the coil assembly (20) is displaced, when one of the magnetic members (11) moves toward the N pole of the magnetic member (11) with its S pole, the magnetic lines of the magnetic member (11) of the magnetic group (10) are parallel to the moving direction. Therefore, a double magnetic attraction point can be generated with respect to the induction coil group (20) (as in (A) of the second figure). If the induction coil group (20) is connected to the load, the magnetic group (10) corresponds to the moving direction and the proliferation. The negative force generated by the magnetic attraction is greater than the positive force, so the coil (22) of the induction coil group (20) is not connected to the load at this time; and since it has a double magnetic attraction point, when the magnetic attraction balance is developed at both ends thereof , as shown in (B) of the second figure, the magnetic groups (10) are in a zero-torque state and are not affected by the proliferative magnetic attraction; and when the coils (22) of the induction coil group (20) are connected to the load, Then, as shown in (C) of the second figure, since the magnet (21) of the induction coil group (20) is different from the yoke (25) having a larger diameter at one end in the moving direction of the magnetic group (10), the magnetic group ( 10) Corresponding operation In the forward direction, the positive force generated by the hyperplastic magnetic attraction is greater than the negative force, and the magnetic yoke (25) of the magnet (21) of the induction coil group (20) rapidly destroys the proliferative magnetic equilibrium relationship, so that the magnetic group ( 10) was Fast driving, enhancing the magnetic assistance of the magnetic group (10) in the moving direction; further, when the magnetic member (11) is moved with its N pole toward the S pole of the magnetic member (11), it is as shown in the third figure. (A)~(C), the magnetic lines of the magnetic members (11) of the magnetic group (10) are parallel to the moving direction, so that a double magnetic attraction point can be generated with respect to the induction coil group (20) (as in the third figure ( A)), if the load is connected to the induction coil group (20), the magnetic group (10) corresponds to the moving direction, and the negative force generated by the hyperplastic magnetic attraction is greater than the positive force, so the induction coil group (20) The coil (22) is not connected to the load; and since it has a double magnetic attraction point, when the magnetic attraction balance is developed at both ends thereof, as shown in (B) of the third figure, the magnetic groups (10) are at The zero-torque state is not affected by the proliferative magnetism; and when the coil (22) of the induction coil group (20) is connected to the load, as shown in the third figure (C), due to the induction coil group (20) The magnet (21) is different from the yoke (25) having a larger diameter at one end in the moving direction of the magnetic group (10), and the magnetic group (10) corresponds to the moving forward direction, so that the positive force generated by the proliferative magnetic force is greater than the negative force. And let the induction coil set (20) Magnetizer (21) of the yoke (25) magnetically rapid destruction proliferation balance, as can the magnetic group (10) is driven quickly, thereby enhancing the magnetic group (10) to the forward movement direction of the magnetic power.

In addition, when the actual operation of the electromagnetic device of the present invention uses the magnetic group (10) as the stator and the induction coil group (20) as the rotor, please refer to the fourth and fifth figures, when the induction coil group (20) is opposite. When the magnetic group (10) is displaced, and the induction coil group (20) is moved from the N pole of one of the magnetic members (11) toward the S pole of the magnetic member (11), the magnetic member (11) magnetic field line of the magnetic group (10) Parallel to the direction of motion, so that a double magnetic attraction point can be generated with respect to the induction coil group (20) (as in the fourth diagram (A)), and if the induction coil group (20) is connected to the load, the induction coil group (20) Corresponding operation In the forward direction, the negative force generated by the hyperplastic magnetic attraction is greater than the positive force, so the coil (22) of the induction coil group (20) is not connected to the load; and since it has a double magnetic attraction point, When the hyperplastic magnetic attraction balance is as shown in the fourth figure (B), the induction coil group (20) is in a zero-torque state and is not affected by the proliferative magnetic attraction; and when the induction coil group (20) is coiled ( 22) When the load is connected, as shown in (C) of the fourth figure, since the magnetizer (21) of the induction coil group (20) has a larger diameter yoke at one end in the moving direction of the induction coil group (20) ( 25), the induction coil group (20) corresponds to the moving forward direction, so that the positive force generated by the proliferative magnetism is greater than the negative force, and the magnetizer (21) of the induction coil group (20) is rapidly yoke (25) Destroying the proliferative magnetic balance relationship, so that the induction coil group (20) is rapidly driven, enhancing the magnetic assistance force of the induction coil group (20) toward the moving direction; further, when the induction coil group (20) is composed of the magnetic group (10) When the magnetic pole of the magnetic member (11) is moved toward the N pole of the magnetic member (11), it is as shown in the fifth figure (A) to (C), and the magnetic member (11) of the magnetic group (10) is magnetically lined. With the sports side Parallel, so that a double magnetic attraction point can be generated with respect to the induction coil group (20) (as in the fifth diagram (A)). If the induction coil group (20) is connected to the load, the induction coil group (20) moves forward correspondingly. In the direction, the negative force generated by the hyperplastic magnetic attraction is greater than the positive force, so the coil (22) of the induction coil group (20) is not connected to the load; and since it has a double magnetic attraction point, the magnetic flux is proliferated at both ends thereof. When the suction balance is as shown in (B) of the fifth figure, the induction coil group (20) is in a zero-torque state and is not affected by the proliferative magnetic attraction; and when the induction coil group (20) is coiled (22) When the load is connected, as shown in (C) of the fifth figure, the yoke (25) having a larger diameter at one end of the magnet (21) of the induction coil group (20) relative to the direction of movement of the induction coil group (20) , the induction coil group (20) corresponds to the direction of motion, and more causes the proliferation of magnetic The positive force is greater than the negative force, and the yoke (25) of the induction coil group (20) can be used to rapidly destroy the proliferative magnetic balance relationship, which can cause the induction coil group (20) to be quickly driven, thereby The magnetic assistance of the induction coil group (20) in the moving direction is enhanced.

In summary, the magnetic lines of the magnetic member (11) of the magnetic group (10) and the coils (22) of the induction coil group (20) are arranged in a direction parallel to the moving direction, so that a double magnetic attraction point is generated, and the induction coil group is simultaneously (20) The design of the larger diameter yoke (25) is provided at one end of the magnet (21), and the yoke (25) of the larger diameter can be used to break the balance of the magnetic attraction at both ends, thereby making it possible to make the level Vector component amplification, which can effectively reduce the dynamic loss rate, can produce the effect of micro-force drive, and simultaneously amplify the vector component of the motion direction to improve its kinetic energy, and can effectively generate large current and increase power generation under inertial acceleration. Its effectiveness further enhances its energy conversion rate.

In this way, it can be understood that this creation is an excellent creation. In addition to effectively solving the problems faced by the practitioners, the effect is greatly enhanced, and the same or similar product creation or public use is not seen in the same technical field. At the same time, it has the effect of improving the efficiency. Therefore, this creation has met the requirements of "newness" and "progressiveness" of the new patent, and is applying for a new type of patent according to law.

(10) ‧‧‧Magnetic Group

(11)‧‧‧Magnetic parts

(20)‧‧‧ coil group

(21)‧‧‧ Magnets

(22)‧‧‧ coil

(25) ‧ ‧ yoke

Claims (4)

An electromagnetic device comprising: a magnetic group defined as a rotor and at least one induction coil group defined as a stator; wherein the magnetic group has at least one magnetic member and adjacent magnetic members The two magnetic poles of each magnetic member are parallel with the moving direction of the magnetic group as the rotor, and each of the induction coil groups has a magnetizer, and a coil is disposed around the magnetizer. The winding of the coil on the magnetizer extends in a direction parallel to the direction of movement of the magnetic group as the rotor, and the magnet of the induction coil group is different from the direction of movement of the magnetic group. yoke. An electromagnetic device comprising: a magnetic group defined as a stator and at least one induction coil group defined as a rotor; wherein the magnetic group has at least one magnetic member and adjacent magnetic members The two poles of the magnetic members are parallel with the moving direction of the induction coil group as the rotor, and the induction coil group has a magnetizer, and the magnetizer is surrounded by a magnet. a coil, the winding of the coil on the magnetizer extends in a direction parallel to the direction of movement of the induction coil assembly as the rotor, and the other end of the induction coil assembly has a larger end with respect to the direction of movement of the induction coil assembly The yoke of the diameter. The electromagnetic device of claim 1 or 2, wherein the relative movement of the magnetic groups and the sets of induction coils is a rotational motion. The electromagnetic device of claim 1 or 2, wherein the relative movement of the magnetic groups and the sets of induction coils is linear.