TW201906288A - Bus-type magnetic block electric device capable of generating the effective magnetic assisting force to produce kinetic energy for output and achieving energy-saving effect - Google Patents

Abstract

The invention relates to a bus-type magnetic block electric device, which is composed of at least one first field magnetic set, at least one second field magnetic set parallel to the first field magnetic set, at least one middle magnetic set parallel to and disposed between the first field magnetic set and the second field magnetic set, and at least one inductive switch set. The first and the second field magnetic sets are composed of at least a first and a second magnetic members and at least a third and a fourth magnetic members arranged at intervals along the moving direction, the magnetic poles of the adjacent first and second magnetic members and the third and fourth magnetic members are oppositely facing each other, furthermore, the magnetic channel space of the first and second field magnetic sets forms a closed region with a directional magnetic flow in a parallel moving direction between the departing points at two ends of the magnetic field lines. The opposed magnetic poles in the third and fourth magnetic members of the second field magnetic set and the corresponding first and second magnetic members of the first field magnetic set have the same poles opposite to each other, so that a magnetic field line space having a vertical Magnetic Drag Force being canceled is produced between the first and third magnetic members and the second and fourth magnetic members of the first and second field magnetic sets. The inductive switch set can control the field magnetic set or the middle magnetic set to supply power in the closed region, and there is no power supplied outside the closed region; as a result, the utilization of the magnetic flux can be improved and the kinetic energy loss can be reduced, so that the field magnetic set and the middle magnetic set mutually generate the most effective magnetic assisting force with leading-end attraction and trailing-end repulsion in the closed region, it effectively improves the outputted kinetic energy to achieve the energy-saving effect.

Description

 Confluent magnetic blocking electric device  

The invention belongs to the technical field of an electric device, in particular to a bus-type magnetic blocking electric device, so that the magnetic lines merge to form a magnetic channel, thereby increasing the magnetic force and further reducing the magnetic field interference across the magnetic region. Reduce kinetic energy loss, improve energy conversion efficiency, and save energy.

According to the general electric device (that is, the general motor), the two opposing magnetic groups are respectively composed of a stator and a rotor, wherein at least one magnetic group is composed of a coil, and the electromagnetic power is intermittently supplied to the coil to make it electromagnetic. Iron, which can generate a magnetic force that repels and attracts relative to another magnetic group, thereby driving the rotor to rotate at a high speed. In the operation of the existing electric device, an intermittent power supply mode is adopted to extract the required magnetic force to drive the rotor. However, under the high magnetic resistance dynamic loss, the output power of the existing electric device is not good; For this reason, the inventor has previously developed a patent for the invention of the "closed high torque electric device" of the Japanese Patent Application No. 105127575, which is composed of at least one magnetic group, at least one central magnetic group and at least one inductive switch group. The medium magnetic group can be relatively moved in the magnetic flux space of the field magnetic group, and the field magnetic group is vertically magnetized by two relative motion directions, and the first magnetic member and the second magnetic pole are opposite to each other. The magnetic component is formed such that a magnetic line space which is offset by the vertical magnetic resistance is formed between the first and second magnetic members of the field magnetic group, and the central magnetic group is magnetized in parallel with respect to the relative motion direction, and the magnetic field is opposite to the field. The magnetic group enters the opposite end of the magnetic pole, and the magnetic field space of the field magnetic group forms a closed region of the parallel magnetic direction of the parallel magnetic field at the magnetic flux lines at the two ends, and the sensing switch group can further control the field magnetic group. Or medium The magnetic group is energized in the closed region, and no power is supplied outside the closed region, so that the field magnetic group and the central magnetic group generate magnetic force of the front magnetic attraction and the rear magnetic repulsion in the closed region, which can effectively improve the kinetic energy of the output, and It can save energy by reducing the loss of movement.

However, it can be more refined in practical applications. In the first figure, since the field magnetic group (10) is vertically magnetized by two relative movement directions and is opposite to the same one of the first magnetic member (11) and the second magnetic member (12), Therefore, the magnetic lines of force between the first and second magnetic members (11, 12) are relatively compressed due to the repulsiveness of the same pole. Although magnetic fluxes in the direction of parallel motion can be formed, magnetic flux clogging due to relative compression causes problems. The magnetic field expands outward, causing the utilization of magnetic lines to decrease, affecting its efficacy. In addition, as shown in the second figure, since the middle magnetic group (20) is disposed between the first and second magnetic members (11, 12) of the field magnetic group (10), a coil member capable of horizontally magnetizing in a relative movement direction is provided. (21), because when the magnetization of the middle magnetic group (20) coil member (21) is magnetized, it will interfere with the magnetic field of the magnetic field across the adjacent first and second magnetic members (11, 12) or the magnetic gap. The reaction force is formed to improve the dynamic loss and energy consumption, and the efficiency of the electric device is greatly reduced. Furthermore, as shown in the third figure, when there are two or more adjacent field magnetic groups (10) and medium magnetic group (20) coil members (21), as the adjacent field magnetic groups (10) are the same In the case of a very adjacent shape, the adjacent coil members (21) of the middle magnetic group (20) will be adjacent to each other due to the induced polarity due to the magnetic assistance of the front magnetic attraction and the rear magnetic repulsion. The reverse inertial magnetic current is generated to form a magnetic line interference across the magnetic domain, causing a problem of weakening of the magnetic force.

In other words, the creation has a further refined space, that is, to improve the utilization of magnetic flux, and to reduce the magnetic field interference between the magnetic field and the magnetic field of the reverse inertial magnetic current, thereby enhancing the magnetic force and reducing the magnetic resistance during operation. In order to increase the magnetic assistance during driving, the power and energy saving effect of the output can be improved, and how to achieve the aforementioned purpose and performance is expected by the present invention.

In view of this, the present inventors have intensively discussed the problems faced by the aforementioned electric devices, and actively pursued solutions through years of research and development experience in related industries, and have succeeded in developing a kind of research through continuous efforts in research and trials. The confluent magnetic blocking electric device can further improve the magnetic line utilization rate of the electric device, and reduce the magnetic field interference between the magnetic field and the magnetic field of the reverse inertial magnetic current, thereby increasing the magnetic force.

Therefore, the main object of the present invention is to provide a confluent magnetic blocking electric device, which can effectively improve the utilization rate of the magnetic flux, thereby enhancing the magnetic assist stress, effectively improving the output power, and achieving the energy saving effect.

Moreover, another main object of the present invention is to provide a bus-type magnetic blocking electric device capable of weakening interference across a magnetic domain to reduce its reaction force, thereby reducing kinetic energy loss and improving operational efficiency.

In addition, the second main object of the present invention is to provide a confluent magnetic blocking electric device capable of avoiding interference across a magnetic field, thereby preventing reverse inertial magnetic current when a multi-magnetic group acts, and preventing weakening of magnetic action, further Improve the reliability of its operation.

Based on this, the present invention mainly achieves the foregoing objects and effects by the following technical means, which is at least a first field magnetic group, at least one parallel first field magnetic group, and a second field magnetic group, at least one. The central magnetic group and the at least one inductive switch group are formed, and the first and second field magnetic groups can synchronously generate linear or rotational motion with respect to the middle magnetic group; and the first field magnetic group is separated by the moving direction Arranging at least one first magnetic member and at least one second magnetic member, wherein the first and second magnetic members are of equal length, and the first and second magnetic members are magnetized in a vertical motion direction, and The magnetic poles corresponding to the second field magnetic group of the first or second magnetic members or the second and second magnetic members are adjacent to each other; and the second magnetic field group of the second magnetic field is arranged by at least one of the intervals along the moving direction. a third magnetic member and at least a fourth magnetic member, wherein the third and fourth magnetic members have the same length, and the third and fourth magnetic members are magnetized in a vertical direction, and adjacent to the third The magnetic field corresponding to the first field magnetic group of the four magnetic members or the fourth and third magnetic members The opposite poles are adjacent, and the third and fourth magnetic members of the second field magnetic group are opposite poles of the first and second magnetic members corresponding to the first field magnetic group, and the first and second fields are opposite. The magnetic group forms a magnetic line space which is offset by the vertical magnetic resistance between the first magnetic member and the third magnetic member and the second magnetic member and the fourth magnetic member; and the middle magnetic group is parallel and is disposed on Between the first and second field magnetic groups, wherein the central magnetic group is composed of at least one fifth magnetic member and at least one sixth magnetic member that are magnetized in a parallel motion direction and are arranged along the moving direction, wherein the first The five magnetic members are adjacent to the adjacent poles of the sixth magnetic members, and the fifth and sixth magnetic members of the central magnetic group are opposite to the first and second magnetic groups. The first and third magnetic members of the field magnetic group are opposite to the second and fourth magnetic members, and the first and third magnetic members and the second and fourth magnetic members of the first and second field magnetic groups are opposite. The magnetic line space is a closed region where the magnetic fluxes at both ends deviate from the points to form a directional magnetic flow in a parallel motion direction; The sensing switch group includes at least one power detecting device disposed in the first and second field magnetic groups, at least one power detecting device, and at least one sensor disposed in the middle magnetic group, wherein the power detecting device The first and third magnetic members of the first and second field magnetic groups are in the closed region of the second and fourth magnetic members, and the corresponding positions of the magnetic lines of the central magnetic group are separated from each other according to the moving direction, and the power is cut off. The locator is disposed at a corresponding position of the first and third magnetic members of the first and second field magnetic members and the second and fourth magnetic members in the closed region of the second and fourth magnetic members away from the magnetic line of the central magnetic group. The inductors are disposed in the middle of the fifth and sixth magnetic members of the middle magnetic group.

In summary, the present invention realizes that the first and second magnetic members of the first and second field magnetic groups of the present invention are perpendicularly magnetized in the relative motion direction and are different in polarity by the implementation of the foregoing technical means. Adjacent, the magnetic flux flows in the magnetic channel space between the first and second field magnetic groups without outward diffusion, increasing the utilization of magnetic flux and enhancing its magnetic assist stress, and further The five or six magnetic members are adjacent to each other, so that the magnetic field can be managed, and the interference of the magnetic field can be weakened, the reaction force can be reduced, and the dynamic loss and energy consumption can be reduced, thereby greatly improving the performance of the electric device and avoiding the cross The interference of the magnetic field can eliminate the reverse inertial magnetic current, and further strengthen the magnetic auxiliary stress, so that the rotation speed and the power can be increased, and the energy conversion efficiency can be improved, and the economic benefit of energy saving can be further realized.

The following is a description of the preferred embodiments of the present invention, and is described in detail with reference to the drawings, and the .

(10) ‧‧‧ Field Magnetic Group

(11)‧‧‧First magnetic parts

(12)‧‧‧Second magnetic parts

(20) ‧‧‧中磁组

(21)‧‧‧Circle parts

(50) ‧‧‧First Magnetic Group

(51)‧‧‧First magnetic parts

(52) ‧‧‧Second magnetic parts

(60) ‧‧‧Second magnetic group

(61)‧‧‧ Third magnetic parts

(62) ‧ ‧ fourth magnetic parts

(70) ‧‧‧中磁组

(71) ‧‧‧ fifth magnetic parts

(72) ‧‧‧ sixth magnetic parts

(80)‧‧‧Induction switch set

(81) ‧‧‧Power detector

(82) ‧‧‧Power failure detector

(85)‧‧‧ Sensors

The first figure is a schematic diagram of the opposite magnetic group structure applied to the vertical magnetization of the electric device.

The second figure is a schematic diagram of the action of the opposing magnetic group and the coil component applied to the vertical magnetization of the electric device.

The third figure is a schematic diagram of the action of multiple sets of opposite magnetic groups and multiple sets of coil components applied to the vertical magnetization of the electric device.

Fourth FIG. 4 is a schematic structural view of a preferred embodiment of a busbar magnetic blocking electric device according to the present invention.

Fig. 5 is a schematic view showing the operation of the preferred embodiment of the confluent magnetic blocking electric device of the present invention for explaining the state of the magnetic attraction in the front stage.

Fig. 6 is a schematic view showing the operation of the preferred embodiment of the bus-type magnetic blocking electric device of the present invention for explaining the state of the magnetic repulsion in the latter stage.

Figure 7 is a schematic view showing the operation of the preferred embodiment of the bus-type magnetic blocking electric device of the present invention for explaining the state of the power-off.

Figure 8 is a schematic view showing the structure of another preferred embodiment of the bus-type magnetic blocking electric device of the present invention.

Figure 9 is a schematic view showing the operation of another preferred embodiment of the bus-type magnetic blocking electric device of the present invention for explaining the state of the magnetic attraction in the front stage.

Fig. 10 is a schematic view showing the operation of another preferred embodiment of the bus-type magnetic blocking electric device of the present invention for explaining the state of the magnetic repulsion in the latter stage.

Figure 11 is a schematic view showing the operation of another preferred embodiment of the bus-type magnetic blocking electric device of the present invention for explaining the state at the time of power-off.

The present invention is a bus-type magnetic blocking electric device, and the specific embodiments of the present invention and its components, as illustrated in the accompanying drawings, all relate to front and rear, left and right, top and bottom, upper and lower, and horizontal and vertical. The references are for convenience of description only, and are not intended to limit the invention, nor to limit its components to any position or spatial orientation. The drawings and the dimensions specified in the specification may be varied in accordance with the design and needs of the specific embodiments of the present invention without departing from the scope of the invention.

The configuration of the bus-type magnetic blocking electric device of the present invention is as shown in the fourth and eighth figures, which is composed of at least a first field magnetic group (50) and at least one parallel first field magnetic group (50). a second field magnetic group (60), at least one parallel, and disposed between the first and second field magnetic groups (50, 60), the magnetic group (70) and the at least one inductive switch group (80), wherein At least one of the first and second field magnetic groups (50, 60) and the middle magnetic group (70) is composed of a coil, and the first and second field magnetic groups (50, 60) and the middle magnetic group ( 70) can be defined as a rotor or a stator, respectively, so that the first and second field magnetic groups (50, 60) can be synchronously or linearly or rotationally moved relative to the central magnetic group (70); as for the confluent magnetic blocking electric device of the present invention For a detailed configuration of the preferred embodiment, please refer to the fourth figure, the first field magnetic group (50) is at least one first magnetic member (51) made of permanent magnets and spaced along the moving direction and at least A second magnetic member (52) is formed, and the lengths of the first and second magnetic members (51, 52) are equal, and the first and second magnetic members (51, 52) are magnetized in a vertical motion direction. , adjacent to the first, The magnetic poles (51, 52) or the magnetic poles of the second magnetic field (52, 51) corresponding to the second field magnetic group (60) are adjacent to each other [for example, when the first magnetic member (51) is S pole) When the adjacent second magnetic member (52) is N pole, or when the first magnetic member (51) is N pole, then the adjacent second magnetic member (52) is S pole]; and the parallel first field magnetic group ( 50) The second field magnetic group (60) is composed of at least one third magnetic member (61) and at least one fourth magnetic member (62) which are made of permanent magnets and are arranged at intervals in the moving direction, and so on. The third and fourth magnetic members (61, 62) are of equal length, and the third and fourth magnetic members (61, 62) are magnetized in a vertical motion direction, and adjacent third and fourth magnetic members (61, 62) or the magnetic poles of the first and third magnetic members (62, 61) corresponding to the first field magnetic group (50) are adjacent to each other [for example, when the third magnetic member (61) is the S pole, the adjacent fourth magnetic When the member (62) is an N pole, or the third magnetic member (61) is an N pole, the adjacent fourth magnetic member (62) is an S pole, and the second field magnetic group (60) is the third. The four magnetic members (61, 62) are in the same polarity as the opposite magnetic poles of the first and second magnetic members (51, 52) of the first field magnetic group (50). And the first and second field magnetic groups (50, 60) are respectively formed between the first magnetic member (51) and the third magnetic member (61) and the second magnetic member (52) and the fourth magnetic member (62). a magnetic line space (A) that cancels the vertical magnetic resistance; and the middle magnetic group (70) is at least a fifth magnetic member (71) that is excited by the parallel motion direction and arranged in the moving direction. a sixth magnetic member (72), wherein the fifth magnetic member (71) and the sixth magnetic member (72) are respectively capable of winding the forward and reverse windings respectively, so that the central magnetic group ( 70) After the coils of the fifth and sixth magnetic members (71, 72) are excited, the adjacent magnetic poles of the fifth and sixth magnetic members (71, 72) are adjacent to each other, and the central magnetic group (70) is arranged. The fifth and sixth magnetic members (71, 72) are opposite to the first and second field magnetic groups (50, 60) and the first and second magnetic groups (50, 60) of the first and third magnetic members (51) , 61) and the second and fourth magnetic members (52, 62) are opposite poles [as shown in the fifth figure, when the first and second field magnetic groups (50, 60) of the first, three magnetic members (51 61) is the opposite of the SS pole, and the fifth magnetic member (71) of the middle magnetic group (70) is opposite to the N pole. Or when the second and fourth magnetic members (52, 62) of the first and second field magnetic groups (50, 60) are NN pole opposite, then the sixth magnetic member (72) of the middle magnetic group (70) enters the end For the S pole opposite, the magnetic field space of the first and third magnetic members (51, 61) and the second and fourth magnetic members (52, 62) of the first and second field magnetic groups (50, 60) (A) is a closed region (C) that forms a directional magnetic flow in a parallel motion direction between the two ends of the magnetic line (X, Y); as for the sensor switch group (80), it is provided in the first and second At least one power detector (81) of the field magnetic group (50, 60), at least one power failure detector (82), and at least one inductor (85) disposed in the central magnetic group (70) for control Whether the coils of the fifth and sixth magnetic members (71, 72) of the middle magnetic group (70) are connected to the power supply. The power detector (81) is disposed on the first and third magnetic members (51, 61) of the first and second field magnetic groups (50, 60) and the second and fourth magnetic members (52, 62). In the closed region (C), the magnetic field lines entering the middle magnetic group (70) in the moving direction are away from the corresponding position of the point (X), and the power failure detector (82) is disposed in the first and second field magnetic groups ( 50, 60) The first and third magnetic members (51, 61) and the second and fourth magnetic members (52, 62) in the closed region (C) deviate from the magnetic lines of the central magnetic group (70) in the moving direction. The corresponding position of the point (Y), and the inductors (85) are disposed in the middle of the coil of the fifth and sixth magnetic members (71, 72) of the middle magnetic group (70) for the middle magnetic group ( 70) The sensor (85) detects the first and third magnetic members (51, 61) of the first and second field magnetic groups (50, 60) and the second and fourth magnetic members (52, 62) When the power detector (81) is supplied, the power source can be connected to the coils of the corresponding fifth and sixth magnetic members (71, 72) to supply power (such as the fifth figure), so that the coil is magnetized into an electromagnet due to the excitation action, as for The inductor (85) on the fifth and sixth magnetic members (71, 72) of the magnetic group (70) detects the first and third magnetic members (51) 61) When the power detecting device (82) of the second and fourth magnetic members (52, 62) is disconnected, the coils of the corresponding fifth and sixth magnetic members (71, 72) are not connected to the power source to form a power failure. The state [as shown in the seventh figure], because the first and second field magnetic groups (50, 60) and the middle magnetic group (70) generate front magnetic waves in the closed region (C) [as shown in the fifth figure] 】, the latter part of the magnetic repulsion [as shown in the sixth figure] of the magnetic kinetic energy of continuous magnetic kinetic energy, to increase the operating rate, to improve kinetic energy and energy saving purposes.

As for the preferred embodiment of the bus-type magnetic blocking electric device of the present invention, as shown in the fifth, sixth and seventh figures, wherein the first and second field magnetic groups (50, 60) are first, The three magnetic members (51, 61) are opposite to the S pole, and the coils of the fifth magnetic member (71) of the middle magnetic group (70) are in contact with the first and third magnetic members (51, 61) after being powered. The end is N pole and the opposite end of the field field group (50, 60) is S pole. In addition, the second and fourth magnetic members (52, 62) of the first and second field magnetic groups (50, 60) are N-pole opposite, and the coil of the sixth magnetic member (72) of the central magnetic group (70). After the power is supplied, the inward end of the second and fourth magnetic members (52, 62) is the S pole, and the opposite end of the field magnetic group (50, 60) is the N pole; thus, as the first and second of the rotor When the field magnetic group (50, 60) is synchronously moved in parallel with the magnetic group (70) in the stator, the inductors (85) on the central magnetic group (70) detect the first and third magnetic members ( 51, 61) and the second and fourth magnetic members (52, 62) enter the end of the power detector (81), the power supply and the central magnetic group (70) fifth and sixth magnetic members (71, 72) The coil is connected to the power supply [as shown in the fifth figure], so that the fifth and sixth magnetic members (71, 72) are magnetized into the electromagnet as the central magnetic group (70) due to the excitation, and the first and second field magnetic groups are 50, 60) The first and third magnetic members (51, 61) and the second and fourth magnetic members (52, 62) are magnetized in the direction of vertical movement and are opposite to the same pole, and are opposite to the central magnetic group (70). The magnetic poles of the six magnetic members (71, 72) are different at the end, so in the first and second field magnetic groups (50, 60) The magnetic poles of the first and third magnetic members (51, 61) and the second and fourth magnetic members (52, 62) are not in the middle of the fifth and sixth magnetic members (71, 72) of the magnetic group (70), due to the The magnetic flux direction of the fifth and sixth magnetic members (71, 72) of the middle magnetic group (70) is different from the directional magnetic current of the first and second field magnetic groups (50, 60), and is in a heteropolar phase. The fifth figure shows the slanting force of the front magnetic attraction; in addition, when the first and second magnetic components (50, 60) of the moving first and third magnetic components (51, 61) and the second and fourth After the magnetic poles of the magnetic members (52, 62) pass the middle portion of the fifth and sixth magnetic members (71, 72) of the intermediate magnetic group (70), the fifth and sixth magnetic members of the central magnetic group (70) The magnetic flow direction of (71, 72) is the same as that of the field magnetic group (50, 60), and is in the same polarity as the repulsion [as shown in the sixth figure], and produces the forward thrust of the magnetic repulsion. Whether the forward tension of the front magnetic attraction or the forward thrust of the rear magnetic repulsion is a magnetic assist force that facilitates the continuous magnetic kinetic energy of the moving direction, the moving speed of the first and second field magnetic groups (50, 60) as the rotor can be increased. Further, the output kinetic energy and energy saving can be improved; in addition, when the first and second field magnetic groups (50, 60) as the rotor continue to move relative to the magnetic group (70) in the stator, the central magnetic group (70) The inductor (85) on the fifth and sixth magnetic members (71, 72) detects the first and third magnetic members (51, 61) and the second and fourth magnetic members (52, 62) from the exit end. When the power detector (82) is turned off [as shown in the seventh figure], the coil power of the fifth and sixth magnetic members (71, 72) of the middle magnetic group (70) is cut off, so that the central magnetic group (70) The fifth and sixth magnetic members (71, 72) do not form an active magnetic field, and the fifth and sixth magnetic members (71, 72) are prevented from interfering magnetic force due to magnetization, and due to the adjacent fifth and sixth magnetic members (71) 72) The first and third magnetic members (51, 61) are different from the magnetic poles of the second and fourth magnetic members (52, 62), causing the same polarity to be adjacent, thereby further avoiding reverse inertial magnetic current and magnetic field interference, and reducing Cross-magnetic The adverse effects of the zone prevent the weakening of the magnetic force, which can reduce the kinetic energy loss, reduce the magnetic resistance which is detrimental to the direction of motion, and can have strong magnetic assistance, and is non-parallel to the moving direction outside the closed zone (C). If the power is not supplied away from the magnetic current, the magnetic resistance can be avoided, and the output kinetic energy and energy saving can be improved.

For a detailed configuration of the second preferred embodiment of the present invention, please refer to the eighth and ninth figures. The first field magnetic group (50) is made of a coil and arranged at least in intervals along the moving direction. The first magnetic member (51A) and the at least one second magnetic member (52A) are formed, and the first and second magnetic members (51A, 52A) have the same wire diameter, and the first and second magnetic members (51A) , 52A) is excited in a vertical motion direction, and the adjacent first and second magnetic members (51A, 52A) or the second and second magnetic members (52A, 51A) correspond to the second field magnetic group after energizing the magnetization (60) The magnetic poles are adjacent to each other. As shown in the ninth figure, when the first magnetic member (51A) is the S pole, the adjacent second magnetic member (52A) is the N pole or the first magnetic member ( 51A) when the N pole is N, then the adjacent second magnetic member (52A) is S pole]; and the second field magnetic group (60) of the parallel first field magnetic group (50) is made of coil and moves along The at least one third magnetic member (61A) and the at least one fourth magnetic member (62A) are arranged in a direction interval, and the first and second field magnetic groups (50, 60) are defined as a stator, and the third, The four magnetic members (61A, 62A) have the same wire diameter. And the third and fourth magnetic members (61A, 62A) are excited in a vertical motion direction, and the adjacent third and fourth magnetic members (61A, 62A) or the fourth and third magnetic members (62A, 61A) are powered. After the magnetization magnetization, the magnetic poles corresponding to the first field magnetic group (50) are adjacent to each other [as shown in the ninth figure, when the third magnetic member (61A) is the S pole, the adjacent fourth magnetic member (62A) is N pole, or when the third magnetic member (61A) is N pole, then the adjacent fourth magnetic member (62A) is S pole], and then the third and fourth magnetic members of the second field magnetic group (60) (61A, 62A) The relative magnetic poles of the first and second magnetic members (51A, 52A) corresponding to the first field magnetic group (50) are in the same polarity, and the first and second field magnetic groups (50, 60) are opposite. A magnetic line space (A) is formed between the first magnetic member (51A) and the third magnetic member (61A) and the second magnetic member (52A) and the fourth magnetic member (62A), respectively, which cancels the vertical magnetic resistance; The middle magnetic group (70) is composed of at least one fifth magnetic member (71A) and at least one sixth magnetic member (72A) which are magnetized in a parallel moving direction and are arranged in the moving direction. The fifth magnetic member (71A) and the sixth magnetic member (72A) may be a permanent magnet, and adjacent poles of the fifth and sixth magnetic members (71A, 72A) are adjacent to the same pole, and the central magnetic group (70) is defined as a rotor, and the central magnetic group (70) is The entry ends of the five or six magnetic members (71A, 72A) may be combined with the first and third magnetic members (51, 61A) of the first and second field magnetic groups (50, 60) and the second and fourth magnetic members (52A, 62A). After being magnetized by the electromagnetism, it is opposite in phase. [As shown in the ninth figure, when the first and second magnetic members (50, 60) of the first and second field magnetic groups (51A, 61A) are magnetized, the SS pole is relatively Then, the fifth magnetic member (71A) of the central magnetic group (70) should be at the N extreme end, or the second and fourth magnetic members (52A, 62A) of the first and second field magnetic groups (50, 60). After the magnetization, the NN pole is opposite, then the sixth magnetic member (72A) of the middle magnetic group (70) should enter the end with S, and the first and second field magnetic groups (50, 60) are opposite. The magnetic field space (A) of the first and third magnetic members (51A, 61A) and the second and fourth magnetic members (52A, 62A) form an orientation of parallel movement directions between the magnetic lines of the opposite ends (X, Y). a closed region (C) of the magnetic current; as such, the inductive switch group (80) is included in the first At least one power detector (81) of the field magnetic group (50, 60), at least one power failure detector (82), and at least one inductor (85) disposed in the central magnetic group (70) for control Whether the first and third magnetic members (51A, 61A) of the first and second field magnetic groups (50, 60) and the coils of the second and fourth magnetic members (52A, 62A) are connected to a power source for power supply. The power detector (81) is disposed on the first and third magnetic members (51, 61A) of the first and second field magnetic groups (50, 60) and the second and fourth magnetic members (52A, 62A). In the closed region (C), the magnetic field lines entering the middle magnetic group (70) in the moving direction are away from the corresponding position of the point (X), and the power failure detector (82) is disposed in the first and second field magnetic groups ( 50, 60) The first and third magnetic members (51A, 61A) are separated from the magnetic lines of the closed region (C) of the second and fourth magnetic members (52A, 62A) away from the central magnetic group (70) in the moving direction. The corresponding position of the point (Y), and the inductors (85) are disposed in the center of the fifth and sixth magnetic members (71A, 72A) of the central magnetic group (70) for the central magnetic group (70). The sensor (85) detects the power supply of the first and third magnetic members (51A, 61A) and the second and fourth magnetic members (52A, 62A) of the first and second field magnetic groups (50, 60). When the detector (81) is used, the first and third magnetic members (51A, 61A) and the second and fourth magnetic members (52A, 62A) corresponding to the first and second field magnetic groups (50, 60) can be used. The coil is connected to the power supply (such as the ninth figure), so that the coil is magnetized into an electromagnet due to the excitation action, and the fifth of the middle magnetic group (70) The inductor (85) on the six magnetic members (71A, 72A) detects the first and third magnetic members (51A, 61A) and the second and fourth magnetic members (52A, 62A) of the power-off detector (82) When the corresponding first and third magnetic members (51A, 61A) and the second and fourth magnetic members (52A, 62A) are not connected to the power source to form a non-powering state [as shown in FIG. 11] Because the field magnetic group (50, 60) and the middle magnetic group (70) generate front magnetic attraction in the closed region (C) [as shown in the ninth figure], and the rear magnetic repulsion [as shown in the tenth figure] The magnetic assistance of the continuous magnetic kinetic energy achieves an increase in the operating rate to improve kinetic energy and save energy.

As for the second preferred embodiment of the bus-type magnetic blocking electric device of the present invention, when it is actually actuated, it is as shown in the ninth figure, wherein the first and third magnetic groups of the first and second field magnetic groups (50, 60) The pieces (51A, 61A) are opposite to the S pole after the magnetization of the electromagnetism, and the fifth magnetic member (71A) of the center magnet group (70) is opposite to the entry end of the first and third magnetic members (51A, 61A). The N pole and the opposite end of the field field group (50, 60) are S poles. In addition, when the second and fourth magnetic members (52A, 62A) of the first and second field magnetic groups (50, 60) are N pole opposite to the magnetization magnetization, and the sixth magnetic member of the middle magnetic group (70) (72A) is opposite to the second and fourth magnetic members (52A, 62A), the entry end is S pole, and the opposite field magnetic group (50, 60) is N pole at the exit end; thus, when used as a rotor magnetic group (70) When the first and second field magnetic groups (50, 60) are moved in parallel as the stator, the inductor (85) on the middle magnetic group (70) detects the first and third magnetic members (51A, 61A) The first and third magnetic members (51A, 61A) of the power supply and field magnetic group (50, 60) when the second and fourth magnetic members (52A, 62A) enter the power supply detector (81). Connected to the coils of the second and fourth magnetic members (52A, 62A) to supply electricity (as shown in the ninth figure), so that the first and third magnetic members (51A, 61A) and the second and fourth magnetic members (52A, 62A) The magnetization is magnetized, and the first and third magnetic members (51A, 61A) of the first and second field magnetic groups (50, 60) are in the same polarity as the second and fourth magnetic members (52A, 62A), and The fifth and sixth magnetic members (71A, 72A) of the middle magnetic group (70) are different in the end magnetic poles, so The magnet midpoint of the fifth and sixth magnetic members (71A, 72A) of the magnetic group (70) does not exceed the first and third magnetic members (51A, 61A) and the second of the first and second field magnetic groups (50, 60). Before the magnetic poles of the four magnetic members (52A, 62A), due to the magnetic flux of the fifth and sixth magnetic members (71A, 72A) of the central magnetic group (70) and the first and second field magnetic groups (50, 60) The directional magnetic currents of the first and third magnetic members (51A, 61A) and the second and fourth magnetic members (52A, 62A) are in a different polarity (as shown in the ninth figure), and the slanting force of the front magnetic attraction is generated. Furthermore, when the moving central magnetic group (70) fifth and sixth magnetic members (71A, 72A) have a permanent magnet midpoint beyond the first and second magnetic groups (50, 60), the first and third magnetic members ( 51A, 61A) after the magnetic poles of the second and fourth magnetic members (52A, 62A), due to the magnetic flux of the fifth and sixth magnetic members (71A, 72A) of the central magnetic group (70) and the first and second field magnetic groups The directional magnetic currents of the first and third magnetic members (51A, 61A) and the second and fourth magnetic members (52A, 62A) of (50, 60) are in the same polarity repulsion [as shown in the tenth figure], resulting in The forward thrust of the magnetic repulsion. Whether the forward tension of the front magnetic attraction or the forward thrust of the rear magnetic repulsion is a magnetic assist force that facilitates the continuous magnetic kinetic energy in the moving direction, the moving speed of the magnetic group (70) in the rotor can be increased, and further improved. The output kinetic energy and energy saving; further, when the magnetic group (70) in the rotor continues to move relative to the field magnetic group (50, 60) as the stator, the inductor on the central magnetic group (70) (85) a power-off detector (82) for detecting the first and third magnetic members (51A, 61A) of the first and second field magnetic groups (50, 60) and the second and fourth magnetic members (52A, 62A) leaving the end When [as shown in Fig. 11], the coil power supply of the first and third magnetic members (51A, 61A) and the second and fourth magnetic members (52A, 62A) of the field magnetic group (50, 60) is cut off. Preventing the first and third magnetic members (51A, 61A) and the second and fourth magnetic members (52A, 62A) from generating magnetic interference due to magnetization, so that the first and second field magnetic groups (50, 60) do not form an active magnetic field. In order to avoid the magnetic resistance, the magnetic resistance which is detrimental to the moving direction can be avoided, and the field magnetic group (50, 60) and the central magnetic group (70) are mutually displaced under the directional magnetic current in the closed region (C). Producing front magnetic The magnetic assist of the continuous magnetic kinetic energy of the rear magnetic repulsion achieves the purpose of increasing the motion rate, improving the kinetic energy and saving energy.

As can be seen from the above description, the first and second magnetic members (51, 52) and the third and fourth magnetic members (61, 62) of the first and second field magnetic groups (50, 60) of the present invention are The relative motion direction is perpendicularly magnetized and adjacent to each other, so that the magnetic lines of force flow in the magnetic field space (A) of the first and second field magnetic groups (50, 60) without outward expansion, thereby improving the utilization of magnetic lines of force. Furthermore, since the fifth and sixth magnetic members (71, 72) of the central magnetic group (70) are in the same polarity, the magnetic field is less than the disturbance, and the cross-region magnetic field interference can be reduced, and the reaction force is reduced. In turn, reducing the dynamic loss and energy consumption can greatly improve the performance of the electric device, and the magnetic flow is managed, and the reverse inertial magnetic current is not generated, and the magnetic assisting force can be further enhanced, so that the rotational speed and the power can be improved, and the energy can be improved. The purpose of conversion efficiency.

In this way, it can be understood that the present invention is an excellent creation, in addition to effectively solving the problems faced by the practitioners, and greatly improving the efficiency, 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, the present invention has met the requirements for "novelty" and "progressiveness" of the invention patent, and is filed for patent application according to law.

Claims (3)

 The utility model relates to a confluent magnetic blocking electric device, which is composed of at least a first field magnetic group, at least one parallel second field magnetic group, a second field magnetic group, at least one middle magnetic group and at least one inductive switch group. And the first and second field magnetic groups can synchronously generate linear or rotational motion with respect to the middle magnetic group; and the first field magnetic group is composed of at least one first magnetic member and at least one second spaced along the moving direction. The magnetic components are composed, and the first and second magnetic members are equal in length, and the first and second magnetic members are magnetized in a vertical movement direction, and the adjacent first and second magnetic members or the second and the first The magnetic poles corresponding to the second field magnetic group of the magnetic member are adjacent to each other; the second field magnetic group is composed of at least one third magnetic member and at least one fourth magnetic member arranged at intervals in the moving direction. And the lengths of the third and fourth magnetic members are equal, and the third and fourth magnetic members are magnetized in a vertical movement direction, and the third or fourth magnetic members or the fourth and third magnetic members are adjacent to each other. The magnetic poles of one magnetic group are adjacent to each other, and the third and fourth of the second magnetic group The opposite magnetic poles of the first and second magnetic members corresponding to the first field magnetic group are in the same polarity, and the first and second field magnetic groups are opposite to the first magnetic member and the third magnetic member and the second magnetic member. A magnetic line space is formed between the fourth magnetic members to cancel the vertical magnetic resistance; and the middle magnetic group is parallel and disposed between the first and second field magnetic groups, and the central magnetic group is parallel motion Forming at least one fifth magnetic member and at least one sixth magnetic member that are magnetized in a direction and arranged in a moving direction, wherein the fifth magnetic members are adjacent to the adjacent magnetic poles of the sixth magnetic members And the fifth and sixth magnetic members of the middle magnetic group are different from the first and second field magnetic groups, and the first and third magnetic members of the first and second field magnetic groups are different from the second and fourth magnetic members. In the opposite direction, the magnetic field lines of the first and third magnetic members and the second and fourth magnetic members in the first and second field magnetic groups form a directional magnetic direction parallel to the point of the magnetic lines at both ends. a closed area of the flow; as described, the sensing switch group includes the first and second field magnetic groups At least one power detector, at least one power detector, and at least one inductor disposed in the middle magnetic group, wherein the power detector is disposed on the first and third magnetic fields of the first and second field magnetic groups And the corresponding position of the magnetic field lines of the middle magnetic group in the closed region of the second and fourth magnetic members entering the magnetic field away from the point, and the power failure detector is disposed at the first of the first and second field magnetic groups, The magnetic field of the three magnetic members and the second and fourth magnetic members are separated from the point of the magnetic field line of the central magnetic group in the moving direction, and the sensors are disposed in the fifth and sixth of the central magnetic group. The middle section of the magnetic piece.    The convection magnetic blocking electric device according to claim 1, wherein the first and second magnetic members of the first field magnetic group and the third and fourth magnetic members of the second field magnetic group may be selected from the group consisting of A permanent magnet, and the fifth and sixth magnetic members of the central magnetic group may be selected from a coil connected to a power source, so that the fifth and sixth magnetic members of the middle magnetic group may be intermittently energized to form an electromagnet.    The convection magnetic blocking electric device according to claim 1, wherein the first and second magnetic members of the first field magnetic group and the third and fourth magnetic members of the second field magnetic group may be selected from the group consisting of Connecting the coil of the power source, and the fifth and sixth magnetic members of the middle magnetic group may be selected from the permanent magnets, so that the first and second magnetic members of the first and second field magnetic groups and the third and fourth magnetic members may be The electromagnet is formed by intermittent power supply.