CN206977293U - Magnetic pole displacement electric device - Google Patents

Abstract

The utility model discloses a magnetic pole dislocation electric device, which is provided with an induction coil group, at least one first magnetic group and at least one second magnetic group which can synchronously and relatively move are respectively arranged at two sides of the induction coil group, the first magnetic group is formed by connecting a first magnetic part and a second magnetic part which are magnetized in the moving direction and arranged in different poles in series at equal intervals, the second magnetic group is formed by connecting a third magnetic part and a fourth magnetic part which are magnetized in the moving direction and arranged in different poles in series at equal intervals, the third magnetic part and the fourth magnetic part are arranged in relative dislocation with the first magnetic part and the second magnetic part, a power switch group for selectively supplying electricity to the induction coil group is arranged between the induction coil group and the first magnetic group and the second magnetic group, thereby, magnetic current can form a magnetic beam which is parallel to the moving direction by utilizing the flowing direction and relative compression of magnetic force lines of the first magnetic group and the second magnetic group, so that the magnetic force lines in the corresponding area do not cut the coil parts, and the induced electromotive force is weakened, the input power is reduced, induction and proliferation are realized during power supply, double magnetic assistance is realized, the output power is improved, and the energy conversion efficiency is improved.

Description

Magnetic pole displacement electric device

technical field

The utility model relates to the field of electromagnetic technology for energy conversion, in particular to a magnetic pole dislocation electric device capable of reducing induced voltage and increasing rotation rate, so that it can be driven by inputting small power to reduce energy loss and simultaneously generate double Magnetic assistance to increase output power.

Background technique

A general electric device is composed of a coil and a magnetic part that can rotate relative to each other. The coil is used as the stator, and the magnetic part is used as the rotor. By intermittently feeding the coil, the coil is magnetized, and the magnetic part of the rotor is generated. The magnetic force of mutual repulsion and attraction drives the rotor to rotate at high speed.

Since the electric device uses intermittent power supply during operation to drive the rotor by picking up the required magnetic force, but affected by the configuration of its coil and magnetic parts, the coil will still be affected by the moment the power supply is suspended. The magnetic parts in the inertial rotation are cut to generate an induced electromotive force. Therefore, in the design of the existing electric device, a large input power is required to drive it, resulting in unnecessary energy loss.

In other words, because the existing electric device is affected by the induced electromotive force generated by magnetic wire cutting, there are problems of large input power for driving and energy loss. The magnetic assist will be able to produce the effect of low input and high output, and improve the efficiency of energy conversion. How to achieve this goal is urgently needed to be developed by the industry.

Because of this, the designer of this utility model has made in-depth discussions on the problems faced by the aforementioned existing electric devices, and has actively sought solutions through years of research and development experience in related industries. After continuous efforts in research and trial production , and finally successfully developed a magnetic pole dislocation electric device to overcome the existing dilemma of low energy conversion caused by large induced electromotive force and high kinetic energy loss.

Utility model content

The purpose of the utility model is to provide a magnetic pole dislocation electric device, so as to reduce the induced electromotive force, achieve the input of small driving power, and further improve its energy conversion efficiency.

Another object of the present invention is to provide a magnetic pole dislocation electric device, which can increase the forward magnetic assist force, effectively increase the running speed, increase its output power, and further improve its energy conversion efficiency.

Based on this, the utility model mainly adopts following technical means to realize the above-mentioned purpose.

A magnetic pole dislocation electric device, the electric device includes an induction coil group, a first magnetic group, a second magnetic group and a power switch group, wherein the first and second magnetic groups can move synchronously relative to the induction coil group, and the The induction coil group has at least one coil part, and each coil part has a magnetic conductor extending in the direction of vertical movement and at least one coil arranged around the magnetic conductor, and the coil is connected to a power supply; and The first magnetic group is composed of at least one first magnetic piece and at least one second magnetic piece connected in series at equal intervals, and each of the first and second magnetic pieces is magnetized in the direction of vertical movement, and the adjacent first and second magnetic pieces The magnetic poles at one end of the corresponding induction coil group are adjacent to each other; the second magnetic group is formed by at least one third magnetic part and at least one fourth magnetic part connected in series at equal intervals, wherein the third and fourth magnetic The length of the first and second magnetic parts is equal to that of the aforementioned first and second magnetic parts, and each of the third and fourth magnetic parts is magnetized in the direction of vertical movement. In addition, the third and fourth magnetic parts of the second magnetic group and the first and second magnetic parts of the first magnetic group are in a relative equidistant dislocation shape, and the pole centers of the third and fourth magnetic parts correspond to the phases of the first and second magnetic parts. The center of the distance between the central axis of the adjacent magnetic pole, and the center of the magnetic pole of the first and second magnetic parts also corresponds to the center of the distance between the central axis of the adjacent magnetic pole of the third and fourth magnetic parts, and the first first magnetic part in the first magnetic group corresponds to the induction The magnetic poles of the coil group are opposite to the magnetic poles of the corresponding induction coil group of the first third magnetic part in the second magnetic group; It is composed of a path induction element and at least one disconnection induction element, wherein the power supply switch is separately arranged in the center of each coil part in the induction coil group corresponding to one end of the first magnetic group, and the power cutoff switch is arranged in each coil part in the induction coil group Corresponding to the center of one end of the second magnetic group, each path inductive element is separately arranged in the center of the magnetic poles of the first and second magnetic parts of the first magnetic group corresponding to one end of the induction coil group, and each open circuit inductive element is separately arranged in the third and second magnetic poles of the second magnetic group. The four magnetic parts correspond to the center of the magnetic pole at one end of the induction coil group, thereby forming an electric device for power supply at the rear stage.

Further, the adjacent first and second magnetic parts of the first magnetic group are in close contact, while the adjacent third and fourth magnetic parts of the second magnetic group are in close contact.

Further, the adjacent first and second magnetic elements of the first magnetic group have a magnetic gap, and the adjacent third and fourth magnetic elements of the second magnetic group have an equidistant magnetic gap.

A magnetic pole displacement electric device, the electric device includes an induction coil group, a first magnetic group, a second magnetic group and a power switch group, wherein the first magnetic group and the second magnetic group can move synchronously relative to the induction coil group , and the induction coil group has at least one coil part, and each coil part has a magnetic conductor extending in the direction of vertical movement and at least one coil set on the magnetic conductor, and the coil is connected to an electric power supply; In addition, the first magnetic group is composed of at least one first magnetic part and at least one second magnetic part connected in series at equal intervals, and each of the first and second magnetic parts is magnetized in the direction of vertical movement, and the adjacent first magnetic parts 1. The magnetic poles of the two magnetic parts corresponding to one end of the induction coil group are adjacent to each other; the second magnetic group is formed by at least one third magnetic part and at least one fourth magnetic part connected in series at equal intervals, wherein the third 1. The length of the four magnetic parts is equal to that of the aforementioned first and second magnetic parts, and each of the third and fourth magnetic parts is magnetized in the direction of vertical movement, and the magnetic poles of the adjacent third and fourth magnetic parts corresponding to one end of the induction coil group are different poles Adjacent, the third and fourth magnetic parts of the second magnetic group are equidistant from the first and second magnetic parts of the first magnetic group, and the center of the magnetic pole of the third and fourth magnetic parts corresponds to the first and second magnetic parts The center of the distance between the central axes of the adjacent magnetic poles, and the center of the poles of the first and second magnetic parts also corresponds to the center of the distance between the central axes of the adjacent magnetic poles of the third and fourth magnetic parts, the first first magnetic part in the first magnetic group The magnetic poles of the corresponding induction coil group are opposite to the magnetic poles of the corresponding induction coil group of the first third magnetic member in the second magnetic group; Consisting of at least one path inductive element and at least one open circuit inductive element, wherein the power supply switch is set at the center of each coil part in the induction coil group corresponding to the end of the second magnetic group, and the power cutoff switch is set at each end of the induction coil group The coil part corresponds to the center of one end of the first magnetic group, and each path induction element is separately arranged in the center of the magnetic pole of one end of the third and fourth magnetic parts of the second magnetic group corresponding to the induction coil group, and each open circuit induction element is separately arranged at the center of the first magnetic group The first and second magnetic parts correspond to the center of the magnetic pole at one end of the induction coil group, thereby forming an electric device for feeding electricity at the front stage.

Preferably, the adjacent first and second magnetic parts of the first magnetic group are in close contact, and the adjacent third and fourth magnetic parts of the second magnetic group are in close contact.

Preferably, the adjacent first and second magnetic elements of the first magnetic group have a magnetic gap, and the adjacent third and fourth magnetic elements of the second magnetic group have an equidistant magnetic gap.

Thereby, after the magnetic pole dislocation electric device of the present utility model adopts the above-mentioned technical means, it can utilize the magnetic flow direction and relative compression of the magnetic force lines of the first and second magnetic groups to form a magnetic flux parallel to the direction of motion, so that in the corresponding area The magnetic line of force does not cut the coil parts, weakens the induced electromotive force, but can reduce the input power, and when it is driven by electricity, it can increase the double magnetic assist by induction, which can increase the output power, thereby improving its energy conversion efficiency, so it can greatly increase its added value. and improve its economic efficiency.

Description of drawings

FIG. 1 is a schematic diagram of the structure of the first embodiment of the magnetic pole displacement electric device of the present invention, which is used to illustrate the power supply state of the latter stage.

FIG. 2 is a schematic diagram of the structure of the second embodiment of the magnetic pole displacement electric device of the present invention, which is used to illustrate the state of power supply in the front stage.

FIG. 3 is a schematic diagram of the structure of the third embodiment of the magnetic pole displacement electric device of the present invention, which is used to illustrate the power supply state of the latter stage.

FIG. 4 is a schematic diagram of the structure of the fourth embodiment of the magnetic pole displacement electric device of the present invention, which is used to illustrate the state of power supply in the front stage.

Fig. 5, Fig. 6 and Fig. 7 are schematic diagrams of the power supply action in the second stage of the first embodiment of the present invention.

Fig. 8, Fig. 9 and Fig. 10 are schematic diagrams of the action of the second embodiment of the utility model for power supply in the front section.

Fig. 11, Fig. 12 and Fig. 13 are schematic diagrams of the third embodiment of the utility model for power supply in the latter stage.

Fig. 14, Fig. 15 and Fig. 16 are schematic diagrams of the power supply action in the front section of the fourth embodiment of the present invention.

【Symbol Description】

10 induction coil group 11 coil parts

12 Magnetic conductor 13 Coil

20 The first magnetic group 21 The first magnetic part

22 second magnetic part 25 magnetic gap

30 second magnetic group 31 third magnetic piece

32 fourth magnetic piece 35 magnetic gap

40 power switch group 41 power supply switch

42 power-off switch 45 channel sensing element

46 open circuit sensing element.

Detailed ways

In order to further understand the structure, features and other purposes of the present utility model, the following are preferred embodiments of the present utility model, which are described in detail in conjunction with the drawings, and at the same time allow those skilled in the art to implement them.

The utility model is a magnetic pole dislocation electric device. Among the specific embodiments of the utility model and its components illustrated in the accompanying drawings, all about front and rear, left and right, top and bottom, upper and lower, and horizontal and vertical The reference is only used for convenience of description, not to limit the utility model, nor to limit its components to any position or direction in space. The dimensions specified in the drawings and the description can be changed according to the design and requirements of the specific embodiments of the utility model without departing from the patent application scope of the utility model.

The composition of the magnetic pole dislocation electric device of the present utility model is shown in Fig. 1, Fig. 2, Fig. 3, and Fig. 4. The electric device has an induction coil group 10, and a first magnetic Group 20 and a second magnetic group 30, and the first and second magnetic groups 20, 30 can move synchronously relative to the induction coil group 10, and wherein the first and second magnetic groups 20, 30 are magnetized in the direction of vertical movement, and the first The magnetic poles of one and two magnetic groups 20 and 30 are equidistantly dislocated, and a power switch group 40 is arranged between the induction coil group 10 and the first magnetic group 20 and the second magnetic group 30, and the power switch group 40 It can selectively control whether the induction coil group 10 is connected to a power supply for power supply, and can intermittently drive the first and second magnetic groups 20, 30 to move relative to the induction coil group 10;

Please refer to Fig. 1, Fig. 2, Fig. 3 and Fig. 4 for the detailed constitution of the first, second, third and fourth embodiments of the magnetic pole dislocation electric device of the present invention, wherein the induction coil group 10 can be defined as a stator , and the first and second magnetic groups 20, 30 are defined as rotors, and the induction coil group 10 is composed of one or more coil parts 11, and each coil part 11 has a magnetic conductor extending in the direction of vertical movement 12 and at least one coil 13 arranged on the magnetizer 12, the coil 13 is also connected to the power supply, so that when the power supply supplies power to the coil 13 of the coil part 11, the coil part 11 can be magnetized, and Form a state of magnetization in the direction of vertical movement, and make the magnetic poles at both ends of the coil part 11 generate magnetic force relative to the first and second magnetic groups 20 and 30, and drive the first and second magnetic groups 20 and 30 to move synchronously relative to the induction coil group 10 ;

Also, the first magnetic group 20 is composed of at least one first magnetic member 21 and at least one second magnetic member 22 connected in series at equal intervals, and each of the first and second magnetic members 21, 22 is magnetized in a vertical direction of motion. , so that the two ends of the first and second magnetic parts 21 and 22 in the vertical movement direction respectively form N poles or S poles, and each adjacent first and second magnetic parts 21 and 22 can be close to each other [as shown in the figure 1. The first and second embodiments of Fig. 2] or there is a magnetic gap 25 between the first and second magnetic parts 21 and 22 [as shown in the third and fourth embodiments of Fig. 3 and Fig. 4], and the adjacent first 1. The magnetic poles of the two magnetic parts 21 and 22 corresponding to one end of the induction coil group 10 are adjacent to each other [that is, if the first magnetic part 21 is an S pole, then the adjacent second magnetic part 22 is an N pole, or the first magnetic part 22 is an N pole. Magnetic piece 21 is N pole, then the second adjacent magnetic piece 22 is S pole];

In addition, the second magnetic group 30 is formed by at least one third magnetic member 31 and at least one fourth magnetic member 32 connected in series at equal intervals, wherein the third and fourth magnetic members 31, 32 are connected with the aforementioned first and second magnetic members. The lengths of the pieces 21, 22 are equal, and the third and fourth magnetic pieces 31, 32 are magnetized in the direction of vertical movement, so that the two ends of the third and fourth magnetic pieces 31, 32 in the vertical movement direction form N poles or S poles respectively The magnetic poles, and each adjacent third and fourth magnetic parts 31 and 32 can be close to each other [as shown in the first and second embodiments of Fig. 1 and Fig. 2] or there is a gap between the third and fourth magnetic parts 31 and 32 Magnetic gap 35 [as the third and fourth embodiments of Fig. 3 and Fig. 4], and the width of the magnetic gap 35 is equal to the width of the aforementioned first and second magnetic parts 21, 22 magnetic gaps 25, and adjacent The magnetic poles of the third and fourth magnetic parts 31, 32 corresponding to one end of the induction coil group 10 are adjacent with different poles [that is, if the third magnetic part 31 is an S pole, then the adjacent fourth magnetic part 32 is an N pole, or The third magnetic part 31 is an N pole, and the adjacent fourth magnetic part 32 is an S pole], and the third and fourth magnetic parts 31, 32 of the second magnetic group 30 are connected with the first and second magnetic parts of the first magnetic group 20. The magnetic parts 21, 22 are in a relative equidistant dislocation shape, that is, the center of the magnetic poles of the third and fourth magnetic parts 31, 32 corresponds to the center of the central axis distance of the adjacent magnetic poles of the first and second magnetic parts 21, 22 [such as Fig. 1, The close contact line of the first and second magnetic parts 21 and 22 of the first and second embodiments in Fig. 2, or the magnetic gap of the first and second magnetic parts 21 and 22 of the third and fourth embodiments in Fig. 3 and Fig. 4 Center], and the center of the magnetic poles of the first and second magnetic parts 21, 22 also corresponds to the center of the central axis distance of the adjacent magnetic poles of the third and fourth magnetic parts 31, 32 [such as the first and second embodiments in Fig. 1 and Fig. 2 The third and fourth magnetic parts 31, 32 close to the line, or the third and fourth magnetic parts 31, 32 magnetic gap center of the third and fourth embodiments in Fig. 3 and Fig. 4], and the first magnetic group The magnetic poles of the first first magnetic part 21 in 20 corresponding to the induction coil group 10 and the magnetic poles of the first third magnetic part 31 in the second magnetic group 30 corresponding to the induction coil group 10 can be opposite in the same pole [as shown in Fig. 1, Fig. 3], and form the power supply to the rear segment of the first magnetic group 20 [as shown in Figures 5 to 7 and Figures 11 to 13]. Or the magnetic pole of the first first magnetic part 21 in the first magnetic group 20 corresponding to the induction coil group 10 and the magnetic pole of the first third magnetic part 31 in the second magnetic group 30 corresponding to the magnetic pole of the induction coil group 10 can be opposite in opposite poles [as shown in Fig. 2 and Fig. 4], and form the front stage power supply relative to the first magnetic group 20 [as shown in Fig. 8 to Fig. 10 and Fig. 14 to Fig. 16];

As for, the power switch group 40 is composed of at least one power supply switch 41, at least one power-off switch 42, at least one path inductive element 45 and at least one open-circuit inductive element 46, as shown in the first and third diagrams of Fig. 1 and Fig. 3 As shown in the embodiment, the power supply switch 41 is separately arranged in the center of each coil part 11 in the induction coil group 10 corresponding to the end of the first magnetic group 20, and the power-off switch 42 is arranged in each coil part 11 in the induction coil group 10 Corresponding to the center of one end of the second magnetic group 30, each path inductive element 45 can be separately arranged at the center of the magnetic pole of one end of the first and second magnetic parts 21, 22 of the first magnetic group 20 corresponding to the induction coil group 10, for the coil part 11 to feed When the switch 41 detects the relative passage inductive element 45, the coil 13 of the coil part 11 is connected to the power supply to form an energized state, and each open circuit inductive element 46 can be separately arranged on the third and fourth magnetic elements of the second magnetic group 30. Parts 31, 32 correspond to the center of the magnetic pole at one end of the induction coil group 10, and when the power-off switch 42 of the coil part 11 detects the relative open circuit induction element 46, the coil 13 of the coil part 11 is disconnected from the power supply to form a power-off state , so as to form a motor function of feeding electricity to the rear sections of the first and second magnetic members 21 and 22 of the first magnetic group 20 . As shown in the second and fourth embodiments of Fig. 2 and Fig. 4, the power supply switch 41 is separately located at the center of each coil element 11 in the induction coil group 10 corresponding to one end of the second magnetic group 30, and the power-off switch 42 is Each coil part 11 is arranged in the center of one end of the first magnetic group 20 in the induction coil group 10, and each path inductive element 45 can be separately arranged on the third and fourth magnetic parts 31, 32 of the second magnetic group 30 corresponding to the induction coil group 10. In the center of the magnetic pole at one end, when the power supply switch 41 of the coil part 11 detects the relative path inductive element 45, the coil 13 of the coil part 11 is connected to the power supply to form a power supply state, and each disconnection inductive element 46 can be separately arranged in The first and second magnetic parts 21, 22 of the first magnetic group 20 correspond to the center of the magnetic pole at one end of the induction coil group 10, and when the power-off switch 42 of the coil part 11 detects the relative open circuit induction element 46, the coil part 11 is activated. The coil 13 is disconnected from the power supply to form a non-energized state, thereby forming a motor action that feeds electricity to the front sections of the first and second magnetic members 21 and 22 of the first magnetic group 20 .

In this way, a magnetic pole displacement electric device that can reduce the induced voltage and increase the magnetic assist is formed.

As for the actual use of the electric device of the present utility model, taking the power supply in the latter stage as an example, its action is as disclosed in Figures 5 to 7 and Figures 11 to 13 of the first and third embodiments, because the first magnetic group 20 is composed of The first and second magnetic parts 21 and 22 magnetized in the moving direction are connected in series at equidistant intervals, and the second magnetic group 30 is composed of third and fourth magnetic parts 31 and 32 which are relatively misaligned and connected in series at equidistant intervals, and The magnetic pole corresponding to the induction coil group 10 of the first first magnetic part 21 in the first magnetic group 20 and the magnetic pole corresponding to the induction coil group 10 of the first third magnetic part 31 in the second magnetic group 30 can be opposite in the same pole, so According to the principle that the lines of force flow from the N pole to the S pole, the lines of force of the two flow in the same direction at the front sections of the first and second magnetic pieces 21, 22 of the first magnetic group 20. At this time, the coil pieces 11 of the induction coil group 10 If the coil 13 is in the non-energized state, it can avoid feeding the electric drive under the high induced electromotive force of the magnetic wire cutting, and the magnetic force lines of the two form a reverse direction at the rear section of the first and second magnetic parts 21, 22 of the first magnetic group 20. It is flowing, so that the magnetic flux in this area is sparse and compressed to form a magnetic flux parallel to the direction of motion. Electric drive under the low induced electromotive force of this non-magnetic wire cutting will reduce its input power, and when the induction coil group has 10 coils After the coil 13 of the part 11 is electromagnetized, it can obtain double magnetic power assist, so it can reduce its input power and provide high output power when it is electrically driven;

Therefore, when the first and second magnetic groups 20 and 30 move synchronously relative to the induction coil group 10, and the power switch group 40 is located at the power supply switch 41 of the coil part 11 corresponding to the first and second magnetic parts 21 and 22 of the first magnetic group 20 When the passage induction element 45 in the center [as shown in Fig. 5 and Fig. 11], the coil 13 of the coil part 11 can be made to be in conduction with the power supply, and form the state of power supply in the back section, so that each coil part 11 One end corresponding to the first and second magnetic parts 21, 22 forms the same polarity for the electric excitation magnetization, and generates a magnetic boost in the direction of motion, and the coil part 11 corresponds to the third and fourth magnetic parts 31, 32 of the second magnetic group 30 One end is also of different polarity, and also generates magnetic assist along the direction of motion, allowing the moving first magnetic group 20 and second magnetic group 30 to obtain dual magnetic assist, thereby greatly increasing their output power.

And when the power-off switch 42 of the coil part 11 detects the relative disconnection induction element 46 on the third and fourth magnetic parts 31, 32 of the second magnetic group 30 [as shown in Fig. 7 and Fig. 13 ], then the power supply can be cut off. The connection of the power supply and the coil 11 of the coil part 11 forms a power outage, avoiding the electric drive under the high induced electromotive force of the magnetic wire cutting, and the magnetic force lines of the first and second magnetic groups 20 and 30 are in the first magnetic group 20. The rear sections of the first and second magnetic parts 21, 22 are in the reverse flow shape, so that the magnetic flux in this area is sparse and compressed to form a magnetic flux parallel to the direction of motion, which is less than the induced electromotive force of magnetic wire cutting, so it can be driven by electricity. reduce its input power.

In addition, when the electric device of the present utility model is actually used, take the power supply in the front section as an example, and its actions are shown in Figures 8 to 10 and Figures 14 to 16. As mentioned above, since the first magnetic group 20 is in the direction of movement The magnetized first and second magnetic parts 21 and 22 are connected in series at equal intervals, and the second magnetic group 30 is formed by connecting the third and fourth magnetic parts 31 and 32 of relative dislocation in series at equal intervals, and the first The magnetic poles of the first first magnetic part 21 in the magnetic group 20 corresponding to the induction coil group 10 and the magnetic poles of the first third magnetic part 31 in the second magnetic group 30 corresponding to the induction coil group 10 can be opposite in opposite poles, so according to the magnetic force lines The principle of flowing from the N pole to the S pole, the magnetic force lines of the two form a reverse flow shape in the front section of the first and second magnetic parts 21, 22 of the first magnetic group 20, so that the magnetic flux in this area is sparse and compressed with each other to form a and motion Direction parallel magnetic flux, when the coil 13 of the induction coil group 10 coil parts 11 is electromagnetized, then can obtain double magnetic assist, so can be used for improving output power, and the magnetic field lines of both are in the first, the first of the first magnetic group 20. The rear section of the two magnetic parts 21, 22 forms a flow shape in the same direction. At this time, the coil parts 11 and coil 13 of the induction coil group 10 are in a non-energized state, avoiding the power supply under the high induced electromotive force of magnetic wire cutting, so the power supply It can reduce its input power when driving;

Therefore, when the first and second magnetic groups 20 and 30 move synchronously relative to the induction coil group 10, and the power switch group 40 is located at the power supply switch 41 of the coil part 11 corresponding to the third and fourth magnetic parts 31 and 31 of the second magnetic group 30, 32 central path inductive element 45 [as shown in Figure 8 and Figure 14 ], the coil 13 of the coil part 11 can be made to be conductive with the power supply, and form the state of power supply in the front section, so that each coil part 11 One end corresponding to the third and fourth magnetic parts 31, 32 is excited and magnetized to form the same polarity, thereby generating a magnetic force in the direction of motion, and the coil part 11 corresponds to one end of the first and second magnetic parts 21, 22 of the first magnetic group 20 They are also of different polarities for generating magnetic assist in the direction of motion, allowing the moving first magnetic group 20 and second magnetic group 30 to obtain dual magnetic assist, thereby greatly increasing their output power.

And when the power-off switch 42 of the coil part 11 detects the relative disconnection induction element 46 on the first and second magnetic parts 21, 22 of the first magnetic group 20 [as shown in Fig. 10 and Fig. 16 ], the power supply can be cut off. The connection of the power supply and the coil 11 of the coil part 11 forms a power outage, avoiding the electric drive under the high induced electromotive force of the magnetic wire cutting, and the magnetic force lines of the first and second magnetic groups 20 and 30 are in the first magnetic group 20. The front sections of the first and second magnetic parts 21, 22 are in the reverse flow shape, so that the magnetic flux in this area is sparse and compressed to form a magnetic flux parallel to the direction of motion, which is less than the induced electromotive force of magnetic wire cutting, so it can be reduced when driving with electricity. its input power.

Through the foregoing description, the magnetic pole dislocation electric device of the present invention utilizes the magnetic fluxes of the first and second magnetic groups 20, 30 to be sparse and mutually compressed to form a magnetic flux parallel to the direction of motion, which is less than the induced electromotive force of magnetic wire cutting, so Its input power can be reduced when it is driven by electricity, and when the coil 13 of the induction coil group 10 coil parts 11 is electrically excited, the magnetic stress generated by the interference with the first and second magnetic groups 20, 30 after magnetization can have The dual magnetic assist can increase the output power, achieve both low input power and high output power, and improve energy conversion efficiency.

In this way, it can be understood that the utility model is a creation with excellent creativity. In addition to effectively solving the problems faced by the practitioners, it can greatly improve the efficacy, and there is no identical or similar product creation or disclosure in the same technical field. Use, and simultaneously have the enhancement of efficacy.

Claims (6)

1. The electric device 1. a kind of magnetic pole misplaces, the electric device include an induction coil group, one first magnetic group, one second magnetic group And a power switch group, wherein first and second magnetic group can synchronous relative induction coil group motion, it is characterised in that：

   And the induction coil group has an at least coil piece, and each coil piece has one with the magnetic conduction for the direction extension that moves vertically Body and at least one coil for being located on the magnetic conductor are formed, and the coil is simultaneously connected to electric power supply；

   The first magnetic group is formed by the mutual equi-spaced apart concatenation of at least one first magnetic part and at least one second magnetic part again, and Each perpendicular direction of motion of first and second magnetic part magnetizes, and first and second adjacent magnetic part corresponds to the magnetic pole of induction coil group one end It is adjacent in heteropole；

   The another second magnetic group is formed by least one the 3rd magnetic part and the mutual equi-spaced apart concatenation of at least one the 4th magnetic part, its In third and fourth magnetic part and foregoing first and second magnetic part equal length, and the perpendicular direction of motion of third and fourth each magnetic part Magnetize, third and fourth adjacent magnetic part corresponds to that the magnetic pole of induction coil group one end is adjacent in heteropole, another second magnetic group the 3rd, Four magnetic parts and first and second magnetic part of the first magnetic group are in relative equidistant dislocation shape, and the magnetic pole center of third and fourth magnetic part is right Answer the center of the adjacent pole central axial line distance of first and second magnetic part, and the magnetic pole center of first and second magnetic part also corresponds to the 3rd, the center of the adjacent pole central axial line distance of four magnetic parts, first the first magnetic part corresponds to the line of induction in the first magnetic group The magnetic pole of the magnetic pole of circle group induction coil group corresponding with first the 3rd magnetic part in the second magnetic group is relative in homopolarity；

   As for, the power switch group by least one to electric switch, at least a cut-off switch, an at least path sensing element and extremely A few breaking sensing element is formed, and the corresponding first magnetic group one of each coil piece in induction coil group should be wherein divided into electric switch The center at end, and the cut-off switch is then located at the center of corresponding second magnetic group one end of each coil piece in induction coil group, and it is each logical Road sensing element be divided into the first magnetic group first and second magnetic part correspond to induction coil group one end magnetic pole center, it is each open circuit sense Answer element be divided into the second magnetic group third and fourth magnetic part correspond to induction coil group one end magnetic pole center, so as to form one kind Electric device of the back segment to electricity.
2. The electric device 2. magnetic pole as claimed in claim 1 misplaces, it is characterised in that：Adjacent first and second magnetic of the first magnetic group Property part is close to, and third and fourth adjacent magnetic part of the second magnetic group is close to.
3. The electric device 3. magnetic pole as claimed in claim 1 misplaces, it is characterised in that：Adjacent first and second magnetic of the first magnetic group Property part has a magnetic gap, and third and fourth adjacent magnetic part of the second magnetic group has an equidistant magnetic gap.
4. The electric device 4. a kind of magnetic pole misplaces, the electric device include an induction coil group, one first magnetic group, one second magnetic group And a power switch group, wherein the first magnetic group and the second magnetic group can synchronous relative induction coil group motions, it is characterised in that：

   And the induction coil group has an at least coil piece, and each coil piece has one with the magnetic conduction for the direction extension that moves vertically Body and at least one coil for being located on the magnetic conductor are formed, and the coil is simultaneously connected to electric power supply；

   The first magnetic group is formed by the mutual equi-spaced apart concatenation of at least one first magnetic part and at least one second magnetic part again, and Each perpendicular direction of motion of first and second magnetic part magnetizes, and first and second adjacent magnetic part corresponds to the magnetic pole of induction coil group one end It is adjacent in heteropole；

   The another second magnetic group is formed by least one the 3rd magnetic part and the mutual equi-spaced apart concatenation of at least one the 4th magnetic part, its In third and fourth magnetic part and foregoing first and second magnetic part equal length, and the perpendicular direction of motion of third and fourth each magnetic part Magnetize, third and fourth adjacent magnetic part corresponds to that the magnetic pole of induction coil group one end is adjacent in heteropole, the second magnetic group third and fourth Magnetic part and first and second magnetic part of the first magnetic group are in relative equidistant dislocation shape, and the magnetic pole center of third and fourth magnetic part is corresponding The center of the adjacent pole central axial line distance of first and second magnetic part, and the magnetic pole center of first and second magnetic part also corresponds to the 3rd, the center of the adjacent pole central axial line distance of four magnetic parts, first the first magnetic part corresponds to the line of induction in the first magnetic group The magnetic pole of the magnetic pole of circle group induction coil group corresponding with first the 3rd magnetic part in the second magnetic group is relative in heteropole；

   As for, the power switch group by least one to electric switch, at least a cut-off switch, an at least path sensing element and extremely A few breaking sensing element is formed, and the corresponding second magnetic group one of each coil piece in induction coil group should be wherein divided into electric switch The center at end, and the cut-off switch is then located at the center of corresponding first magnetic group one end of each coil piece in induction coil group, and it is each logical Third and fourth magnetic part that road sensing element is divided into the second magnetic group corresponds to the magnetic pole center of induction coil group one end, and each open circuit Sensing element be divided into the first magnetic group first and second magnetic part correspond to induction coil group one end magnetic pole center, so as to form one Electric device of the kind leading portion to electricity.
5. The electric device 5. magnetic pole as claimed in claim 4 misplaces, it is characterised in that：Adjacent first and second magnetic of the first magnetic group Property part is close to, and third and fourth adjacent magnetic part of the second magnetic group is close to.
6. The electric device 6. magnetic pole as claimed in claim 4 misplaces, it is characterised in that：Adjacent first and second magnetic of the first magnetic group Property part has a magnetic gap, and third and fourth adjacent magnetic part of the second magnetic group has an equidistant magnetic gap.