阅读说明：本技术 多磁极电磁铁动能动力机 (Multi-magnet electromagnet kinetic energy power machine ) 是由 胡传胜 于 2019-09-12 设计创作，主要内容包括：一种多磁极电磁铁动能动力机,其特点是：依据电磁铁的自然规律性在额定功率下利用增加电磁铁截面直径和增加线圈匝数进行增大引力或斥力,利用多磁极并联之技术减少线圈的电阻产热和提高运动速度,采用上述方案后验结果显示120W输入6300W输出,根据现象还会出现更佳结果。(A multi-pole electromagnet kinetic energy power machine is characterized in that: according to the natural regularity of the electromagnet, under the rated power, the attraction force or the repulsion force is increased by increasing the section diameter of the electromagnet and increasing the number of turns of the coil, the resistance heat production of the coil is reduced and the movement speed is improved by using the multi-magnetic-pole parallel connection technology, the 120W input 6300W output is displayed by adopting the posterior result of the scheme, and a better result can be generated according to the phenomenon.)

1. A multi-pole electromagnet kinetic energy power machine is characterized in that: the multi-magnet electromagnet kinetic energy power machine 1 is implemented by that a flywheel (113) in the structure chart 1 is arranged at one end of a crankshaft (114) and outside a bracket (66), the bracket (66) is arranged at one end of the crankshaft (114), one end of the crankshaft (114) and an output shaft used for doing work outside the outer part of the flywheel (113), one end of a connecting rod (67) is connected with an eccentric shaft (111) and the other end is connected with a pin (56) in an electromagnet power assembly (A1), one end of a connecting rod (110) is connected with an eccentric shaft (68) and the other end is connected with the pin (56) in the electromagnet power assembly (A2), a bracket (109) is arranged at the other end of the crankshaft (114) and inside a gear (108), the gear (108) is arranged at the other end of the crankshaft (114), a cam (107) is arranged on the eccentric shaft (68), a bearing (1) in a normally open switch assembly (C1) is in contact fit with the cam (107), the cam (112) is arranged on the eccentric shaft (111), a bearing (1) in the normally open switch assembly (C2) is in contact fit with the cam (112), the gear (70) is arranged at the shaft head of the generator (69) and is occluded with the gear (108), one ends of wires (71) and (72) are connected with the generator (69) and the other ends are connected with the voltage stabilizer (77), one ends of wires (78) and (79) are connected with the voltage stabilizer (77) and the other ends are connected with the charger (80), one ends of wires (81) and (82) are connected with the charger (80) and the other ends are connected with the battery (83), one ends of wires (84) and (85) are connected with the battery (83) and the other ends are connected with the switch (86), one ends of wires (87) and (88) are connected with the switch (86) and the other ends are connected with the single chip microcomputer automatic controller (91), one ends of wires (92) and (93) are connected with the single chip, one end of each of the wires (95) and (96) is connected with the sliding resistor (94) and the other end is connected with the switch (97), one end of each of the wires (98) and (99) is connected with the switch (97) and the other end is connected with the switchboard (100), one end of each of the wires (101) is connected with the switchboard (100) and the other end is connected with the wire (102), one end of each of the wires (105) is connected with the switchboard (100) and the other end is connected with the copper block (10) in the normally open switch assembly (C2), one end of each of the wires (104) is connected with the copper block (18) of the normally open switch assembly (C2) and the other end is connected with the wire (103), one end of the wire (103) is connected with the wires (52) and (53) at one end of the dynamic electromagnet (35) in the electromagnet power assembly (A2) and the other end is connected with the wires (47) and (48) at one end of the static electromagnet (40) in the electromagnet power assembly (A2), and one end of the 45) The other end of the lead (46) is connected with leads (54) and (55) at one end of a dynamic electromagnet (35) in an electromagnet power assembly (A2), one end of a lead (73) is connected with a copper block (10) in a normally open switch assembly (C1), the other end is connected with a lead (75), one end of a lead (106) is connected with a copper block (18) in a normally open switch assembly (C1), the other end is connected with a switchboard (100), one end of the lead (74) is connected with the switchboard (100), the other end is connected with a lead (76), one end of the lead (75) is connected with leads (52) and (53) at one end of the dynamic electromagnet (35) in the electromagnet power assembly (A1) and connected with leads (47) and (48) at one end of a static electromagnet (40) in the electromagnet power assembly (A1), one end of the lead (76) is connected with a lead (54) at one end of the dynamic electromagnet (35) in the electromagnet power assembly (A1), (55) The other end of the connection is connected with wires (45) and (46) at one end of a static electromagnet (40) in an electromagnet power assembly (A1), a support (66) and (109) are fixed on a workbench, a generator (69) is fixed on the workbench, a normally open switch assembly (C1) and (C2) are fixed on the workbench through wire holes (14), the electromagnet power assembly (A1) and (A2) are fixed on the workbench, a distribution board (100), a sliding resistor (94), a single-chip automatic controller (91), a voltage stabilizer (77), a charger (80), a battery (83), a switch (86) and a switch (97) are fixed on the workbench.

2. The multi-pole electromagnet kinetic energy power machine as set forth in claim 1, wherein: the 2 nd implementation structure diagram of the multi-magnet electromagnet kinetic energy power machine is that in the structure diagram 2, a bracket (128) is installed at one end of a crankshaft (149) and fixed on a workbench, a bracket (117) is installed at the other end of the crankshaft (149) and fixed on the workbench, a gear (108) is installed at one end of the crankshaft (149) and outside the bracket (128), one end of the crankshaft (149) and an output shaft for doing work outwards is arranged on the outer side part of the gear (108), eccentric shafts (131), (134), (137) and (139) are sequentially arranged from one end of the crankshaft (149), a cam (129) is arranged on the eccentric shaft (131) and is in contact fit with a bearing (1) in a normally open switch assembly (C4), a cam (135) is arranged on the eccentric shaft (134) and is in contact fit with a bearing (1) in the normally open switch assembly (C3), a cam (136) is arranged on the eccentric shaft (137) and is in contact fit with the bearing (1) in the normally open switch assembly (, the eccentric shaft (139) is provided with a cam (118) and is matched with a bearing (1) in a normally open switch assembly (C1) when in contact, one end of a connecting rod (130) is connected with the eccentric shaft (131) and the other end is connected with a pin (56) in an electromagnet power assembly (B4), one end of a lead (127) is connected with the other end of a distribution board (100) and a lead (146), one end of the lead (148) is connected with a lead (147) and the other end is connected with a copper block (10) in the normally open switch assembly (C4), one end of a lead (124) is connected with the distribution board (100) and the other end is connected with a copper block (18) in the normally open switch assembly (C4), one end of the lead (147) is connected with leads (47, 48 and 61) at one end of a static electromagnet (40) in the electromagnet power assembly (B4) and the other end is connected with a lead (52) at one end of a dynamic electromagnet (35) in the electromagnet power assembly, (53) (64), one end of a lead (146) is connected with leads (45), (46), (60) at one end of a static electromagnet (40) in an electromagnet power assembly (B4), the other end of the lead is connected with leads (54), (55), (65) at one end of a dynamic electromagnet (35) in the electromagnet power assembly (B4), one end of a connecting rod (133) is linked with an eccentric shaft (134) and the other end of the connecting rod is linked with a pin (56) of the electromagnet power assembly (B3), one end of a lead (125) is linked with leads (45), (46), (60) at one end of the static electromagnet (40) in the electromagnet power assembly (B3) and the other end of the lead is linked with leads (54), (55), (65) at one end of the dynamic electromagnet (35) in the electromagnet power assembly (B3), one end of the lead (132) is linked with a copper block (10) in a normally open switch assembly (C3) and the other end of the lead (126), one end of a lead (122) is linked with the distribution board (100) and the other end is linked with a copper block (18) in a normally open switch assembly (C3), one end of a lead (123) is linked with the distribution board (100) and the other end is linked with a lead (125), one end of a lead (126) is linked with leads (47), (48) and (61) at one end of a static electromagnet (40) in an electromagnet power assembly (B3) and the other end is linked with leads (52), (53) and (64) at one end of a dynamic point electromagnet (35) in an electromagnet power assembly (B3), one end of a connecting rod (138) is linked with an eccentric shaft (137) and the other end is linked with a pin (56) in an electromagnet power assembly (B2), one end of a lead (144) is linked with leads (52), (53) and (64) at one end of a dynamic electromagnet (35) in an electromagnet power assembly (B2) and the other end is linked with a lead (47) at one end of a static electromagnet (40) in an electromagnet power, (48) (61) one end of a lead (145) is linked with leads (54), (55) and (65) at one end of a dynamic electromagnet (35) in an electromagnet power assembly (B2) and the other end is linked with leads (45), (46) and (60) at one end of a static electromagnet (40) in the electromagnet power assembly (B2), one end of a lead (143) is linked with a copper block (18) in a normally open switch assembly (C3) and the other end is linked with a lead (144), one end of a lead (142) is linked with the lead (145) and the other end is linked with a switchboard (100), one end of a switchboard (100) of a lead (141) is linked with a copper block (10) in a normally open switch assembly (C3), one end of a connecting rod (140) is linked with an eccentric shaft (139) and the other end is linked with a pin (56) in the electromagnet power assembly (B1), one end of a lead (121) is linked with leads (45) and (46) at one end of a static electromagnet (40) in an electromagnet power assembly (B1), (60) The other end of the link is linked with the leads (54), (55), (65) at one end of the dynamic electromagnet (35) in the electromagnet power assembly (B1), one end of the lead (120) is linked with the leads (47), (48), (61) at one end of the static electromagnet (40) in the electromagnet power assembly (B1), the other end of the link is linked with the leads (52), (53), (64) at one end of the dynamic electromagnet (35) in the electromagnet power assembly (B1), one end of the lead (119) is linked with the lead (120), the other end of the link is linked with the distribution board (100), one end of the lead (116) is linked with the distribution board (100), the other end of the link is linked with the copper block (18) in the normally open switch assembly (C1), one end of the lead (115) is linked with the distribution board (100), the other end of the link is linked with the copper block (10) in the normally open switch assembly (C1), and the other structures are, outlined.

Technical Field

The invention relates to an electromagnet power machine, in particular to a multi-pole electromagnet kinetic energy power machine which is composed of multi-pole coils and moves at high frequency.

Background

At present, electromagnets used by people in social production and life are basically products with small two-pole lead volume and large energy consumption; power machines used, such as: the invention relates to a multi-pole electromagnet kinetic energy power machine, which comprises a motor, a diesel engine, a gasoline engine, a steam engine, a gas engine and the like, wherein the motor, the diesel engine, the gasoline engine, the steam engine, the gas engine and the like are all products consuming natural energy, carbon monoxide, carbon dioxide, heat and noise are discharged to pollute the natural environment and influence the health of human bodies.

Disclosure of Invention

The invention aims to provide a method for preparing: the multi-magnet electromagnet kinetic energy power machine does not consume new continuous energy, does not generate waste gas and can change the power according to the use requirements of people.

The purpose of the invention is realized as follows: the multi-magnet electromagnet kinetic energy power machine 1 is implemented by that a flywheel (113) in the structure chart 1 is arranged at one end of a crankshaft (114) and outside a bracket (66), the bracket (66) is arranged at one end of the crankshaft (114), one end of the crankshaft (114) and an output shaft used for doing work outside the outer part of the flywheel (113), one end of a connecting rod (67) is connected with an eccentric shaft (111) and the other end is connected with a pin (56) in an electromagnet power assembly (A1), one end of a connecting rod (110) is connected with an eccentric shaft (68) and the other end is connected with the pin (56) in the electromagnet power assembly (A2), a bracket (109) is arranged at the other end of the crankshaft (114) and inside a gear (108), the gear (108) is arranged at the other end of the crankshaft (114), a cam (107) is arranged on the eccentric shaft (68), a bearing (1) in a normally open switch assembly (C1) is in contact fit with the cam (107), the cam (112) is arranged on the eccentric shaft (111), a bearing (1) in the normally open switch assembly (C2) is in contact fit with the cam (112), the gear (70) is arranged at the shaft head of the generator (69) and is occluded with the gear (108), one ends of wires (71) and (72) are connected with the generator (69) and the other ends are connected with the voltage stabilizer (77), one ends of wires (78) and (79) are connected with the voltage stabilizer (77) and the other ends are connected with the charger (80), one ends of wires (81) and (82) are connected with the charger (80) and the other ends are connected with the battery (83), one ends of wires (84) and (85) are connected with the battery (83) and the other ends are connected with the switch (86), one ends of wires (87) and (88) are connected with the switch (86) and the other ends are connected with the single chip microcomputer automatic controller (91), one ends of wires (92) and (93) are connected with the single chip, one end of each of the wires (95) and (96) is connected with the sliding resistor (94) and the other end is connected with the switch (97), one end of each of the wires (98) and (99) is connected with the switch (97) and the other end is connected with the switchboard (100), one end of each of the wires (101) is connected with the switchboard (100) and the other end is connected with the wire (102), one end of each of the wires (105) is connected with the switchboard (100) and the other end is connected with the copper block (10) in the normally open switch assembly (C2), one end of each of the wires (104) is connected with the copper block (18) of the normally open switch assembly (C2) and the other end is connected with the wire (103), one end of the wire (103) is connected with the wires (52) and (53) at one end of the dynamic electromagnet (35) in the electromagnet power assembly (A2) and the other end is connected with the wires (47) and (48) at one end of the static electromagnet (40) in the electromagnet power assembly (A2), and one end of the 45) The other end of the lead (46) is connected with leads (54) and (55) at one end of a dynamic electromagnet (35) in an electromagnet power assembly (A2), one end of a lead (73) is connected with a copper block (10) in a normally open switch assembly (C1), the other end is connected with a lead (75), one end of a lead (106) is connected with a copper block (18) in a normally open switch assembly (C1), the other end is connected with a switchboard (100), one end of the lead (74) is connected with the switchboard (100), the other end is connected with a lead (76), one end of the lead (75) is connected with leads (52) and (53) at one end of the dynamic electromagnet (35) in the electromagnet power assembly (A1) and connected with leads (47) and (48) at one end of a static electromagnet (40) in the electromagnet power assembly (A1), one end of the lead (76) is connected with a lead (54) at one end of the dynamic electromagnet (35) in the electromagnet power assembly (A1), (55) The other end of the connection is connected with wires (45) and (46) at one end of a static electromagnet (40) in an electromagnet power assembly (A1), a support (66) and (109) are fixed on a workbench, a generator (69) is fixed on the workbench, a normally open switch assembly (C1) and (C2) are fixed on the workbench through wire holes (14), the electromagnet power assembly (A1) and (A2) are fixed on the workbench, a distribution board (100), a sliding resistor (94), a single-chip automatic controller (91), a voltage stabilizer (77), a charger (80), a battery (83), a switch (86) and a switch (97) are fixed on the workbench.

The 2 nd implementation structure diagram of the multi-magnet electromagnet kinetic energy power machine is that in the structure diagram 2, a bracket (128) is installed at one end of a crankshaft (149) and fixed on a workbench, a bracket (117) is installed at the other end of the crankshaft (149) and fixed on the workbench, a gear (108) is installed at one end of the crankshaft (149) and outside the bracket (128), one end of the crankshaft (149) and an output shaft for doing work outwards is arranged on the outer side part of the gear (108), eccentric shafts (131), (134), (137) and (139) are sequentially arranged from one end of the crankshaft (149), a cam (129) is arranged on the eccentric shaft (131) and is in contact fit with a bearing (1) in a normally open switch assembly (C4), a cam (135) is arranged on the eccentric shaft (134) and is in contact fit with a bearing (1) in the normally open switch assembly (C3), a cam (136) is arranged on the eccentric shaft (137) and is in contact fit with the bearing (1) in the normally open switch assembly (, the eccentric shaft (139) is provided with a cam (118) and is matched with a bearing (1) in a normally open switch assembly (C1) when in contact, one end of a connecting rod (130) is connected with the eccentric shaft (131) and the other end is connected with a pin (56) in an electromagnet power assembly (B4), one end of a lead (127) is connected with the other end of a distribution board (100) and a lead (146), one end of the lead (148) is connected with a lead (147) and the other end is connected with a copper block (10) in the normally open switch assembly (C4), one end of a lead (124) is connected with the distribution board (100) and the other end is connected with a copper block (18) in the normally open switch assembly (C4), one end of the lead (147) is connected with leads (47, 48 and 61) at one end of a static electromagnet (40) in the electromagnet power assembly (B4) and the other end is connected with a lead (52) at one end of a dynamic electromagnet (35) in the electromagnet power assembly, (53) (64), one end of a lead (146) is connected with leads (45), (46), (60) at one end of a static electromagnet (40) in an electromagnet power assembly (B4), the other end of the lead is connected with leads (54), (55), (65) at one end of a dynamic electromagnet (35) in the electromagnet power assembly (B4), one end of a connecting rod (133) is linked with an eccentric shaft (134) and the other end of the connecting rod is linked with a pin (56) of the electromagnet power assembly (B3), one end of a lead (125) is linked with leads (45), (46), (60) at one end of the static electromagnet (40) in the electromagnet power assembly (B3) and the other end of the lead is linked with leads (54), (55), (65) at one end of the dynamic electromagnet (35) in the electromagnet power assembly (B3), one end of the lead (132) is linked with a copper block (10) in a normally open switch assembly (C3) and the other end of the lead (126), one end of a lead (122) is linked with the distribution board (100) and the other end is linked with a copper block (18) in a normally open switch assembly (C3), one end of a lead (123) is linked with the distribution board (100) and the other end is linked with a lead (125), one end of a lead (126) is linked with leads (47), (48) and (61) at one end of a static electromagnet (40) in an electromagnet power assembly (B3) and the other end is linked with leads (52), (53) and (64) at one end of a dynamic point electromagnet (35) in an electromagnet power assembly (B3), one end of a connecting rod (138) is linked with an eccentric shaft (137) and the other end is linked with a pin (56) in an electromagnet power assembly (B2), one end of a lead (144) is linked with leads (52), (53) and (64) at one end of a dynamic electromagnet (35) in an electromagnet power assembly (B2) and the other end is linked with a lead (47) at one end of a static electromagnet (40) in an electromagnet power, (48) (61) one end of a lead (145) is linked with leads (54), (55) and (65) at one end of a dynamic electromagnet (35) in an electromagnet power assembly (B2) and the other end is linked with leads (45), (46) and (60) at one end of a static electromagnet (40) in the electromagnet power assembly (B2), one end of a lead (143) is linked with a copper block (18) in a normally open switch assembly (C3) and the other end is linked with a lead (144), one end of a lead (142) is linked with the lead (145) and the other end is linked with a switchboard (100), one end of a switchboard (100) of a lead (141) is linked with a copper block (10) in a normally open switch assembly (C3), one end of a connecting rod (140) is linked with an eccentric shaft (139) and the other end is linked with a pin (56) in the electromagnet power assembly (B1), one end of a lead (121) is linked with leads (45) and (46) at one end of a static electromagnet (40) in an electromagnet power assembly (B1), (60) The other end of the link is linked with the leads (54), (55), (65) at one end of the dynamic electromagnet (35) in the electromagnet power assembly (B1), one end of the lead (120) is linked with the leads (47), (48), (61) at one end of the static electromagnet (40) in the electromagnet power assembly (B1), the other end of the link is linked with the leads (52), (53), (64) at one end of the dynamic electromagnet (35) in the electromagnet power assembly (B1), one end of the lead (119) is linked with the lead (120), the other end of the link is linked with the distribution board (100), one end of the lead (116) is linked with the distribution board (100), the other end of the link is linked with the copper block (18) in the normally open switch assembly (C1), one end of the lead (115) is linked with the distribution board (100), the other end of the link is linked with the copper block (10) in the normally open switch assembly (C1), and the other structures are, outlined.

The pin (56) of the electromagnet power assembly (A) related to the implementation structure of the multi-magnet electromagnet kinetic energy power machine is arranged at one end of a connecting frame (57), the other end of the connecting frame (57) is matched with one end of a dynamic electromagnet (35), the middle part of the dynamic electromagnet (35) is arranged in a fixed frame (37), one side of the bottom of the dynamic electromagnet (35) provided with a positioning groove (59) is provided with a positioning groove (36), the other side of the dynamic electromagnet (35) is provided with a positioning groove (51), a bearing (33) is arranged in the positioning groove (59) and fixed at the bottom of the fixed frame (37) by a shaft (34), a bearing (38) is arranged in the positioning groove (36) and fixed at one side of the fixed frame (37) by a shaft (39), a bearing (50) is arranged in the positioning groove (51) and fixed at the other side of the fixed frame (37) by a shaft (49), and leads (52) and (53) are respectively, the leads (54) and (55) are respectively connected with two positive poles of the inner coil of the dynamic electromagnet (35) and are arranged at one end of the dynamic electromagnet (35), the static electromagnet (40) is arranged on the base (44), the cover plate (43) is arranged on the upper side of the base (44), the cover plate (43) is provided with a wire hole (42), the base (44) is provided with a wire hole (41), the dynamic electromagnet (35) and the static electromagnet (40) are in concentric shaft fit, the other end of the dynamic electromagnet (35) and the other end of the static electromagnet (40) are contact surfaces, a gap is left between the installation according to actual requirements, the leads (45) and (46) are connected with two positive poles of the inner coil of the static electromagnet (40) and are arranged at one end of the static electromagnet (40), the leads (47) and (48) are respectively connected with two negative poles of the inner coil of the static electromagnet (40), the implementation structure of the electromagnet power assembly (A) is the same as the implementation structures of the electromagnet power assemblies (A1) and (A2).

One end of a magnetic ring (62) in an electromagnet power assembly (B) related to the implementation structure of the multi-magnet electromagnet kinetic energy power machine is arranged at the other end of a static electromagnet (40), the other end of a dynamic electromagnet (35) is arranged in a hole at the other end of the magnetic ring (62), a breathing hole (63) is arranged on the magnetic ring (62), leads (52), (53) and (64) are respectively connected with two cathodes of an inner coil of the dynamic electromagnet (35) and are arranged at one end of the dynamic electromagnet (35), leads (54), (55) and (65) are respectively connected with two anodes of the inner coil of the dynamic electromagnet (35) and are arranged at one end of the dynamic electromagnet (35), leads (45), (46) and (60) are connected with two anodes of the inner coil of the static electromagnet (40) and are arranged at one end of the static electromagnet (40), and leads (47), (48) and (61) are respectively connected with two cathodes of the inner coil of the static electromagnet and are arranged at one, the electromagnet power assembly (B) has the same implementation structure as the electromagnet power assemblies (B1), (B2), (B3) and (B4), and the rest are the same as the electromagnet power assembly (A), which is outlined in the description.

The normally open switch assembly (C) related to the implementation structure of the multi-magnet electromagnet kinetic energy power machine has the following structure: the bearing (1) is fixed in a bearing groove (3) by a shaft (2) at one end of a sliding plug (4), an insulating plate (5) is arranged at one end of the sliding plug (4) through a guide hole (32), one end of the insulating plate (5) is matched with one end of an insulating plate (9) and fixed by a bolt (28), the other end of the insulating plate (5) is matched with one end of an insulating plate (24) and fixed by a bolt (28), the insulating plate (27) is arranged at one end of the sliding plug (4) and is arranged at the inner side of the insulating plate (5), a copper plate (25) is arranged on the sliding plug (4) and is fixed on the insulating plate (27), a spring (29) is arranged on the sliding plug (4) and is arranged between the insulating plate (27) and the insulating plate (11), the insulating plate (11) is arranged on the sliding plug (4) and is arranged at one side of a rubber spring (15), the other side of the rubber spring (15) is provided with the insulating plate (22), one end of, the insulating plate (22) is installed at the other end of the sliding plug (4) through the guide hole (19), one end of the insulating plate is matched with the other end of the insulating plate (9), the other end of the insulating plate is fixed through the bolt (12), the other end of the insulating plate is matched with the other end of the insulating plate (24) and fixed through the bolt (12), the guide shaft (6) is fixed through the guide hole (7), (8), (13) and (15) through the nut (16), the guide shaft (31) is fixed through the guide holes (30), (26), (23) and (20) through the nut (21), and the two ends of the insulating plate (5) and the insulating plate (22) are provided with screw holes (14) for being fixed.

The effective effect is as follows: by adopting the scheme, the diameter of the iron core is 140 mm, the height of the iron core is 140 mm, the number of turns of the coil is 3600 turns, the diameter of the lead is 1.4, the copper core wire is used for manufacturing the direct current electromagnet with the voltage of 60V, and the direct current electromagnet is detected by an instrument: the attractive force or the repulsive force of two electromagnets at the position of 20 mm is 626 kg, the ammeter displays that the current reading is 5.4A, the energy consumption of the electromagnets is 324W, and the output power is 3500W according to the 300-time movement frequency of the electromagnets per minute; after coils of the electromagnet are changed into four poles and connected in parallel, the reading of an ammeter is 12A, the attractive force and the repulsive force at the position of 20 mm are 1686 kg respectively, the energy consumption of the electromagnet is 720W, and the output power of the electromagnet is 9426.5W according to the frequency calculation of 300 times per minute during movement; the eccentric shaft is provided with the cam, so that timely electrification and timely outage are realized under the condition of ensuring sufficient electrification time by utilizing the electrification angle and the outage angle, and the problem of adhesion of the dynamic electromagnet (35) and the static electromagnet (40) at a flat angle of 180 degrees after outage is solved, so that the normal operation of the whole machine is ensured; because the invention adopts a plurality of groups of electromagnets to do work progressively according to the angle of the crankshaft respectively, the pulse of the output power is solved, and the sliding resistor (94) in the invention is used for controlling the movement frequency of the electromagnets; the electric energy generated by the generator (69) is used as internal energy to supply, a prototype machine is successfully manufactured by adopting the scheme, and the effective effect of amplifying the power by 20 times is completed by instrument detection, so that the prototype machine can be provided.

Drawings

Fig. 1 is a structural view of a first embodiment of the present invention.

Fig. 2 is a structural view of a second embodiment of the present invention.

Fig. 3 is a structural diagram of an electromagnet power assembly a of the present invention.

Fig. 4 is a structural diagram of an electromagnet power assembly B of the present invention.

Fig. 5 is a structural diagram of an embodiment of a normally open switch assembly C of the present invention.

In the figure: 1. bearing, 2, shaft, 3, bearing groove, 4, sliding plug, 5, insulating plate, 6, guide shaft, 7, guide hole, 8, guide hole, 9, insulating plate, 10, copper block, 11, insulating plate, 12, bolt, 13, guide hole, 14, screw hole, 15, guide hole, 16, nut, 17, rubber spring, 18, copper block, 19, guide hole, 20, guide hole, 21, nut, 22, insulating plate, 23, guide hole, 24, insulating plate, 25, copper plate, 26, guide hole, 27, insulating plate, 28, bolt, 29, spring, 30, guide hole, 31, nut, 32, guide hole, 33, bearing, 34, shaft, 35, dynamic electromagnet, 36, positioning groove, 37, fixing frame, 38, bearing, 39, shaft, 40, static electromagnet, 41, screw hole, 42, screw hole, 43, cover plate, 44, base, 45, lead wire, 46, lead wire, 47, cover plate, 44, guide hole, base, and guide hole, Wire, 48, wire, 49, shaft, 50, bearing, 51, detent, 52, wire, 53, wire, 54, wire, 55, wire, 56, bolt, 57, coupling frame, 58, nut, 59, detent, 60, wire, 61, wire, 62, magnetic ring, 63, breathing hole, 64, wire, 65, wire, 66, bracket, 67, link, 68, eccentric shaft, 69, generator, 70, gear, 71, wire, 72, wire, 73, wire, 74, wire, 75, wire, 76, wire, 77, regulator, 78, wire, 79, wire, 80, charger, 81, wire, 82, wire, 83, battery, 84, wire, 85, wire, 86, switch, 87, wire, 88, wire, 89, wire, 90, wire, 91, single chip microcomputer automatic controller, 92, wire, 93, wire, 94, sliding resistor, 95, wire, 96. wire, 97, switch, 98, wire, 99, wire, 100, switchboard, 101, wire, 102, wire, 103, wire, 104, wire, 105, wire, 106, wire, 107, cam, 108, gear, 109, bracket, 110, link, 111, eccentric shaft, 112, cam, 113, flywheel, 114, crankshaft, 115, wire, 116, wire, 117, bracket, 118, cam, 119, wire, 120, wire, 121, wire, 122, wire, 123, wire, 124, wire, 125, wire, 126, wire, 127, wire, 128, bracket, 129, cam, 130, link, 131, eccentric shaft, 132, wire, 133, link, 134, eccentric shaft, 135, cam, 136, cam, 137, eccentric shaft, 138, link, 139, eccentric shaft, 140, link, 141, wire, 142, wire, 143, wire, 144, wire, 145, wire, 146, cam, 114, cam, 124, wire, 125, wire, bracket, 126, wire, cam, and/or eccentric shaft, 140, the device comprises a lead 147, a lead 148, a lead 149, a crankshaft, A1, an electromagnet power assembly, A2, an electromagnet power assembly, B1, an electromagnet power assembly, B2, an electromagnet power assembly, B3, an electromagnet power assembly, B4, an electromagnet power assembly, C1, a normally open switch assembly, C2, a normally open switch assembly, C3, a normally open switch assembly, C4 and a normally open switch assembly.

Detailed Description