TW201347366A - Second-generation wheel generator (an axis of two core linked to the motor generats) - Google Patents

Abstract

The present invention is to a combination of electric motor (motor) and the generator two sets of equipment as a group, a rotor, a shaft, the original motor of a certain child and the generator of a shaft a rotor is a certain sub-composed of one axis two rotor two stators, referred to as an axis of twocore linked to the motor generator. Motor (motor) or a generator each set of rotor and a stator, the rotor can be rotated, while the stator is fixed and surrounded by the rotor, the motor is the external current into the rotor or stator generate electromagnetic fields to drive the rotor and shaft. Motor principle and the principle of the generator are very similar. The generator is gear leather rely on external forces, such as a rotating shaft of the rotor produces a magnetic field to the line of rings of the stator voltage, the only difference between the two in one rely on the external current into the rotating rotor, one rotation of the rotor to generate electricity by external forces.. Motors and generators the same internal structure and operation principle. An axis of two core with dynamic motor generator motor and generator shaft changed to a shaft two rotor-stator (twins) principle unchanged. So it is convenient, and a rotation motor, generator followed rotate, so that does not occupy space, two generators do not need the belt and other gear excess objects driven, so that materials and design will save a lot. One axis and two core linked to the volume size of the motor generator can be work requirements to make general motors and generators, the generator output power in accordance with the work required to million voltage on the power plants, small can to micro-volts to 6 volts. An axis of two core with moving motor generator practical use in the home, electric cars, power plants, as long as the generator equipment platform can be used.

Description

Second-generation wheel generator (one-axis two-core motor generator)

The first generation of the invention is a (wheel generator) extension that combines the current AC-DC single-phase or three-phase multi-phase induction motor (motor) with the generator two sets of mechanical improvement design into a group of internal ones. Two rotors (cores) of the two axes of the rotary shaft, the other internal components are unchanged. Only one (rotary axis) is changed into one, which is called a one-axis two-core linkage motor generator. The motor can use the battery's DC motor or change the AC motor. The linked motor generator can also be attached to the engine. It can be used when the motor and the generator are required to operate at the same time or the engine and the generator can be used on the same rotary shaft. (The motor generator can also be turned upside down. The front is the generator and the motor can be customized according to the needs of the working platform.) It does not stand in space, and is environmentally friendly. It is powered by the gasoline and diesel engines used by the current generators. It is the same, but gasoline and diesel will pollute the air. The linked motor generator is driven by the front motor to drive the rear generator, which can save the existing additional parts such as the chain gear belt, and can also be attached to the engine shaft, where the engine is attached, and the AC and DC generator It is directly bonded to the motor.

One-axis two-core linkage motor generator, inside is a rotary shaft with two rotors, the first rotor is a DC motor rotor, the second rotor is a generator rotor, a split core or a pole core rotor, and the DC motor moves together Directly drive the generator to generate electricity, no external accessories. The AC motor and the alternator are produced in the same form. The motor generator can be lying flat. It can be erected according to the terrain. The power is large and can be made according to the situation. It can be used as a micro motor. The linkage motor generator is the most environmentally friendly. It uses the battery to start the motor and then generates electricity by the linkage generator. The current is directly transmitted to the battery storage patrol system and then the current is transmitted to the front motor, which becomes a patrol system. (One-axis two-core motor generator can drive a powerful current generator to generate electricity according to a small current motor, for example, an AC generator after DC motor).

The invention combines the existing single-phase or three-phase AC/DC multiple induction motor (motor) and the generator into a group. Inside, there are two rotors with one rotary shaft. The front of the rotor is driven by the rotor of the motor. The stator and other original internal components are unchanged. The existing gears or belts are removed, and the space is not occupied. Moreover, it does not affect the operation of the motor and the generator. The front and rear of the two shafts can also be reversed. The front is the generator and the motor can also be used. As long as the two rotors on one rotary shaft are turned back and forth, it is more practical. .

One-axis two-core DC-linked motor generator is a rotor with two rotors and a general motor and generator are separated. For example, a one-axis two-core motor generator is a one-axis two-core when custom-made. Figure 2, 2-1 a rotating shaft, 2-2 front insulated iron core coil rotor slot. 2-3 pole core rotor. 2-4 front insulated iron core coil rotor slot. 2-5 squirrel cage rotor. Figure 3. Internal perspective view of a two-core (DC motor) and (iron core) rotor. 3-1 bearing beads. 3-2 slide. 3-3 copper slip ring. 3-4 front insulated iron core coil rotor slot. 3-5 commutator. 3-6 slides. 3-7 bearing beads. 3-8 bearing beads. 3-9 slides. 3-10 copper slip ring. 3-11 squirrel cage rotor. 3-12 commutator. 3-13 slides. 3-14 bearing beads. Figure 4. One-axis two-core (DC motor) and pole-core rotor. 4-1 bearing beads. 4-2 slide 4-3 copper slip ring. 4-4 front insulated core coil rotor slot. 4-5 commutator. 4-6 slides. 4-7 bearing beads. 4-8 bearing beads. 4-9 slides. 4-10 magnetic pole rotor. 4-11 commutator. 4-12 slides. 4-13 bearing beads. One-axis two-core linkage motor generator, two rotors on a rotary shaft are arranged in sequence, Figure 5, (DC motor) and (core generator) upright explosion diagram. 5-1 on the tuyere. 5-2 fan casing tuyere cover. 5-3 The lower base of the fan case. 5-4 fan cooling blades. 5-5 bearings. 5-6 stator cover. 5-7 stator N-pole magnet. 5-8 stator S pole magnet. 5-9 front and rear end caps. 5-10 intermediate fixed spacer. 5-11 stator core. 5-12 bearings. 5-13 stator cover. 5-14 rear end cover. 5-15 erected stand. Figure 6, side view detail, 6-1 rotary axis. 6-2 bearing. 6-3 stator cover. 6-4 bearing beads. 6-5 slides. 6-6 copper slip ring. 6-7 coils. 6-8 stator N-pole magnet. 6-9 stator S pole magnet. 6-10 front insulated core coil rotor slot. 6-11 commutator. 6-12 slides. 6-13 left and right nails. 6-14 carbon brush sticks. 6-15 positive and negative output terminals. 6-16 bearing beads. 6-17 front and rear end caps. 6-18 intermediate fixed spacer. 6-19 bearings. 6-20 stator cover. 6-21 bearing beads. 6-22 positive and negative output terminals. 6-23 copper slip ring. 6-24 insulation paper. 6-25 coils. 6-26 squirrel cage rotor. 6-27 stator core. 6-28 commutator. 6-29 slides. 6-30 bearing beads. 6-31 or so nails. 6-32 or so carbon brush stick. 6-33 positive and negative output terminals. 6-34 erected stand. Figure 7 is a flat type. 7-1 The cover on the tuyere. 7-2 fan casing tuyere cover. 7-3 fan case lower base. 7-4 fan cooling blades. 7-5 bearings. 7-6 stator N-pole magnet. 7-7 stator S pole magnet. 7-8 stator cover. 7-9 front and rear end caps. 7-10 intermediate fixed spacer base. 7-11. Bearing. 7-12 stator cover. 7-13 stator core. 7-14 end base ventilation plate. Figure 8. Side exploded view of (DC motor) and (pole core generator). 8-1 on the tuyere. 8-2 fan casing tuyere cover. 8-3 fan cooling blades. 8-4 fan case lower base. 8-5 bearings. 8-7 bearing beads. 8-8 slides. 8-9 copper slip ring. 8-10 stator N-pole magnet. 8-11 stator S pole magnet. 8-12 coils. 8-13 front insulated core coil rotor slot. 8-14 commutator. 8-15 rotary axis. 8-16 slides. 8-17 or so nails. Carbon brush sticks around 8-18. 8-19 positive and negative output 瑞子. 8-20 positive and negative output terminals. 8-21 front and rear end caps. 8-22 bearing beads. 8-23 intermediate fixed spacer base. 8-24 slides. 8-25 copper slip ring. 8-26 coils. 8-27 insulation paper. 8-28 pole core rotor. 8-29 stator core. 8-30 bearings. 8-31 stator cover. 8-32 commutator. 8-33 slide. 8-34 nails. . 8-35 carbon brush stick. 8-36 bearing beads. 8-37 positive and negative output 瑞子. 8-38 endless base venting plate. Figure IX, DC linkage motor flat type, 9-1 tuyere cover. 9-2 fan casing tuyere cover. 9-3 fan cooling blades. 9-4 flat type internal perspective view. Figure 10, 10-1 upright type. 10-2 fan casing tuyere cover. 10-3 fan cooling blades. 10-4 upright internal perspective view.

Figure 3. Internal perspective view of a two-core (DC motor) and (iron core) rotor.

3-1. . . Bearing beads

3-2. . . Slide

3-3. . . Copper slip ring

3-4. . . Front insulated core coil rotor slot

3-5. . . Commutator

3-6. . . Slide

3-7. . . Bearing beads

3-8. . . Bearing beads

3-9. . . Slide

3-10. . . Copper slip ring

3-11. . . Squirrel cage rotor

3-12. . . Commutator

3-13. . . Slide

3-14. . . Axis diagram

Six, side view detail map.

6-1. . . Rotary axis

6-2. . . Bearing

6-3. . . Stator cover

6-4. . . Bearing beads

6-5. . . Slide

6-6. . . Copper slip ring

6-7. . . Coil

6-8. . . Stator N-pole magnet

6-9. . . Stator S pole magnet

6-10. . . Front insulated core coil rotor slot

6-11. . . Commutator

6-12. . . Slide

6-13. . . Left and right nails

6-14. . . Left and right carbon brush

6-15. . . Positive and negative output terminals

6-16. . . Bearing beads

6-17. . . Front and rear end caps

6-18. . . Intermediate fixed spacer

6-19. . . Bearing

6-20. . . Stator cover

6-21. . . Bearing beads

6-22. . . Positive and negative output terminals

6-23. . . Copper slip ring

6-24. . . Insulating paper

6-25. . . Coil

6-26. . . Squirrel cage rotor

6-27. . . Stator core

6-28. . . Commutator

6-29. . . Slide

6-30. . . Bearing beads

6-31. . . Left and right nails

6-32. . . Left and right carbon brush

6-33. . . Positive and negative output terminals

6-34. . . Unterminated stand

Figure 4. One-axis two-core (DC motor) and pole-core rotor.

4-1. . . Bearing beads

4-2. . . Slide

4-3. . . Copper slip ring

4-4. . . Front insulated core coil rotor slot

4-5. . . Commutator

4-6. . . Slide

4-7. . . Bearing beads

4-8. . . Bearing beads

4-9. . . Slide

4-10. . . Magnetic pole core rotor

4-11. . . Commutator

4-12. . . Slide

4-13. . . Bearing beads

Figure 8. Side exploded view of (DC motor) and (pole core generator).

8-1. . . Air outlet cover

8-2. . . Fan casing tuyere cover

8-3. . . Fan cooling blade

8-4. . . Fan case lower base

8-5. . . Bearing

8-7. . . Bearing beads

8-8. . . Slide

8-9. . . Copper slip ring

8-10. . . Stator N-pole magnet

8-11. . . Stator S pole magnet

8-12. . . Coil

8-13. . . Front insulated core coil rotor slot

8-14. . . Commutator

8-15. . . Rotary axis

8-16. . . Slide

8-17. . . Left and right nails

8-18. . . Left and right carbon brush

8-19. . . Positive and negative output terminals

8-20. . . Positive and negative output

8-21. . . Front and rear end caps

8-22. . . Bearing beads

8-23. . . Intermediate fixed spacer base

8-24. . . Slide

8-25. . . Copper slip ring

8-26. . . Coil

8-27. . . Insulating paper

8-28. . . Magnetic pole core rotor

8-29. . . Stator core

8-30. . . Bearing

8-31. . . Stator cover

8-32. . . Commutator

8-33. . . Slide

8-34. . . Left and right nails

8-35. . . Left and right carbon brush

8-36. . . Bearing beads

8-37. . . Positive and negative output terminals

8-38. . . Endless ventilator

Figure 1: One-axis two-core (DC motor) and (DC pole core) diagrams.

Figure 2: Internal cross-section of a two-axis rotary shaft and a (magnetic core ‧ iron core) rotor.

Figure 3: Internal perspective view of a two-core (DC motor) and (core) rotor.

Figure 4: One-axis two-core (DC motor) and (pole core) rotor. Side exploded view.

Figure 5: Upright exploded view of a two-core (DC motor) (iron core generator).

Figure 6: Side exploded view of a two-core (DC motor) and (core generator).

Figure 7: One-axis two-core (DC motor) and (pole-core generator) diagrams.

Figure 8: One-axis two-core (DC motor) and (pole-core generator). Side exploded view.

Figure 9: Flat view of a one-axis two-core DC linked motor.

Figure 10: Upright view of a one-axis two-core DC linked motor.

The drawing diagram is represented by a DC motor, and the AC motor manufacturing method is also the same.

1-1. . . Side view of one-axis two-core (DC motor) and (pole-core generator)

1-2. . . Internal sectional view of one-axis two-core (DC motor) and (pole-core generator)

1-3. . . One-axis two-core rear venting diagram

1-4. . . One-axis two-core DC motor) Xing (iron core generator) upright side view

1-5. . . One-axis two-core (DC motor) Xing (core generator) upright internal section view

Claims (1)

The one-axis two-core linkage motor generator is a new type of interlocking motor and generator that combines the existing single-phase or three-phase AC and DC multi-induction motor (motor) and generator. There are two rotors on the inner rotating shaft. The first rotor is the rotor of the motor, and the second rotor is the rotor of the generator. The core is divided into iron core or pole core rotor. The motor starts directly to drive the generator to generate electricity without external components. The AC motor and the alternator are produced in the same form. The motor generator can be laid flat, and can be erected according to the terrain. The power can be made according to the needs of the situation, and the micro motor can be used. The linkage motor generator is very environmentally friendly. It uses the battery to start the motor and then the generator to generate electricity. Then the current is directly transmitted to the battery storage patrol system, and then the current is transmitted to the front motor, which becomes a patrol system. ring. (One-axis two-core motor generator can drive a powerful current generator to generate electricity according to a small current motor, for example, an AC generator after DC motor). The patent range of one-axis two-core linkage motor generator: the former is single-phase or three-phase multi-induction AC or DC motor (motor), the latter is connected with AC or DC generator, and the appearance is integrated into flat and vertical type. The one-axis two-core linkage motor generator can drive a powerful current generator to generate electricity according to a small current motor, for example, an AC generator after the DC motor. (The motor generator can also be turned upside down. The front is the generator and the motor can be customized according to the needs of the working platform). Brief description of the figure: Figure 1: One-axis two-core (DC motor) and (DC. magnetic core) diagram. Figure 2: Internal cross-sectional view of a two-core rotary shaft and a (pole core. iron core) rotor. Figure 3: Internal perspective view of a two-core (DC motor) and (iron core) rotor. Figure 4: One-axis two-core (DC motor) and (pole core) rotor. Side exploded view. Figure 5: Upright explosion view of one-axis two-core (DC motor) Xing (core generator). Figure 6: Side-explosion diagram of one-axis two-core (DC motor) and (core generator). Figure 7: One-axis two-core (DC motor) and (pole-core generator) diagram. Figure 8: Side exploded view of one-axis two-core (DC motor) and (pole-core generator). Figure 9: One-axis two-core DC linkage motor flat type. Figure 10: One-axis two-core DC linkage motor upright type.