CN214506906U - Magneto-electric air energy generator set - Google Patents

Abstract

The utility model discloses a magnetic-electric air energy generator set, which comprises a plurality of generator devices, wherein one generator device is used as a master machine, the other generator devices are used as submachine, and each submachine is respectively and electrically connected with the master machine; the generator device comprises a power module, a power generation module and a high-voltage control cabinet; the power generation module comprises a starter, an air compressor, an energy storage box, a speed control machine and a generator; the rotating shaft of the starter, the rotating shaft of the energy storage box and the rotating shaft of the speed control machine are connected together; a rotating shaft of the speed control machine is connected with a main shaft of the generator; an air outlet of the air compressor is connected into the energy storage box; the starter and the speed controller are respectively electrically connected with the power supply module; the high-voltage control cabinet is electrically connected with the generator; the high-voltage control cabinet of the master machine is also electrically connected with the air compressors of the master machine and the submachine respectively; and the high-voltage control cabinet of the submachine is electrically connected with the booster station. The utility model discloses can effectively combine magnetoelectric power and high-speed air compression power together, utilize the electricity that the mother's machine sent to supply power for each submachine simultaneously.

Description

Magneto-electric air energy generator set

Technical Field

The utility model belongs to the technical field of generating set, concretely relates to magnetism electric air can generating set.

Background

In order to reduce environmental pollution, wind power generation, magnetomotive power generation and hydroelectric power generation are advocated. However, wind power generation and hydroelectric power generation rely on external energy power as a basis, and the production scale is limited by the scale of the energy power, seasons and climate, so that the power generation can not be realized at any time and any place. The magnetic power generation is not limited by the environment, so that the magnetic power generation is easier to realize compared with wind power generation and hydraulic power generation. However, the generated electricity of the existing magnetic power generation only reaches 320 volts and cannot reach 400 to 600 volts, so the requirements of certain specific scenes cannot be met, and in addition, the generation cost of the magnetic power is higher.

Therefore, there is a need to develop a magneto-electric air energy generator set.

Disclosure of Invention

The utility model aims at providing a magnetism electronic air can generating set can effectively combine magnetoelectric power and high-speed air compression power together, makes the voltage of the electricity that the generator sent can reach 400 volts-600 volts, can utilize the electricity that the mother machine sent to supply power for each submachine simultaneously to ensure that each submachine can normally generate electricity.

The utility model discloses a magneto-electric air energy generator set, including a plurality of generator devices, wherein one generator device is used as the mother machine, the other generator devices are used as the submachine, each submachine is respectively connected with the mother machine, and the mother machine supplies power for each submachine;

the generator device comprises a power module, a power generation module and a high-voltage control cabinet;

the power generation module comprises a starter, an air compressor, an energy storage box, a speed control machine and a generator; the energy storage box comprises a shell, a stator component, a rotor component, a wind impeller and a rotating shaft; the rotating shaft is arranged on the shell through a bearing; the stator assembly, the rotor assembly and the wind impeller are all positioned in the shell; the stator assembly is fixedly arranged on the shell, the rotor assembly is fixedly arranged on the rotating shaft, and the stator assembly and the rotor assembly are arranged oppositely; the stator assembly comprises a first mounting plate, and a plurality of first magnets are arranged on the first mounting plate along the circumference; the rotor assembly comprises a second mounting plate, and a plurality of second magnets are arranged on the second mounting plate along the circumference; the polarities of the first magnet and the second magnet are opposite; the wind impeller is fixedly arranged on the rotating shaft; an air inlet is formed in the position, corresponding to the air impeller, of the shell, and an air outlet is formed in the shell; the rotating shaft of the starter, the rotating shaft of the energy storage box and the rotating shaft of the speed control machine are connected together; a rotating shaft of the speed control machine is connected with a main shaft of the generator; an air outlet of the air compressor is connected into the energy storage box; the starter and the speed controller are respectively electrically connected with the power supply module; the high-voltage control cabinet is electrically connected with the generator;

the high-voltage control cabinet of the master machine is also electrically connected with the air compressors of the master machine and the submachine respectively;

and the high-voltage control cabinet of the submachine is electrically connected with the booster station.

Optionally, one end of the rotating shaft of the starter is connected with the rotating shaft of the energy storage box, the other end of the rotating shaft of the starter is connected with one end of the rotating shaft of the speed controller, and the other end of the rotating shaft of the speed controller is connected with the main shaft of the generator.

Optionally, the rotating shaft of the starter is connected with one end of the rotating shaft of the energy storage box, the other end of the rotating shaft of the energy storage box is connected with one end of the rotating shaft of the speed controller, and the other end of the rotating shaft of the speed controller is connected with the main shaft of the generator.

Optionally, the power module includes an ac-to-dc conversion module, a first storage battery and a second storage battery, the ac-to-dc conversion module is electrically connected to the first storage battery and the second storage battery, the ac-to-dc conversion module is configured to convert an incoming 220V ac power into a 72V dc power and then charge the first storage battery and the second storage battery, the first storage battery is electrically connected to the starter, the first storage battery supplies power to the starter, the second storage battery is electrically connected to the speed control machine, and the second storage battery supplies power to the speed control machine.

Optionally, the main unit further comprises a low-voltage transformer, and the low-voltage transformer is electrically connected with a high-voltage control cabinet of the main unit;

the low-voltage transformer is also electrically connected with the AC-DC conversion module of each submachine respectively; the power is supplied to the master machine and the first storage battery and the second storage battery of each subsidiary machine through the electricity generated by the master machine.

Optionally, the main unit further includes a power switching module, an input end of the power switching module is electrically connected to the commercial power and the low-voltage transformer of the main unit, and an output end of the power switching module is electrically connected to the ac-to-dc conversion module of the main unit.

Optionally, each stator assembly, each mover assembly and each wind impeller are coaxially arranged.

Optionally, two stator assemblies are respectively and fixedly mounted on the housing;

the two rotor assemblies are respectively arranged on the rotating shaft, and the two rotor assemblies and the two stator assemblies are arranged in a one-to-one correspondence manner;

the number of the wind impellers is two, and the two wind impellers are arranged between the two rotor assemblies.

Optionally, six first magnets are uniformly distributed on the first mounting plate along the circumference; and three second magnets are uniformly distributed on the second mounting plate along the circumference.

Optionally, a silencer is arranged on the air outlet.

The beneficial effects of the utility model reside in that:

(1) the electricity generated by the master machine is used for supplying power to all the submachine so as to ensure that all the submachine can generate electricity normally, and the electricity generated by the submachine is boosted by the booster station and then is merged into a power grid;

(2) when the rotor assembly rotates, alternating magnetic field waves are generated between the N pole and the S pole, and the strength force (namely, magnetoelectric power and magnetic suspension force) of the alternating magnetic field waves is transmitted to the generator through the rotating shaft to serve as load power. Simultaneously, through the air compressor to the air after the casing input compression (high-speed air compression power promptly), promote the rotation of impeller through high-speed air compression power, transmit the power to the generator as load power. The load power acted on the generator by the rotor assembly and the stator assembly is about 20%. The load power that the impeller acted on the generator is about 80% to combine magnetoelectric power, magnetic suspension power, high-speed air compression power effectively together. The utility model discloses can effectively combine magnetoelectric power, magnetic suspension power, high-speed air compression power together, make the voltage of the electricity that the generator sent can reach 400 volts-600 volts, and the cost of generating electricity is lower.

Drawings

Fig. 1 is one of the schematic structural diagrams of the present embodiment (including utility power and a booster station);

fig. 2 is a second schematic structural diagram (including the utility power and the booster station) of the present embodiment;

FIG. 3 is a schematic structural diagram of an energy storage tank according to the present embodiment;

FIG. 4 is a second schematic structural diagram of the energy storage box of the present embodiment;

FIG. 5 is a schematic view of the construction of the stator assembly of the present embodiment;

FIG. 6 is a schematic structural view of the moving member assembly of the present embodiment;

in the figure: 1. the air conditioner comprises a shell, 2, a stator assembly, 3, a rotor assembly, 4, a fan blade wheel, 5, an air inlet, 6, a first magnet, 7, a rotating shaft, 8, a second magnet, 9, an air outlet, 10, a silencer, 11, a first mounting plate, 12, a second mounting plate, 13, a low-voltage transformer, 14, a mains supply, 15, a power supply switching module, 16, an alternating current-to-direct current (AC-to-DC) module, 17, a first storage battery, 18, a second storage battery, 19, an air compressor, 20, an energy storage box, 21, a starter, 22, a speed control machine, 23, a generator, 24, a high-voltage control cabinet, 25, a booster station, 26, a mother machine, 27 and a sub machine.

Detailed Description

The present embodiment will be described in detail below with reference to the accompanying drawings.

As shown in fig. 1 and fig. 2, in the present embodiment, a magneto-electric air energy generator set includes a plurality of generator devices, one of the generator devices is used as a master machine 26, the other generator devices are used as slave machines 27, each slave machine 27 is electrically connected to the master machine 26, and power is supplied to each slave machine 27 by the electricity generated by the master machine 26; the slave unit 27 can normally generate power.

As shown in fig. 1 and 2, in the present embodiment, the power generation module of the master unit 26 is the same as the power generation module of the slave unit 27, and the power generation module of the master unit 26 is explained below as an example:

as shown in fig. 1 and 2, in the present embodiment, the generator device includes a power module, a power generation module, and a high voltage control cabinet 24. The power generation module comprises a starter 21, an air compressor 19, an energy storage tank 20, a speed controller 22 and a generator 23; the energy storage box 20 comprises a shell 1, a stator assembly 2, a rotor assembly 3, a wind impeller 4 and a rotating shaft 7; the rotating shaft 7 is arranged on the shell 1 through a bearing; the stator assembly 2, the rotor assembly 3 and the wind impeller 4 are all positioned in the shell 1; stator module 2 fixed mounting is on casing 1, active cell subassembly 3 fixed mounting is on axis of rotation 7, and stator module 2 sets up with active cell subassembly 3 relatively. The stator assembly 2 includes a first mounting plate 11, and a plurality of first magnets 6 are circumferentially disposed on the first mounting plate 11. The mover assembly 3 includes a second mounting plate 12, and a plurality of second magnets 8 are circumferentially provided on the second mounting plate 12. The polarities of the first magnet 6 and the second magnet 8 are opposite; the wind impeller 4 is fixedly mounted on the rotating shaft 7. An air inlet 5 is arranged at the position, corresponding to the air impeller 4, on the shell 1, and an air outlet 9 is also arranged on the shell 1. The rotating shaft of the starter 21, the rotating shaft 7 of the energy storage box 20 and the rotating shaft of the speed controller 22 are connected together. A rotating shaft of the speed control machine 22 is connected with a main shaft of a generator 23; the air outlet 9 of the air compressor 19 is connected into the energy storage box 20, and the air compressor 19 outputs compressed air to drive the wind impeller 4 to rotate. The starter 21 and the speed controller 22 are respectively electrically connected with the power supply module; the high voltage control cabinet 24 is electrically connected with the generator 23.

As shown in fig. 1 and 2, in the present embodiment, the high-voltage control cabinet 24 of the master unit 26 is also electrically connected to the air compressors 19 of the master unit 26 and the slave units 27, respectively. The high-voltage control cabinet 24 of the parent machine 26 is used for converting the electricity output by the generator 23 of the parent machine 26 into 380V alternating current to supply power for the air compressor 19 of the parent machine 26. The high-voltage control cabinet 24 of the master unit 26 is also electrically connected to the air compressors 19 of the respective slave units 27, and the air compressors 19 of the respective slave units 27 are supplied with power by the power generated by the master unit 26.

As shown in fig. 1 and fig. 2, in the present embodiment, the high voltage control cabinet 24 of the slave unit 27 is electrically connected to the booster station 25, and the power generated by the slave unit 27 is boosted by the booster station 25 and then directly input to the power grid.

As shown in fig. 3 and 4, in the present embodiment, one end of the rotating shaft of the starter 21 is connected to the rotating shaft 7 of the energy storage box 20, the other end of the rotating shaft of the starter 21 is connected to one end of the rotating shaft of the speed controller 22, and the other end of the rotating shaft of the speed controller 22 is connected to the main shaft of the generator 23.

As shown in fig. 3 and 4, in the present embodiment, the rotating shaft of the starter 21 is connected to one end of the rotating shaft 7 of the energy storage box 20, the other end of the rotating shaft 7 of the energy storage box 20 is connected to one end of the rotating shaft of the speed controller 22, and the other end of the rotating shaft of the speed controller 22 is connected to the main shaft of the generator 23.

As shown in fig. 1 and fig. 2, in the present embodiment, the power module includes an ac-to-dc module 16, a first battery 17 and a second battery 18, the ac-to-dc module 16 is electrically connected to the first battery 17 and the second battery 18, respectively, the first battery 17 is electrically connected to a starter 21, and the second battery 18 is electrically connected to a speed controller 22. The ac-dc conversion module 16 is configured to convert the incoming 220V ac power into 72V dc power and then charge the first battery 17 and the second battery 18. The first battery 17 is used to power the starter 21 of the parent machine 26. The second battery 18 is used to power the speed controller 22. The power is supplied by the storage battery, so that the stability of power supply can be ensured.

As shown in fig. 1 and fig. 1, in the present embodiment, the main unit 26 further includes a low voltage transformer 13, and the low voltage transformer 13 is electrically connected to the high voltage control cabinet 24 of the main unit 26. The low voltage transformer 13 is also electrically connected to the ac-to-dc modules 16 of the respective slave machines 27. The low voltage transformer 13 is used for converting 380V ac output by the high voltage control cabinet 24 of the main unit 26 into 220V ac, and inputting the 220V ac to each ac-dc conversion module 16.

As shown in fig. 1 and fig. 2, in this embodiment, the main unit 26 further includes a power switching module 15, an input end of the power switching module 15 is electrically connected to the commercial power 14 and the low-voltage transformer 13 of the main unit 26, respectively, and an output end of the power switching module 15 is electrically connected to the ac-to-dc conversion module 16 of the main unit 26. At the starting stage of the master unit 26, the mains supply 14 supplies power to the master unit 26, after the master unit 26 is started and normally generates power, the power generated by the generator 23 of the master unit 26 is stabilized by the high-voltage control cabinet 24 of the master unit 26 and then outputs 380V alternating current, then the 380V alternating current is transformed into 220V alternating current by the low-voltage transformer 13 of the master unit 26 to supply power to the master unit 26, and then the master unit 26 supplies power to each slave unit 27. Because the cost of generating electricity with the mother machine is lower than the cost of the commercial power 14.

In this embodiment, the air compressor 19 is used to provide high-speed wind power to the energy storage tank 20, and transmit the wind power to the wind impeller 4 mounted on the rotating shaft 7, and the wind impeller 4 converts the wind power into electric energy, and the wind power is a main power and accounts for 80% of the power of the unit.

In this embodiment, the energy storage box 20 fully utilizes air compression energy storage to transmit the power of wind power and magnetic field to the generator 23, and the stator assembly 2, the rotor assembly and the wind impeller 4 are installed in the energy storage box 20. The stator assembly 2 is provided with an N pole, the rotor assembly is provided with an S pole, when the starter 21 is started, the N pole and the S pole are alternated, an alternating power supply and an alternating magnetic field waveform (namely, the intensity force of a magnetic field wave) are generated, the intensity force of the magnetic field wave is transmitted to the generator 23 to serve as load power, the power is more than 20%, and the power of the wind impeller 4 is more than 80% (adjustable).

In this embodiment, the starter 21 is responsible for starting the generator 23.

In the present embodiment, the speed controller 22 is used for controlling the rotation speed of the generator 23 to ensure that the rotation speed of the generator 23 can fluctuate within ± 5% of the set value.

In this embodiment, the generator 23 generates electricity based on the magnetic electricity and the power source provided by the compressed air.

In this embodiment, the number of the stator assemblies 2 is one, or two, or three, or four, or more than four. The number of the mover assemblies 3 is the same as the number of the stator assemblies 2. The number of the wind impeller 4 is one, or two, or three, or four, or more than four. And each stator module 2, each rotor module 3 and each wind impeller 4 are coaxially arranged.

As shown in fig. 3 and 4, the following describes the present embodiment in detail, taking two stator assemblies 2, two mover assemblies 3, and two wind impellers 4 as examples:

in this embodiment, two stator module 2 subassemblies are respectively fixed on casing 1 through the bolt, and mover assembly 3 is two, and two mover assemblies 3 are all installed on axis of rotation 7, and two mover assemblies 3 and two stator module 2 one-to-one settings. Two wind impellers 4 are arranged between the two mover assemblies 3.

As shown in fig. 5 and 6, in the present embodiment, six first magnets 6 are uniformly distributed on the first mounting plate 11 along the circumference; three second magnets 8 are uniformly distributed on the second mounting plate 12 along the circumference. If the first magnet 6 is N-pole, the second magnet 8 is S-pole.

In this embodiment, the first mounting plate 11 and the second mounting plate 12 are made of aluminum alloy and made into disks.

In this embodiment, the energy storage box 20 is used as a power source of the generator 23, so that the voltage of the electricity generated by the generator 23 can reach 400 v-600 v.

In this embodiment, in order to reduce noise, a muffler 10 is provided at the outlet 9 of the energy storage box 20. The muffler 10 is used to reduce noise when the energy storage tank 20 discharges air, and the noise can be controlled to be 55 minutes or less.

In this embodiment, the operation principle of the master 26 is as follows:

at the time of starting, the rotation shaft 7 is started to rotate by the starter 21, and when the rotation shaft 7 rotates, the two mover assemblies 3 and the two wind impeller 4 can rotate together with the rotation shaft 7. When the rotor assembly 3 rotates, alternating magnetic field waves are generated between the N pole and the S pole, and the intensity force (i.e., magnetoelectric power and magnetic levitation force) of the alternating magnetic field waves is transmitted to the generator 23 through the rotating shaft 7 as load power. Simultaneously, send into the air after the compression (high speed air compression power promptly) in to casing 1 through air compressor 19, promote the rotation of impeller 4 through high speed air compression power, convey the generator 23 as load power to power. The load power of the mover assembly 3 and the stator assembly 2 acting on the generator 23 is about 20%. The load of the wind impeller 4 on the generator 23 is about 80%. The electricity generated by the generator 23 is input to the high-voltage control cabinet 24, and the voltage output by the generator 23 is regulated through the high-voltage control cabinet 24 so as to ensure the stability and safety of power supply.

In the present embodiment, the power generation principle of the slave unit 27 is the same as that of the master unit 26.

In this embodiment, the power generated by the master unit 26 is used to supply power to each slave unit 27, so as to ensure the normal operation of each slave unit 27, and one master unit 26 can ensure the normal operation of 50 slave units 27. The electricity generated by each sub-machine 27 is finally debugged and matched with the power supply of the network through the booster station 25.

Claims (10)

1. The utility model provides a magnetism electric air can generating set which characterized in that: the power generation system comprises a plurality of power generator devices, wherein one power generator device is used as a master machine (26), the other power generator devices are used as slave machines (27), each slave machine (27) is electrically connected with the master machine (26), and the master machine (26) supplies power to each slave machine (27);

the generator device comprises a power supply module, a power generation module and a high-voltage control cabinet (24);

the power generation module comprises a starter (21), an air compressor (19), an energy storage box (20), a speed control machine (22) and a generator (23); the energy storage box (20) comprises a shell (1), a stator assembly (2), a rotor assembly (3), a wind impeller (4) and a rotating shaft (7); the rotating shaft (7) is arranged on the shell (1) through a bearing; the stator assembly (2), the rotor assembly (3) and the wind impeller (4) are all positioned in the shell (1); the stator assembly (2) is fixedly arranged on the shell (1), the rotor assembly (3) is fixedly arranged on the rotating shaft (7), and the stator assembly (2) and the rotor assembly (3) are arranged oppositely; the stator assembly (2) comprises a first mounting plate (11), and a plurality of first magnets (6) are arranged on the first mounting plate (11) along the circumference; the rotor assembly (3) comprises a second mounting plate (12), and a plurality of second magnets (8) are arranged on the second mounting plate (12) along the circumference; the polarities of the first magnet (6) and the second magnet (8) are opposite; the wind impeller (4) is fixedly arranged on the rotating shaft (7); an air inlet (5) is formed in the position, corresponding to the air impeller (4), of the shell (1), and an air outlet (9) is formed in the shell (1); the rotating shaft of the starter (21), the rotating shaft (7) of the energy storage box (20) and the rotating shaft of the speed controller (22) are connected together; a rotating shaft of the speed control machine (22) is connected with a main shaft of a generator (23); an air outlet (9) of the air compressor (19) is connected into the energy storage box (20); the starter (21) and the speed controller (22) are respectively electrically connected with the power supply module; the high-voltage control cabinet (24) is electrically connected with the generator (23);

the high-voltage control cabinet (24) of the master machine (26) is also electrically connected with the master machine (26) and the air compressors (19) of all the slave machines (27) respectively;

the high-voltage control cabinet (24) of the sub machine (27) is electrically connected with the booster station (25).

2. A magneto-electric air energy generator set according to claim 1, wherein: one end of a rotating shaft of the starter (21) is connected with the rotating shaft (7) of the energy storage box (20), the other end of the rotating shaft of the starter (21) is connected with one end of a rotating shaft of the speed control machine (22), and the other end of the rotating shaft of the speed control machine (22) is connected with a main shaft of the generator (23).

3. A magneto-electric air energy generator set according to claim 1, wherein: the rotating shaft of the starter (21) is connected with one end of the rotating shaft (7) of the energy storage box (20), the other end of the rotating shaft (7) of the energy storage box (20) is connected with one end of the rotating shaft of the speed control machine (22), and the other end of the rotating shaft of the speed control machine (22) is connected with a main shaft of the generator (23).

4. A magneto-electric air energy generator set according to any one of claims 1 to 3, wherein: the power module comprises an AC-DC module (16), a first storage battery (17) and a second storage battery (18), the AC-DC module (16) is electrically connected with the first storage battery (17) and the second storage battery (18) respectively, the first storage battery (17) is electrically connected with a starter (21), and the second storage battery (18) is electrically connected with a speed control machine (22).

5. A magneto-electric air energy generator set according to claim 4, wherein: the main machine (26) further comprises a low-voltage transformer (13), and the low-voltage transformer (13) is electrically connected with a high-voltage control cabinet (24) of the main machine (26);

the low-voltage transformer (13) is also electrically connected with the AC-DC conversion module (16) of each sub machine (27).

6. A magneto-electric air energy generator set according to claim 5, wherein: the main unit (26) further comprises a power supply switching module (15), the input end of the power supply switching module (15) is electrically connected with the mains supply (14) and the low-voltage transformer (13) of the main unit (26) respectively, and the output end of the power supply switching module (15) is electrically connected with the alternating current-to-direct current module (16) of the main unit (26).

7. A magneto-electric air energy generator set according to claim 1 or 2 or 3 or 5 or 6, wherein: each stator component (2), each rotor component (3) and each wind impeller (4) are coaxially arranged.

8. A magneto-electric air energy generator set according to claim 7, wherein: the number of the stator assemblies (2) is two, and the two stator assemblies are respectively and fixedly arranged on the shell (1);

the two rotor assemblies (3) are respectively arranged on the rotating shaft (7), and the two rotor assemblies (3) and the two stator assemblies (2) are arranged in a one-to-one correspondence manner;

the number of the wind impellers (4) is two, and the two wind impellers (4) are arranged between the two rotor assemblies (3).

9. A magneto-electric air energy generator set according to claim 1, 2, 3, 5, 6 or 8, wherein: six first magnets (6) are uniformly distributed on the first mounting plate (11) along the circumference; and three second magnets (8) are uniformly distributed on the second mounting plate (12) along the circumference.

10. A magneto-electric air energy generator set according to claim 9, wherein: and a silencer (10) is arranged on the air outlet.

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