CN214590632U - Combined energy consumption power generation system - Google Patents

Abstract

The utility model discloses a combined energy resource consumption power generation system, include: a combined power supply module; the input side of the first electric energy conversion device is connected with the combined power supply module electrode; a bus bar, an input side of which is connected to an output side electrode of the first power conversion device; a second electric energy conversion device connected to an output side electrode of the bus bar; an aluminum energy conversion system connected to the second electrical energy conversion device electrode; the utility model discloses renewable energy power generation, electric wire netting millet electricity and aluminium air battery electricity generation reach the whole consumptions of renewable energy electricity generation through appropriate combination.

Description

Combined energy consumption power generation system

Technical Field

The utility model relates to a new forms of energy utilization technical field, more specifically the utility model relates to a combined energy resource power generation system that absorbs that says so.

Background

At present, renewable energy is mainly wind power generation or solar power generation, and particularly in coastal areas and western areas of China, the wind power generation is main renewable energy; other eastern areas and sunny areas are mainly used as renewable energy sources. The conventional commercial power is high in peak electricity price in daytime, the renewable energy power generation and supply system can be utilized, the power supply at night can be adjusted by using the net valley electricity, and the power supply at daytime can be adjusted by using the aluminum air battery power generation system.

However, at present, the renewable energy power generation and the electricity consumption valley of the commercial power are not connected, so that certain energy waste is caused.

Therefore, how to provide a combined power consumption system capable of solving the above problems is a problem that needs to be solved by those skilled in the art.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a combined energy power generation system that absorbs reaches the whole absorption of renewable energy electricity generation through appropriate combination to renewable energy electricity generation, electric wire netting millet electricity and aluminium air battery electricity generation.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a combined energy-absorbing power generation system, comprising:

a combined power supply module;

the input side of the first electric energy conversion device is connected with the combined power supply module electrode;

a bus bar, an input side of which is connected to an output side electrode of the first power conversion device;

a second electric energy conversion device connected to an output side electrode of the bus bar;

an aluminum energy conversion system in electrode connection with the second electrical energy conversion device.

The beneficial effect who adopts above-mentioned device does: the combined power supply module supplies power, and the provided electric energy enters the aluminum energy conversion system to be converted into aluminum energy after being converted by the first electric energy conversion device, the bus and the second electric energy conversion device.

Preferably, the first electric energy conversion device includes: a first DC/DC converter, a first AC/DC converter, and a second DC/DC converter;

an output side of the first DC/DC converter, an output side of the first AC/DC converter, and an output side of the second DC/DC converter are connected to the input-side electrode of the bus bar.

Preferably, the combined power supply module includes: the system comprises a photovoltaic power generation unit, a wind power generation unit, a commercial power module and an aluminum-air battery power generation unit;

the output side of the photovoltaic power generation unit is connected with the input side electrode of the first DC/DC converter, the output side of the wind power generation unit and the output side of the commercial power module are connected with the input side electrode of the first AC/DC converter, and the output side of the aluminum air battery power generation unit is connected with the input side electrode of the second DC/DC converter.

Preferably, the method further comprises the following steps: and the intelligent control device is connected with the output side of the photovoltaic power generation unit, the output side of the wind power generation unit, the output side of the commercial power module and the output side electrode of the aluminum-air battery power generation unit.

Preferably, the second electric energy conversion device includes: a third DC/DC converter, a first DC/AC converter, a fourth DC/DC converter and a second DC/AC converter;

an input side of the third DC/DC converter, an input side of the first DC/AC converter, an input side of the fourth DC/DC converter, and an input side of the second DC/AC converter are connected to an output side electrode of the bus bar.

Preferably, the aluminum energy conversion system comprises an aluminum energy conversion storage device, an aluminum water transportation device, a high-purity aluminum anode preparation device and a high-purity aluminum anode preparation device which are connected in sequence.

The system converts intermittent and unstable renewable energy and valley electric energy of a power grid into aluminum energy, and the aluminum energy is used for regulating the renewable energy through power generation of the aluminum-air battery to stably and reliably supply power to a load

Preferably, the aluminum energy conversion and storage device is connected to an output side electrode of the third DC/DC converter, the molten aluminum transportation device is connected to an output side electrode of the first DC/AC converter, the high purity aluminum anode preparation device is connected to an output side electrode of the fourth DC/DC converter, and the high purity aluminum anode preparation device is connected to an output side electrode of the second DC/AC converter.

According to the above technical scheme, compare with prior art, the utility model discloses a combined energy consumption power generation system has following beneficial effect:

(1) the power generation of the renewable energy source is regulated by utilizing the valley electricity of the power grid, so that the power generation of the renewable energy source is completely consumed;

(2) the system converts intermittent and unstable renewable energy and valley power of a power grid into aluminum energy, the aluminum energy is used for stably and reliably supplying power to the aluminum energy conversion system through the adjustment of the renewable energy through the power generation of the aluminum air battery, the renewable energy power generation, the valley power of the power grid and the power generation of the aluminum air battery form a combined power supply, the renewable energy power generation is completely consumed and converted into the aluminum energy, and high-purity aluminum is produced to be used as an anode material of the aluminum air battery and also supply market requirements;

(3) the discharging of the aluminum air battery can stabilize the fluctuation and intermittence of the power generation of the renewable power source, so that the power generation of the renewable energy source is completely absorbed;

(4) the renewable energy power generation and the online off-peak power are linked, the renewable energy and the online off-peak power are converted into the aluminum energy, and the aluminum air battery power generation system is used for supplying power to the outside in a distributed mode.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

Fig. 1 is a schematic block diagram of a combined energy consumption power generation system provided by the present invention;

fig. 2 is a top view of an aluminum energy conversion storage device according to an embodiment of the present invention;

fig. 3 is a front view of an aluminum energy conversion storage device according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a high-purity aluminum anode preparation device provided by an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to the attached figure 1, the embodiment of the utility model discloses a combined energy consumption power generation system, include:

a combined power supply module 1;

the input side of the first electric energy conversion device 2 is connected with the electrode of the combined power supply module 1;

a bus bar 3, an input side of the bus bar 3 being connected to an output side electrode of the first power conversion device 2;

a second electric energy conversion device 4, the second electric energy conversion device 4 being connected to the output side electrode of the bus bar 3;

and the aluminum energy conversion system 5 is connected with the second electric energy conversion device 4 in an electrode mode.

In a specific embodiment, the first electric energy conversion device 2 includes: a first DC/DC converter 21, a first AC/DC converter 21, and a second DC/DC converter 23;

the output side of the first DC/DC converter 21, the output side of the first AC/DC converter 21, and the output side of the second DC/DC converter 23 are connected to the input-side electrode of the bus bar 3.

In a particular embodiment, the combined power supply module 1 comprises: the system comprises a photovoltaic power generation unit 11, a wind power generation unit 12, a commercial power module 13 and an aluminum air battery power generation unit 14;

the output side of the photovoltaic power generation unit 11 is connected to the input side electrode of the first DC/DC converter 21, the output side of the wind power generation unit 12 and the output side of the utility power module 13 are connected to the input side electrode of the first AC/DC converter 21, and the output side of the aluminum air battery power generation unit 14 is connected to the input side electrode of the second DC/DC converter 23.

In a specific embodiment, the method further comprises the following steps: and the intelligent control device 6 is connected with the output side of the photovoltaic power generation unit 11, the output side of the wind power generation unit 12, the output side of the commercial power module 13 and the output side electrode of the aluminum-air battery power generation unit 14 through the intelligent control device 6.

Specifically, the intelligent control device 6 has 10 monitoring points in total, and monitors the output of the wind power generation unit 12, the output of the photovoltaic power generation unit 11, the valley power output of the commercial power module 13, the output of the aluminum air battery power generation unit 14, the input of the aluminum energy conversion and storage device 51, the input of the high-purity aluminum anode preparation device 53, the input of the aluminum water transportation device 52, the input of the high-purity aluminum anode preparation device 54 and the input of the electric energy of the bus bar 3.

The monitoring data of the intelligent control device 6 mainly comprises power input and output, voltage and current, the intelligent control device 6 adopts intelligent control, and the monitoring principle is to always keep balance between the input power and the output power of the DC bus and stabilize the output voltage. When the output of the regenerative power supply is unstable, the voltage and the current fluctuate, and the output current of the aluminum-air battery power generation system makes up for the insufficient part and stabilizes the fluctuation of the regenerative power supply.

Wind power and photovoltaic power are started all year round, the commercial power is turned on during the valley power and turned off during the peak power, and the aluminum-air battery power generation unit 14 supplies power and sends an instruction to control the on-off state according to the requirement through the intelligent control device 6. The low-temperature aluminum electrolysis needs to be started all year round, the aluminum energy lifting system needs to be started all year round, the molten aluminum transportation system needs to be started all year round, and the high-purity aluminum plate preparation system needs to be started all year round. The DC bus power input is equal to the output, balance is kept, voltage is stable, and current is stable. The produced high-purity aluminum is used for aluminum air battery distributed power generation and other functional materials besides the aluminum air battery anode material.

In a specific embodiment, the second electric energy conversion device 4 includes: a third DC/DC converter 41, a first DC/AC converter 42, a fourth DC/DC converter 43, and a second DC/AC converter 44;

the input side of the third DC/DC converter 41, the input side of the first DC/AC converter 42, the input side of the fourth DC/DC converter 43, and the input side of the second DC/AC converter 44 are connected to the output-side electrode of the bus bar 3.

In one embodiment, the aluminum energy conversion system 5 comprises an aluminum energy conversion storage device 51, an aluminum water transportation device 52, a high purity aluminum anode preparation device 53 and a high purity aluminum anode preparation device 54, which are connected in sequence.

In a specific embodiment, an aluminum energy conversion storage device 51 is connected to the output side electrode of the third DC/DC converter 41, an aluminum water transport device 52 is connected to the output side electrode of the first DC/AC converter 42, a high purity aluminum anode preparation device 53 is connected to the output side electrode of the fourth DC/DC converter 43, and a high purity aluminum anode preparation device 54 is connected to the output side electrode of the second DC/AC converter 44.

Specifically, referring to fig. 2-3, the aluminum energy conversion and storage device 51 may be a low-temperature aluminum electrolysis cell, which includes a cathode 511, an anode 512, an aluminum collection chamber 513, an insulating layer 514, and outer shells 515 and 516;

the cathode 511 and the anode 512 are arranged in the electrolytic chamber, and the aluminum collecting chamber 513 collects aluminum generated in the electrolytic chamber, so that the aluminum and oxygen are separated. Oxygen is discharged to an oxygen pipeline system through an oxygen outlet arranged on an electrolytic chamber cover, and the attached figure 3 shows a partition-free aluminum electrolytic cell for collecting aluminum by electrolyte circulation. In the electrolytic cell, electrolyte circularly flows between the electrolytic chamber and the aluminum collecting chamber, aluminum separated out from the cathode enters the aluminum collecting chamber from the electrolytic chamber, the cathode of the electrolytic cell adopts a frame structure, the anode is inserted into the frame, the effective working area of electrolysis is increased, the cover of the electrolytic chamber is fully sealed, and feeding, aluminum discharging and slag discharging are carried out in the aluminum collecting chamber. The structure has better separation of aluminum and oxygen and high current efficiency; the bottom area of the unit groove is higher in aluminum production; without cathode chamber exhaust, the electric energy consumption is low.

Specifically, the electrolyte is a heavy electrolyte and consists of 25-30% AlF₃，16％～20％CaF₂，15％～20％MgF₂，25％～30％BaF₂10-15% of KF, and 30% of AlF₃，20％CaF₂，15％MgF₂，25％BaF₂And 10% KF, in which case higher electrolysis efficiencies can be achieved.

Specifically, referring to fig. 4, the high purity aluminum anode manufacturing apparatus 54 may include: a steel crucible 531, a first heat-insulating layer 532, a heating coil 533, a second heat-insulating layer 534, a condenser 535, a housing 536 and a lifting lug 537;

a second heat-insulating layer 534, a heating coil 535, a first heat-insulating layer 532 and a shell 537 are sequentially sleeved outside the steel crucible 531, the steel crucible 531 can be lifted by a lifting lug 538 and separated from the second heat-insulating layer 534, the upper end of the steel crucible 531 is provided with an opening, and a heat-insulating cover 539 detachably connected with the opening is arranged at the opening; a temperature thermocouple 5381 and a feeding pipe 5382 are arranged on the heat preservation cover 538, a discharge port 5383 is arranged on one side of the steel crucible 531, and the temperature thermocouple 5381 is used for measuring the temperature of the aluminum liquid in the steel crucible 531 and purifying the aluminum.

Specifically, the above converters and modules are all common knowledge in the art.

The utility model discloses specific working process as follows:

(1) the intelligent control device is started, detects the power input and output data, the voltage data and the current data of the bus 3, and sends out an instruction in time according to the monitoring data to discharge the power generation unit of the aluminum-air battery, so as to keep the power input and the demand balance of the bus, the voltage stability and the current stability; when the current of the regenerative power supply fluctuates, the aluminum air battery power generation unit starts discharging to inhibit the fluctuation of the current of the regenerative power supply.

(2) The discharge product of the power generation unit of the aluminum-air battery is used as a charging medium, an aluminum energy conversion and storage device is continuously added to be used as a low-temperature aluminum electrolysis raw material, oxygen is discharged, liquid aluminum is produced, and energy storage of renewable energy sources is realized. Because the current of the renewable energy source is unstable, the power generation system of the aluminum-air battery continuously discharges according to the instruction, and the voltage and the current of the renewable energy source are balanced to supply the aluminum energy conversion memory to work.

The aluminum-air battery power generation unit comprises the following working steps:

1. continuously adding a charging medium into the aluminum energy conversion storage device;

2. the working temperature is 670-.

3. Liquid aluminum is transported to the high-purity aluminum anode preparation device through the aluminum water transportation device, and under the action of cooling water and a high-frequency magnetic field, aluminum continuously grows at the bottom of the equipment, so that the purity is improved, aluminum containing can be further improved, and high-purity aluminum and impurity-containing aluminum are periodically taken out.

4. The high-purity aluminum can be rolled, spun and cut into an aluminum-air battery anode plate, an aluminum-air battery monomer module is assembled, and the whole electrode module is switched on the aluminum-air battery power generation system. And the aluminum air battery is charged.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other. The device disclosed by the embodiment corresponds to the method disclosed by the embodiment, so that the description is simple, and the relevant points can be referred to the method part for description.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (7)

1. A combined energy consumption power generation system, comprising:

a combined power supply module (1);

a first electric energy conversion device (2), wherein the input side of the first electric energy conversion device (2) is connected with the electrode of the combined power supply module (1);

a bus bar (3), wherein the input side of the bus bar (3) is connected with the output side electrode of the first electric energy conversion device (2);

a second electric energy conversion device (4), wherein the second electric energy conversion device (4) is connected with an output side electrode of the bus bar (3);

the aluminum energy conversion system (5), the aluminum energy conversion system (5) is connected with the second electric energy conversion device (4) in an electrode mode.

2. A combined energy-consuming power generation system according to claim 1, wherein the first energy conversion means (2) comprises: a first DC/DC converter (21), a first AC/DC converter (22), and a second DC/DC converter (23);

the output side of the first DC/DC converter (21), the output side of the first AC/DC converter (22), and the output side of the second DC/DC converter (23) are connected to the input-side electrode of the bus bar (3).

3. A combined energy-consuming power generation system according to claim 2, wherein the combined power supply module (1) comprises: the system comprises a photovoltaic power generation unit (11), a wind power generation unit (12), a commercial power module (13) and an aluminum-air battery power generation unit (14);

the output side of the photovoltaic power generation unit (11) is connected with the input side electrode of the first DC/DC converter (21), the output side of the wind power generation unit (12) and the output side of the commercial power module (13) are connected with the input side electrode of the first AC/DC converter (22), and the output side of the aluminum air battery power generation unit (14) is connected with the input side electrode of the second DC/DC converter (23).

4. A combined energy-efficient power generation system according to claim 3, further comprising: the intelligent control device (6) is connected with the output side of the photovoltaic power generation unit (11), the output side of the wind power generation unit (12), the output side of the commercial power module (13) and the output side electrode of the aluminum-air battery power generation unit (14).

5. A combined energy-consuming power generation system according to claim 1, wherein the second energy conversion means (4) comprises: a third DC/DC converter (41), a first DC/AC converter (42), a fourth DC/DC converter (43), and a second DC/AC converter (44);

an input side of the third DC/DC converter (41), an input side of the first DC/AC converter (42), an input side of the fourth DC/DC converter (43), and an input side of the second DC/AC converter (44) are connected to an output side electrode of the bus bar (3).

6. The combined energy consumption power generation system according to claim 5, wherein the aluminum energy conversion system (5) comprises an aluminum energy conversion storage device (51), an aluminum water transportation device (52), a high-purity aluminum anode preparation device (53) and a high-purity aluminum anode preparation device (54) which are connected in sequence.

7. A combined energy-consuming electricity generation system according to claim 6, wherein the aluminium energy conversion and storage means (51) is connected to the output-side electrode of the third DC/DC converter (41), the aluminium water transport means (52) is connected to the output-side electrode of the first DC/AC converter (42), the high-purity aluminium anode preparation means (53) is connected to the output-side electrode of the fourth DC/DC converter (43), and the high-purity aluminium anode preparation means (54) is connected to the output-side electrode of the second DC/AC converter (44).

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