CN113488690A

CN113488690A - Metal fuel oxygen power generation and reduction device

Info

Publication number: CN113488690A
Application number: CN202110868298.8A
Authority: CN
Inventors: 徐杨
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-07-30
Filing date: 2021-07-30
Publication date: 2021-10-08

Abstract

A metal fuel oxygen power generation device is characterized in that an electrolyte box is arranged in a generator shell, and the electrolyte box is connected with a battery module through a circulating water pump and an upper liquid pipe; the electrolyte box is provided with a stirrer; the electrolyte box is connected with the metal powder adding port through a metal powder adding pipe; one side of the electrolyte box is connected with an electrolyte adding port arranged on the shell of the generator through an electrolyte adding pipe; the lower part of the electrolyte tank is provided with a liquid discharging port; the battery module is connected with an oxygen source through an oxygen regulating valve and an oxygen pipeline, and a power box and an auxiliary power supply are arranged on the shell of the generator; the liquid discharging port is connected with the reduction system through a power generation system liquid discharging pipe, a reduction system water pump, a reduction system four-way valve and a reduction system liquid feeding pipe; the discharge current is continuous and stable, no noise, no emission, zero pollution, simple operation, large output power, reduced self consumption of the metal-oxygen battery, safety and reliability, and can be recycled.

Description

Metal fuel oxygen power generation and reduction device

Technical Field

The invention belongs to the technical field of fuel cells, and particularly relates to a metal fuel oxygen power generation and reduction device. The metal fuel is used as fuel, oxygen is used as oxidant, and then the metal fuel is used for chemical reaction under the action of catalyst, so that the chemical energy is converted into electric energy.

Background

During the past several years, it was recognized that global energy sources are reducing interest in identifying energy solutions that are electrically efficient, while also minimizing environmental impacts stemming from the use of fossil fuels through the release of harmful exhaust gases. Fuel cells provide such a promising means of power generation with an electrical efficiency of at least 50%. When compared to thermal engines, fuel cells do not emit harmful polluting gases, making them more environmentally friendly. A fuel cell includes an anode, a cathode, and an electrolyte that enables ionic charge to flow between the anode and the cathode while electrons are forced to adopt an external electrical pathway to provide power.

Fuel cells are generally classified according to the type of electrolyte used, for example, Solid Oxide Fuel Cells (SOFC), Alkaline Fuel Cells (AFC), Phosphoric Acid Fuel Cells (PAFC), Proton Exchange Membrane Fuel Cells (PEMFC), and Molten Carbonate Fuel Cells (MCFC), or according to the operating temperature thereof. For example, SOFCs have operating temperatures of about 700 ℃ to 1000 ℃. Temperature variations may occur on the fuel cell and may have a negative impact on fuel cell service life while also having positive effects such as improving fuel cell efficiency. Therefore, fuel cell design is highly dependent on a compromise of competing factors to achieve good fuel cell efficiency and service life.

Fuel cells convert chemical energy from a fuel (i.e., a reactant) into electricity through a chemical reaction with oxygen or other oxidizing agents (i.e., oxidants). Hydrogen is the most common fuel but hydrocarbons such as natural gas can also be used as well as methanol and the like. However, current fuel cells also have a number of disadvantages, such as:

1. the requirements on safety performance are high.

2. The sealing requirements are high.

3. The cost is high.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention aims to provide a metal fuel oxygen power generation and reduction device, the device has the advantages that the raw materials can be recycled, the metal raw materials and electrolyte can be reduced and recycled by the reduction device, and zero loss is realized; the power generation and reduction device is green and environment-friendly, and has no emission and pollution when being used in a fully closed state; the power generation and reduction device has simple manufacturing process and low cost; the device has the advantages of large specific energy, high specific power, stable output and low self consumption; the safety and reliability are realized, and explosion and combustion cannot occur when external open fire, short circuit, puncture, impact and other conditions occur; the oxygen consumption of the power generation device is very low. The power generation and reduction device has certain innovation on the aerospace industry, national defense science and technology and the existing power generation method, and particularly has great innovation on anoxic and anaerobic areas, such as submarines, aerospace and the like.

In order to achieve the purpose, the invention adopts the technical scheme that:

a metal fuel oxygen power generation device comprises a power generation device shell (25), an electrolyte box (6) is arranged in the power generation device shell (25), and the electrolyte box (6) is connected with a battery module (3) through a circulating water pump (7) and a liquid feeding pipe (4); the electrolyte tank (6) is provided with a stirrer (5); the electrolyte box (6) is connected with a metal powder adding port (9) through a metal powder adding pipe (8); one side of the electrolyte box (6) is connected with an electrolyte adding port (1) arranged on the generator shell (25) through an electrolyte adding pipe (2); the lower part of the electrolyte tank (6) is provided with a liquid discharging port (24); the battery module (3) is connected with an oxygen source through an oxygen regulating valve (19) and an oxygen pipeline (22), and a generator shell (25) is provided with a power supply box (15) and an auxiliary power supply (20); the liquid discharging port (24) is connected with the reduction system through a power generation system liquid discharging pipe (48), a reduction system water pump (49), a reduction system four-way valve (50) and a reduction system liquid feeding pipe (47);

the reduction device can be independent of the power generation device, is favorable for reduction of electrolyte mixed liquor, is not limited by the power generation device, and can be used for reducing and recycling raw materials at any place.

The oxygen source is an oxygen storage tank (23)) or an oxygen generating device.

An oxygen filling port (21) is arranged on an oxygen pipeline (22) connected with the oxygen storage tank (23).

The oxygen generating device consists of an oxygen generating agent filling port (26), an oxygen drying box (27), an oxygen generating agent storage tank (28), an oxygen generating adjusting valve (29) and an oxygen generating generator (30); the oxygen drying box (27) is connected with an oxygen production generator (30), and the lower part of the oxygen production agent storage tank (28) is connected with the oxygen production generator (30) through an oxygen production regulating valve (29); a pipeline is arranged between the oxygen production generator (30) and the oxygen drying box (27), and the oxygen production generator (30) is provided with an oxygen production agent filling port (26).

An oxygen generation regulating valve (29) is arranged on the funnel below the oxygen generation agent storage tank (28).

The power box (15) is provided with a power output (10), a voltage output indicator (11), a current output indicator (12), a linkage oxygen regulating valve A (16), an under-voltage strip lamp switch (13), a work indicator lamp (14), a starting button (17) and a cleaning button (18); the oxygen regulating valve A (16), the oxygen regulating valve B (19) and the oxygen regulating valve C (29) are in linkage regulation; the output voltage indicator (11) and the output current indicator (12) are respectively connected with the power output end (10) and used for indicating the voltage and the current output by the power generation device; the switch part of the under-voltage lamp-carrying switch (13) is connected with the output end of the auxiliary power supply (50), is a working switch of the power supply, opens the under-voltage lamp-carrying switch (13), indicates that the starting button (17) needs to be pressed when the lamp is on, indicates that the lamp normally works when the lamp is off, stops pressing the starting button (17), and closes the under-voltage lamp-carrying switch (13); the undervoltage indicator lamp with the lamp switch (13) is connected to the power output end (10) and used for detecting output voltage and indicating the operation of the starting button (17); the working indicator light is connected to the power output end (10) and used for indicating whether the power generation device works normally or not; the starting button is respectively connected with the standby power supply (20), the stirrer (5) and the circulating water pump (7), when the power generation device is used for the first time, the starting button (17) is pressed to enable the circulating pump (7) and the stirrer (5) to work, and electrolyte and metal powder are pumped into the power supply module (3) to enable the power generation device to start working; the oxygen regulating valve A (16), the oxygen regulating valve B (19) and the oxygen regulating valve C (29) are linkage devices, and the oxygen regulating valve B (19) and the oxygen regulating valve C (29) can be simultaneously regulated only by the oxygen regulating valve A (16) so as to regulate the oxygen supply amount of the power generation device, so that the device can normally work; when the power generation device works normally, the auxiliary power supply (20) is charged by a self-contained charger of the auxiliary power supply (20) so as to ensure the next use.

The battery module (3) consists of a power module oxygen inlet (34), a power module shell (32), a battery monomer (33), a power module liquid feeding pipe (51), a power module water pump (46) and a battery monomer output line (35); a battery monomer (33) is arranged in the power module shell (32); the battery monomer (33) top intercommunication is connected power module oxygen air inlet (34), and power module shell (32) below is through power module water pump (7) connection power module liquid feeding pipe (51), and power module liquid feeding pipe (51) are connected power module shell (32) top.

The battery single body (33) is characterized in that a single battery positive electrode frame (37) is arranged in a power module shell (32); the single battery positive electrode frame (37) is inserted into the single battery positive electrode plate (38), the single battery diaphragm (39) and the single battery negative electrode current collector (40); a single battery oxygen inlet (36) is arranged above the power module shell (32).

The reduction system comprises a reduction system shell (41), a reduction system positive plate (43), a reduction system negative plate (44), a reduction system water pump (49), a reduction system four-way valve (50), a reduction system liquid feeding pipe (47), a power generation system liquid discharging pipe (48) and a reduction system strangulation device (42), wherein the reduction system strangulation device (42) is arranged in the middle of the reduction system shell (41), the reduction system positive plate (43) and the reduction system negative plate (44) are arranged on two sides of the reduction system strangulation device (42), and a reduction system liquid discharging valve (45) is arranged below the reduction system shell (41); the reduction system is connected with the power generation system through a reduction system water pump (49), a reduction system four-way valve (50), a reduction system liquid feeding pipe (47) and a power generation system liquid discharging pipe (48), and the reduction system can be independent of the power generation system and can be used independently.

The invention has the beneficial effects that:

the discharge current is continuous and stable, no noise, no emission, zero pollution, simple operation, large output power, reduced self consumption of the metal-oxygen battery, safety and reliability, and can be recycled.

Drawings

FIG. 1 is a schematic view of a power generation and reduction apparatus (oxygen charging type) according to the present invention

FIG. 2 is a schematic view of the power generation and reduction apparatus (oxygen generation type) of the present invention

FIG. 3 is a schematic diagram of a battery module and a battery cell of the power generation device of the present invention

FIG. 4 is a schematic view of a reduction structure according to the present invention.

Wherein, 1 is an electrolyte adding port; 2 is an electrolyte adding pipe; 3 is a battery module; 4 is a liquid feeding pipe; 5 is a stirrer; 6 is an electrolyte box; 7 is a circulating water pump; 8 is a metal powder filling pipe; 9 is a metal powder filling port; 10 is the output end of the discharge device; 11 output voltage indication; 12 is an output current indication; 13 is an undervoltage indicator lamp; 14 is a work indicator light; 15 is a power box; 16 is an oxygen regulating valve; 17 is a start button; 18 is a cleaning button; 19 is an oxygen regulating valve; 20 is an auxiliary power supply; 21 is an oxygen filling port; 22 is an oxygen pipeline; 23 is an oxygen storage tank; 24 is a liquid discharging port; 25 is a power generation device shell; 26 is an oxygen production agent filling port; 27 is an oxygen drying oven; 28 is an oxygen generating agent storage tank; 29 is an oxygen regulating valve; 30 is an oxygen generator; 31 is an electrolyte inlet; 32 is a power module shell; 33 is a single battery; 34 power module oxygen inlet; 35 is a single battery output line; 36 is a cell oxygen port; 37 is a battery anode frame; 38 is a single battery positive plate; 39 is a single battery diaphragm; 40 is a negative current collector of the elevator battery; 41 is a reduction system shell; 42 is a reducing system strangler; 43 is a reduction system positive plate; 44 is a reduction system negative plate; 45 is a reducing system liquid discharge valve; and 46 is a power module water pump. 47 reducing the upper liquid pipe of the system; 48 is a liquid discharge pipe of the power generation system; 49 reducing the system water pump; 50 reducing a system four-way valve; 51 power module upper liquid pipe.

Detailed Description

The invention is further described below with reference to the accompanying drawings.

As shown in figure 1, the metal fuel oxygen power generation device comprises a power generation device shell (25), an electrolyte box (6) is arranged in the power generation device shell (25), and the electrolyte box (6) is connected with a battery module (3) through a circulating water pump (7) and a liquid feeding pipe (4); the electrolyte tank (6) is provided with a stirrer (5); the electrolyte box (6) is connected with a metal powder adding port (9) through a metal powder adding pipe (8); one side of the electrolyte box (6) is connected with an electrolyte adding port (1) arranged on the generator shell (25) through an electrolyte adding pipe (2); the lower part of the electrolyte tank (6) is provided with a liquid discharging port (24); the battery module (3) is connected with an oxygen source through an oxygen regulating valve (19) and an oxygen pipeline (22), and a generator shell (25) is provided with a power supply box (15) and an auxiliary power supply (20); the liquid discharging port (24) is connected with the reduction system through a power generation system liquid discharging pipe (48), a reduction system water pump (49), a reduction system four-way valve (50) and a reduction system liquid feeding pipe (47);

As shown in fig. 2, the oxygen generation device consists of an oxygen generation agent filling port (26), an oxygen drying box (27), an oxygen generation agent storage tank (28), an oxygen generation regulating valve (29) and an oxygen generation generator (30); the oxygen drying box (27) is connected with an oxygen production generator (30), and the lower part of the oxygen production agent storage tank (28) is connected with the oxygen production generator (30) through an oxygen production regulating valve (29); a pipeline is arranged between the oxygen production generator (30) and the oxygen drying box (27), and the oxygen production generator (30) is provided with an oxygen production agent filling port (26).

As shown in fig. 3, the battery module (3) is composed of a power module oxygen inlet (34), a power module housing (32), a battery cell (33), a power module liquid feeding pipe (51), a power module water pump (46) and a battery cell output line (35); a battery monomer (33) is arranged in the power module shell (32); the battery monomer (33) top intercommunication is connected power module oxygen air inlet (34), and power module shell (32) below is through power module water pump (7) connection power module liquid feeding pipe (51), and power module liquid feeding pipe (51) are connected power module shell (32) top.

As shown in fig. 1 and 4, the reduction system is composed of a reduction system shell (41), a reduction system positive plate (43), a reduction system negative plate (44), a reduction system water pump (49), a reduction system four-way valve (50), a reduction system liquid feeding pipe (47), a power generation system liquid discharging pipe (48) and a reduction system strangulation device (42), the reduction system strangulation device (42) is arranged in the middle of the reduction system shell (41), the reduction system positive plate (43) and the reduction system negative plate (44) are arranged on two sides of the reduction system strangulation device (42), and a reduction system liquid discharging valve (45) is arranged below the reduction system shell (41); the reduction system is connected with the power generation system through a reduction system water pump (49), a reduction system four-way valve (50), a reduction system liquid feeding pipe (47) and a power generation system liquid discharging pipe (48), and the reduction system can be independent of the power generation system and can be used independently.

The working principle of the invention is

The generator prepares to add the metal powder in proper order during operation, behind electrolyte and the oxygenerator, open the undervoltage and take the lamp switch, the undervoltage lamp switch that takes lights this moment, open linkage oxygen regulating valve, make oxygen get into power module, press the start button, the liquid water pump begins work under auxiliary power supply is supplementary, evenly bring electrolyte and metal powder into in the battery module, after the undervoltage lamp switch that takes extinguishes, loosen the start button, the generator begins normal work this moment, power generation facility can charge in order to ensure recycling when normally working for auxiliary power supply. And after the mixed liquid is discharged, adding cleaning liquid and pressing a cleaning button to clean for 2-3 times.

When the generator works, the liquid feeding water pump stops working, the battery module water pump starts working, electrolyte and metal powder are uniformly brought into the battery module, so that the metal powder is uniformly accumulated on the negative current collector, the negative electrode of the battery reacts with oxygen through the diaphragm and the positive electrode, and electric energy output is generated.

When the generator works, the liquid adding part is driven by the water pump of the battery module, liquid continuously circulates in the battery, zinc powder is brought in, and oxides and heat are brought out, so that stable electric energy output is achieved.

The oxygen adding part is used for uniformly adding the oxygen-generating agent into the oxygen reaction box to generate oxygen, and the oxygen is dried by the drying box and then added into the battery module at a certain pressure. The oxygen generator can also use a pressure oxygen tank, and the oxygen tank is added into the power supply module after the oxygen tank is adjusted to the required pressure by a linkage oxygen pressure adjusting valve. The electric appliance part adjusts the adding amount of the zinc powder under the control of current and voltage, so that the battery outputs stable voltage and current. After the use is finished, the oxygen valve is closed, the load is disconnected, the tapping valve is opened to discharge electrolyte mixed liquor, then the system reduction water pump is opened, the mixed liquor enters the reduction system through the tapping pipe, the reduction water pump, the reduction feeding pipe and the reduction four-way valve to be reduced so as to ensure the recycling, and after the mixed liquor is discharged, cleaning liquor is added into the liquid feeding port to press the cleaning button to clean for 2-3 times. And the discharged used liquid is put into a reduction device for reduction for recycling. The power generation device and the matched reduction device can be one system or two independent systems which are complementary and do not influence each other.

Claims

1. A metal fuel oxygen power generation device comprises a power generation device shell (25), and is characterized in that an electrolyte box (6) is arranged in the power generation device shell (25), and the electrolyte box (6) is connected with a battery module (3) through a circulating water pump (7) and a liquid feeding pipe (4); the electrolyte tank (6) is provided with a stirrer (5); the electrolyte box (6) is connected with a metal powder adding port (9) through a metal powder adding pipe (8); one side of the electrolyte box (6) is connected with an electrolyte adding port (1) arranged on the generator shell (25) through an electrolyte adding pipe (2); the lower part of the electrolyte tank (6) is provided with a liquid discharging port (24); the battery module (3) is connected with an oxygen source through an oxygen regulating valve (19) and an oxygen pipeline (22), and a generator shell (25) is provided with a power supply box (15) and an auxiliary power supply (20); the liquid discharging port (24) is connected with the reduction system through a power generation system liquid discharging pipe (48), a reduction system water pump (49), a reduction system four-way valve (50) and a reduction system liquid feeding pipe (47).

2. The metal-fuel oxygen power plant of claim 1, wherein the oxygen source is an oxygen storage tank (23)) or an oxygen generator.

3. The metal-fuel oxygen power generation device according to claim 2, wherein the oxygen pipe (22) connected to the oxygen storage tank (23) is provided with an oxygen filling port (21).

4. The metal fuel oxygen power generation device according to claim 2, wherein the oxygen generation device is composed of an oxygen generation agent filling port (26), an oxygen drying box (27), an oxygen generation agent storage tank (28), an oxygen generation regulating valve (29) and an oxygen generation generator (30); the oxygen drying box (27) is connected with an oxygen production generator (30), and the lower part of the oxygen production agent storage tank (28) is connected with the oxygen production generator (30) through an oxygen production regulating valve (29); a pipeline is arranged between the oxygen production generator (30) and the oxygen drying box (27), and the oxygen production generator (30) is provided with an oxygen production agent filling port (26).

5. A metal fuel oxygen power plant according to claim 4, characterized in that the hopper below the oxygen production agent storage tank (28) is provided with an oxygen production regulating valve (29).

6. The metal fuel oxygen power generation device according to claim 1, wherein the power box (15) is provided with a power output (10), a voltage output indicator (11), a current output indicator (12), a linkage oxygen regulating valve A (16), an under-voltage lighted switch (13), a work indicator (14), a start button (17) and a cleaning button (18); the oxygen regulating valve A (16), the oxygen regulating valve B (19) and the oxygen regulating valve C (29) are in linkage regulation; the output voltage indicator (11) and the output current indicator (12) are respectively connected with the power output end (10); the switch part of the under-voltage light-carrying switch (13) is connected with the output end of the auxiliary power supply (50), and the indicator light of the under-voltage light-carrying switch (13) is connected with the output end (10) of the power supply; the work indicator light is connected to the power output end (10); the starting button is respectively connected with a standby power supply (20), a stirrer (5) and a circulating water pump (7), and the oxygen regulating valve A (16), the oxygen regulating valve B (19) and the oxygen regulating valve C (29) are linkage devices.

7. The metal fuel oxygen power generation device according to claim 1, wherein the battery module (3) is composed of a power module oxygen inlet (34), a power module shell (32), a battery cell (33), a power module liquid feeding pipe (51), a power module water pump (46) and a battery cell output line (35); a battery monomer (33) is arranged in the power module shell (32); the battery monomer (33) top intercommunication is connected power module oxygen air inlet (34), and power module shell (32) below is through power module water pump (7) connection power module liquid feeding pipe (51), and power module liquid feeding pipe (51) are connected power module shell (32) top.

8. A metal-fuel oxygen power plant according to claim 7, characterized in that the battery cells (33) are formed by a cell positive frame (37) arranged in a power module housing (32); the single battery positive electrode frame (37) is inserted into the single battery positive electrode plate (38), the single battery diaphragm (39) and the single battery negative electrode current collector (40); a single battery oxygen inlet (36) is arranged above the power module shell (32).

9. The metal fuel oxygen power generation device according to claim 7, wherein the reduction system is composed of a reduction system shell (41), a reduction system positive plate (43), a reduction system negative plate (44), a reduction system water pump (49), a reduction system four-way valve (50), a reduction system liquid feeding pipe (47), a power generation system liquid discharging pipe (48) and a reduction system strangler (42), the reduction system strangler (42) is arranged in the middle of the reduction system shell (41), the reduction system positive plate (43) and the reduction system negative plate (44) are arranged on two sides of the reduction system strangler (42), and a reduction system liquid discharging valve (45) is arranged below the reduction system shell (41); the reduction system is connected with the power generation system through a reduction system water pump (49), a reduction system four-way valve (50), a reduction system liquid feeding pipe (47) and a power generation system liquid discharging pipe (48), and the reduction system can also be independently used outside the power generation system.