KR20160128886A - Metal air battery having air purification module, electrochemical cell having air purification module and operation method of the same - Google Patents

Abstract

Disclosed are a metal air battery having an air purification module and an operation method thereof. The metal air battery fluid-communicates with a battery cell module and includes the air purification module for purifying air supplied from the outside. The air purification module may include: a first air purification unit which filters first impurity among a plurality of impurities included in air supplied from the outside; and a second air purification unit which filters second impurity different from the first impurity among the plurality of impurities.

Description

Technical Field [0001] The present invention relates to a metal air cell having an air purification module, an electrochemical cell, and a method of operating the same.

A metal air cell, an electrochemical cell, and a method of operating the same are disclosed. More particularly, a metal air cell, an electrochemical cell, and an operation method thereof having an air purification module are disclosed.

An electrochemical cell, for example, a metal air cell includes a plurality of metal air battery cells, wherein each metal air battery cell includes a cathode capable of storing and releasing ions and a cathode using oxygen in the air as an active material . In the anode, reduction and oxidation of oxygen introduced from the outside takes place, and oxidation and reduction of the metal occur at the cathode. The chemical energy generated at this time is converted into electrical energy and extracted. For example, metal air cells absorb oxygen during discharge and release oxygen during charge. Since the metal air cell uses oxygen present in the air, the energy density of the battery can be dramatically improved. For example, a metal air cell can have an energy density several times higher than the energy density of a conventional lithium ion battery.

In addition, the metal air cell has a low possibility of ignition due to abnormally high temperature, and therefore has excellent stability, and it is not necessary to use a heavy metal, and operates only by absorbing and releasing oxygen. Due to these various advantages, much research is now being made on metal air cells.

When a metal air cell is operated, air is supplied to the anode side, and oxygen molecules are used as an active material. At this time, impurities such as moisture (H ₂ O) and carbon dioxide (CO ₂ ) contained in the air interfere with the production of metal peroxide (for example, Li ₂ O ₂ ), thereby decreasing the capacity and lifetime of the metal air battery .

One embodiment provides a metal air cell and an electrochemical cell having an air purification module.

Another embodiment provides a method of operating the metal air cell.

The metal air battery according to one aspect,

A battery cell module that generates electricity using oxidation of metal and reduction of oxygen; And

And an air purification module that is in fluid communication with the battery cell module and purifies air supplied from the outside to supply the cleaned air to the battery cell module,

Wherein the air purifying module comprises: a first air purifier for filtering a first impurity among a plurality of impurities contained in air introduced from the outside; and a second air purifier for filtering a second impurity of the plurality of impurities And an air purification unit.

Wherein the metal air cell comprises a concentration detector for detecting a concentration of at least one impurity among a plurality of impurities contained in air introduced from the outside, And a control unit for controlling the negative operation.

The plurality of impurities may include at least two of water, carbon dioxide, and nitrogen.

The second air purifier may be disposed between the first air purifier and the battery cell module, and may filter the second impurity from air that has passed through the first air purifier.

The second air purifier may concentrate oxygen such that the oxygen concentration in the air supplied to the battery cell module is 21% or more.

Wherein the control unit adjusts the first power consumption of the first air cleaning unit based on the information detected by the concentration detection unit and controls the second air cleaning unit based on the adjusted first power consumption of the first air cleaning unit, The second power consumption of the purifier can be adjusted.

When the concentration of the impurity detected by the concentration detecting section is increased, the control section may increase the first power consumption of the first air purification section and reduce the second power consumption of the second air purification section.

When the concentration of the impurity detected by the concentration detector is reduced, the controller may decrease the first power consumption of the first air purifier and increase the second power consumption of the second air purifier.

The air purifying module may further include a third air purifier for filtering third impurities different from the first and second impurities.

The first and second air purifiers may be disposed in one chamber and may filter the first and second impurities from the air introduced into the chamber.

The air purification module may be configured to operate by pressure swing adsorption (PSA), thermal swing adsorption (TSA), pressure thermal swing adsorption (PTSA), vacuum swing adsorption (VSA) .

The air purification module may include at least one of an adsorbent and a selective permeable membrane.

The sorbent material may be selected from zeolite, alumina, silica gel, metal-organic framework (MOF), zeolitic imidazolate framework (ZIF), activated carbon or a mixture of two or more thereof.

The metal air cell may be a lithium air battery.

The metal air cell may further include a first connection path for fluidly connecting the first air purification unit and the second air purification unit, a second connection path for fluidly connecting the second air purification unit and the battery cell module, A bypass path bypassing the second air purifier and fluidly connecting the first and second connection paths and a flow rate controller for controlling a flow rate of air supplied to the second air purifier.

Wherein the flow rate regulator is configured to regulate the flow rate of the air supplied by the second air purifier to the flow rate of the air to be concentrated by the second air purifier so as to be equal to or smaller than a maximum air flow rate that can have an oxygen concentration of 95% Can be adjusted.

The battery cell module may be supplied with air mixed with air passing through the bypass path and air passing through the second air purifier.

According to another aspect of the present invention, there is provided a method of operating a metal-

Filtering the first impurity among the plurality of impurities contained in the air introduced from the outside by the first air purifying unit; And

And filtering the second impurity, which is different from the first impurity, among the plurality of impurities by the second air purification unit.

The method of operating the metal air cell may include detecting a concentration of at least one impurity among a plurality of impurities contained in air flowing into the air purifying module; And controlling the operation of the first and second air purifiers to filter the first and second impurities based on the concentration of the detected impurities.

Wherein the control unit controls the first power consumption of the first air cleaning unit based on the information detected by the concentration detection unit in the step of controlling the operation of the first and second air cleaning units, The second power consumption of the second air cleaning unit can be adjusted based on the first power consumption.

When the detected concentration of the impurity is increased, the control unit may increase the first power consumption of the first air purifier and reduce the second power consumption of the second air purifier.

When the detected concentration of the impurity is decreased, the control unit may decrease the first power consumption of the first air purifier and increase the second power consumption of the second air purifier.

The step of filtering the first impurity and the step of filtering the second impurity may be carried out sequentially or simultaneously.

A part of the air filtered by the first air purifier is supplied to the second air purifier, the rest of the air filtered by the first air purifier is supplied to the bypass path, And the air passing through the bypass path may be mixed and supplied to the battery cell module.

The flow rate of the air supplied to the second air purifier can be adjusted by the flow rate controller.

Wherein the flow rate controller adjusts the flow rate of the air supplied by the second air purifier so that the flow rate of the air supplied by the second air purifier is equal to or smaller than a maximum air flow rate that can have an oxygen concentration of 95% The flow rate can be adjusted.

According to another aspect of the present invention, there is provided an electrochemical cell comprising:

A battery cell module that generates electricity using a chemical reaction; And

And an air purification module that is in fluid communication with the battery cell module and purifies air supplied from the outside to supply the cleaned air to the battery cell module,

Wherein the air-

A first air purifier for filtering the first impurity among a plurality of impurities included in the air introduced from the outside,

And a second air purifier for filtering a second impurity different from the first impurity among the plurality of impurities.

The electrochemical cell may further include a first connection path for fluidly connecting the first air purification unit and the second air purification unit, a second connection path for fluidly connecting the second air purification unit and the battery cell module, A bypass path bypassing the second air purifier and fluidly connecting the first and second connection paths and a flow rate controller for controlling a flow rate of air supplied to the second air purifier.

The metal air cell and the electrochemical cell according to an embodiment of the present invention can prevent a side reaction due to impurities by removing a plurality of impurities from the air supplied to the battery cell module, The life can be improved.

In addition, the metal air cell according to an embodiment of the present invention can maximize the operation efficiency of the metal air battery by controlling the operation of the plurality of air purifying units based on the impurity concentration in the air introduced from the outside, The energy efficiency of the metal air cell can be improved.

1 is a schematic diagram of an electrochemical cell according to one embodiment.
2 is a schematic view of a metal air cell including an air purifying module according to an embodiment.
3 is a graph showing changes in battery capacity per unit weight as the number of charging and discharging times increases in the metal air cell according to Example 1 and Comparative Examples 1 and 2. FIG.
4 is a schematic view of a metal air cell including an air purifying module according to another embodiment of the present invention.
5A and 5B show the output power of the metal air battery according to the adjustment of the concentration of water and the concentration of oxygen in the air supplied to the battery cell module when air having different moisture concentrations is introduced into the air purifying module .
6A to 6C are diagrams illustrating an operation method of the metal anode battery of FIG.
7 is a schematic view of a metal air cell including an air purification module according to another embodiment of the present invention.
8 is a schematic view of a metal air cell according to another embodiment.
9 shows the oxygen flow rate and the oxygen concentration according to the air flow rate introduced into the second air purifier.
10 is a graph showing oxygen concentration with respect to the air flow rate of the air purifying module according to the first and second embodiments.
FIG. 11 shows changes in oxygen concentration with time in the air purifying module according to the first and second embodiments. FIG.
12A and 12B are graphs for explaining the response speed of the air purifying module according to the first and second embodiments.
13 is a cross-sectional view schematically showing an example of a battery cell module provided in a metal air cell.

Hereinafter, a metal air cell, an electrochemical cell, and a method of operating the metal air battery according to an embodiment will be described in detail with reference to FIG.

Referring to FIG. 1, an electrochemical cell according to an embodiment includes a battery cell module 10 and an air purification module 20. The electrochemical cell may be a metal air cell. The metal air cell may be a lithium air battery. However, the metal air cell is not limited thereto, and may be a sodium air battery, a zinc air battery, a potassium air battery, a calcium air battery, a magnesium air battery, an iron air battery, an aluminum air battery, Air battery.

The battery cell module 10 generates electricity using oxidation of metal and reduction of oxygen.

For example, when the metal is lithium (Li), the metal air cell generates a lithium peroxide (Li ₂ O ₂ ) by reacting with lithium (Li) Generate electricity.

[Reaction Scheme 1]

Li + 1 / 2O ₂ ? 1 / 2Li ₂ O ₂

However, when impurities such as water (H ₂ O) are present in the air, the energy density and lifetime of the metal air cell are reduced due to the reaction of generating lithium hydroxide (LiOH) .

[Reaction Scheme 2]

4Li + 6H ₂ O + O ₂ → 4 (LiOH · H ₂ O)

The air purifying module 20 is in fluid communication with the battery cell module 10.

The air purifying module 20 removes impurities in the air A1 from the outside to purify the air A1 and supplies the purified air A2 to the battery cell module 10 do.

The air purifying module 20 according to the embodiment can filter a plurality of impurities from the air A1 introduced into the air purifying module 20. [

The plurality of impurities may be at least two of the substances other than oxygen (O ₂ ), for example, water (H ₂ O), carbon dioxide (CO ₂ ) and nitrogen (N ₂ ) Or more. For example, the air purification module 20 may filter the first and second impurities.

2 is a schematic view of a metal air cell including an air purification module 20a according to an embodiment. Referring to FIG. 2, the air purifying module 20a includes a first air purifying part 21 and a second air purifying part 22.

The first air purification unit 21 can filter the first impurities. The first impurity may be any one of water, carbon dioxide, and nitrogen. For example, the first air cleaning unit 21 can remove moisture. The first air cleaning unit 21 for removing moisture may be referred to as an "air dryer ".

And the second air purifier 22 can filter the second impurity. The second impurity may be any one of water, carbon dioxide, and nitrogen. The second impurity may be different from the first impurity. For example, when the first air cleaning unit 21 removes moisture, the second air cleaning unit 22 can remove nitrogen. However, the filtration of the second impurity by the second air purification unit 22 is not limited to the removal of only the second impurity. For example, filtration of the first impurity and filtration of the second impurity .

The second air purifier 22 can remove nitrogen and concentrate oxygen. The second air purifier 22 can concentrate oxygen so that the oxygen concentration in the air supplied to the battery cell module 10 is 21% or more, for example, 30% or more, and more preferably 40% or more . The second air purifier 22 for concentrating oxygen may be referred to as an "oxygen generator ".

The second air purifier 22 may be disposed between the first air purifier 21 and the battery cell module 10. The second air purifier 22 is in fluid communication with the first air purifier 21 and can remove the second impurity from the air that has passed through the first air purifier 21. [

The air purification module 20a may be configured to be operated by pressure swing adsorption (PSA), temperature swing adsorption (TSA), pressure thermal swing adsorption (PTSA), vacuum swing adsorption (VSA) . As used herein, the term " PSA " means a technique in which a specific gas is preferentially adsorbed or captured on a sorbent at a high partial pressure, and the specific gas is desorbed or released when the partial pressure is reduced. Refers to a technique in which a specific gas is preferentially adsorbed or trapped at an adsorbent at room temperature and the specific gas is desorbed or released when the temperature is increased. The term " PTSA "Quot; VSA " means a technique in which a specific gas is preferentially adsorbed or trapped in the adsorbent near the atmospheric pressure, and operates under the principle that the specific gas is desorbed or released under vacuum.

The first and second air purifiers 21 and 22 may be filled with a sorbent material (not shown), a selective permeable membrane (not shown) may be disposed, a sorbent material may be filled and a selective permeable membrane may be disposed .

The adsorbent selectively adsorbs impurities in the air (A1). Such sorbents can be selected from zeolites, alumina, silica gel, metal-organic framework (MOF), zeolitic imidazolate framework (ZIF), activated carbon or a mixture of two or more thereof. As used herein, the term " MOF " means a crystalline compound consisting of a metal ion or metal cluster coordinated to an organic molecule and forming a porous primary, secondary or tertiary structure. As used herein, the term " ZIF " refers to a nanoporous compound consisting of tetrahedral clusters of MN ₄ (M is a metal) linked by an imidazolate ligand.

The selective permeable membrane selectively permeates the remaining components except for the impurities in the air (A1). These selective permeable membranes may include a plurality of ion exchange hollow fibers disposed side by side (i.e., disposed in parallel to the flow direction of air A1).

As described above, in the course of the air A1 flowing into the air purifying module 20a from the outside through the first and second air purifying sections 21 and 22, 2 Impurities can be removed.

If the air purification module has a structure for filtering only one impurity, unlike the embodiment, other impurities excluding the impurities to be filtered are supplied to the battery cell module 10 without being filtered, Side reaction can not be avoided. As a result, the energy density of the metal air cell is reduced and the service life is shortened.

However, in the air purifying module 20a according to the embodiment, by removing the plurality of impurities contained in the air A1 by the first and second air purifying sections 21 and 22, It is possible to prevent shortening of the life of the battery and improve energy efficiency.

FIG. 3 shows changes in cell capacity per unit weight as the number of times of charge and discharge increases in the metal air cell according to Example 1 and Comparative Examples 1 and 2. FIG. The air purifying module 20a of the metal air cell according to Embodiment 1 (X) includes a first air purifying portion 21 for filtering moisture and a second air purifying portion 22 for filtering nitrogen to concentrate oxygen do. On the other hand, the air purifying module of the metal air cell according to Comparative Example 1 (Y1) includes only the first air purifying portion 21 for filtering moisture, and the air purifying module of the metal air battery according to Comparative Example 2 (Y2) And only the second air purifier 22 for concentrating oxygen by filtering nitrogen.

The air A2 blown into the battery cell module 10 by the air purifying module 20a according to the embodiment 1 (X) is removed by the first air purifying part 21 so that the moisture concentration is 40 ppm And the nitrogen is removed by the second air purifier 22, and the oxygen concentration is 70%. In this case, the battery capacity per unit weight of the metal air cell is maintained at 300 mAh / g until the number of charge / discharge cycles is about 9 times.

The air purifying module according to Comparative Example 1 (Y1) removes moisture from the air A2 introduced into the battery cell module 10 by the first air purifying portion 21 to have a moisture concentration of 40 ppm, Is not removed and oxygen is not concentrated, so the oxygen concentration is 21%. In this case, the battery capacity per unit weight starts to decrease from the time when the number of charging / discharging times of the metal air battery becomes twice.

With the air purification module according to Comparative Example 2 (Y1), the air (A2) introduced into the battery cell module (10) is subjected to nitrogen removal by the second air purification portion (22) %, But the moisture is not removed and the moisture concentration is 68000 ppm (60 ° C and 50% relative humidity). In this case, the battery capacity per unit weight of the metal air battery drastically decreases from when the number of times of charging and discharging becomes about four times.

As described above, it can be seen that the number of charge / discharge cycles of the air purifying module 20a according to the embodiment 1 (X) is longer than that of the air purifying module according to the comparative examples 1 and 2 (Y1, Y2) have. It can be seen from this that, when a plurality of impurities are filtered by a plurality of air purifying units, the service life of the metal air cells is remarkably increased.

Although the first and second air purifying sections 21 and 22 are exemplified as the plurality of air purifying sections in the above-described embodiments, the present invention is not limited thereto and may include three or more air purifying sections.

For example, as shown in Fig. 4, the air purification module 20b may further include a third air purifier 23 for filtering third impurities which are impurities different from the first and second impurities. When the first and second impurities are water and nitrogen, the third impurity may be carbon dioxide.

On the other hand, the plurality of air purifying units consume a predetermined power consumption to remove a plurality of impurities. For example, the first air cleaning unit 21 consumes the first power consumption E1 to remove the first impurity, and the second air cleaning unit 22 consumes the second power consumption E2 to remove the second impurity. Power E2 is consumed.

2, the air purifying module 20a according to the embodiment includes a concentration detecting portion 25 for detecting the concentration of at least one impurity in the air introduced into the air purifying module 20a, a concentration detecting portion 25 The control unit 26 may control the first and second air purifying units 21 and 22 based on the information detected by the first and second air purifying units 21 and 22. [ The air purifying module 20a includes the first and second air purifying sections 21 and 22 so that the increase in power consumption by the first and second air purifying sections 21 and 22 can be minimized have.

The concentration detecting unit 25 can detect the concentration of the first impurity contained in the air A1 flowing into the air purifying module 20a. For example, the concentration detecting unit 25 can detect the concentration of water contained in the air A1 introduced from the outside.

The control unit 26 can control the operation of the first air purification unit 21 based on the information related to the concentration of the first impurity detected by the concentration detection unit 25. [ For example, the operation of the first air purification unit 21 can be controlled based on the concentration change amount of the first impurity detected by the concentration detection unit 25. [

When the concentration of the first impurity is increased, the control unit 26 can increase the first power consumption E1 of the first air purification unit 21. [ The first power consumption E1 of the first air cleaning unit 21 can be reduced when the concentration of the first impurity is decreased. When there is no change in the concentration of the first impurity, the control section 26 can maintain the first power consumption E1 of the first air purification section 21. [ Here, the fact that the concentration of the first impurity is increased, decreased or maintained means that the concentration detected by the concentration detecting section 25 is increased (compared to the concentration detected by the concentration detecting section 25) , ≪ / RTI > decrease, or the like.

The first air purifier 21 can increase or decrease at least one of the purging flow rate and the operation time of the first air purifier 21 as the first power consumption E1 increases or decreases .

The control unit 26 can adjust the second power consumption E2 of the second air purifying unit 22 based on the first power consumption E1 adjusted by the first air purifying unit 21 as described above have. Accordingly, the oxygen concentration in the air (A2) supplied to the battery cell module (10) can be changed in accordance with the change of the second power consumption (E2).

As an example, the control unit 26 can control the second power consumption E2 of the second air cleaning unit 22 such that the increase amount DELTA P _OUT of the output power of the metal air cell is maximized.

The increase amount DELTA P _OUT of the output power of the metal air cell can be calculated by the following expression 1 as the change amount of the output power of the battery cell module 10 according to the operation of the first and second air purifying units 21 and 22 B1 *? V _{H2O + B1 * ΔV O2) * A} ) in the first and second air cleaning unit (21, 22) the amount of change in the power consumption consumed by the operation of (ΔE _H2O + DELTA E _O2 ). The change amount of the output power of the battery cell module 10 is determined by the amount of change (B1 *? V _H2O + B1 * DELTA V _O2 ) can be multiplied by a predetermined current value (A). Here, B1 and B2 are weights for the first and second air purifiers 21 and 22, and B1 + B2 = 1.

[Relation 1]

The controller 26 determines whether the voltage of the battery cell module 10 increases as the concentration of the first impurity decreases and the concentration of the oxygen increases and the value of the voltage of the battery cell module 10 consumed for decreasing the first impurity concentration and increasing the concentration of oxygen The second power consumption E2 consumed by the second air purification unit 22 and the oxygen concentration thereof corresponding to the change amount DELTA P _OUT of the output power of the metal air cell are compared with each other, Can be determined.

5A is a graph showing the relation between the concentration of moisture in the air supplied to the battery cell module 10 and the concentration of oxygen when the concentration of water contained in the air introduced from the outside is the first concentration, . FIG. 5B is a graph showing the relationship between the concentration of water in the air supplied to the battery cell module 10 and the concentration of oxygen when the concentration of moisture contained in the air introduced from the outside is the second concentration, . Here, the first and second concentrations are different predetermined moisture concentrations.

Referring to FIG. 5A, when the moisture concentration contained in the air A1 introduced from the outside is the first concentration, the increase amount DELTA P _OUT of the output power of the metal air battery becomes maximum at the point P1. For example, when the moisture concentration contained in the air A1 introduced from the outside is the first concentration, the outside air A1 is purified by the first air purifying unit 21 so that the moisture concentration is 100 ppm, The amount of increase (? P _OUT ) of the output power of the metal air battery can be maximized when the outside air (A1) is purified by the second air cleaning unit (22) so that the oxygen concentration is 60%.

The control unit 26 controls the second air purifying unit 22 so that the output power of the metal air cell is maximized by the second air purifying unit 22 so that the oxygen concentration becomes 60% ).

Depending on the change of the external environment, the concentration of water contained in the air A1 introduced from the outside may be changed. For example, the concentration of water contained in the air A1 introduced from the outside may be changed from the first concentration to the second concentration. Accordingly, as shown in Fig. 5B, the increase amount DELTA P _OUT of the output power of the metal air battery can be maximized at the point P2. For example, when the moisture concentration contained in the air A1 introduced from the outside is the second concentration, the outside air A1 is purified by the first air purifying unit 21 so that the water concentration becomes 500 ppm, The amount of increase (? P _OUT ) of the output power of the metal air cell can be maximized when the outside air (A1) is purified by the second air cleaning unit (22) so that the oxygen concentration is 21%. As described above, the point at which the increase amount (DELTA P _OUT ) of the output power of the metal air battery is maximized with the change of the external environment can be changed from P1 to P2.

In accordance with the change of the external environment, the control unit 26 controls the second air purifier 22 so that the oxygen concentration is 21% such that the increase amount DELTA P _OUT of the output power of the metal air battery is maximized, And determines the second power consumption E2 of the purifier 22.

Hereinafter, a method of operating the metal air electrode will be described in detail with reference to FIGS. 1 and 6A to 6C.

The metal air battery detects the concentration of at least one impurity contained in the air (A1) flowing into the air purification module (20) through the concentration detection unit (25). For example, the concentration detecting unit 25 detects the concentration of water contained in the air flowing into the air purifying module 20. The concentration of water may vary in the air A1 flowing into the air purification module 20 due to various environmental changes such as temperature and humidity. The change in the concentration of water in the air A1 can be calculated or measured based on the concentration detected by the concentration detector 25. [

The control unit 26 can control the operation of the first and second air purifying units 21 and 22 based on the detected moisture concentration in order to improve the energy efficiency.

The control section 26 can maintain, increase or decrease the first power consumption E1 of the first air purification section 21 based on the change in the detected moisture concentration.

For example, when the concentration of the detected moisture is higher than the concentration of the previously detected moisture, the control unit 26 calculates the first power consumption E1 of the first air purification unit 21 to filter the increased moisture Can be increased by? E1. When the detected concentration of water is lower than the previously detected concentration of water, the control unit 26 can reduce the first power consumption E1 of the first air purification unit 21 by DELTA E1 by a reduced number of minutes. The controller 26 can maintain the first power consumption E1 of the first air cleaning unit 21 when the detected concentration of water is equal to the concentration of the previously detected moisture.

The control unit 26 can adjust the second power consumption E2 of the second air purification unit 22 by DELTA E2 based on the change amount DELTA E1 of the first power consumption EL1 of the first air purification unit 21. [ have.

6B, when the first power consumption E1 of the first air cleaning unit 21 is increased by DELTA E1, the control unit 26 controls the second air purifying unit 21, The second power consumption E2 of the power supply 22 can be reduced. The change amount E2 of the second power consumption E2 may be the same as the change amount E1 of the first power consumption E1. However, the change amount? E2 of the second power consumption E2 is not limited to this, and may be proportional to the change amount? E1 of the first power consumption E1.

The amount of change DELTA E2 of the second power consumption E2 of the second air purification unit 22 is set so as to satisfy the oxygen concentration of the air A2 that has been purified by the second air purification unit 22 to a predetermined reference value or more Can be limited. For example, when the increase amount DELTA E1 of the first power consumption E1 is equal to or larger than the predetermined limit power consumption E _limit , the variation amount DELTA E2 of the second power consumption of the second air purifying portion 22 is limited Power (E _limit ).

In addition, the amount of change DELTA E2 of the second power consumption E2 of the second air purification unit 22 can be limited so that the output power of the battery cell module 10 is equal to or greater than a predetermined reference value. When the second power consumption E2 decreases by DELTA E2, the oxygen concentration C in the air purified by the second air purifier 22 decreases by DELTA C, and the voltage V of the battery cell module 10 becomes DELTA V. When the voltage V of the battery cell module 10 decreases to V-? V, the output power of the battery cell module 10 may decrease. Therefore, when the voltage V-V of the battery cell module 10 becomes equal to or smaller than the predetermined limit voltage V _limit , the voltage V-V of the battery cell module 10 becomes the predetermined limit voltage V- It is possible to reduce the change amount DELTA E2 of the second power consumption E2 to be V _limit .

When the voltage V-DELTA V of the battery cell module 10 is larger than the predetermined limit voltage V _limit , the control section 26 changes the second air purification section 22 to the second power consumption E2- ? E2). Further, the control unit 26 operates the battery cell module 10 at a changed voltage (V-? V).

6C, when the first power consumption E1 of the first air cleaning unit 21 is decreased by DELTA E1, the control unit 26 calculates the second power DELTA E1 by the amount of change DELTA E1 of the first power consumption E1, It is possible to increase the second power consumption E2 of the portion 22. The change amount E2 of the second power consumption E2 may be the same as the change amount E1 of the first power consumption E1. However, the change amount? E2 of the second power consumption E2 is not limited to this, and may be proportional to the change amount? E1 of the first power consumption E1.

The increased second power consumption (E2 + [Delta] E2) increases the filtration of the second impurity and the concentration of oxygen. The increase (C + DELTA C) of the oxygen concentration due to the increase (E2 + DELTA E2) of the second power consumption E2 and the resulting voltage increase (V + DELTA V) of the battery cell module 10 can be calculated have.

When the voltage increase amount? V of the battery cell module 10 is larger than the predetermined reference voltage? _Vmin , the controller 26 sets the second air purifying section 22 to the increased second power consumption E2 +? E2 ). Further, the control unit 26 operates the battery cell module 10 at the changed voltage (V +? V).

However, the second electric power consumption of the battery cell module 10, the voltage increase amount (ΔV) is, if the same or less and a predetermined reference voltage (ΔV _min), the control section 26 of the second air filter 22 of the ( E2 without increasing the power consumption E2. In addition, the control unit 26 operates the battery cell module 10 with the existing voltage V without increasing the voltage.

6A, when the detected concentration of water is equal to the previously detected concentration of water, the controller 26 controls the first air purification unit 21 to change the first power consumption E1 without changing the first power consumption E1 Drive. Accordingly, the second air cleaning unit 22 is operated without changing the second power consumption E2. In addition, the control unit 26 operates the battery cell module 10 at the existing voltage V without changing the voltage.

The above-described process of detecting the moisture concentration and controlling the operation of the first and second air purifying units 21 and 22 can be repeatedly performed at predetermined intervals.

On the other hand, in the air purifying module 20 according to the above-described embodiment, the step of filtering the first impurity by the control unit 26 and the step of filtering the second impurity are sequentially controlled. However, the step of filtering the first and second impurities in the air purification module 20c is not limited to this, and may be performed at the same time. For example, the first and second air purifiers 21 and 22 may be disposed inside one chamber 29 as shown in FIG. Each of the first and second air purifiers 21 and 22 may be an adsorbent. Accordingly, the first and second air purifiers 21 and 22 can remove the first and second impurities from the air introduced into the chamber 29. In this case, the control unit 26 controls the operation of the first and second air purifying units 21 and 22

8 is a schematic view of a metal air cell according to another embodiment.

Referring to FIG. 8, the metal air battery includes an air purification module 20d and a battery cell module 10. The air purifying module 20d includes a first air purifying part 21, a second air purifying part 22, a first connection path 22 for fluidly connecting the first air purifying part 21 and the second air purifying part 22, A second connection path 32 for fluidly connecting the second air purification unit 22 and the battery cell module 10, a bypass path 33 bypassing the second air purification unit 22, And a flow control unit 27 for controlling a flow rate of air supplied to the second air purifier 22.

The first air purification unit 21 can filter the first impurities. For example, the first air cleaning unit 21 can remove moisture.

The second air cleaning unit 22 can remove the second impurity, for example, nitrogen, which is different from the first impurity. The second air purifier 22 can concentrate oxygen by removing nitrogen. For example, the second air purifier 22 may be configured such that the oxygen concentration of the air that has passed through the second air purifier 22 is 21% or more, for example, 30% or more, and more preferably 40% Oxygen can be concentrated.

However, the oxygen concentration characteristic of the second air purifier 22 may vary depending on the flow rate of the air A111 flowing into the second air purifier 22. [ This is because there is a limit to the amount by which the second air cleaning unit 22 can adsorb or remove nitrogen. In other words, the adsorption capacity that can be adsorbed by the second air cleaning unit 22 may be fixed. Therefore, when the adsorption capacity of the second air cleaning unit 22 is exceeded, nitrogen out of the adsorption capacity is not adsorbed by the second air cleaning unit 22, and the oxygen concentration of the second air cleaning unit 22 The characteristics can be degraded.

FIG. 9 shows the oxygen flow rate and the oxygen concentration according to the air flow rate introduced into the second air purifier 22. 9, the maximum oxygen concentration that can be concentrated by the second air cleaning unit 22 is 94%.

Referring to FIG. 9, when the air supplied to the second air purifier 22 is 30 L / min, the oxygen concentration of the air passing through the second air purifier 22 is 94%. When the flow rate of the air supplied to the second air purifier 22 exceeds 30 L / min, the oxygen concentration of the air purified by the second air purifier 22 is lowered.

In the section where the flow rate of the air supplied to the second air purification section 22 is 35 L / min or less, that is, in the range of 30 L / min to 35 L / min, the air purified by the second air purification section 22 The oxygen concentration in the atmosphere is gradually lowered. When the air flow rate is 35 L, the oxygen concentration in the air passing through the second air purifying section 22 may be 89%.

However, when the flow rate of the air supplied to the second air purifier 22 exceeds 35 L / min, the oxygen concentration of the air purified by the second air purifier 22 is rapidly lowered and the oxygen flow rate is increased The speed is significantly lowered.

Referring to FIG. 8 again, in consideration of this point, the flow rate regulator 27 can regulate the flow rate of the air A111 supplied to the second air purifier 22.

The flow rate regulating portion 27 may be disposed in the bypass path 33. [ The bypass path 33 may fluidly connect the first connection path 31 and the second connection path 32. A flow rate regulator 27 is disposed in the bypass path 33 and the flow rate regulator 27 is capable of regulating the flow rate of the air A112 supplied to the bypass path 33. The air A11 that has passed through the first air purification unit 21 is supplied separately from the second air purification unit 22 and the bypass path 33. Therefore, The flow rate of the air A111 supplied to the first air purification unit 21 can be adjusted. However, it is needless to say that the arrangement of the flow rate regulating portion 27 is not limited to this, and may be disposed in the first connecting path 31 as well.

The flow rate regulating section 27 is a valve for regulating the flow rate of the air A21 that has passed through the second air purifying section 22 to a maximum value capable of having an oxygen concentration of 95% The flow rate of the air A111 supplied to the second air purifier 22 can be adjusted so as to be equal to or less than the air flow rate.

As an example, when the maximum oxygen concentration in the air that can be condensed by the second air purifier 22 is 94%, the maximum flow rate capable of having an oxygen concentration of about 89% or more, which is 95% of the maximum oxygen concentration 94% 35 L / min < / RTI > In this case, the flow rate regulator 27 can adjust the flow rate of the air A111 supplied to the second air purifier 22 to 35 mL or less.

As described above, the air purification module 20d according to the embodiment can control the flow rate of the air A111 supplied to the second air purification portion 22 to a predetermined reference flow rate or less by the flow rate adjustment portion 27 have. Accordingly, in the air purifying module 20d according to the embodiment, even if the flow rate of the air A1 supplied to the first air purifying portion 21 increases, the flow rate adjusting portion 27 controls the second air purifying portion 22 can be adjusted to be equal to or less than a predetermined reference flow rate.

Therefore, in the air purification module according to the embodiment, the oxygen concentration can be advanced at the optimum point where the oxygen concentration efficiency is the best. The second air purifier 22 can concentrate the oxygen so that the oxygen concentration of the air that has passed through the second air purifier 22 is a predetermined concentration, for example, 85% or more.

In addition, since the change in the oxygen concentration is small when the oxygen concentration is within the adsorption capacity of the second air purification unit 22 as compared with the range out of the adsorption capacity of the second air purification unit 22, the oxygen concentration can be stably controlled have.

10 is a graph showing the oxygen concentration with respect to the air flow rate of the air purifying module 20d according to the first and second embodiments. Fig. 11 shows changes in oxygen concentration with time in the air purifying module 20d according to the first and second embodiments. 12A and 12B are graphs for explaining the response speed of the air cleaning module 20d according to the first and second embodiments.

10 to 12B, the air purifying module 20d according to the first and second embodiments includes the first and second air purifying sections 21 and 22 having the same characteristics. The air purifying module 20d according to the second embodiment includes the bypass path 33 and the flow rate adjusting part 27 while the air purifying module 20d according to the first embodiment includes the bypass path 33, And the flow rate regulating portion 27 are not included. The oxygen concentration of the air that has passed through the first air purification unit 21 is 21% and the maximum oxygen concentration 94% when the air flow rate supplied to the second air purification unit 22 is 30 L / min.

10, in the air purifying module 20d according to the first embodiment, the second air purifier 22 is operated at an air flow rate of 60 L / min, which is the same as the air flow rate passed through the first air purifier 21, The oxygen concentration of the air A2 supplied to the battery cell module 10 is 56.5%.

Unlike the first embodiment, in the air purifying module 20d according to the second embodiment, the flow rate control section 27 controls the flow rate of the second air purifying section 21 to 35 L / min, which is a part of the air flow rate passing through the first air purifying section 21, Is supplied to the air purifying section 22 and is supplied to the bypass path 33 at a rate of 25 L / min, which is the remaining air flow rate passed through the first air purifying section 21. [ The air A21 that has passed through the second air purification unit 22 and the air A22 that has passed through the bypass path 33 are mixed and supplied to the battery cell module 10. [ In this case, the oxygen concentration of the air A21 that has passed through the second air purification unit 22 is about 89%, and the oxygen concentration of the air A22 that has passed through the bypass path 33 is equal to the oxygen concentration of the first air purification unit The oxygen concentration of the mixed air A2 supplied to the battery cell module 10 was found to be 60%.

As described above, in the air purifying module 20d according to the second embodiment, by adjusting the flow rate of the air supplied to the second air purifying portion 22, And an increase in oxygen concentration corresponding to 6.2% is observed.

Referring to Fig. 11, the air cleaning module 20d according to the second embodiment shows a smaller change in oxygen concentration with respect to time, as compared with the air cleaning module 20d according to the first embodiment.

As described above, the reason why the oxygen concentration varies with time is that the adsorption performance of the second air cleaning unit 22 is saturated according to the flow rate of the air A111 supplied to the second air cleaning unit 22 This is because the speed varies.

For example, when the air flow rate supplied to the second air purifier 22 according to the first embodiment is 60 L / min, the adsorption performance of the second air purifier 22 can be saturated in only 5 seconds, When the air flow rate supplied to the second air purifier 22 according to the second embodiment is 30 L / min, the adsorption performance of the second air purifier 22 can be saturated when it is 10 seconds.

As described above, in the air purifying module 20d according to the second embodiment, the flow rate of the air A111 supplied to the second air purifying section 22 is smaller than that of the air purifying module 20d according to the first embodiment , The adsorption performance of the second air cleaning unit 22 can be saturated late. Thus, compared with the air purifying module 20d according to the first embodiment, the air purifying module 20d according to the second embodiment can show a small change in oxygen concentration with respect to time variation

Referring to FIG. 12A, in the air purifying module 20d according to the first embodiment, it takes about 110 seconds to adjust the oxygen concentration passing through the air purifying module 20d from about 70% to about 62%. On the other hand, referring to FIG. 12B, in the air purifying module 20d according to the second embodiment, it takes about 22 seconds to adjust the oxygen concentration passing through the air purifying module 20d from about 63% to about 56%. Although the oxygen concentration range is somewhat different, it can be seen that the time required to adjust the oxygen concentration is significantly reduced according to Example 2.

Hereinafter, the configuration of the battery cell module 10 provided in the metal air battery will be described with reference to FIG.

13, the battery cell module 10 includes a housing 11, a negative electrode metal layer 12, a negative electrode electrolyte membrane 13 disposed on the negative electrode metal layer 12, an oxygen barrier layer 13 disposed on the negative electrode electrolyte membrane 13, A layer 14, an anode layer 15 disposed over the oxygen barrier layer 14, and a gas diffusion layer 16 disposed over the anode layer 15.

The housing 11 serves to receive and seal the cathode metal layer 12, the cathode electrolyte membrane 13, the oxygen barrier layer 14, the anode layer 15, and the gas diffusion layer 16.

The negative electrode metal layer 12 functions to store and release metal ions. The cathode metal layer 12 is formed of a metal such as Li, Na, Zn, K, Ca, Mg, Fe, And an alloy composed of two or more of them.

The cathode electrolyte membrane 13 serves to transfer metal ions to the anode layer 15 through the oxygen barrier layer 14. [ For this purpose, the cathode electrolyte membrane 13 may include an electrolyte.

As an example, the electrolyte may be a solid phase including a polymer electrolyte, an inorganic electrolyte, or a composite electrolyte obtained by mixing the electrolyte and the electrolyte, and may be manufactured to be bent.

As another example, the electrolyte may be formed by dissolving a metal salt in a solvent.

The metal salt is _{LiN (SO 2 CF 2 CF 3} ) 2, LiN (SO 2 C 2 F 5) 2, LiClO 4, LiBF 4, LiPF 6, LiSbF 6, LiAsF 6, LiCF 3 SO 3, LiN (SO 2 A lithium salt such as LiC (CF ₃ ) ₂ , LiC (SO ₂ CF ₃ ) ₃ , LiN (SO ₃ CF ₃ ) ₂ , LiC ₄ F ₉ SO ₃ , LiAlCl ₄ or LiTFSI (lithium bis (trifluoromethanesulfonyl) imide) , Other metal salts such as AlCl ₃ , MgCl ₂ , NaCl, KCl, NaBr, KBr, CaCl ₂ and the like may be further added to the above lithium salt.

The solvent can be used without limitation as long as it can dissolve such lithium salts and metal salts. For example, the solvent may be a carbonate-based solvent such as dimethyl carbonate (DMC), an ester-based solvent such as methyl acetate, an ether-based solvent such as dibutyl ether, a ketone-based solvent such as cyclohexanone, A solvent, a phosphine-based solvent such as triethylphosphine, or a mixture of two or more thereof.

The oxygen barrier layer 14 may be one having conductivity to metal ions while preventing the permeation of oxygen. Such an oxygen barrier layer 14 may comprise a flexible polymeric material. For example, the oxygen barrier layer 14 may be a porous separator comprising a porous nonwoven fabric such as a nonwoven fabric of polypropylene material or a nonwoven fabric of polyphenylene sulfide material, a porous film of olefin resin such as polypropylene, or a combination thereof .

The oxygen barrier layer 14 and the cathode electrolyte membrane 13 may be formed as separate layers, but may be formed as a single layer by impregnating an electrolyte in the pores of the porous separator having an oxygen barrier function. For example, the electrolyte formed by mixing polyethylene oxide (PEO) and LiTFSI may be impregnated into the pores of the porous separator to integrate the cathode electrolyte membrane 13 and the oxygen barrier layer 14.

The anode layer 15 may comprise an electrolyte for the conduction of metal ions, a catalyst for the oxidation and reduction of oxygen, a conductive material and a binder. For example, a cathode slurry is prepared by mixing the electrolyte, the catalyst, the conductive material, and the binder described above, followed by adding a solvent, applying the cathode slurry on the oxygen barrier layer 14, . The solvent may be the same as the solvent used in the production of the electrolyte contained in the cathode electrolyte membrane 13.

The electrolyte included in the anode layer 15 may include a lithium salt included in the cathode electrolyte membrane 13 and, optionally, a metal salt.

Wherein the catalyst comprises an oxide of a metal selected from platinum (Pt), gold (Au), silver (Ag), manganese (Mn), nickel (Ni), cobalt (Co), two or more alloys thereof, .

The conductive material may be a carbon-based material having porosity such as carbon black, graphite, graphene, activated carbon, carbon fiber or carbon nanotube; A conductive organic material such as a copper powder, a silver powder, a conductive metal material in the form of a metal powder such as a nickel powder or an aluminum powder, or a polyphenylene derivative, or a mixture of two or more thereof.

The binder may comprise polytetrafluoroethylene (PTFE), polypropylene, polyvinylidene fluoride (PVDF), polyethylene, styrene-butadiene rubber or a mixture of two or more thereof.

The gas diffusion layer 16 serves to uniformly supply the purified air A2 to the anode layer 15. [ However, this gas diffusion layer 16 is an optional component, and may be omitted in the battery cell module 10 as the case may be.

The gas diffusion layer 16 may comprise a metal, ceramic, polymer, carbon material having a porous structure, or a mixture of two or more thereof. The gas diffusion layer 16 has a porous structure, so that the air A2 discharged from the air purification module 20 can be absorbed and diffused smoothly.

As the metal having the porous structure, a foamed metal in the form of a sponge or a metal fiber mat may be used.

As the porous ceramics, a magnesium-aluminum silicate may be used.

As the porous polymer, porous polyethylene or porous polypropylene can be used.

As the porous carbon material, carbon paper, carbon cloth, or carbon felt using carbon fiber may be used.

The battery cell module 10 provided in the metal air battery of the present invention is not limited to the above-described structure, and may have various other structures.

In the above-described embodiment, the metal-air battery is described as an example of the electrochemical cell, but the electrochemical cell is not limited thereto. For example, an electrochemical cell may be another cell capable of generating electrical energy using a chemical reaction, for example, a fuel cell. Here, the chemical reaction of the electrochemical cell may occur as the air purified by the air purification module is supplied to the anode layer.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, . Accordingly, the scope of protection of the present invention should be determined by the appended claims.

10: battery cell module 11: housing
12: cathode metal layer 13: cathode electrolyte membrane
14: oxygen barrier layer 15: anode layer
16: gas diffusion layer
20, 20a, 20b, 20c, 20d: air purification module
21: first air purifier 22: second air purifier
23: third air purifier 25: concentration detector
26: control unit 27: flow rate control unit
29: chambers 31, 32: first and second connecting paths
33: Bypass path
A1, A2, A11, A12: air

Claims (28)

A battery cell module that generates electricity using oxidation of metal and reduction of oxygen; And
And an air purification module that is in fluid communication with the battery cell module and purifies air supplied from the outside to supply the cleaned air to the battery cell module,
Wherein the air-
A first air purifier for filtering the first impurity among a plurality of impurities included in the air introduced from the outside,
And a second air purifier for filtering a second impurity different from the first impurity among the plurality of impurities. The method according to claim 1,
Wherein the air-
A concentration detecting unit for detecting a concentration of at least one impurity among a plurality of impurities contained in the air introduced from the outside,
And a control unit for controlling the operation of the first and second air purifying units based on the information detected by the density detecting unit. The method according to claim 1,
Wherein the plurality of impurities include at least two of water, carbon dioxide, and nitrogen. The method according to claim 1,
Wherein the second air purifier is disposed between the first air purifier and the battery cell module and filters the second impurity from the air that has passed through the first air purifier. The method according to claim 1,
And the second air purifier concentrates oxygen so that the oxygen concentration in the air supplied to the battery cell module is 21% or more. 3. The method of claim 2,
Wherein,
A second power control unit for controlling the first power consumption of the first air cleaning unit based on the information detected by the density detection unit,
And adjusts the second power consumption of the second air cleaning unit based on the adjusted first power consumption of the first air cleaning unit. The method according to claim 6,
Wherein the control unit increases the first power consumption of the first air cleaning unit and reduces the second power consumption of the second air cleaning unit when the concentration of the impurity detected by the concentration detecting unit is increased. The method according to claim 6,
Wherein the control unit reduces the first power consumption of the first air cleaning unit and the second power consumption of the second air cleaning unit when the concentration of the impurity detected by the concentration detection unit is reduced. The method according to claim 1,
Wherein the air-
And a third air purifier for filtering third impurities other than the first and second impurities. The method according to claim 1,
Wherein the first and second air purifiers are disposed in one chamber and filter the first and second impurities from air introduced into the chamber. The method according to claim 1,
The air purification module may be a metal air cell configured to operate in at least two of these methods: pressure swing adsorption (PSA), thermal swing adsorption (TSA), pressure thermal swing adsorption (PTSA), vacuum swing adsorption (VSA) . 12. The method of claim 11,
Wherein the air purification module comprises at least one of an adsorbent and a selective permeable membrane. 13. The method of claim 12,
Wherein the sorbent material is selected from zeolite, alumina, silica gel, metal-organic framework (MOF), zeolitic imidazolate framework (ZIF), activated carbon or a mixture of two or more thereof. The method according to claim 1,
Wherein the metal air cell is a lithium air battery. 6. The method of claim 5,
A first connection path for fluidly connecting the first air purifier and the second air purifier,
A second connection path for fluidly connecting the second air cleaning unit and the battery cell module,
A bypass path that bypasses the second air cleaning unit and fluidly connects the first and second connection paths,
Further comprising a flow rate regulator for regulating a flow rate of air supplied to the second air purifier. 16. The method of claim 15,
Wherein the flow rate regulator is configured to regulate the flow rate of the air supplied by the second air purifier to the flow rate of the air to be concentrated by the second air purifier so as to be equal to or smaller than a maximum air flow rate that can have an oxygen concentration of 95% Adjustable, metallic air cell. 16. The method of claim 15,
Wherein air mixed with air passing through the bypass path and air passing through the second air purifying section is supplied to the battery cell module. 18. A method of operating a metal air battery according to any one of claims 1 to 17,
Filtering the first impurity among the plurality of impurities contained in the air introduced from the outside by the first air purifying unit; And
And filtering a second impurity different from the first impurity among the plurality of impurities by a second air purifying unit. 19. The method of claim 18,
Detecting a concentration of at least one impurity among a plurality of impurities contained in air introduced into the air purification module; And
And controlling the operation of the first and second air purifiers to filter the first and second impurities based on the detected concentration of the impurities. 20. The method of claim 19,
In the step of controlling the operation of the first and second air purifiers,
A second power control unit for controlling the first power consumption of the first air cleaning unit based on the information detected by the density detection unit,
And the second power consumption of the second air cleaning unit is adjusted based on the first power consumption adjusted by the first air cleaning unit. 21. The method of claim 20,
And increasing the first power consumption of the first air cleaning unit and the second power consumption of the second air cleaning unit when the detected concentration of the impurity is increased. 21. The method of claim 20,
And decreases the first power consumption of the first air cleaning unit and the second power consumption of the second air cleaning unit when the detected concentration of the impurity is decreased. 19. The method of claim 18,
Wherein the step of filtering the first impurity and the step of filtering the second impurity proceed sequentially or simultaneously. 19. The method of claim 18,
A part of the air filtered by the first air purifier is supplied to the second air purifier and the rest of the air filtered by the first air purifier is supplied to the bypass path,
Wherein the air filtered by the second air purifier and the air passing through the bypass path are mixed and supplied to the battery cell module. 25. The method of claim 24,
And the flow rate of the air supplied to the second air purification unit is controlled by the flow rate control unit. 26. The method of claim 25,
Wherein the flow rate controller adjusts the flow rate of the air supplied by the second air purifier so that the flow rate of the air supplied by the second air purifier is equal to or smaller than a maximum air flow rate that can have an oxygen concentration of 95% A method of operating a metal air cell in which the flow rate is controlled. A battery cell module that generates electricity using a chemical reaction; And
And an air purification module that is in fluid communication with the battery cell module and purifies air supplied from the outside to supply the cleaned air to the battery cell module,
Wherein the air-
A first air purifier for filtering the first impurity among a plurality of impurities included in the air introduced from the outside,
And a second air purifier for filtering a second impurity different from the first impurity among the plurality of impurities. 28. The method of claim 27,
A first connection path for fluidly connecting the first air purifier and the second air purifier,
A second connection path for fluidly connecting the second air cleaning unit and the battery cell module,
A bypass path that bypasses the second air cleaning unit and fluidly connects the first and second connection paths,
Further comprising a flow rate regulator for regulating a flow rate of air supplied to the second air purifier.

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