KR20180113212A - METHOD AND APPARATUS FOR ANALYZING GAS GENES OF POWERED DEVICE - Google Patents

Abstract

A plurality of sample containers each having an internal pressure lower than that of the test container; a plurality of communication channels communicating the test container and the plurality of sample containers; And a plurality of flow path opening / closing valves are sequentially opened and closed at different timings. The internal gas of the test container is sucked and collected in each of the sample containers at the timing at which the flow path opening / closing valve communicated with the sample container is opened and closed. Then, the internal gas collected at different timings is analyzed for each sample container.

Description

METHOD AND APPARATUS FOR ANALYZING GAS GENES OF POWERED DEVICE

The present invention relates to a method and an apparatus for analyzing a generated gas in a power storage device that collects and analyzes a gas generated from a power storage device.

In recent years, lithium ion batteries and the like have been actively utilized as power storage devices. The lithium ion battery has a feature of high energy density. However, there is still a problem regarding safety such as rapid heat generation. Thus, for example, as in Patent Document 1, an analyzer for analyzing the gas generated during the safety evaluation test and evaluating the safety of the lithium ion battery has been proposed. In this analyzer, as shown in Fig. 6, a power storage device 11 is set in a test container 19 which becomes a sealed voltage booster, and a safety evaluation test is performed to short-circuit the power storage device 11. Fig. The entire amount of the gas generated during the test is collected in the gas bag 71 communicating with the buffer tank 67 through the pipe 65 and analyzed for the gas which has been collected in the gas bag 71. According to this testing apparatus, the total amount of gas generated from the power storage device 11 during the safety evaluation test is collected, and the collected gas is supplied to the analysis after the test.

Japanese Patent Application Laid-Open No. 2011-3513

According to the above-described method, although it is possible to analyze the total generated gas amount and the gas component of the gas generated from the start to the end of the test, there is a problem in that it is not possible to grasp the change over time such as the gas change during the test or the change in each gas component there was.

An object of the present invention is to provide a method and apparatus for analyzing a generated gas of a battery device capable of analyzing a change with time of a gas generated during a test from an electrical storage device while performing a safety evaluation test of the electrical storage device.

The present invention provides a method for analyzing a generated gas of a power storage device described below.

A method for analyzing a generated gas in a power storage device for trapping and analyzing a gas generated from a power storage device,

A plurality of sample containers which are accommodated in the container inside the container and filled with an inert gas; a plurality of sample containers which are held at a lower internal pressure than the test container; And a flow path opening / closing valve provided between the test container and the sample container of the plurality of communication paths, the flow path opening / closing valve is closed to perform a safety evaluation test The flow path opening / closing valves provided in the plurality of communication flow paths are opened and closed at different timings sequentially for each of the communication flow paths, and the flow path opening / closing valve The internal gas of the test container is sucked and collected at the timing of opening and closing The process,

A step of analyzing the internal gas collected at each of the plurality of sample vessels at different timings for each of the sample vessels

Of the power generation device.

The method for analyzing the generated gas of the electrical storage device of the present invention may be the following method.

A method for analyzing a generated gas in a power storage device for trapping and analyzing a gas generated from a power storage device,

And a gas collecting device having a gas discharging passage for discharging an internal gas in the housing of the power storage device is used as the power storage device in the test container accommodating the power storage device in the container, an inert gas supply portion for supplying the inert gas into the housing of the power storage device, Supplying the inert gas from the inert gas supply section to the housing of the power storage device at a specific timing after the start of the safety evaluation test of the power storage device;

A step of analyzing the internal gas discharged in the housing of the power storage device at the specific timing with the supply timing of the inert gas

Of the power generation device.

The present invention also provides a generation gas analysis apparatus for a power storage device described below.

A generated gas analyzing apparatus for a power storage device that collects and analyzes a gas generated from a power storage device,

A test container accommodating the electric storage device inside the container, the inside of the container filled with an inert gas,

A plurality of sample containers held at a lower internal pressure than the test container,

A plurality of communication channels communicating the test container and the plurality of sample containers,

A flow path opening / closing valve provided between the test container and the sample container of the plurality of communication paths,

The flow path opening / closing valves of a plurality of the communication flow paths are opened and closed at different timings for the respective communication flow paths so that the sample container is communicated with the flow path opening / A gas collecting drive unit for sucking and collecting the internal gas of the test vessel,

An analyzer for analyzing the internal gas collected at different timings at each of the plurality of sample containers,

Wherein the power generation device is a power generation device.

The apparatus for analyzing the generated gas of the power storage device of the present invention may be the following apparatus.

A generated gas analyzing apparatus for a power storage device that collects and analyzes a gas generated from a power storage device,

A test container for accommodating the power storage device in a container;

An inert gas supply unit for supplying an inert gas into the housing of the power storage device;

A gas discharge passage through which the internal gas in the housing of the power storage device is discharged,

A gas discharge driving part for supplying an inert gas from the inert gas supply part into the housing of the power storage device at a specific timing and discharging the internal gas to the gas discharge path,

An analyzer for analyzing the internal gas discharged at the specific timing into the gas discharge passage at each specific timing,

Wherein the power generation device is a power generation device.

According to the present invention, it is possible to analyze the change over time of the generated gas in the safety evaluation test of the electrical storage device.

1 is a schematic configuration diagram showing a first configuration example of a generation gas analysis apparatus for a power storage device.
2 is a schematic configuration diagram of the analyzer of the second configuration example.
3 is a graph showing a state of battery surface temperature, atmosphere temperature, and voltage changes over time recorded by a data logger of the analyzer of the first configuration example;
4 is a graph showing changes in the charging depth with voltage, current, battery temperature, and ambient temperature recorded by the data logger of the analyzer of the second configuration example.
5 is a graph showing a result of continuous analysis of a part of the gas generated during the test by the analyzer.
6 is a schematic diagram showing a conventional analyzer.
FIG. 7 is a graph showing changes in voltage, nail penetration depth, cell surface temperature, and ambient temperature with time in a conventional analyzer.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

<First Configuration Example>

1 is a schematic configuration diagram of a generated gas analysis apparatus 100 of a power storage device. The generated gas analyzer (hereinafter abbreviated as an analyzer) 100 of the power storage device collects the gas generated from the power storage device 11 during the safety evaluation test of the power storage device 11, Analyze. The power storage device 11 used here exemplifies a lithium ion battery, but may be a battery of another kind.

The analyzer 100 includes a gas collector 13 for collecting the gas generated from the power storage device 11, an analyzer 15 for analyzing the gas collected by the gas collector 13, a data logger 45).

The gas collector 13 has a test vessel 19 and a single or a plurality of gas collecting lines 21 connected to the test vessel 19. In the test container 19, the electrical storage device 11 is accommodated in the container interior 17, and the inside of the container 17 is filled with the inert gas. In this state, the safety evaluation test of the electrical storage device 11 is carried out. The gas collecting line 21 in the illustrated example has a total of four lines, but the present invention is not limited to this, and any number of gas collecting lines can be arranged.

The gas collecting line (21) has a communication passage (23) extending from the test container (19) or the housing of the power storage device (11). The upstream passage opening / closing valve 27, the sample container 29, and the downstream passage opening / closing valve 31 are disposed in this communication passage 23 in this order from the test container 19 side.

The upstream-side flow path opening / closing valve 27 is an electromagnetic valve that is opened and closed by a drive signal, for example, and restricts the inflow of gas into the sample vessel 29. The sample container 29 is a container for collecting gas, which is connected to a vacuum pump (not shown) or the like, and held at a pressure lower than that of the test container 19. The downstream-side flow path opening / closing valve 31 is closed when the gas is trapped in the sample container 29, and is opened when the trapped gas trapped in the sample container 29 is sent to the analyzer 15.

The tip end of the communication passage 23 on the side of the test container 19 is not only disposed inside the housing of the power storage device 11 as shown in the drawing but also formed in the test container 19 near the outside of the power storage device 11. [ As shown in Fig.

The test vessel (19) is provided with a perforation (33) for performing a nail penetration test, which is one of the safety evaluation tests. The nail polish 33 has a nail portion 33a that pierces the power storage device 11 at its tip end, and the nail portion 33a is supported so as to be movable up and down. The up-and-down movement of the nose portion 33a may be manual, or may be an operation by a driving mechanism such as a motor.

A temperature sensor 35 for detecting the temperature of the power storage device 11 is disposed on the surface of the power storage device 11 housed in the test container 19. [ Inside the test container 19, a temperature sensor 37 for detecting the ambient temperature of the power storage device 11 is disposed. As the temperature sensors 35 and 37, a thermocouple, a thermistor, or the like can be used.

A current voltage detection section 43 for detecting the current and voltage of the power storage device 11 is connected to the electrode terminals 41A and 41B of the power storage device 11. [ The temperature sensors 35 and 37 and the current-voltage detecting unit 43 are connected to the data logger 45. The data logger 45 records the change over time of each output signal of the temperature sensors 35 and 37 and the current-voltage detecting unit 43 connected thereto. Each of the above units is collectively controlled by a gas collecting drive unit (not shown).

Next, a method for analyzing the generated gas using the analyzer 100 having the above configuration will be described.

First, the power storage device 11 to be tested is set in the test container 19. [ A temperature sensor 35 is attached to the surface of the power storage device 11 and a probe of the current and voltage detection portion 43 is attached to the electrode terminals 41A and 41B of the power storage device 11. [ Then, the inside of the container of the test container 19 in which the power storage device 11 is housed is filled with an inert gas such as helium gas or nitrogen gas from an inert gas supply unit (not shown).

On the other hand, with respect to the gas collecting line 21, all of the upstream-side flow path opening / closing valve 27 and the downstream-side flow path opening / closing valve 31 are closed and the internal pressure of the sample vessel 29 is reduced by a vacuum pump I will. At this time, the internal pressure of the sample container 29 is made lower than the internal pressure of the test container 19.

After completion of the preparation process described above, the nail polish 33 is driven to pierce the electrical storage device 11 with the nail portion 33a, and a safety evaluation test is started.

After the start of the safety evaluation test, gas is generated in the housing of the electrical storage device 11. The generated gas is sequentially collected at different timings by a plurality of gas collecting lines (21). This gas collecting method will be described in detail below.

The safety evaluation test is started when all of the upstream-side passage opening / closing valve 27 and the downstream-side passage opening / closing valve 31 are closed. After starting the test, the upstream-side flow path opening / closing valves 27 provided in the plurality of communication flow paths 23 are sequentially opened at different timings. Then, the internal gas in the test container 19 or the housing of the power storage device 11 is sucked through the communication flow path 23 in accordance with the internal pressure of the sample container 29. The sucked gas is introduced into the container of the sample container 29, respectively. Then, the upstream-side flow path opening / closing valve 27 is closed at the time when the inner pressure of the sample vessel 29 becomes atmospheric pressure or after a predetermined time for each gas collection line 21.

Thereby, the sample container 29 of each gas collecting line 21 is supplied with the gas sucked from the test container 19 side at the timing of opening and closing the upstream side flow path opening / closing valve 27 for each gas collecting line 21 Collected. That is, the suctioned gas in the test container 19 or the housing of the power storage device 11 is collected at each of the sample containers 29 at different timings with the passage of time.

Next, the gas collected in each sample container 29 is analyzed by the analyzer 15 for each sample container 29 sequentially. For example, when the sample containers 29 of the plurality of gas collecting lines 21 are moved in the order of the opening and closing operations of the upstream-side flow path opening / closing valves 27 on the time axis, Is set in the analyzer 15, and the collected gas is analyzed.

Analysis of the trapped gas by the analyzer 15 is performed based on at least one of the GC-MS method, the GC method, the IC method, the ICP-AES method, the ICP-MS method, the optical absorption method and the IR method .

The GC-MS (Gas Chromatograph Mass Spectrometry) method is an analysis method using a gas chromatograph-mass spectrometer. According to this method, the chromatogram indicated by the detection time is plotted on the abscissa and the detection intensity is plotted on the ordinate, and gas species are identified from the mass spectrum measured for each separated component based on the chromatogram. The GC (Gas Chromatograph) method is an analysis using the above-mentioned chromatogram.

In the IC (Ichnunochromatography) method, a solution sample is passed through an ion exchange resin to separate ion species contained therein, and electric conductivity is measured. This is a measurement method for quantifying the content of ion species in a sample from the relation line between the electric conductivity and the ion content by the standard solution.

The ICP-AES (Inductively Coupled Plasma Atomic Emission Spectroscopy) method is an emission spectroscopy method using a high frequency inductively coupled plasma (ICP) as a light source. The sample solution is introduced into an Ar plasma in the form of a mist, the light emitted when the excited element returns to the ground state is analyzed, and quantitation is performed from the qualities of the element and the intensity from the wavelength.

Among the above-described analysis methods, an optimum method is selected according to the type of the power storage device 11, the evaluation item, and the evaluation purpose.

The safety evaluation test of the electrical storage device 11 is not limited to the above-mentioned nail penetration test but may be applied to various types of tests such as an overcharge test, a heating test, an external short circuit test, an over discharge test, .

Specifically, for each test, the overcharge test is a test for evaluating the durability against a voltage higher than the charge voltage, for example, UN 38.3.4.7, IEC 62660-2 6.3.2, UL2580 8, UL2271 7.2, SAE2464 4.5.2 , QC / T 743-2006 6.2.12.2, 6.3.8.2, KMVSS 48.6.2, SBA S1101: 2011 8.2.5, and so on.

In the heating test, the single cell of the power storage device is subjected to a heating test by a heater, and the temperature of the cell surface and the temperature of the gas ejected are measured. For example, it is confirmed that after the temperature of the battery is raised at a constant rate, the battery is sufficiently held at that temperature for a long time after reaching a predetermined temperature, and fumes, ignition, and rupture do not occur. The test temperature is, for example, 150 占 폚 in the UL standard (Underwriters Laboratories Inc., UL1642 (lithium battery)) and 130 占 폚 in the lithium secondary battery safety evaluation standard guide (Battery Industry Association).

The external short circuit test is a test for shorting the electrodes of the battery with a small resistance. For example, a test of the following standard can be mentioned. UN 38.3.4.5, IEC 62660-2 6.3.1, UL2580 9, UL2271 7, SAE 2464 4.5.1, QC / T 743-2006 6.2.12.3, 6.3.8.3, KMVSS 48.6.5, SBA S1101: 2011 8.2. One

In the compression test, for example, in the safety standard prescribed in IEC 62133, ignition or the like is not performed even if a weight of up to 13 kN is applied to a flat plate.

Conservation tests are defined in ISO 12405-1, IEC 62660-1, JIS C 8711, QC / T 743 and so on.

The charging / discharging test is a test for evaluating deterioration of a battery by repeatedly performing charging and discharging, and the overdischarge test is a test for evaluating battery deterioration when the battery is left in a discharged state.

According to the analyzer 100 of this configuration, the safety evaluation test of the electrical storage device 11 is performed, and the gas generated from the electrical storage device 11 during the test is sequentially supplied to the plurality of sample containers 29 It can be collected by timing. Since the collected gas is accommodated in each of the sample containers 29, it is possible to analyze the collected gas at each collection timing by irradiating each of the plurality of sample containers 29 with gas. Therefore, it is possible to grasp the gas generation amount and the gas generation component over time during the safety evaluation test, and it becomes possible to quantitatively analyze the generated gas with the lapse of time.

&Lt; Second Configuration Example &

Next, a second configuration example of the generated gas analyzer of the electrical storage device will be described.

2 is a schematic configuration diagram of the analyzer 200 of the second configuration example. In the following description, the same reference numerals are given to the same components or members as those of the analyzer 100 of the above-described first configuration example, and the description thereof is omitted or simplified.

The analyzer 200 according to the present configuration communicates the analyzer 15 with the inside of the housing of the power storage device 11 and the test container 19 in which the power storage device 11 is accommodated, An inert gas supply unit 53, a gas bag 55, and a data logger 45. The communication channel 51, the inert gas supply unit 53, the gas bag 55,

The inert gas supply unit 53 supplies an inert gas into the housing of the power storage device 11 and functions as a gas discharge drive unit. The gas bag 55 collects the gas discharged from the power storage device 11 by the supply of the inert gas.

A branch passage 57 for branching from the communication passage 51 toward the gas bag 55 is provided in the communication passage 51 through which the exhaust gas flows.

The data logger 45 is provided with a temperature sensor 35 provided on the surface of the power storage device 11 and a temperature sensor 37 disposed in the test container 19 for detecting the ambient temperature and connected to the electrode terminals 41A and 41B And various output signals from the current / voltage detection unit 43 are input.

Next, a method for analyzing the generated gas using the analyzer 200 having the above configuration will be described.

First, the power storage device 11 to be tested is set in the test container 19, the temperature sensor 35 is disposed on the surface of the power storage device 11, and the probe of the current- (41A, 41B).

After completing the preparation process described above, the safety evaluation test of the electrical storage device 11 is started. The safety evaluation test of the electrical storage device 11 may be any of a piercing test, an overcharge test, a heating test, an external short circuit test, an over discharge test, a compression test, a charge / discharge test, and a storage test as described above.

After starting the safety evaluation test, gas is generated from the electrical storage device (11). The generated gas is extruded into the communication passage 51 by supplying He gas into the housing of the electrical storage device 11 by the inert gas supply part 53 at a specific timing. The extruded gas is collected in the gas bag 55 and a part thereof is sent to the analyzer 15 for analysis.

In this case, the analysis process by the analyzer 15 is performed based on the GC-MS method or the IR method.

The supply of the inert gas from the inert gas supply unit 53 can be performed sequentially or continuously after the start of the safety evaluation test, and the generated gas can be sequentially sent to the analyzer 15 at different timings with different timings. For this reason, the analyzer 15 can analyze the gas sent from the power storage device 11 at different timings with different timings at different timings. Therefore, it is possible to grasp the gas generation amount and the gas generation component over time during the safety evaluation test, and it becomes possible to quantitatively analyze the generated gas with the lapse of time.

The sending timing of the inert gas supply unit 53 can be arbitrarily changed, and analysis can be performed at desired time intervals. Further, when the gas is supplied continuously from the inert gas supply unit 53, it is possible to perform a time-based analysis for each cycle time of the analysis process of the analyzer 15.

Example

Next, the analysis results of the analyzer 100 of the first configuration example and the analysis device 200 of the second configuration example and the analysis results obtained by collectively analyzing the collected gas during the safety evaluation test as a comparative example .

&Lt; Analysis result by the analyzing apparatus 100 of the first configuration example >

Using the analyzer 100 shown in Fig. 1, a piercing test was conducted as a safety evaluation test on the lithium ion battery of 3Ah as the electricity storage device 11. During the test, the surface temperature of the lithium ion battery and the ambient temperature of the test container (19) were detected by temperature sensors (35, 37) and recorded in the data logger (45). In addition, the battery voltage was also recorded in the data logger 45 by the current-voltage detector 43. The gas generated from the lithium ion battery was supplied to the upstream side flow path opening / closing valve 27 (at the time of the nippering, before the piercing, after the piercing 3 seconds, after the piercing 6 seconds, ) For 3 seconds), a plurality of sample vessels 29 were used to intermittently capture and collect the gas, and the gas generation amount and the generated gas component of the collected gas were analyzed.

The graph of FIG. 3 shows the state of the battery surface temperature recorded by the data logger, the change of the atmosphere temperature and the voltage with time. At about 1.22 minutes after the start of the test, the nail portion 33a of the nail punch 33 started to be pushed into the lithium ion battery, and a short circuit occurred and the voltage began to drop significantly. At the same time, the surface temperature of the lithium ion battery began to rise. The voltage which had once dropped greatly was returned to about 4 V at the point where about 1.4 minutes had elapsed, and was then continuously maintained at around 4 V thereafter. The surface temperature of the lithium ion battery rose from the maximum temperature to about 55 ° C.

The gas generated from the lithium ion battery was intermittently agitated for four hours during the test (prior to the puncture, 3 seconds after the puncture, 6 seconds after the puncture, 6 minutes after the puncture, and 3 seconds of the valve opening time at each time) The results are shown in Table 1. The major components of the generated gas were found to be hydrogen, carbon dioxide, carbon monoxide, methane, ethane, and ethylene. The concentration of each gas was high after 3 seconds of nail piercing, and after 6 hours of piercing, the concentration was half or less, and there was no significant difference from the concentration after 6 minutes of piercing. From this result, it was proved that gas was generated within 3 seconds immediately after the piercing.

&Lt; Analysis result of the analyzer 200 of the second configuration example >

Using the analyzer 200 shown in Fig. 2, the gas generated during the safety evaluation test was collected in a gas bag, and a part of the gas was directly sent to the analyzer for analysis. An overcharging test was conducted using a prismatic lithium ion battery of 5 Ah as the electricity storage device 11. During the test, the surface temperature of the lithium ion battery and the ambient temperature of the test container (19) were detected by temperature sensors (35, 37) and recorded in the data logger (45). The battery voltage and current are detected by the current-voltage detector 43 and recorded in the data logger 45. During the test, the gas generated from the lithium ion battery was sent to the housing of the lithium ion battery through the inert gas supply part 53, and the generated gas was extruded in the housing to be collected in the gas bag. Further, a part of the extruded generated gas was sent to a mass spectrometer, which is an analyzer 15, and analyzed continuously during the test.

The graph of FIG. 4 shows a change in the charging depth with respect to the voltage, current, battery temperature, and ambient temperature recorded in the data logger 45. In addition, the voltage and current scales on the vertical axis of the graph are represented by common values. As shown in Fig. 4, charging started from the discharge state (filling depth: SOC = 0%). The temperature rise of the lithium ion battery started to be observed from around 150% of the SOC, and fuming from the lithium ion battery was observed with a sudden temperature rise near SOC 350%.

Table 2 shows the analysis results of the generated gas collected in the gas bag 55 between the start and the end of the safety evaluation test. Except He of the atmospheric gas, it was found that the main components of the gas generated during the test were CO ₂ , H ₂ , CO, ethane, and diethyl carbonate (DEC). The amounts of generated gases were 0.69 L, 0.66 L, 0.15 L, 0.12 L, and 0.11 L, respectively.

A part of the gas generated during the test was continuously analyzed by the analyzer and the result is shown in Fig. It has been found that CO ₂ is abruptly generated in the vicinity of SOC 150%, and it has also been found that the amounts of CO, methane, and ethane are also increased from these vicinities. By using a gas quantitative analysis of the generated gas collected in the bag 55, the result, it is possible to calculate the amount per measurement interval (220msec), CO ₂ is the later is, SOC 170% was up to SOC 130% amount is substantially 0 It has been found that there is an occurrence of 20 to 25 mu L per measurement interval.

&Lt; Configuration of Analyzing Apparatus of Comparative Example &

Fig. 6 is a reference diagram showing a schematic configuration of an analyzer as a comparative example.

The analyzing apparatus 300 of the comparative example has a structure in which the nail polish 33 having the nail portion 33a is mounted on the frame 63 provided on the lifting frame 61 and the test container 19 accommodated in the container, A buffer tank 67 communicating with the test vessel 19 through a pipe 65 and a gas bag 71 communicating with the buffer tank 67 through a pipe 69. [ An inert gas can be supplied to the test vessel (19) through a pipe (73).

The analyzer 300 accumulates the total amount of the gas generated from the power storage device 11 in the test container 19 during the safety evaluation test as the nail drilling test and sends the gas in the test container 19 to the test container 19 to the gas bag 71 communicating with the buffer tank 67 through the piping 65. [ Then, the gas containing the generated gas from the power storage device 11 stored in the gas bag 71 is analyzed using an analyzer (not shown).

&Lt; Analysis result by analyzing apparatus of comparative example >

Using the analyzer 300 having the above-described configuration, a piercing test was conducted on a lithium ion battery of 5 Ah. During the test, the surface temperature of the lithium ion battery and the ambient temperature of the test container (19) were measured in a thermocouple and recorded in a data logger. The battery voltage was also recorded in a data logger. All the gases generated during the test were collected in the gas bag 71 to analyze the collected gas (gas generation amount and generated gas component).

Fig. 7 is a graph showing a time change of voltage, nail penetration depth, cell surface temperature, and ambient temperature recorded in a data logger. In addition, the scale of nail penetration depth and temperature on the graph's longitudinal axis is shown as a common value. According to this recording result, it was thought that the nail was started to be punctured into the lithium ion battery in the vicinity of about 0.13 minutes, and at the same time, the battery voltage began to drop, and the battery temperature and the temperature in the container were observed to rise. At about 0.3 minutes, the voltage was zero.

The gas collected in the gas bag 71 was analyzed by an analyzer and it was found that the main components of the trapping gas were H ₂ , CO, CO ₂ , CH ₄ and C ₂ H ₄ . It was also found that the total amount of generated gases was about 8 L and that the amounts thereof were H ₂ : 0.10 L, CO: 1.3 L, CO ₂ : 4.0 L, CH ₄ : 0.28 L and C ₂ H ₄ : 1.1 L, . However, a change with time of each gas component and the amount of gas generation is unclear.

The present invention is not limited to the above-described embodiments, but it is also contemplated by the present invention that a person skilled in the art changes and applies them on the basis of combinations of the configurations of the embodiments, description of the specification, and well- , And are included in the scope of seeking protection.

As described above, the following matters are disclosed in this specification.

(1) A method for analyzing a generated gas in a power storage device for trapping and analyzing a gas generated from the power storage device,

A plurality of sample containers which are accommodated in the container inside the container and filled with an inert gas; a plurality of sample containers which are held at a lower internal pressure than the test container; And a flow path opening / closing valve provided between the test container and the sample container of the plurality of communication paths, the flow path opening / closing valve is closed to perform a safety evaluation test The flow path opening and closing valves provided in the plurality of communication flow paths are opened and closed at different timings sequentially for each of the communication flow paths and the flow path opening and closing valve The internal gas of the test container is sucked and collected at the timing of opening and closing A step,

A step of analyzing the internal gas collected at each of the plurality of sample vessels at different timings for each of the sample vessels

Of the power generation device.

According to the method for analyzing the generated gas of the electrical storage device, the internal gas of the test container is sucked at different timings at different timings and is collected in the sample container. The gas collected in these sample containers is analyzed for each sample container by the analyzer. Therefore, it is possible to analyze the change over time of the generated gas.

(2) The step of analyzing the internal gas is a step of analyzing based on at least one of the GC-MS method, the GC method, the IC method, the ICP-AES method, the ICP-MS method, the optical absorption method, ) &Lt; / RTI &gt;

According to the method for analyzing the generated gas of the power storage device, various analysis methods are selectively performed, thereby enabling desired analysis of the generated gas.

(3) A method for analyzing a generated gas in a power storage device for capturing and analyzing a gas generated from an electrical storage device,

And a gas collecting device having a gas discharging passage for discharging an internal gas in the housing of the power storage device is used as the power storage device in the test container accommodating the power storage device in the container, an inert gas supply portion for supplying the inert gas into the housing of the power storage device, Supplying the inert gas from the inert gas supply section to the housing of the power storage device at a specific timing after the start of the safety evaluation test of the power storage device;

A step of analyzing the internal gas discharged in the housing of the power storage device at the specific timing with the supply timing of the inert gas

Of the power generation device.

According to the method for analyzing the generated gas of the power storage device, the internal gas in the housing of the power storage device is extruded at different timings with time and analyzed by the analyzer. Therefore, it is possible to analyze the change over time of the generated gas.

(4) A method for analyzing a generated gas in a power storage device according to (3), wherein the step of analyzing the internal gas is a step of analyzing based on a GC-MS method or an IR method.

According to the method for analyzing the generated gas of the power storage device, various analysis methods are selectively performed, thereby enabling desired analysis of the generated gas.

(5) The above safety evaluation test is carried out in the same manner as in (1) to (4), which is at least one of tests for piercing test, overcharge test, heating test, external short circuit test, A method for analyzing a generated gas in any one of power storage devices.

According to the method for analyzing the generated gas of the electrical storage device, it is possible to analyze the change with time of the gas generated in various safety evaluation tests.

(6) The method for analyzing generated gas of any one of (1) to (5), wherein the step of analyzing the internal gas is a step of obtaining at least one of a generated gas atmosphere and a gas component.

According to the method for analyzing the generated gas of the power storage device, it is possible to obtain a change with time of the gas and a change with time of the gas component of the generated gas.

(7) A generated gas analyzing apparatus for a power storage device that collects and analyzes gas generated from the power storage device,

A test container accommodating the electric storage device inside the container, the inside of the container filled with an inert gas,

A plurality of sample containers held at a lower internal pressure than the test container,

A plurality of communication channels communicating the test container and the plurality of sample containers,

A flow path opening / closing valve provided between the test container and the sample container of the plurality of communication paths,

The flow path opening / closing valves of a plurality of the communication flow paths are opened and closed at different timings for each of the communication flow paths, and the sample container, which is in communication with the flow path opening / A gas collecting drive unit for sucking and collecting the internal gas of the test vessel,

An analyzer for analyzing the internal gas collected at different timings at each of the plurality of sample containers,

Wherein the power generation device is a power generation device.

(8) A generated gas analyzing device for a power storage device that collects and analyzes gas generated from a power storage device,

A test container for accommodating the power storage device in a container;

An inert gas supply unit for supplying an inert gas into the housing of the power storage device;

A gas discharge passage through which the internal gas in the housing of the power storage device is discharged,

A gas discharge driving part for supplying an inert gas from the inert gas supply part into the housing of the power storage device at a specific timing and discharging the internal gas to the gas discharge path,

An analyzer for analyzing the internal gas discharged at the specific timing into the gas discharge passage at each specific timing,

Wherein the power generation device is a power generation device.

The present application is based on Japanese Patent Application (Japanese Patent Application No. 2016-66849) filed on March 29, 2016, the contents of which are incorporated herein by reference.

11: Power storage device
13: Gas collector
15: Analyzer
17: Inside the container
19: Test vessel
21: Gas collection line
23:
27: upstream-side flow path opening / closing valve (flow path opening / closing valve)
29: Sample container
31: downstream-side flow path opening / closing valve
33: Nail polish study
33a:
35, 37: Temperature sensor
41A, 41B: electrode terminal
43: Current voltage detector
45: Data logger
51: communication channel (gas discharge channel)
53: Inert gas supply part (gas discharge drive part)
55: gas bag
57: Branching Euro
100, 200: Analyzing apparatus (generating gas analyzing apparatus of electric storage device)

Claims (9)

A method for analyzing a generated gas in a power storage device for trapping and analyzing a gas generated from a power storage device,
A plurality of sample containers which are accommodated in the container inside the container and filled with an inert gas; a plurality of sample containers which are held at a lower internal pressure than the test container; And a flow path opening / closing valve provided between the test container and the sample container of the plurality of communication paths, the flow path opening / closing valve is closed to perform a safety evaluation test The flow path opening and closing valves provided in the plurality of communication flow paths are opened and closed at different timings sequentially for each of the communication flow paths and the flow path opening and closing valve The internal gas of the test container is sucked and collected at the timing of opening and closing A step,
A step of analyzing the internal gas collected at each of the plurality of sample vessels at different timings for each of the sample vessels
Of the power generation device. The method according to claim 1, wherein the step of analyzing the internal gas comprises the step of analyzing based on at least one of GC-MS method, GC method, IC method, ICP-AES method, ICP-MS method, A method for analyzing a generated gas in a power storage device. A method for analyzing a generated gas in a power storage device for trapping and analyzing a gas generated from a power storage device,
And a gas collecting device having a gas discharging passage for discharging an internal gas in the housing of the power storage device is used as the power storage device in the test container accommodating the power storage device in the container, an inert gas supply portion for supplying the inert gas into the housing of the power storage device, Supplying the inert gas from the inert gas supply section to the housing of the power storage device at a specific timing after the start of the safety evaluation test of the power storage device;
A step of analyzing the internal gas discharged in the housing of the power storage device at the specific timing with the supply timing of the inert gas
Of the power generation device. The method according to claim 3, wherein the step of analyzing the internal gas is a step of analyzing based on a GC-MS method or an IR method. The safety evaluation test according to any one of claims 1 to 4, wherein the safety evaluation test is at least one of a nailing test, an overcharge test, a heating test, an external short circuit test, an over discharge test, Of the power generation device. The method according to any one of claims 1 to 4, wherein the step of analyzing the internal gas is a step of obtaining at least one of a generated gas atmosphere and a gas component. The method according to claim 5, wherein the step of analyzing the internal gas is a step of obtaining at least one of a generated gas atmosphere and a gas component. A generated gas analyzing apparatus for a power storage device that collects and analyzes a gas generated from a power storage device,
A test container accommodating the electric storage device inside the container, the inside of the container filled with an inert gas,
A plurality of sample containers held at a lower internal pressure than the test container,
A plurality of communication channels communicating the test container and the plurality of sample containers,
A flow path opening / closing valve provided between the test container and the sample container of the plurality of communication paths,
The flow path opening / closing valves of a plurality of the communication flow paths are opened and closed at different timings for each of the communication flow paths, and the sample container is connected to the flow path opening / A gas collecting drive unit for sucking and collecting the internal gas of the test vessel,
An analyzer for analyzing the internal gas collected at different timings at each of the plurality of sample containers,
Wherein the power generation device is a power generation device. A generated gas analyzing apparatus for a power storage device that collects and analyzes a gas generated from a power storage device,
A test container for accommodating the power storage device in a container;
An inert gas supply unit for supplying an inert gas into the housing of the power storage device;
A gas discharge passage through which the internal gas in the housing of the power storage device is discharged,
A gas discharge driving part for supplying an inert gas from the inert gas supply part into the housing of the power storage device at a specific timing and discharging the internal gas to the gas discharge path,
An analyzer for analyzing the internal gas discharged at the specific timing into the gas discharge passage at each specific timing,
Wherein the power generation device is a power generation device.

Images