JP2017090224A - Gas analysis cell and gas analysis system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a gas analysis cell and a gas analysis system that can efficiently prevent outside air from entering a cell body.SOLUTION: A positive electrode 7 and a negative electrode 8 are arranged in a measurement room 6 of a cell body 2. Between the electrodes 7 and 8, a separator 9 is arranged. The measurement room 6 is closed by attaching cover members 3, 4, 5 to the cell body 2. Between the cell body 2 and the cover members 3, 4, 5, a plurality of seal members 41-45 are provided so that the measurement room 6 is closed. A first gas supply path supplies gas to spaces formed between the seal members 41-45.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a gas analysis cell and a gas analysis system in which a pair of electrodes including a positive electrode and a negative electrode and a diaphragm disposed between the pair of electrodes are provided inside.

  In various batteries (secondary batteries) such as lithium ion batteries, gas is generated from the positive electrode and the negative electrode during discharging or charging, and the gas deteriorates the electrode or the electrolyte, or reduces the efficiency of discharging or charging. There is a case. Therefore, in the research or development of batteries, there are cases in which the relationship between the change in voltage between the positive electrode and the negative electrode and the component and amount of gas generated from the positive electrode and the negative electrode in accordance with the change may be analyzed.

  In such a case, use a positive electrode and a negative electrode formed of the same material as that used in an actual battery, and place the positive electrode and the negative electrode in a cell for gas analysis to perform discharging or charging. Thus, the gas generated in the gas analysis cell is analyzed by an analyzer such as a gas chromatograph (for example, see Non-Patent Document 1 below).

“Electrochemical Test Cell ECC-DEMS User Manual”, EL-CELL, [online], February 11, 2015, [October 28, 2015 search], Internet <URL: http: // el-cell. com / wp-content / uploads / manuals / ECC_DEMS_manual.pdf>

  A measurement chamber is formed in the cell body of the gas analysis cell, and a positive electrode and a negative electrode are arranged in the measurement chamber. The measurement chamber is closed by a cover member attached to the cell body. In order to improve the airtightness of the measurement chamber, a seal member such as an O-ring is provided between the cell body and the cover member.

  However, even when the sealing member as described above is provided, external air may pass through the sealing member and enter the cell body. In particular, since components contained in air such as oxygen are generated as gas in each electrode, there is a problem that analysis cannot be performed accurately if external air is mixed into the generated gas.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a gas analysis cell and a gas analysis system capable of effectively suppressing external air from entering the cell body. .

(1) A cell for gas analysis according to the present invention includes a cell body, a pair of electrodes, a diaphragm, a cover member, a plurality of seal members, and a first gas supply channel. The cell body has a measurement chamber inside. The pair of electrodes includes a positive electrode and a negative electrode disposed in the measurement chamber. The diaphragm is disposed between the pair of electrodes. The cover member is attached to the cell body and closes the measurement chamber. The plurality of seal members are provided between the cell main body and the cover member, and seal the measurement chamber. The first gas supply channel supplies gas to a space formed between the plurality of seal members.

  According to such a configuration, since a plurality of sealing members are provided between the cell main body and the cover member, it is possible to improve the airtightness of the measurement chamber and make it difficult for outside air to enter the cell main body. Furthermore, since the gas is supplied from the first gas supply flow path to the space formed between the plurality of seal members, even if external air flows in, it can be thinned and expelled to the outside. is there. Therefore, it is possible to effectively suppress external air from entering the cell body.

(2) The gas analysis cell may further include a second gas supply channel for supplying a carrier gas into the cell body. In this case, the first gas supply channel may supply the carrier gas to a space formed between the plurality of seal members.

  According to such a configuration, the carrier gas supplied into the cell body is also supplied to the space formed between the plurality of seal members. Therefore, even when the gas supplied into the space enters the cell body, the gas does not adversely affect the analysis, so that the analysis can be performed with high accuracy. In addition, since it is not necessary to prepare a gas different from the carrier gas, the apparatus configuration can be simplified.

(3) The cell body has a pair of collections in which the gas generated on the positive electrode side with respect to the diaphragm and the gas generated on the negative electrode side with respect to the diaphragm are separately collected. May be provided. In this case, the second gas supply channel may supply a carrier gas to at least one of the pair of collection parts.

  According to such a configuration, the gas generated on the positive electrode side with respect to the diaphragm and the gas generated on the negative electrode side with respect to the diaphragm are separately collected in a pair of collection parts, The gas collected by each collection part can be analyzed individually. Therefore, the analysis can be performed with higher accuracy compared to the case where the gases generated on the positive electrode side and the negative electrode side are analyzed without being separated from each other.

(4) A gas analysis system according to the present invention includes the gas analysis cell and a gas analysis unit that analyzes a gas generated in the cell body.

  According to such a configuration, by analyzing the gas generated in the gas analysis cell by the gas analysis unit, it is possible to analyze the components in the gas with higher accuracy.

(5) The gas analysis system does not include the first supply state in which the gas generated in the gas analysis cell is supplied to the gas analysis unit together with the carrier gas, or the gas generated in the gas analysis cell. A supply switching unit that switches to one of the second supply states in which the carrier gas is supplied to the gas analysis unit may be further provided.

  According to such a configuration, continuous analysis can be performed by directly supplying the gas generated in the gas analysis cell together with the carrier gas to the gas analysis unit in the first supply state. Therefore, compared to a configuration in which the gas generated in the gas analysis cell is injected into the gas analysis unit using a syringe, external air is less likely to enter the gas flow path. Thereby, since mixing of air can prevent an analysis result from being influenced, continuous analysis can be performed more accurately.

  In addition, since the gas generated in the gas analysis cell can be supplied to the gas analysis unit for analysis every interval while the supply switching unit is switched, the quantitative analysis of the gas generated at each interval can be performed accurately. It can be carried out.

  Furthermore, if the gas analysis cell is attached to the supply switching unit in the second supply state, piping can be connected in a state where the gas analysis cell does not communicate with the gas analysis unit. As a result, it is not necessary to connect the gas analysis cell via a pipe communicating with the gas analysis unit, so that the installation work is facilitated.

(6) In the first supply state, a carrier gas is supplied to the gas analysis unit through the gas analysis cell, and in the second supply state, the carrier gas is supplied to the gas analysis unit without going through the gas analysis cell. A carrier gas may be supplied.

  According to such a configuration, in the first supply state, the gas generated in the gas analysis cell is directly supplied from the gas analysis cell to the gas analysis unit. Therefore, it is possible to perform analysis with higher accuracy with a simple configuration.

(7) The gas analysis system may further include a buffer unit that accommodates gas generated in the gas analysis cell. In this case, in the first supply state, a carrier gas is supplied to the gas analysis unit via the buffer unit, and in the second supply state, a carrier gas is supplied to the gas analysis unit without passing through the buffer unit. The gas generated in the gas analysis cell may be stored in the buffer unit.

  According to such a configuration, in the second supply state, the gas generated in the gas analysis cell is stored in the buffer unit, and if the gas is subsequently switched from the second supply state to the first supply state, it is stored in the buffer unit. Gas can be supplied to the gas analyzer together with the carrier gas. Therefore, if the configuration is such that more gas can be accommodated in the buffer unit than in the gas analysis cell, more gas can be supplied from the buffer unit to the gas analysis unit. This improves the detection sensitivity and enables more accurate analysis.

  According to the present invention, the air tightness of the measurement chamber can be increased, and external air can be made difficult to enter the cell body, and gas is supplied into the space formed between the plurality of seal members. It is possible to effectively suppress external air from entering the cell body.

It is the perspective view which showed the structural example of the cell for gas analysis which concerns on one Embodiment of this invention. It is the perspective view which looked at the cell for gas analysis of FIG. 1 from the opposite side. It is a disassembled perspective view of the cell for gas analysis of FIG. It is sectional drawing when the cell for gas analysis of FIG. 1 is cut | disconnected in the horizontal direction. It is sectional drawing when the cell for gas analysis of FIG. 1 is cut | disconnected in the perpendicular direction. It is sectional drawing when the cell for gas analysis of FIG. 1 is cut | disconnected in the perpendicular direction, The cross section in the position different from the case of FIG. 5A is shown. It is a schematic plan view for demonstrating operation | movement of a three-way valve | bulb. It is a channel figure showing the example of composition of the gas analysis system concerning a 1st embodiment of the present invention. It is a channel figure showing the example of composition of the gas analysis system concerning a 1st embodiment of the present invention. It is a channel figure showing the example of composition of the gas analysis system concerning a 2nd embodiment of the present invention. It is a channel figure showing the example of composition of the gas analysis system concerning a 2nd embodiment of the present invention.

1. Configuration of Gas Analysis Cell FIG. 1 is a perspective view showing a configuration example of a gas analysis cell 1 according to an embodiment of the present invention. FIG. 2 is a perspective view of the gas analysis cell 1 of FIG. 1 viewed from the opposite side. FIG. 3 is an exploded perspective view of the gas analysis cell 1 of FIG. 4 is a cross-sectional view of the gas analysis cell 1 of FIG. 1 when cut in the horizontal direction. FIG. 5A is a cross-sectional view of the gas analysis cell 1 of FIG. 1 when cut in the vertical direction. 5B is a cross-sectional view when the gas analysis cell 1 of FIG. 1 is cut in the vertical direction, and shows a cross-section at a position different from the case of FIG. 5A.

  The gas analysis cell 1 is for analyzing gas generated from a lithium ion battery which is an example of a secondary battery. In the gas analysis cell 1, the same structure as that of the lithium ion battery is reproduced inside, thereby generating the same gas as that of the lithium ion battery, and the gas can be analyzed by a gas chromatograph or the like.

  The cell 1 for gas analysis includes a cell body 2 and a plurality of cover members 3, 4, 5 attached to the cell body 2. The cell main body 2 and the cover members 3, 4, 5 form a measurement chamber 6 sealed in the cell main body 2. In the measurement chamber 6, a positive electrode 7, a negative electrode 8, a separator (diaphragm) 9, an electrode The guide 10, the first current collector 11, the second current collector 12, the separator gasket 13, the spring 14 and the like are accommodated (see FIG. 3). 4, 5 </ b> A, and 5 </ b> B, the positive electrode 7, the negative electrode 8, the separator 9, and the like are omitted.

  The cell body 2 and the electrode guide 10 are formed by, for example, a peak (PEEK: polyetheretherketone). Each cover member 3, 4, 5, the 1st current collection part 11, the 2nd current collection part 12, and the spring 14 are formed, for example by stainless steel (SUS). The cell body 2 has a plurality of screw shafts 16 erected on the surface on which the cover members 3, 4, and 5 are attached. Each cover member 3, 4, 5 is fixed to the cell body 2 by tightening the nut 17 on the shaft 16.

  At this time, the first current collector 11 is pressed toward the second current collector 12 by the cover member 3 via the spring 14, and the second current collector 12 is pressed toward the first current collector 11 by the cover member 4. Pressed. As a result, the positive electrode 7, the negative electrode 8, and the separator 9 are sandwiched between the first current collector 11 and the second current collector 12. Current collecting rods 18 and 19 made of, for example, stainless steel (SUS) are fixed to the cover members 3 and 4. Thereby, the current collecting rod 18 is electrically connected to the positive electrode 7 via the cover member 3, the spring 14 and the first current collecting portion 11, and the current collecting rod 19 is arranged via the cover member 4 and the second current collecting portion 12. Thus, it is electrically connected to the negative electrode 8.

  The positive electrode 7 is made of, for example, a lithium alloy. The negative electrode 8 is made of, for example, carbon. The positive electrode 7 and the negative electrode 8 have, for example, a disk shape with an outer diameter of 34 mm, and are formed larger than the outer diameter of an actual lithium ion battery. The separator 9 is a porous thin film having an outer diameter of 41 mm made of, for example, polypropylene and has a thickness of, for example, 24 μm. However, the diaphragm disposed between the pair of electrodes 7 and 8 is not limited to the separator 9. The positive electrode 7 and the negative electrode 8 need to be close to each other, and the distance is defined by the thickness of the diaphragm. The said thickness of the separator 9 is only an example, and is not limited to this value. The thickness of the diaphragm is preferably, for example, several hundred μm or less.

  The measurement chamber 6 is filled with, for example, an electrolytic solution made of an organic solvent, and the positive electrode 7, the negative electrode 8, and the separator 9 are immersed in the electrolytic solution. During charging, lithium ions are generated from the positive electrode 7, and the lithium ions pass through the separator 9 and move to the negative electrode 8 side. On the other hand, during discharge, lithium ions on the negative electrode 8 side pass through the separator 9 and move to the positive electrode 7 side.

  When gas is generated from each of the electrodes 7 and 8 while the pair of electrodes 7 and 8 is energized, the gas is captured by the pair of collecting portions 21 and 22 formed in the cell body 2. Be collected. Specifically, the gas generated on the positive electrode 7 side with respect to the separator 9 is collected by the collection unit 21, and the gas generated on the negative electrode 8 side with respect to the separator 9 is collected by the collection unit 22. It has become. In the present embodiment, as described above, the generated gas can be separated into different collectors 21 and 22 while arranging the positive electrode 7 and the negative electrode 8 at a very short distance.

  The applied voltage to the positive electrode 7 and the negative electrode 8 is controlled by a charge / discharge device (not shown). A reference electrode 20 may be provided in the cell body 2 as indicated by a broken line in FIG. 5B. The reference electrode 20 is made of, for example, lithium, which is the same material as the positive electrode 7, and is immersed in the electrolytic solution filled in the measurement chamber 6 by being inserted into the collection unit 21. If the reference electrode 20 is used, the potential measured between the reference electrode 20 and the positive electrode 7 and between the reference electrode 20 and the negative electrode 8 can be analyzed using the voltage measured by the reference electrode 20 as a reference voltage. .

  The first current collector 11 is formed in a cylindrical shape. The end surface on the positive electrode 7 side in the first current collector 11 is a flat surface, and the entire flat surface is in contact with the positive electrode 7. On the other hand, a concave portion 111 for accommodating the spring 14 is formed on the end surface of the first current collector 11 opposite to the positive electrode 7 side, and the spring 14 is accommodated in the concave portion 111 in the state where the spring 14 is accommodated. The first current collector 11 is pressed by the cover member 3 via the spring 14.

  The electrode guide 10 is formed in a cylindrical shape. The inner diameter of the electrode guide 10 is substantially the same as the outer diameter of the first current collector 11, and is arranged in the measurement chamber 6 with the first current collector 11 being inserted into the electrode guide 10. The positive electrode 7 is held in a state of being disposed inside the electrode guide 10. A plurality of openings 15 are formed in the peripheral surface of the electrode guide 10, and these openings 15 communicate with the collection portion 21. Therefore, the gas generated on the positive electrode 7 side with respect to the separator 9 is guided to the collection unit 21 through the opening 15. As a result, the gas generated on the positive electrode 7 side is well collected from the electrode guide 10 through the opening 15 to the collection unit 21.

  The second current collector 12 is configured by integrally forming a small-diameter portion 121 and a large-diameter portion 122 that are each formed in a cylindrical shape on the same axis. The end surface of the small diameter portion 121 opposite to the large diameter portion 122 is a flat surface, and the entire flat surface is in contact with the negative electrode 8 disposed in the measurement chamber 6 outside the electrode guide 10.

  On the inner peripheral surface of the cell main body 2, an arc-shaped recess is formed in a portion facing the small diameter portion 121, and this recess provides a guide path 23 that guides the gas generated on the negative electrode 8 side to the collection portion 22. It is composed. That is, the gas generated on the negative electrode 8 side with respect to the separator 9 is guided to the collection unit 22 via the guide path 23. Thereby, the gas generated on the negative electrode 8 side outside the electrode guide 10 is favorably collected by the collection part 22 through the guide path 23 formed in the cell body 2.

  Thus, in this embodiment, the gas generated on the positive electrode 7 side with respect to the separator 9 and the gas generated on the negative electrode 8 side with respect to the separator 9 are separated into a pair of collecting portions 21, Therefore, the gas collected in each of the collection units 21 and 22 can be analyzed individually. Therefore, the analysis can be performed with higher accuracy compared to the case where the gas generated on the positive electrode 7 side and the negative electrode 8 side is analyzed without being separated from each other.

  A pair of septum holders 31 and 32 made of, for example, stainless steel (SUS) are attached to the cover member 5. Each of the septum holders 31 and 32 is formed in a cylindrical shape, and is attached to the cover member 5 so as to press the disc-shaped septums 33 and 34 at the lower end surfaces thereof (see FIGS. 5A and 5B). One septum holder 31 is opposed to the collecting portion 21 that collects the gas generated on the positive electrode 7 side with a septum 33 interposed therebetween. The other septum holder 32 is opposed to the collecting portion 22 that collects the gas generated on the negative electrode 8 side with the septum 34 interposed therebetween.

  In this way, the pair of collection parts 21 and 22 are closed by the pair of septums 33 and 34, respectively. The septums 33 and 34 are made of, for example, polytetrafluoroethylene (PTFE) or butyl rubber. Thereby, a syringe (not shown) was inserted into each collection part 21 and 22 via a pair of septums 33 and 34, and it was separated and collected by each collection part 21 and 22 with the syringe. Analysis (intermittent analysis) can be performed by individually sucking gas. Such intermittent analysis may be performed by manually operating the syringe, or may be performed by automatically controlling the syringe.

  In the present embodiment, not only the intermittent analysis using the syringe as described above, but also a carrier gas is supplied to each of the collection units 21 and 22, and the gas generated in the cell body 2 is collected together with the carrier gas to each of the collection units. This gas can be analyzed (continuous analysis) by letting it flow out from 21 and 22. Therefore, in each collection part 21 and 22, the inflow ports 211 and 221 into which the carrier gas flows into the collection parts 21 and 22 and the outflow ports 212 and 222 through which the carrier gas flows out from the collection parts 21 and 22 Are formed (see FIG. 3).

  Connectors 213 and 223 are attached to the respective inlets 211 and 221. On the other hand, connectors 214 and 224 are attached to the outlets 212 and 222, respectively. Three-way valves 215, 216, 225, and 226 are connected to the connectors 213, 214, 223, and 224 through pipes, respectively (see FIGS. 1 and 2).

  FIG. 6 is a schematic plan view for explaining the operation of the three-way valves 215, 216, 225, and 226. Gas supply passages (second gas supply passages) 217 and 227 for supplying a carrier gas to the respective inlets 211 and 221 are connected to the three-way valves 215 and 225 communicating with the respective inlets 211 and 221. On the other hand, gas discharge passages 218 and 228 for discharging carrier gas from the respective outlets 212 and 222 are connected to the three-way valves 216 and 226 communicating with the respective outlets 212 and 222.

  A bypass flow path 219 is connected to a pair of three-way valves 215 and 216 that communicate with one collection unit 21. Therefore, the gas supply channel 217 can be communicated with either the collection unit 21 or the bypass channel 219 by switching the three-way valves 215 and 216 constituting the bypass switching unit. Similarly, a bypass channel 229 is connected to a pair of three-way valves 225 and 226 that communicate with the other collection unit 22. Therefore, the gas supply channel 227 can be communicated with either the collection unit 22 or the bypass channel 229 by switching the three-way valves 225 and 226 constituting the bypass switching unit.

  In a state where the gas supply flow paths 217 and 227 are communicated with the collection parts 21 and 22, the gas supply flow paths 217 and 227 and the gas discharge flow paths 218 and 228 are connected via the collection parts 21 and 22, The carrier gas supplied from the supply flow paths 217 and 227 is guided to the collection units 21 and 22 as indicated by an arrow A in FIG. On the other hand, in a state where the gas supply passages 217 and 227 are communicated with the bypass passages 219 and 229, the gas supply passages 217 and 227 and the gas discharge passages 218 and 228 are connected via the collection parts 21 and 22, respectively. Without being connected, and the carrier gas supplied from the gas supply passages 217 and 227 is guided to the gas discharge passages 218 and 228 via the bypass passages 219 and 229 as indicated by an arrow B in FIG.

  Therefore, after the gas supply flow paths 217 and 227 are communicated with the bypass flow paths 219 and 229, the air in the gas supply flow paths 217 and 227 is discharged through the bypass flow paths 219 and 229, and then the gas supply flow paths The carrier gas can be supplied to the collecting units 21 and 22 by connecting the 217 and 227 to the collecting units 21 and 22. Thereby, since it can prevent that the air in the gas supply flow paths 217 and 227 flows into the collection parts 21 and 22 and exerts a bad influence on an analysis, it can analyze more accurately. However, if the bypass switching unit is configured to be able to switch between the gas supply channels 217 and 227 and the collection units 21 and 22 or the bypass channels 219 and 229, the three-way valve 215 It is not limited to 216, 225, 226, and may be composed of other parts.

  Referring again to FIG. 3, seal members 41 and 42 are provided between the cell body 2 and the cover members 3 and 4. The seal member 41 is constituted by an annular O-ring formed by perflo, for example. On the other hand, the seal member 42 is made of, for example, butyl rubber, and is formed of an annular O-ring whose outer periphery is longer than that of the seal member 41.

  Seal members 43, 44, 45 are provided between the cell body 2 and the cover member 5. The seal members 43 and 44 are annular O-rings formed by, for example, perfloation, and the outer periphery of the seal member 44 is longer than the seal member 43. On the other hand, the seal member 45 is made of, for example, butyl rubber, and includes an annular O-ring having a longer outer periphery than the seal member 44.

  Thus, the measurement chamber 6 is sealed with the sealing members 41 to 45. Since a plurality of seal members 41 to 45 are provided between the cell main body 2 and the cover members 3, 4, 5, respectively, the air tightness of the measurement chamber 6 is improved and it is difficult for outside air to enter the cell main body 2. can do. However, the number of seal members provided between the cell body 2 and the cover members 3 and 4 is not limited to two, and may be three or more. Similarly, the number of seal members provided between the cell main body 2 and the cover member 5 is not limited to three, and may be two or four or more. Further, the shape and material of the seal member are not limited to those described above, but may be other shapes and materials.

  Furthermore, in this embodiment, gas is supplied to the space formed between the plurality of seal members 41 to 45 in each cover member 3, 4, 5. Specifically, as shown in FIGS. 1 and 2, two connectors 46 and 47 are attached to the cover member 3, and gas flowing from one connector 46 via the pipe 61 is covered with the cover member 3. After passing through the annular space between the seal member 41 on the third side and the seal member 42, it flows out from the other connector 47. Two connectors 48 and 49 are attached to the cover member 5, and the connector 48 is connected to the connector 47 via a pipe 62. Thereby, the gas flowing out from the connector 47 flows into the connector 48, passes through the annular space between the seal member 44 and the seal member 45, and then flows out from the other connector 49. Two connectors 50 and 51 are attached to the cover member 4, and the connector 50 is connected to the connector 49 via a pipe 63. Thereby, the gas flowing out from the connector 49 flows into the connector 50, passes through the annular space between the sealing member 41 and the sealing member 42 on the cover member 4 side, and then flows out from the other connector 51.

  The connector 51 is connected to a T-shaped tube 52 via a pipe 64, and this T-shaped tube 52 is further connected to connectors 53 and 54 via pipes 65 and 66. The connectors 53 and 54 are attached to the septum holders 31 and 32, respectively. Thereby, the gas flowing out from the connector 51 flows into the septum holders 31 and 32 through the T-shaped tube 52 and the connectors 53 and 54, and is discharged to the outside through the space in the septum holders 31 and 32.

  Thus, the pipes 61, 62, and 63 constitute a gas supply channel (first gas supply channel) that supplies gas to a space formed between the plurality of seal members 41 to 45. Since the gas is supplied from the pipes 61, 62, and 63 to the space formed between the plurality of seal members 41 to 45, even if external air flows in, it can be thinned and expelled to the outside. It is. Therefore, it is possible to effectively suppress external air from entering the cell body 2.

  The gas supplied from the pipe 61 and flowing sequentially to the pipes 62, 63, 64, 65, 66 is the same carrier gas as the carrier gas supplied from the gas supply passages 217, 227 to the collection units 21, 22. Also good. In this case, the carrier gas supplied from a gas supply unit (not shown) may be branched in the middle and guided to the pipe 61. As described above, if the carrier gas supplied into the cell body 2 is also supplied to the space formed between the plurality of seal members 41 to 45, the gas supplied into the space is used. Even when the gas enters the cell body 2, the gas does not adversely affect the analysis, so that the analysis can be performed with high accuracy. In addition, since it is not necessary to prepare a gas different from the carrier gas, the apparatus configuration can be simplified.

2. First Embodiment of Gas Analysis System FIGS. 7A and 7B are flow charts showing a configuration example of a gas analysis system according to the first embodiment of the present invention. The gas analysis system includes the gas analysis cell 1 as described above and a gas analysis unit 100 that analyzes the gas generated in the cell body 2 of the gas analysis cell 1.

  This gas analysis system is for performing continuous analysis using the gas analysis cell 1, and the gas collected in at least one of the pair of collection units 21 and 22 is guided to the gas analysis unit 100. . That is, at least one of the gas in the collection unit 21 discharged from the gas discharge channel 218 and the gas in the collection unit 22 discharged from the gas discharge channel 228 shown in FIG. It becomes the analysis object by. The gas collected by the collection unit 21 and the gas collected by the collection unit 22 are guided to different gas analysis units 100 and analyzed. 7A and 7B, a case where the gas collected by one of the collection unit 21 or the collection unit 22 is analyzed by the gas analysis unit 100 will be described.

  The gas analysis unit 100 includes a flow controller 101, a sample introduction unit 102, a column 103, a detector 104, and the like. For example, helium is used as the carrier gas. A flow controller 101 controls the flow rate of the carrier gas supplied from a gas supply unit (not shown). The carrier gas supplied from the flow controller 101 to the cell 1 for gas analysis is guided to the sample introduction unit 102 together with the gas generated in the cell body 2 and is introduced from the sample introduction unit 102 to the column 103.

  Components contained in the gas introduced into the column 103 are separated while passing through the column 103, and each separated component is detected by the detector 104. As the detector 104, for example, a barrier discharge ionization detector (BID) or a pulse discharge ionization detector (PDD) is used. Thereby, analysis can be performed with higher accuracy using a barrier discharge ionization detector or a pulse discharge ionization detector with high detection sensitivity.

  In particular, the gas generated from the positive electrode 7 and the negative electrode 8 used in batteries includes hydrogen, oxygen, nitrogen, carbon monoxide, carbon dioxide, methane, etc., and is used for barrier discharge ionization detectors and pulse discharges. The ionization detector has high detection sensitivity for these gases, but cannot detect helium. Therefore, if helium is used as the carrier gas and the gas generated in the gas analysis cell 1 is detected by the barrier discharge ionization detector or the pulse discharge ionization detector, the gas analysis is not affected by the component of the carrier gas. A wide variety of gases generated in the working cell 1 can be analyzed with high accuracy. However, the detector 104 is not limited to these, and may be another detector such as a thermal conductivity detector (TCD) or a flame ionization detector (FID). Thermal conductivity detectors are insensitive to all components of hydrogen, oxygen, nitrogen, carbon monoxide, carbon dioxide and methane, while flame ionization detectors are sensitive to methane, Oxygen, nitrogen, carbon monoxide, and carbon dioxide are insensitive, so barrier discharge ionization detectors and pulsed discharge ionization that are sensitive to all components of hydrogen, oxygen, nitrogen, carbon monoxide, carbon dioxide, and methane A detector is more suitable as the detector 104 in this embodiment.

  In the example of FIGS. 7A and 7B, the gas analysis cell 1 is connected between the flow controller 101 and the sample introduction unit 102 via a six-way valve 105 as a supply switching unit. Specifically, among the six ports 151 to 156 provided in the six-way valve 105, the flow controller 101 is connected to the first port 151, and the sample introduction unit 102 is connected to the second port 152. In the gas analysis cell 1, the gas supply channels 217 and 227 are connected to the third port 153, and the gas discharge channels 218 and 228 are connected to the fourth port 154. A flow controller 106 different from the flow controller 101 of the gas analyzer 100 is connected to the fifth port 155, and the sixth port 156 is an exhaust port. The same carrier gas (for example, helium) as the flow controller 101 is supplied from the flow controller 106.

  In the state of FIG. 7A, the first port 151 and the second port 152 are in communication. Therefore, the carrier gas supplied from the flow controller 101 is sent to the sample introduction unit 102 without passing through the gas analysis cell 1, and is supplied from the sample introduction unit 102 to the column 103. In this state, the gas generated in the gas analysis cell 1 is not introduced into the column 103 and only the carrier gas is supplied to the column 103.

  7A, the third port 153 and the fifth port 155 communicate with each other, and the fourth port 154 and the sixth port 156 communicate with each other. Therefore, the carrier gas supplied from the flow controller 106 is supplied into the gas analysis cell 1 through the fifth port 155 and the third port 153, and together with the gas generated in the cell body 2, the fourth port 154 and It is discharged to the outside through the sixth port 156.

  When the hexagonal valve 105 is rotated from this state to a state as shown in FIG. 7B, the first port 151 and the third port 153 communicate with each other, and the second port 152 and the fourth port 154 communicate with each other. In the state of FIG. 7B, the carrier gas from the flow controller 101 is supplied into the gas analysis cell 1 and introduced into the column 103 from the sample introduction unit 102 together with the gas generated in the cell body 2. Further, the fifth port 155 and the sixth port 156 communicate with each other, and the carrier gas from the flow controller 106 is discharged to the outside as it is.

  The state shown in FIG. 7B is a first supply state in which the carrier gas is supplied to the gas analysis unit 100 via the gas analysis cell 1. On the other hand, the state shown in FIG. 7A is a second supply state in which the carrier gas is supplied to the gas analysis unit 100 without going through the gas analysis cell 1. The six-way valve 105 is alternately switched between the first supply state and the second supply state by rotating at a predetermined interval of, for example, about 5 to 40 minutes.

  In the present embodiment, the gas generated in the gas analysis cell 1 is supplied to the gas analysis unit 100 together with the carrier gas by the six-way valve 105 (see FIG. 7B), or in the gas analysis cell 1 It is possible to switch to any one of the second supply states (see FIG. 7A) in which the carrier gas not containing the generated gas is supplied to the gas analysis unit 100. In the first supply state, continuous analysis can be performed by directly supplying the gas generated in the gas analysis cell 1 to the gas analysis unit 100 together with the carrier gas. Therefore, compared with a configuration in which the gas generated in the gas analysis cell 1 is injected into the gas analysis unit 100 using a syringe, external air is less likely to enter the gas flow path. Thereby, since mixing of air can prevent an analysis result from being influenced, continuous analysis can be performed more accurately.

  Further, since the gas generated in the gas analysis cell 1 can be supplied to the gas analysis unit 100 for analysis every interval while the hexagonal valve 105 is switched, the quantitative analysis of the gas generated in each interval can be performed. Can be done accurately.

  Furthermore, if the gas analysis cell 1 is attached to the hexagonal valve 105 in the second supply state shown in FIG. 7A, piping can be connected in a state where the gas analysis cell 1 does not communicate with the gas analysis unit 100. This eliminates the need to connect the gas analysis cell 1 to the gas analysis cell 1 by connecting a pipe communicating with the gas analysis unit 100, thereby facilitating the installation work.

  In particular, in the present embodiment, in the first supply state shown in FIG. 7B, the gas generated in the gas analysis cell 1 is directly supplied from the gas analysis cell 1 to the gas analysis unit 100. Therefore, it is possible to perform analysis with higher accuracy with a simple configuration. However, the supply switching unit is not limited to the six-way valve 105, and may be configured by other valves.

  The gas analysis cell 1 and the hexagonal valve 105 can be adjusted to a relatively high temperature of, for example, room temperature to 90 ° C., more preferably about 80 ° C. Thereby, a strict durability check is possible. The temperature control temperature is set to an appropriate value according to the boiling point of the electrolytic solution in the gas analysis cell 1.

3. Second Embodiment of Gas Analysis System FIGS. 8A and 8B are flow charts showing a configuration example of a gas analysis system according to a second embodiment of the present invention. This gas analysis system is for performing continuous analysis using the gas analysis cell 1 as in the first embodiment, and in the gas analysis cell 1 and the cell body 2 of the gas analysis cell 1. And a gas analyzer 100 for analyzing the generated gas. Since the configuration of the gas analysis unit 100 is the same as that of the first embodiment, the same reference numerals are given to the same configurations, and detailed description thereof is omitted.

  In this gas analysis system, the gas collected in at least one of the pair of collection units 21 and 22 is guided to the gas analysis unit 100 as in the first embodiment. That is, at least one of the gas in the collection unit 21 discharged from the gas discharge channel 218 and the gas in the collection unit 22 discharged from the gas discharge channel 228 shown in FIG. It becomes the analysis object by. The gas collected by the collection unit 21 and the gas collected by the collection unit 22 are guided to different gas analysis units 100 and analyzed. 8A and 8B, a case where the gas collected by one of the collection unit 21 or the collection unit 22 is analyzed by the gas analysis unit 100 will be described.

  8A and 8B, the gas analysis cell 1 and the buffer unit 107 are connected between the flow controller 101 and the sample introduction unit 102 via a six-way valve 105 as a supply switching unit. The buffer unit 107 is a so-called sample tube, and is a hollow member having therein a buffer region larger than the internal volume of the gas analysis cell 1.

  The flow controller 106 is connected to the first port 151 among the six ports 151 to 156 provided in the hexagonal valve 105, and the gas analysis cell 1 is interposed between the flow controller 106 and the first port 151. Has been. That is, the gas supply channels 217 and 227 of the gas analysis cell 1 are connected to the flow controller 106, and the gas discharge channels 218 and 228 are connected to the first port 151. Further, the second port 152 and the fifth port 155 are connected, and the buffer unit 107 is interposed between the second port 152 and the fifth port 155. The sixth port 156 is connected to the flow controller 101, and the fourth port 154 is connected to the sample introduction unit 102. The third port 153 is an exhaust port. The same carrier gas (for example, helium) as the flow controller 101 is supplied from the flow controller 106.

  In the state of FIG. 8A, the fourth port 154 and the sixth port 156 are in communication. Therefore, the carrier gas supplied from the flow controller 101 is sent to the sample introduction unit 102 without passing through the buffer unit 107, and is supplied from the sample introduction unit 102 to the column 103. In this state, the gas generated in the gas analysis cell 1 is not introduced into the column 103 and only the carrier gas is supplied to the column 103.

  8A, the first port 151 and the second port 152 communicate with each other, and the third port 153 and the fifth port 155 communicate with each other. Accordingly, the carrier gas supplied from the flow controller 106 is supplied into the gas analysis cell 1 and passes through the buffer unit 107 via the first port 151 and the second port 152 together with the gas generated in the cell body 2. After that, it is discharged to the outside through the fifth port 155 and the third port 153. Thereby, the gas generated in the cell body 2 is accommodated in the buffer unit 107.

  When the hexagonal valve 105 is rotated from this state to a state as shown in FIG. 8B, the second port 152 and the fourth port 154 communicate with each other, and the fifth port 155 and the sixth port 156 communicate with each other. In the state shown in FIG. 8B, the carrier gas from the flow controller 101 is supplied into the buffer unit 107 and introduced into the column 103 from the sample introduction unit 102 together with the gas in the buffer unit 107. In addition, the first port 151 and the third port 153 communicate with each other, and the carrier gas from the flow controller 106 is directly discharged to the outside through the gas analysis cell 1.

  The state shown in FIG. 8B is a first supply state in which the carrier gas is supplied to the gas analysis unit 100 via the buffer unit 107. On the other hand, the state illustrated in FIG. 8A is a second supply state in which the carrier gas is supplied to the gas analysis unit 100 without using the buffer unit 107. The six-way valve 105 is alternately switched between the first supply state and the second supply state by rotating at a predetermined interval of, for example, about 5 to 40 minutes.

  In the present embodiment, a first supply state (see FIG. 8B) in which the gas generated in the gas analysis cell 1 and accommodated in the buffer unit 107 is supplied to the gas analysis unit 100 together with the carrier gas by the hexagonal valve 105, or The carrier gas that does not contain the gas generated in the gas analysis cell 1 can be switched to one of the second supply states (see FIG. 8A) in which the carrier gas is supplied to the gas analyzer 100. In the first supply state, continuous analysis can be performed by directly supplying the gas generated in the gas analysis cell 1 and accommodated in the buffer unit 107 together with the carrier gas to the gas analysis unit 100. Therefore, compared with a configuration in which the gas generated in the gas analysis cell 1 is injected into the gas analysis unit 100 using a syringe, external air is less likely to enter the gas flow path. Thereby, since mixing of air can prevent an analysis result from being influenced, continuous analysis can be performed more accurately.

  Further, since the gas generated in the gas analysis cell 1 and stored in the buffer unit 107 can be supplied to the gas analysis unit 100 for analysis every interval during which the hexagonal valve 105 is switched, each interval can be analyzed. Quantitative analysis of gas generated in can be performed accurately.

  In particular, in the present embodiment, if the gas generated in the gas analysis cell 1 is stored in the buffer unit 107 in the second supply state shown in FIG. 8A and then switched to the first supply state shown in FIG. The gas stored in the unit 107 can be supplied to the gas analysis unit 100 together with the carrier gas. Therefore, as in the present embodiment, if the configuration is such that more gas can be accommodated in the buffer region in the buffer unit 107 than in the gas analysis cell 1, more gas can be transferred from the buffer unit 107. Since it can supply to the gas analysis part 100, the detection sensitivity in the gas analysis part 100 improves, and it can analyze more accurately.

  The temperature of the gas analysis cell 1, the hexagonal valve 105, and the buffer unit 107 can be adjusted to a relatively high temperature of, for example, room temperature to 90 ° C, more preferably about 80 ° C. Thereby, a strict durability check is possible. The temperature control temperature is set to an appropriate value according to the boiling point of the electrolytic solution in the gas analysis cell 1. Further, for example, a filter (not shown) that does not allow high-boiling substances to pass through is provided in the buffer unit 107, thereby preventing the column 103 from being contaminated.

  In both the first embodiment and the second embodiment, three-way valves 215 and 225 are connected to the gas supply channels 217 and 227 of the gas analysis cell 1, and three-way valves 216 are connected to the gas discharge channels 218 and 228. , 226 are connected (see FIG. 6). The three-way valves 215 and 225 constitute supply side valves that open and close the gas supply passages 217 and 227, and the three-way valves 216 and 226 constitute discharge side valves that open and close the gas discharge passages 218 and 228. Yes.

  Thus, when the gas analysis cell 1 is manufactured, the gas analysis cell 1 is assembled in an environment without air (replaced with a specific gas such as argon or helium), and the supply side valves (three-way valves 215 and 225) are assembled. ) And the discharge side valves (three-way valves 216, 226) are closed, air is not mixed into the gas analysis cell 1 and internal components are not deteriorated. Then, after the work of connecting the gas supply channels 217 and 227 and the gas discharge channels 218 and 228 of the gas analysis cell 1 to the six-way valve 105 is performed, the supply-side valve (three-way valves 215 and 225) and the discharge-side valve If the three-way valves 216 and 226 are switched to the opened state, the attachment work can be easily performed while preventing air from being mixed. However, the supply side valve and the discharge side valve are not limited to the three-way valves 215, 216, 225, and 226, and may be other valves such as a two-way valve.

  In the above embodiment, the configuration in which the electrode guide 10 holds the positive electrode 7 inside has been described. However, the configuration is not limited thereto, and the configuration in which the negative electrode 8 is held inside may be used. In this case, the gas generated on the negative electrode 8 side with respect to the separator 9 may be collected by the collection unit 22 through the opening 15. Further, the guide path 23 is not limited to the configuration in which the gas generated on the negative electrode 8 side with respect to the separator 9 is guided to the collection unit 22, and the gas generated on the positive electrode 7 side with respect to the separator 9 is collected. It may be configured to lead to

  Moreover, in the above embodiment, the gas generated on the positive electrode 7 side with respect to the separator 9 and the gas generated on the negative electrode 8 side with respect to the separator 9 are separated to form a pair of collecting units 21 and 22. The configuration that is collected in the above is described. However, the configuration that increases the pressure in the space by supplying gas to the space formed between the plurality of seal members 41 to 45 is separated into a pair of collecting portions 21 and 22. In such a configuration that the gas generated on the positive electrode 7 side with respect to the separator 9 and the gas generated on the negative electrode 8 side with respect to the separator 9 are collected in one collecting part. Is also applicable. Further, the gas used at this time may be a gas other than the carrier gas.

1 Gas Analysis Cell 2 Cell Body 3, 4, 5 Cover Member 6 Measurement Chamber 7 Positive Electrode 8 Negative Electrode 9 Separator 10 Electrode Guide 11, 12 Current Collector 13 Separator Gasket 14 Spring 15 Opening 16 Screw Shaft 17 Nuts 18, 19 Electrode 20 Reference electrodes 21, 22 Collection unit 23 Guide path 31, 32 Septum holders 33, 34 Septums 41 to 45 Seal members 46 to 51 Connector 52 T-tube 53 Connectors 61 to 65 Piping 100 Gas analysis unit 101 Flow controller 102 Sample Introduction part 103 Column 104 Detector 105 Six-way valve 106 Flow controller 107 Buffer part 211 Inlet 212 Outlet 213, 214 Connector 215, 216 Three-way valve 217 Gas supply passage 218 Gas discharge passage 219 Bypass passage 225, 226 Three-way valve 227 Ga Supply channel 228 gas discharge channel 229 bypass passage

Claims (7)

A cell body having a measurement chamber therein;
A pair of electrodes consisting of a positive electrode and a negative electrode disposed in the measurement chamber;
A diaphragm disposed between the pair of electrodes;
A cover member attached to the cell body and closing the measurement chamber;
A plurality of sealing members provided between the cell main body and the cover member for sealing the measurement chamber;
A gas analysis cell comprising: a first gas supply channel that supplies gas to a space formed between the plurality of seal members. A second gas supply channel for supplying a carrier gas into the cell body;
2. The gas analysis cell according to claim 1, wherein the first gas supply channel supplies the carrier gas to a space formed between the plurality of seal members. The cell body includes a pair of collecting portions that separate and collect a gas generated on the positive electrode side with respect to the diaphragm and a gas generated on the negative electrode side with respect to the diaphragm. ,
3. The gas analysis cell according to claim 1, wherein the second gas supply channel supplies a carrier gas to at least one of the pair of collection parts. A gas analysis cell according to any one of claims 1 to 3,
A gas analysis system comprising: a gas analysis unit that analyzes gas generated in the cell body.   A first supply state in which gas generated in the gas analysis cell is supplied to the gas analysis unit together with a carrier gas, or a carrier gas not containing gas generated in the gas analysis cell is supplied to the gas analysis unit The gas analysis system according to claim 4, further comprising a supply switching unit that switches to any one of the second supply states. In the first supply state, a carrier gas is supplied to the gas analysis unit via the gas analysis cell,
6. The gas analysis system according to claim 5, wherein in the second supply state, a carrier gas is supplied to the gas analysis unit without passing through the gas analysis cell. A buffer unit for storing gas generated in the gas analysis cell;
In the first supply state, a carrier gas is supplied to the gas analysis unit through the buffer unit,
The carrier gas is supplied to the gas analysis unit without passing through the buffer unit in the second supply state, and the gas generated in the gas analysis cell is stored in the buffer unit. 5. The gas analysis system according to 5.

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