JPH0829408A - Background removing device - Google Patents

Abstract

PURPOSE:To reduce the change in moving phase flow rate by doubling a removing liquid passage with an ion excgange memberane, and arranging electrodes in a passage which is not in contact with a moving phase. CONSTITUTION:An eluate containing moving phase of a measurement object component flows from a moving phase introducing port 31b to a groove 38a partitioned by an ion exchange memberane in the background removing device. Removing liquid respectively introduced (31c and 32b) to grooves 36a and 40a flows in the counter current direction to a moving phase, and flows in grooves 34a and 42a which are not in contact with the moving phase. When voltage is impressed on electrodes 50 and 51 arranged in these grooves 34a and 42a, an ion in the moving phase is attracted to the (-) electrode 51, and exchanges an ion with an ion of the removing liquid through a sheet 39 of the exhange memberane. Liquid containing this component elutes from a groove 38a. Liquid containing the removing liquid whose ion is exchanged with a cation in eluate elutes from the grooves 34a and 42a. In this case, a gas generating place is the grooves 34a and 42a arranged in the electrodes 50 and 51, and sheets 37 and 39 sandwiching the groove 38a in which the moving phase flows, are not influenced. Therefore, the channge in moving phase flow rate is reduced, and a base line noise is not generated, too.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a background removal device used in an ion analysis device.

[0002]

2. Description of the Related Art Next, a conventional example will be described with reference to the drawings.
FIG. 5 is an exploded perspective view of a conventional background removal device. In the figure, 1 and 2 are a first substrate and a second substrate made of polypropylene, for example. Projections 1a and 2a (projections 1a are not shown) are formed on the first and second substrates 1 and 2. Further, the first substrate 1 is formed with a mobile phase inlet 1b, a mobile phase outlet 1b ', a removing liquid first inlet 1c, and a removing liquid first outlet 1c'. In addition, the second substrate 2 has a second introduction port 2 for removing liquid.
b and a second outlet 2b 'for removing liquid are formed. Three
Is a first sheet of a sheet-like permeable and permeable membrane that allows air bubbles generated on the electrode surface to pass therethrough, 4 is a Teflon second sheet having a groove 4a serving as a removal liquid passage formed in the central portion, and 5 is a sheet-like ion A third sheet of an exchange membrane, 6 is a Teflon fourth sheet in which a groove 6a serving as a mobile phase channel is formed in the central portion,
Reference numeral 7 is a fifth sheet of ion exchange membrane, and 8 is a Teflon-made sixth sheet in which a groove 8a serving as a removing liquid channel is formed in the central portion.
The sheet 9 is a seventh sheet-like air-permeable permeable membrane that allows air bubbles generated on the electrode surface to pass therethrough.

In the groove 4a of the second sheet 4, a woven net-shaped first electrode 10 having the same shape as the groove 4a is provided, and in the groove 8a of the sixth sheet 8.
The second electrodes 11 having the same shape as the grooves 8a and having a woven mesh shape are provided in each of them. A voltage is applied to these electrodes 10 and 11 via lead wires 10a and 11a.

Then, the first substrate 1, the first to seventh sheets 3 to 9 and the second substrate 2 are laminated and sandwiched by screws 12. Next, the operation of the apparatus having the above configuration will be described. Of the three chambers (groove 4a, groove 6a, groove 8a) partitioned by the third sheet 5 and the fifth sheet 7 of the ion exchange membrane,
The mobile phase (eluent containing the component to be measured or liquid to be measured, which is eluted from the separation column) flows through the groove 6a via the mobile phase inlet 1b. On the other hand, the removing liquid (for example, H ₂ O) flows through the removing liquid introducing ports 1c and 2b in the grooves 4a and 8a in a countercurrent direction to the mobile phase.

In this state, for example, when a cation exchange membrane is used for the fifth and third sheets 7 and 5, the first electrode 10
When a voltage is applied to these electrodes 10 and 11 so that the positive electrode is positive and the second electrode 11 is negative, the ions (for example, Na ⁺ ions) in the mobile phase of the groove 6a become negative second electrode 1
Drawn to 1. At the same time, ion exchange is performed with the ion species (for example, H ⁺ ions) having the same charge as the ions contained in the removing solution through the fifth sheet 7 which is an exchange membrane.

At this time, the eluent from the separation column and the component to be measured (eg Cl ⁻ ion) in the liquid to be measured are attracted to the first electrode 10 having the opposite polarity, but the same charge as that of the ion exchange membrane. Since it has a groove, ion exchange is not performed, and the groove 6a
Remains.

For this reason, the liquid eluted from the groove 6a is ion-exchanged, and the counter ion is, for example, H ⁺ type. , HCl), which elutes from the grooves 4a, 8a, becomes a Na + type removal liquid by ion exchange with cations in the eluent or the liquid to be measured (for example, NaO).
H) and a surplus removal liquid (for example, H ₂ O) become a high conductivity liquid, and the conductivity background of the eluent can be removed.

[0008]

However, in the background removing device having the above structure, the first electrode 10 and the second electrode
H ₂ or O ₂ gas is generated on the electrode surface, and these gases press the third and fifth sheets 5 and 7 to flow the mobile phase between the third and seventh sheets 5 and 7. Fluctuates,
There is a problem that baseline noise occurs.

Further, since the sheets between the first substrate 1 and the second substrate 2 are thin and are simply laminated, it is difficult to laminate the sheets. The present invention has been made in view of the above problems, and an object of the first invention is to provide a background removal device in which fluctuations in mobile phase flow rate are small and baseline noise is small.

A second object of the present invention is to provide a background removing device which is easy to assemble and can easily replace a sheet.

[0011]

Means for Solving the Problems A first method for solving the above problems is described below.
Of the present invention, a first sheet, a second sheet in which a groove is formed in the central portion and a first electrode is provided in the groove, a third sheet of an ion exchange membrane, and a fourth sheet having a groove in the central portion. A fifth sheet of an ion exchange membrane, a sixth sheet having a groove in the center, a seventh sheet of an ion exchange membrane, an eighth sheet having a groove in the center, and a ninth sheet of an ion exchange membrane A first electrode having a groove formed in a central portion and a second electrode provided in the groove.
The 0th sheet and the 11th sheet are laminated, and the upper and lower sides thereof are sandwiched between a first substrate having a groove formed on the surface in contact with the first sheet and a second substrate having a groove formed on the surface contacting with the seventh sheet. And the mobile phase is flowed through the groove of the eighth sheet sandwiched between the seventh and ninth sheets, and sandwiched between the groove of the fourth sheet sandwiched between the third and fifth sheets and the seventh and ninth sheets. The removing liquid is caused to flow in the groove of the eighth sheet in the direction opposite to the mobile phase, and the removing liquid flowing through the groove of the fourth sheet is treated as the first and third
Flow into the groove of the second sheet sandwiched between the sheets of
The removing liquid flowing through the sheet is caused to flow into the groove of the tenth sheet sandwiched between the ninth and eleventh sheets.

A second aspect of the present invention is a background removing apparatus comprising a sheet having a groove in which a mobile phase flows in the central portion and two ion exchange membrane sheets provided so as to sandwich the sheet, The three sheets are previously bonded with an adhesive.

[0013]

In the background removing apparatus of the first invention, the gas is the groove of the first sheet provided with the electrodes and the first sheet.
It occurs in the groove of the 0th sheet and does not affect the 5th and 7th sheets sandwiching the groove of the 6th sheet through which the mobile phase flows.

Therefore, the fluctuation of the mobile phase flow rate is small and no baseline noise is generated. In the background removal device of the second aspect of the invention, the three sheets are adhered with an adhesive, so that the assembly work is easy and the exchange of the sheets is also easy.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT An embodiment of the present invention will be described with reference to the drawings. 1 is an exploded perspective view of an embodiment of the present invention, and FIG. 2 is FIG.
FIG. 3 is an overall configuration diagram of an ion analyzer provided with the background removal device shown in FIG. 3, and FIG. 3 is a diagram for explaining the operation in FIG.

First, the overall structure of the ion analyzer will be described with reference to FIG. In the figure, 21 is an eluent tank in which the eluent is stored, 22 is an eluent suctioned from the eluent tank 21,
It is a pump that pressure-feeds the sample injector 23. Sample injector 2
3 collects a predetermined amount of sample liquid, and conveys the collected sample liquid to the separation column 24 as an eluent.
The separation column 24 is filled with an ion exchange resin and separates and elutes the ions contained in the injected fluid.

28 is a removing liquid tank in which the removing liquid is stored, 29
Is a pump that sucks the removal liquid from the removal liquid tank 28 and pressure-feeds it to the background removal device 26. Reference numeral 25 is an AC power supply that applies an AC voltage to the electrodes of the background removal device 26, and 27 is a detector that detects the electrical conductivity of the eluent from the background removal device 26.

Next, the structure of the background removing device 26 will be described with reference to FIG. Reference numerals 31 and 32 are a first substrate and a second substrate made of a hard resin such as polypropylene and polyethylene. Grooves 31a and 32a (the groove 31a is not shown) are formed in the first and second substrates 31 and 32. Further, the first substrate 31 has a mobile phase inlet 31b, a mobile phase outlet 31b ', a removing liquid first inlet 31c, a removing liquid first outlet 31c', and a returning removing liquid first inlet. Port 31d and first removal port 3 for return removal liquid
1d 'is formed. Further, the second substrate 2 has a second removal liquid inlet 32b, a second removal liquid outlet 32b ', a second return removal liquid inlet 32c, and a second return removal liquid outlet 3c.
2c 'is formed. 33 is a first sheet of a sheet-like breathable permeable membrane that allows air bubbles generated on the electrode surface to pass therethrough, and 3
4 is a second sheet made of, for example, Teflon having a groove 34a serving as a return removing liquid passage formed in the central portion, 35 is a third sheet of a sheet-shaped ion exchange membrane, and 36 is a groove 36a serving as a removing liquid passage in the central portion. Formed of, for example, a Teflon-made fourth sheet, 37 is a sheet-shaped ion-exchange membrane fifth sheet, and 38 is a Teflon-made sixth sheet having a groove 38a which is a groove for a mobile phase channel formed in the central portion. A sheet, 39 is a sheet-shaped ion-exchange membrane seventh sheet, 40 is a Teflon-made eighth sheet in which a groove 40a serving as a removal liquid passage is formed in the central portion, and 41 is a sheet-shaped ion-exchange membrane ninth. Seat, 42
Is a tenth sheet made of, for example, Teflon having a groove 42a serving as a return removal liquid passage formed in the central portion, and 43 is a sheet-like breathable permeable membrane 11th sheet that allows the bubbles generated on the electrode surface to pass therethrough.
It is a sheet.

The groove 34a of the second sheet 34 has a groove 34a.
The woven net-shaped first electrode 50 having the same shape as that of the tenth sheet 4
The second groove 42a has a second woven mesh shape having the same shape as the groove 42a.
Electrodes 51 are arranged respectively. These electrodes 50,
A voltage is applied to 51 via lead wires 50a and 51a.

Also, these first to eleventh sheets 33 to 43
Are pre-laminated, with hot melt sheets between each sheet
(Thermolite 9400: Polyolefin type) is installed, and pressure,
By heating (about 100 ° C., about 10 minutes), each sheet was bonded.

Then, these first substrate 31, first to eleventh
The sheets 33 to 43 and the second substrate 32 are laminated and sandwiched by the screws 52 to prevent liquid leakage between the sheets.

Next, the operation of the apparatus having the above structure will be described.
First, the entire ion analyzer will be described with reference to FIG. The eluent is sucked up from the eluent tank 21 by the pump 22 and sent to the sample injector 23. Sample injector 23
The sample is sandwiched between the eluents and is sent to the separation column 24. In the separation column 24, the sample is separated into each ion and sent to the background removing device 26 together with the eluent. The background is reduced in the background removing device 26, and the conductivity of each ion is increased and sent to the detector 27, where ion analysis is performed, and after the analysis, it is discarded as waste liquid.

On the other hand, the removing liquid is sucked up from the removing liquid tank 28 by the pump 29, and the removing liquid enters the background removing device 26. At that time, the flow of the removing liquid is branched into two streams, each of which is caused to flow countercurrently with the eluent, and further,
The structure is such that they flow in the same direction. Then, the removal liquid that has exited the background removal device is drained.

Next, the background removing apparatus of this embodiment will be described with reference to FIG. Ion exchange membrane third sheet 35, fifth sheet 37, seventh sheet 39, ninth sheet 41
5 rooms separated by (groove 34a, groove 36a, groove 38
a, grooves 40a, 42a), in the groove 38a, an eluent or a liquid to be measured containing a mobile phase (a component to be measured (eg, Cl ⁻ ions) eluted from a separation column) via a mobile phase inlet 31b. (Eg, Na ₂ CO ₃ containing NaCl) flows. On the other hand, the removal liquid introduction ports 31c and 32b are provided in the grooves 36a and 40a.
The removal liquid (for example, H ₂ O) flows countercurrently to the mobile phase through the groove, and the removal liquid flowing through these grooves 36 a and 40 a is removed by the groove 34.
a, 42a.

In this state, for example, the first electrode 50 is
These electrodes 5 so that the second electrode 51 is negative
When a voltage is applied to 0 and 51, the ions in the mobile phase of groove 38a
On (for example, Na⁺Ion) is the negative second electrode 51
Be attracted to. At the same time, the removal solution (e.g., H₂Included in O)
Ion species with the same charge as the ion being stored (for example, H ⁺
(Ions) and ions through the seventh sheet 39, which is an exchange membrane.
Exchange.

At this time, the eluent from the separation column or the component to be measured (eg Cl ⁻ ion) in the liquid to be measured is attracted to the first electrode 50 having the opposite polarity, but the same charge as that of the ion exchange membrane. Since it has a groove, ion exchange is not performed and the groove 38
remain in a.

Therefore, the liquid eluted from the groove 38a is ion-exchanged, and the counter ion is, for example, an H ⁺ -type component.
A liquid (eg H ₂ CO ₃ ) containing (eg HCl) and having a background of conductivity removed. Also, the grooves 34a, 4
The liquid that elutes from 0a includes a removing liquid (for example, NaOH) that has become Na ⁺ type by ion exchange with cations in the eluent and the liquid to be measured (for example, NaOH) and an excess removing liquid (for example, H ₂ O). It becomes a liquid with high conductivity. As a result, it is possible to remove the conductivity background of the eluent.

By the way, in this embodiment, the removing liquid is used as the groove 36.
After flowing through the a and 40a, it is returned again to the groove 34a provided with the first electrode 50 and the groove 42a provided with the second electrode 51a. Therefore, the gas is generated in the groove 3
Since they are 4a and 42a, they do not affect the fifth sheet 37 and the seventh sheet 39 sandwiching the groove 38a through which the mobile phase flows, fluctuations in the mobile phase flow rate are small, and baseline noise does not occur.

Further, since the first to eleventh sheets 33 to 43 are previously bonded to each other by using hot melt,
Assembly work is easy and seats can be easily replaced.
The present invention is not limited to the above embodiment. Bonding the sheets with hot melt is also applicable to sheets used in conventional type background removal devices. For example, as shown in FIG. 4, the hot melt sheets 60 and 61 are arranged between the third sheet 5, the fourth sheet 6 and the fifth sheet 7 in FIG. It is easy and the seat can be easily replaced.

Further, the adhesive is not limited to hot melt.

[0031]

As described above, according to the first invention,
The flow path for the removal liquid is doubled using an ion exchange membrane,
By providing an electrode in the flow path on the side that does not contact the mobile phase,
It is possible to realize a background removal device in which fluctuations in mobile phase flow rate are small and baseline noise is small.

According to the second aspect of the invention, the sheets are preliminarily laminated with the adhesive, so that the assembling work is easy,
It is possible to realize a background removal device that allows easy replacement of sheets.

[Brief description of drawings]

FIG. 1 is an exploded perspective view of an embodiment of the present invention.

FIG. 2 is an overall configuration diagram of an ion analyzer provided with the background removal device shown in FIG.

FIG. 3 is a diagram illustrating an operation in FIG.

FIG. 4 is a configuration diagram of another embodiment.

FIG. 5 is an exploded perspective view of a conventional background removal device.

[Explanation of symbols]

 31 1st board 32 2nd board 33 1st sheet 34 2nd sheet 34a, 36a, 38a, 40a, 42a Groove 35 3rd sheet 36 4th sheet 37 5th sheet 38 6th sheet 39 7th sheet 40 8th sheet 41 9th sheet 42 10th sheet 43 11th sheet 50 1st electrode 51 2nd electrode

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Naoki Nakagawa 1-15-5 Nakamachi, Musashino City, Tokyo Mitaka Takagi Building Yokogawa Analytical Systems Co., Ltd.

Claims (2)

[Claims] 1. A first sheet, a second sheet having a groove formed in the center thereof and a first electrode provided in the groove, a third sheet of an ion exchange membrane, and a fourth sheet having a groove at the center. Sheet, fifth sheet of ion exchange membrane, sixth sheet having groove in central portion, seventh sheet of ion exchange membrane, eighth sheet having groove in central portion, ninth sheet of ion exchange membrane A tenth sheet and an eleventh sheet each having a groove formed in the central portion and having a second electrode provided in the groove, and a first groove having a groove formed on a surface in contact with the first sheet above and below The substrate and the second substrate having a groove formed on the surface in contact with the seventh sheet are sandwiched, and the mobile phase is flown in the grooves of the eighth sheet sandwiched between the seventh and ninth sheets, and the third and Groove of 4th sheet sandwiched between 5th sheet and 8th sheet sandwiched between 7th and 9th sheets Flowing the removing liquid in the groove in the direction opposite to the mobile phase, flowing the removing liquid flowing in the groove of the fourth sheet into the groove of the second sheet sandwiched between the first and third sheets, A background removal device, characterized in that the removal liquid that has flowed through 8 sheets is flowed into the groove of the 10th sheet sandwiched between the 9th and 11th sheets. 2. A background removal device comprising a sheet having a groove formed with a mobile phase in the center thereof and two ion exchange membrane sheets provided so as to sandwich the sheet, wherein The background removing device is characterized in that the sheet is previously bonded with an adhesive.