JPH0712796A - Background elimination device - Google Patents

Abstract

PURPOSE:To provide a background elimination device without any need of elimination liquid, an elimination liquid tank and an elimination liquid pump, while having a relatively high S/N ratio, regarding a background elimination device used for an ion analysis device. CONSTITUTION:This device has an enclosure 21 with the first and second chambers separated with a film having the capability of ion exchange, a cathode 23 laid in the second chamber of the enclosure 21, an anode 22 laid in the second chamber of the enclosure 21, and a power supply for applying voltage, to the cathode 23 and the anode 22. In addition, one end of the first chamber is connected to the outlet of a separation column 25, with the other end connected to the inlet of a detector 26, and liquid coming out of the detector 265 is introduced to the second chamber.

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 overall configuration diagram of the ion removing device, and FIG. 6 is a configuration conceptual diagram of background removal in FIG.

First, the overall structure of a conventional ion analyzer will be described with reference to FIG. In the figure, 1 is an eluent tank in which the eluent is stored, and 2 is a pump which sucks the eluent from the eluent tank 1 and pressure-feeds it to the sample injector 3. The sample injector 3 collects a predetermined amount of the sample liquid and conveys the collected sample liquid to the separation column 4 as an eluent. The separation column 4 is filled with an ion exchange resin and chromatographically separates and elutes the ions contained in the injected fluid.

Reference numeral 5 is a removing liquid tank in which the removing liquid is stored, and 6 is a pump for sucking the removing liquid from the removing liquid tank 5 and sending it to the background removing device 7 under pressure. Reference numeral 8 is a detector for detecting the physical properties (eg, electric conductivity) of the eluent discharged from the background removal device 7.

Next, the concept of electrolyzing the removing liquid will be described in detail with reference to FIG. In this figure, 10 and 11 are ion exchange membranes having an ion exchange capacity (in the case of the conventional example, anions), 12 is a cathode, and 13 is an anode.

These two ion-exchange membranes 10 and 11 and electrodes 12 and 13 form three chambers, that is, the first chamber 1.
4, second chamber 15 and third chamber 16 are formed. Of the three chambers, the second chamber 15 has the separation column 4
The eluent from the first and second chambers 14 and 16 flows in a countercurrent direction with the eluent. Reference numeral 17 is a power source for applying a voltage to the cathode 12 and the anode 13.

Next, the overall operation of the ion analyzer will be described. The eluent (eg, HCl) is sucked up from the eluent tank 1 by the pump 2 and sent to the sample injector 3.
A fixed amount of sample (for example, a solution to be measured containing Na ⁺ and K ⁺ ) collected by the sample injector 3 is sent to the separation column 4 so as to be sandwiched between the eluent and the eluent. In the separation column 4, the sample is separated into each ion and sent to the background removing device 7 together with the eluent. On the other hand, the removal liquid (for example, NaOH) is removed from the removal liquid tank 5 by the pump 6.
Are sucked up, and the removing liquid enters the background removing device 7.

In the background removing device 7, positive ions move toward the cathode 12 and negative ions move toward the anode 13 by the voltage E applied between the cathode 12 and the anode 13. However, the ion-exchange membranes 10 and 11 having anion-exchange ability allow the anions to freely pass through the ion-exchange membranes 10 and 11 and move to the anode 13, while the cations are ion-exchange membranes 10 and 11. Can't pass through. Therefore, HCl in the eluent
Becomes H ⁺ and Cl ^−, and while passing through the second chamber 15, Cl
^- moves through the ion-exchange membrane 10 to the anode 13.
On the other hand, in the third chamber 16 in which the removing solution NaOH flows, OH ⁻ is supplied to the second chamber 15 through the ion exchange membrane 11.
Therefore, the eluent undergoes a reaction represented by the following equation (1).

[0009] Also, each ion separated and eluted in the separation column 4 is
In the form of KCl, it enters the second chamber 15 and reacts as in the following equation (2).

[0010] In this way, HCl in the eluent is changed to H
Since it changes to ₂ O, the conductivity of the eluent decreases and the baseline is very low and stable.

Then, the background of the eluent is reduced in the background removing device 7, the electric conductivity of each ion is increased, and the eluate is sent to the detector 8 for ion analysis, and after the analysis, the liquid is drained. Is thrown away.

[0012]

However, in the ion analyzer of the above construction, the removing solution, the removing solution tank 5, the pump 6 for delivering the removing solution, the removing solution line, etc. are required, and the apparatus is large in size. It had the drawback of becoming complicated and complicated.

The present invention has been made in view of the above problems, and an object thereof is to provide a background removing device having a relatively high S / N ratio, which does not require a removing liquid, a removing liquid tank, and a removing liquid pump. To do.

[0014]

The invention according to claim 1 for solving the above-mentioned problems, comprises a housing having a first chamber and a second chamber separated by a membrane having an ion exchange capacity, and a first housing of the housing. Two
A cathode provided in the chamber, an anode provided in the second chamber of the housing, the cathode, a power source for applying a voltage to the anode, one end side of the first chamber, It is connected to the outlet of the separation column, the other end side is connected to the inlet of the detector, and the liquid discharged from the detector is introduced into the second chamber.

According to the second aspect of the present invention, a tube having an ion exchange capacity is connected along the starting side to the outlet side of the separation column, and the terminal side is connected to the inlet side of the detector, and the tube is provided along the tube. A cathode part, facing the cathode part through the tube, an anode part provided along the tube, the tube, the cathode part and the anode part are housed, and in the vicinity of the terminal side of the tube. A removing liquid inlet connected to the outlet side of the detector, a chamber in which a removing liquid discharge port is formed near the starting end side of the tube, and a power source for applying a voltage to the cathode portion and the anode portion. It consists of

[0016]

In the background removing apparatus according to the first and second aspects of the invention, the liquid from the separation column is ion-exchanged in the first chamber of the housing, the background is lowered, and the ion concentration is detected by the detector, This time, it enters the second chamber of the housing as a removing liquid. Here, by electrolyzing this removing liquid to create ions to be ion-exchanged, the removing liquid, the removing liquid tank, and the removing liquid pump can be eliminated.

[0017]

Embodiments of the present invention will now be described in detail with reference to the drawings. FIG. 1 is a block diagram of the first embodiment of the present invention.
In this figure, reference numeral 21 denotes a housing, and inside the housing 21, a hollow cylindrical anode ring 2 having both open ends is formed.
2 and a cathode rod 23 provided in the inner cylinder of the anode ring 22. A tube 24 having an ion exchange capacity is spirally wound around the cathode rod 23. One end of the tube 24 is connected to the outlet of the separation column 25, and the other end of the tube 24 is connected to the inlet of the detector 26.

The outlet of the detector 26 is the detector 2 of the housing 21.
A tube 27 is connected to the removal liquid inlet 26a opened on the 6th side. Furthermore, the separation column 2 of the housing 21
A removing liquid discharge port 25b is opened on the 5th side.

Reference numeral 28 is, for example, a DC power source for applying a voltage to the anode ring 22 and the cathode rod 23. Next, the operation of the above configuration will be described. The eluent discharged from the separation column 25 passes through the tube 24 and reaches the detector 26, where the conductivity is detected. The eluent that has flowed out of the detector 26 enters the housing 21 through the removal liquid introduction port 25a of the housing 21 again via the tube 27, and in the housing 21, the eluent flows countercurrently with the eluent and is removed. The liquid is discharged from the liquid discharge port 25b.

Here, the eluent coming from the separation column 25 is
The background removal apparatus of this embodiment will be described assuming that the tube 24 has HCl and the anion exchange ability is used. HCl in eluent H ⁺ and Cl ^- has electrolysis and,
When passing through the tube 24 having the anion exchange ability, Cl ⁻ passes through the membrane of the tube 24 having the anion exchange ability by diffusion.

On the other hand, around the tube 24 in the housing 21, the drained liquid discharged from the detector 26 exists, and the anode ring 22,
The removal liquid (for example, H ₂ O) is electrolyzed by the cathode rod 23 according to the following equation.

[0022] ^{_{H 2 O → H + + OH}} - ...... (3) such electrolysis generated by OH- is tube 2
After passing through No. 4, it is replaced with Cl ⁻ in the eluent and enters the tube 24. Therefore, the eluent in the tube 24 becomes H ₂ O.

Then, H ₂ O passes through the detector 26 and is passed through the housing 2
It returns to 1 as drainage. Then, the electrolysis of equation (3) is performed again. Thus, HCl in eluent H ₂
Since it changes to O 2, the electric conductivity of the eluent decreases at the detector 26, and the baseline becomes very low and stable.

According to the above structure, the anode ring 22 and the cathode rod 23 are used to actively perform ion exchange, and the ion-exchanged one of the ions is electrolyzed and the ion-exchanged eluent is electrolyzed. The removal liquid can be used as the removal liquid by removing the removal liquid, the removal liquid tank, and the removal liquid pump.

Next, a second embodiment of the present invention will be described with reference to FIGS. 2 is a diagram for explaining the second embodiment of the present invention, and FIG. 3 is a sectional view taken along the line AA in FIG.
In these figures, inside the housing 31, an opening at the outer end is formed on the side surface of the housing, an opening at the inner end is formed on the bottom surface of the housing, and the cross-sectional shape is rectangular and the planar shape is spiral. Hole 3
2 is formed.

Inside the hole 32, a tube 33 having an ion exchange capacity is arranged. Further, an anode plate 34 is provided above the tube 33, and a cathode plate 35 is provided below the tube 33.
Are provided along the axial direction of the tube 33. The starting end side of the tube 33 is connected to the outlet side of the separation column 35, and the terminal end side of the tube 33 is connected to the inlet side of the detector 36. The eluent flows through the tube 33 and the outside of the tube 33. Drainage is designed to flow. Furthermore, the outlet of the detector 36 and the opening at the inner end of the hole 32 of the housing 31 are connected by a tube 37, and the eluent that has flowed out of the detector 36 is returned to the hole 32 as a removal liquid. 38
Is a DC power source for applying a voltage to the anode plate 34 and the cathode plate 35.

Next, the operation of the above configuration will be described. The eluent discharged from the separation column 35 passes through the tube 33 and reaches the detector 36, where the conductivity is detected. Detector 3
The eluent exiting 6 is again passed through the tube 37 to the housing 3 again.
1 enters the hole 32 through the opening at the inner end of the hole 32, flows countercurrently with the eluent, and is discharged through the opening at the outer end of the hole 32.

Here, the eluent coming from the separation column 35 is
The background removal apparatus of this embodiment will be described assuming that HCl and the tube 33 have anion exchange ability. HCl in the eluent is ionized into H ⁺ and Cl ⁻ , and when passing through the tube 33 having anion exchange ability, Cl ^−.
Passes through the membrane of the tube 33 having anion exchange capacity by diffusion.

On the other hand, around the tube 33 in the hole 32, there is a removing liquid that has flowed out of the detector 36, and the drainage (for example, H ₂ O) is expressed by the following formula by the anode plate 34 and the cathode plate 35. Is electrolyzed like.

[0030] ^{_{H 2 O → H + + OH}} - is tube 3 ^- ...... (4) OH generated by such electrolysis
It passes through 3 and displaces Cl ⁻ in the eluent. Therefore, the eluent in the tube 33 becomes H ₂ O.

This H ₂ O returns to the inside of the hole 32 through the detector 36 and the opening at the inner end of the hole 32. And again,
(4) is electrolyzed and becomes the removal liquid. Like this
Since HCl in the eluent changes to H ₂ O, the conductivity of the eluent at the detector 36 is lowered, and the baseline is very low and stable.

According to the above construction, the anode plate 34 and the cathode plate 3
5 is used for positive ion exchange, and the ion-exchanged eluent is electrolyzed into a removing solution to create ions to be ion-exchanged, thereby removing the removing solution, the removing solution tank, and the removing solution pump. It can be unnecessary.

Next, a third embodiment of the present invention will be described with reference to FIG. 41 is a thin-walled cylindrical casing. A tube 42 having an ion exchange capacity is arranged in the housing 41, and an inner chamber 43 and an outer chamber 44 are formed with the cylindrical surface of the tube 42 as a boundary. Inside the outer chamber 44, there are a hollow cylindrical anode ring 47 and a cathode ring 4 which are open at both ends.
6 are provided.

One open surface of the tube 42 is connected to the separation column 51, and the other open surface is connected to the detector 48. Furthermore, on the detector 48 side of the outer cylinder surface of the housing 41,
The removal liquid inlet 41a is formed, and the removal liquid outlet 41b is formed on the separation column 51 side. The outlet of the detector 48 is connected to the removal liquid introduction port 41a of the housing 41 using a tube 49. 50 is an anode ring 4
7. A power source for applying a voltage to the cathode ring 46.

Next, the operation of the above configuration will be described. The eluent emitted from the separation column 51 passes through the tube 42 and reaches the detector 48, where the conductivity is detected. Detector 4
The eluent exiting 8 enters the inner chamber 43 through the removal liquid introduction port 41a of the housing 41 through the tube 49, flows countercurrently with the eluent, and is discharged through the removal liquid discharge port 41b.

Here, the background removing apparatus of this embodiment will be described on the assumption that the eluent eluted from the separation column 51 is HCl and the tube 42 has anion exchange capacity. The eluent HCl is electrolyzed into H ⁺ and Cl ⁻ , and when passing through the tube 42 having anion exchange capacity,
Cl ⁻ passes through the tube 42 having anion exchange capacity.

On the other hand, in the outer chamber 44 of the housing 41, the detector 4
There is drainage exiting 8 and being led through tube 49. This drainage liquid is electrolyzed by the cathode ring 46 and the anode ring 47 as in the following equation.

H ₂ O → H ⁺ + OH ⁻ (5) The OH ⁻ produced by such electrolysis is in the tube 4
Through the 2, Cl in the eluent ^- the interchanged. Therefore, the eluent in the tube 42 becomes H ₂ O.

This H ₂ O passes through the detector 48 and returns to the outer chamber 44 from the removal liquid inlet 41c. And again
(5) is electrolyzed and becomes the removal liquid. Thus, since HCl in the eluent is converted to H ₂ O, the conductivity of the eluent is lowered at the detector 48, and the baseline is very low and stable.

According to the above construction, the ion-exchanged eluent is electrolyzed to produce the ions to be ion-exchanged to form the removing solution, and the removing solution, the removing solution tank and the removing solution pump can be eliminated. .

The present invention is based on the above-mentioned first, second and third aspects.
The present invention is not limited to the embodiment described above, but various modifications are possible.

[0042]

As described above, according to the present invention, a background removing device having a relatively high S / N ratio can be realized without the need for a removing liquid, a removing liquid tank, and a removing liquid pump.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a first embodiment of the present invention.

FIG. 2 is a diagram illustrating a second embodiment of the present invention.

3 is a cross-sectional view taken along the line AA in FIG.

FIG. 4 is a diagram illustrating a third embodiment of the present invention.

FIG. 5 is an overall configuration diagram of an ion analyzer.

FIG. 6 is a conceptual diagram of the configuration for background removal in FIG.

[Explanation of reference numerals] 21 case 25 separation column 26 detector 28 power supply

Claims (2)

[Claims] 1. A casing (21) having a first chamber and a second chamber separated by a membrane having an ion exchange capacity, and a cathode (23) provided in the second chamber of the casing (21). An anode (22) provided in the second chamber of the housing (21)
And a power source (28) for applying a voltage to the cathode (23) and the anode (22), and one end side of the first chamber is connected to the outlet of the separation column (25). The other end side is connected to the inlet of the detector (26), and the liquid discharged from the detector (26) is introduced into the second chamber. 2. A tube having an ion exchange capacity, a starting end side of which is connected to an outlet side of a separation column and an end side of which is connected to an inlet side of a detector, a cathode portion provided along the tube, and the cathode. Section and the anode section provided along the tube, the tube section, the cathode section and the anode section are provided, and the outlet side of the detector is provided near the terminal side of the tube. The removing liquid introducing port connected to the chamber comprises a chamber in which a removing liquid discharging port is formed near the starting end side of the tube, and a power source for applying a voltage to the cathode part and the anode part. Background removal device.