JP2022132242A - column unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide simple nozzles for a liquid chromatograph and the liquid chromatograph, which can feed eluent by selecting one column from a plurality of columns arranged in parallel.

SOLUTION: Nozzles 2 for a liquid chromatograph are arranged at an upstream side and a downstream side of a column unit 1 and relatively move forward and backward to an end plate 12 of the column unit 1 in a same direction as a posture of the column 11. The column unit 1 includes a plurality of cylindrical columns 11 of which inner surfaces of at least both ends have elasticity and which is arranged in parallel, and a pair of end plates 12 that has a plurality of communication holes 121 continuous with respective ends of column 11 and sandwiches the respective ends of the plurality of columns 11. The nozzle 2 for the liquid chromatograph includes a reduced diameter portion 21 having a portion inserted so as to be pressed into the end of column 11, and an enlarged diameter portion 22 inserted into the communication hole 121 of the end plate 12. The reduced diameter portion 21 has a tapered portion 211 gradually enlarged from a tip edge to the enlarged diameter portion 22.

SELECTED DRAWING: Figure 1

COPYRIGHT: (C)2022,JPO&INPIT

Description

The present invention relates to a liquid chromatograph that separates and detects each component of a liquid sample, and a liquid chromatograph nozzle provided in the liquid chromatograph.

Chromatography (method) and chromatograph (apparatus) are used as techniques for physically separating samples containing various components such as pharmaceuticals, foods, and beverages. A chromatograph includes a column, a detector, and the like. The column is cylindrically formed of stainless steel, resin, or the like. The column is filled with a medium called stationary phase. The stationary phase is a particle such as silica gel, porous gel, or synthetic resin.

The sample is entrained in a medium stream called the mobile phase and moves through the column. A chromatograph that uses a liquid as the mobile phase is called a liquid chromatograph. Various components contained in the sample pass through the stationary phase in the column while interacting with the stationary phase along with the flow of the mobile phase. Various components in the sample move through the column at different speeds. Therefore, each component is sent from the column to the detector at different timings and analyzed by the detector.

Patent Document 1 describes a microcolumn array system as an example of such a liquid chromatograph. This microcolumn array system includes a column unit in which a plurality of columns are arranged, a liquid-sending unit that sends liquids to the plurality of columns, and a sample dissolved in an eluent in the plurality of columns (Patent Document 1 describes "detection object ”), and a detection means for detecting a detected substance that has passed through the column unit.

The liquid transfer unit includes a solution pump that pressure-feeds the eluent, a piping system (main pipe and branch pipes) connected from the solution pump to the inlet of each microcolumn, and a liquid transfer selection mechanism inserted in each branch pipe. Consists of In the piping system, microtubes and branch pipes are combined. The liquid-sending mechanism is composed of an electromagnetic valve inserted in each branch pipe, or a microtube that opens and closes with a clip or the like. The eluent sent from the solution pump is distributed and supplied to each microcolumn from a selected branch pipe by opening/closing control of the liquid sending mechanism. The eluent separates the samples in the macrocolumn.

JP 2006-292636 A

The microcolumn array system described in Patent Document 1 has a liquid transfer selection mechanism for distributing and supplying an eluent to a microcolumn selected from a plurality of microcolumns. The liquid transfer selection mechanism is composed of an electromagnetic valve inserted in each branch pipe, or a microtube that is opened and closed with a clip or the like. Therefore, the microcolumn array system has a complicated configuration due to the liquid transfer selection mechanism.

The present invention provides a simple liquid chromatograph capable of selecting one column from a plurality of columns arranged in parallel and feeding an eluent, and a liquid chromatograph nozzle provided in this liquid chromatograph. intended to

The liquid chromatograph nozzle according to the present invention comprises
A plurality of cylindrical columns arranged side by side having elasticity at least at the inner surfaces of both ends thereof, and a plurality of communicating holes continuing to the respective ends of the columns, wherein the ends of the plurality of columns are connected to each other. A liquid chromatograph that is disposed upstream and downstream of a column unit, and is relatively advanced and retreated toward the end plates of the column unit in the same direction as the posture of the column. a nozzle for
comprising a diameter-reduced portion having a portion that is inserted so as to be pushed into the end of the column, and an enlarged-diameter portion that is inserted into the communication hole of the end plate,
The reduced-diameter portion has a tapered portion that gradually increases in diameter from the leading edge toward the increased-diameter portion.

In the liquid chromatograph nozzle,
The communication hole of the end plate is formed as a stepped hole having a small diameter portion continuing to the column and a large diameter portion opening on the surface side of the end plate,
The reduced diameter portion has a base portion that is inserted into the reduced diameter portion.

In the liquid chromatograph nozzle,
It has a shaft-shaped connection end connected to the base end side edge of the enlarged diameter portion.

The liquid chromatograph according to the present invention is
A plurality of cylindrical columns arranged side by side having elasticity at least at the inner surfaces of both ends thereof, and a plurality of communicating holes continuing to the respective ends of the columns, wherein the ends of the plurality of columns are connected to each other. a column unit comprising a pair of end plates sandwiched between;
a liquid chromatograph nozzle according to the present invention, which is arranged upstream and downstream of the column unit;
a slide mechanism that advances and retreats the liquid chromatograph nozzle facing the column unit on the upstream side;
a driving mechanism for intermittently moving the column unit by the pitch of the columns arranged in parallel;
It has

In the liquid chromatograph according to the present invention,
The column unit arranges a plurality of the columns in a vertical direction,
The drive mechanism also moves up and down in the vertical direction.

In the liquid chromatograph according to the present invention,
The slide mechanism includes a horizontal piston having a piston rod, and a holder fixed to the piston rod and holding the liquid chromatograph nozzle on the upstream side.

In the liquid chromatograph according to the present invention,
The drive mechanism has a stopper on the side facing the slide mechanism,
The slide mechanism includes a base plate on which the piston is installed and to which the stopper contacts and separates.

In the liquid chromatograph according to the present invention,
The slide mechanism inserts and removes the diameter-reduced portion of the upstream liquid chromatograph nozzle into and out of the upstream end of the column, and slides the column unit toward the downstream liquid chromatograph nozzle. The nozzle for liquid chromatography on the downstream side is inserted into or removed from the end of the column on the downstream side by moving it forward or backward.

According to the present invention, a simple liquid chromatograph capable of selecting one column from a plurality of columns arranged in parallel and feeding an eluent, and a liquid chromatograph nozzle provided in this liquid chromatograph can be provided.

1 is a schematic perspective view of a liquid chromatograph according to the present invention, viewed obliquely from the front; FIG. 1 is a schematic perspective view of a liquid chromatograph according to the present invention, viewed obliquely from the rear; FIG. 1 is a schematic perspective view of a main part of a liquid chromatograph including a nozzle for a liquid chromatograph according to the present invention, as seen obliquely from the front; FIG. 1 is a schematic perspective view showing a column unit provided in a liquid chromatograph according to the present invention; FIG. 1 is a cross-sectional plan view showing part of a liquid chromatograph nozzle and column according to the present invention; FIG. FIG. 6 is an enlarged cross-sectional plan view showing a part of the liquid chromatograph nozzle and a part of the column according to the present invention, which are surrounded by a dashed line in FIG. 5 ; FIG. 2 is a plan view showing the initial state of operation of the liquid chromatograph according to the present invention; FIG. 4 is a plan view showing a state during operation of the liquid chromatograph according to the present invention; FIG. 4 is a plan view showing a state during operation of the liquid chromatograph according to the present invention; FIG. 5 is a plan view showing another initial state of operation of the liquid chromatograph according to the present invention;

An embodiment of a liquid chromatograph nozzle and a liquid chromatograph according to the present invention will be described below with reference to FIGS. 1 to 10. FIG. This fluid chromatograph can correspond to both normal phase chromatograph (NPLC) and reversed phase chromatograph (RPLC). In the case of NPLC, silica gel, polyamine, carbon nanotubes (CN), etc., are used as separating agents, and n-hexane, which is a non-polar solvent, is used as an eluent. On the other hand, in the case of RPLC, as a separating agent, a chemically bonded packing material in which silica gel is modified with ligands such as C19 (octadecyl group, ODS), C8, C4, Cl, Ph, etc. is used. A solvent such as water or acetonitrile (ACN) is used. The ligand used for ligand modification can be selected from existing organic polymers depending on the object to be separated. In addition, various separating agents used in HPLC columns such as size exclusion chromatography (SEC), gel permeation chromatography (GPC), gel filtration chromatography (GFC), ion exchange chromatography, chiral chromatography, etc. can be used in inventions.

FIG. 1 is a schematic perspective view of a liquid chromatograph according to the present invention, viewed obliquely from the front. FIG. 2 is a schematic perspective view of the liquid chromatograph according to the present invention, viewed obliquely from the rear. FIG. 3 is a schematic perspective view showing a main part of a liquid chromatograph including the nozzle for liquid chromatograph according to the present invention, viewed obliquely from the front. FIG. 4 is a schematic perspective view showing a column unit provided in the liquid chromatograph according to the invention. FIG. 5 is a plan view showing the liquid chromatograph nozzle and microcolumn according to the present invention. FIG. 6 is an enlarged cross-sectional plan view showing part of the liquid chromatograph nozzle and part of the column according to the present invention, which is surrounded by the dashed-dotted line in FIG. FIG. 7 is a plan view showing the initial state of operation of the liquid chromatograph according to the present invention. FIG. 8 is a plan view showing a state during operation of the liquid chromatograph according to the present invention. FIG. 9 is a plan view showing a state during operation of the liquid chromatograph according to the present invention. FIG. 10 is a plan view showing another initial state of operation of the liquid chromatograph according to the present invention.

As shown in FIG. 1, a liquid chromatograph for separating and detecting components of a liquid sample includes a column unit 1, a liquid chromatograph nozzle (hereinafter mainly referred to as "nozzle") 2, and a slide. A mechanism 3 and a drive mechanism 4 are provided. The liquid chromatograph further comprises a base plate 5 installed in a horizontal position. An opening 51 surrounding the column unit 1 is formed in the base plate 5 .

As shown in FIG. 4 , the column unit 1 includes multiple columns 11 and a pair of end plates 12 . The column unit 1 further includes fixtures 13 and stoppers 14 .

As shown in FIGS. 5 and 6, the column 11 is a cylindrical body made of stainless steel or a resin such as fluororesin. ) to the downstream side (right side in the drawing). As shown in FIG. 4, a large number of columns 11 are horizontally arranged (20 columns at equal intervals in the horizontal direction, 5 columns at equal intervals in the vertical direction, 100 columns in total). The column 11 is packed with a stationary phase (not shown) except for both ends. At least both ends of the column 11 have elasticity, and are slightly compressed and deformed when the tip of the nozzle 2 is press-fitted.

A band plate-shaped fixture 13 is attached to each end edge of the plurality of columns 11 arranged in parallel. A plurality (100 in the drawing) of communication holes 131 communicating with the plurality of columns 11 are formed in the fixture 13 . As shown in FIGS. 5 and 6, the communication hole 131 of the fixture 13 is formed like a stepped hole with a small diameter on the column 11 side and a large diameter on the outside. Both fixtures 13 are set on a plate 15 in a horizontal position. As shown in FIG. 4, a stepped plate-like stopper 14 is provided on a plate 15 on the side (left side in the drawing) on which one end of the column 11, which is the upstream side of the sample, is arranged. ing. The fixture 13, table and stopper 14 are made of stainless steel, resin, or the like.

An end plate 12 made of resin is joined to the outer surface of each fixture 13 . The end plate 12 is formed to have the same height and length as the fixture 13, and has a communication hole 121 communicating with the communication hole 131 of the column 11 and the fixture 13. As shown in FIG. The communication hole 121 of the end plate 12 is countersunk on the outer surface. The stopper 14 is located upstream of the surface of the end plate 12 on the upstream side (left exposed surface in the drawing).

Such a column unit 1 advances and retreats in the same direction as the posture of the column 11, that is, in the longitudinal direction of the column 11. As shown in FIG. In addition, the column unit 1 is intermittently moved in the width direction and the vertical direction by the drive mechanism 4 at the same pitch as the pitch of the adjacent columns 11 .

Nozzles 2 are provided upstream and downstream of the column unit 1 . As shown in FIG. 5, each nozzle 2 includes a reduced diameter portion 21, an enlarged diameter portion 22, and a large diameter portion 23 coaxially. A continuous flow path (not numbered) is formed in the central axis of the reduced diameter portion 21, the enlarged diameter portion 22, and the large diameter portion 23. As shown in FIG. Each nozzle 2 further comprises a connecting end 24 . A stepped hole coaxial with the flow path is formed in the central axis of the connecting end portion 24 . A tubular connector 25 is connected to the connecting end portion 24 . The tip of the connector 25 is crimped and fixed to the deep part of the stepped hole of the connection end 24 . A connection hole (not numbered) is formed in the central axis of the connector 25 . The tip of the tube 6 through which the sample is fed is inserted into this connection hole. A pump (not shown) is attached to the upstream end of the tube 6 . The pump may be a liquid chromatograph pump, a syringe pump, or the like.

The reduced-diameter portion 21 of the nozzle 2 has a tapered portion 211 and a small-diameter straight portion 212 that are continuously provided. The tapered portion 211 tapers from the distal edge toward the enlarged diameter portion 22 at a small angle (eg, about 10°) so that it can be easily pushed into the end of the column 11 . The small-diameter straight portion 212 has an outer shape slightly larger than the inner diameter of the column 11 . Since the end portion of the column 11 into which the reduced diameter portion 21 is inserted has elasticity, the small diameter straight portion 212 expands the end portion of the column 11, and the end portion of the column 11 is plugged. as close as possible. Therefore, watertightness is ensured between the end portion of the column 11 and the reduced diameter portion 21 of the nozzle 2 .

The large-diameter portion 23 of the nozzle 2 passes through the inside of the small-diameter communication hole 131 of the fixture 13 . The boundary between the enlarged diameter portion 22 of the nozzle 2 and the straight portion of the reduced diameter portion 21 is formed in a tapered shape with a large angle (for example, about 20°). This tapered portion is formed longer than the countersunk portion formed at the end of the column 11 to ensure liquid-tightness therebetween.

Two annular grooves (not numbered) are formed on the outer periphery of the connection end portion 24 provided in the nozzle 2 . An O-ring 26 is fitted in the annular groove. The O-ring 26 has cushioning properties. Therefore, the connection end 24 of the nozzle 2 is centered while allowing misalignment by the O-ring 26 .

The nozzle 2 advances and retreats by a slide mechanism 3 . The slide mechanism 3 is installed on one end side (left side in the drawing) of the base plate 5 and includes a header 31 , a piston 32 , an actuator 33 , a pair of guide rods 34 and a block 35 .

The header 31 is formed with a through hole into which the tip side of the connecting end portion 24 of the nozzle 2 is inserted. The piston 32 has a piston rod 321 . The piston rod 321 is extended and retracted by the actuator 33 . A proximal end of the block 35 is fixed to the distal end of the piston rod 321 . Guide rods 34 are installed on both sides of the piston 32 . A proximal end of a block 35 is fixed to the distal end of the guide rod 34 . The block 35 maintains a horizontal posture by the guide rod 34 and advances/retreats by the piston rod 321 .

The block is formed with a mounting hole (not numbered) into which the connecting end 24 of the nozzle 2 is inserted. An intermediate portion of the connecting end portion 24 of the nozzle 2 is inserted into this mounting hole. Since an O-ring 26 is fitted in the intermediate portion of the connection end 24, the O-ring 26 abuts against the inner surface of the mounting hole so that the nozzle 2 can be centered. A header 31 is fixed to the tip surface of the block 35 . As the piston rod 321 protrudes and retracts, the upstream nozzle 2 fixed to the header 31 advances and retreats toward the upstream side of the column 11 .

The nozzle 2 on the downstream side is arranged so as to face the nozzle 2 on the upstream side. However, the column unit 1 is arranged between the nozzle 2 on the upstream side and the nozzle 2 on the downstream side, and positioned so that both nozzles 2 are inserted into the ends of the respective columns 11 . The nozzle 2 on the downstream side is fixed on the base 52 on the other end side (on the right side in the drawing) of the base plate 5 and does not move.

Here, a method for separating and detecting each component of a sample using a liquid chromatograph will be described. In the columns 11 shown in FIG. 4, the upper left column 11 is called the (1-1) column 11, and the columns 11 adjacent to each other on the right side are called the (1-2) column 11 and the (1-3) column 11. . The uppermost column 11 in the column unit 1 shown in FIG. 4 is arranged in parallel up to the (1-20) column 11 . Columns 11 on the second stage from the top are arranged in parallel from (2-1) column 11 to (2-20) column 11 . Since the column unit 1 has five layers of columns 11, the columns 11 at the bottom are arranged in parallel from column 11 (5-1) to column 11 (5-20).

7 to 10, a method of transferring a sample using a liquid chromatograph will be described in steps 1 to 10. FIG.

As shown in FIG. 7, in the first stage of standby, the upstream nozzle 2 faces the upstream end of the (1-1) column 11 at a distance, and the downstream nozzle 2 faces the (1-1) column 11 facing away from the downstream end of the Therefore, the table on which the column unit 1 is set is located on the right side (lower side in the drawing) of the column 11 when viewed from the upstream end to the downstream end of the column 11 .

As shown in FIG. 8, in the second stage, the upstream nozzle 2 is advanced (moved rightward in FIG. 8) by the slide mechanism 3, and as shown in FIGS. The reduced diameter portion 21 is inserted into the upstream end of the (1-1) column 11 . Since the surface of the end plate 12 is countersunk, even if the central axis of the upstream nozzle 2 and the central axis of the (1-1) column 11 do not exactly match, the reduced diameter portion 21 (1-1) is inserted so as to be pushed into the upstream end of the column 11 . Nozzle 2 is centered by O-ring 26 . Also, the ends of the column 11 have elasticity. Therefore, as shown in FIG. 6, the straight portion 212 of the reduced diameter portion 21 of the upstream nozzle 2 and the end of the column 11 are in close contact. In addition, the end of the column 11 pressed by the tapered portion formed at the boundary between the diameter-reduced portion 21 and the diameter-enlarged portion 22 of the nozzle 2 is deformed into a countersink shape.

In the third step, the slide mechanism 3 further advances the nozzle 2 on the upstream side. Then, the table of the drive mechanism 4 is pushed, and (1-1) the column 11 moves toward the nozzle 2 on the downstream side. As shown in FIG. 9, in the fourth step, (1-1) the reduced diameter portion 21 of the downstream nozzle 2 is inserted into the downstream end of the column 11 . Since the diameter-reduced portion 21 of the nozzle 2 on the downstream side gradually expands in diameter from the tip edge, it is smoothly (1-1) inserted into the end portion of the column 11 in a liquid-tight manner. The tapered portion 211 of the reduced diameter portion 21 of the downstream nozzle 2 and the end portion of the column 11 are in close contact with each other.

In the fifth step, a sample containing various components is sent from the pump to the tube 6 connected to the nozzle 2 on the upstream side. A sample is sent into the column 11 from the nozzle 2 on the upstream side. The sample separates into components within the column 11 and travels downstream at different velocities. Then, each component is sent to the nozzle 2 on the downstream side at different timings. Each end of the column 11 has elasticity and is in close contact with the diameter-reduced portion 21 of each nozzle 2 to ensure watertightness. A sample is sent from a downstream nozzle 2 to a tube 6 and analyzed by a detector (not shown) connected to the tube 6 . When a predetermined amount of material has been transferred, the transfer of the sample to the tube 6 is temporarily interrupted.

In the sixth stage, the piston rod 321 of the slide mechanism 3 is retracted, whereby the nozzle 2 on the upstream side is retracted (moved leftward in the drawing). Since the upstream nozzle 2 and the upstream end of the column 11 are engaged with each other, the column 11 also retreats following the upstream nozzle 2 . However, since the nozzle 2 on the downstream side is fixed to the base 52, it does not follow the nozzle 2 on the upstream side and does not move. Therefore, the downstream end of the column 11 is removed from the downstream nozzle 2 . That is, in this sixth stage, the state is the same as in FIG.

The column 11 retreating while being pulled by the nozzle 2 on the upstream side stops when the stopper 14 projecting from the table of the drive mechanism 4 hits the edge of the opening 51 of the base plate 5 of the slide mechanism 3 . In the seventh stage, the piston rod 321 of the slide mechanism 3 is subsequently retracted, so that the reduced diameter portion 21 of the upstream nozzle 2 is removed from the upstream end of the column 11 . That is, at this stage, the state is the same as in FIG.

As shown in FIG. 10, in the eighth stage, the column unit 1 is moved by the driving mechanism 4 so that both nozzles 2 face the column 11 (1-2) from the state facing the column 11 (1-1). moves by one pitch in the radial direction of the column 11 (upper left direction in FIG. 10). After that, the liquid chromatograph operates like the operations in the second to fourth stages, and as in the fifth stage, the sample (1-2) is sent through the column 11 and discharged from the nozzle 2 on the downstream side. Ejected. Then, in the ninth stage, both nozzles 2 are removed from both ends of the column 11 as in the seventh stage.

Then, as in the eighth stage, the driving mechanism 4 moves horizontally by one pitch, so that both nozzles 2 face the (1-3) column 11, and the sample is transferred from the upstream nozzle 2 to (1-3). The liquid is sent into the column 11 and discharged from the nozzle 2 on the downstream side. By repeating the same operation, up to (1-20) column 11 is used.

In the next ninth step, the column unit 1 is lifted by one pitch by the driving mechanism 4, and operates like the second to fourth steps, and (2-1) the sample is sent to the column 11. FIG. Then, by operating as in the eighth step, the operation for transferring the sample from (2-2) the column 11 to (2-20) the column 11 is the same operation as in the first step to the seventh step. The sample is sent from the nozzle 2 on the upstream side into the column 11 and discharged to the nozzle 2 on the downstream side.

In the ninth and subsequent stages, the column unit 1 is similarly raised by one pitch by the driving mechanism 4, and (3-1) the sample is sent to the column 11. FIG. (3-2) From column 11 to (3-20) The sample is similarly fed to column 11, column unit 1 is raised by one pitch by drive mechanism 4, and (4-1) from column 11 to (4-20) ) The samples are sent to the columns 11 respectively, and the samples are also sent to the columns 11 through (5-1) to (5-20).

When the sample is sent to all the columns 11 in this manner, the column unit 1 is disassembled to replace the stationary phase in the columns 11 . That is, the column 11 is replaced by removing the end plate 12 and the fixing plate of the column unit 1 .

Embodiments of the liquid chromatograph nozzle 2 and the liquid chromatograph according to the present invention are not limited to the contents described above, and include modifications and improvements within the scope of achieving the object of the present invention.

In the above embodiment, the small diameter portion of the nozzle 2 connects the tapered portion 211 and the small diameter straight portion 212 . However, instead of the small-diameter straight portion 212 , the nozzle 2 may be formed so that the diameter gradually decreases and expands from the tapered portion 211 toward the enlarged-diameter portion 22 . This diameter reduction/diameter expansion may be formed not only in a series but also in a plurality of series.

In the above embodiment, the nozzle 2 is assumed to have the connecting end 24 . However, the nozzle 2 may be configured such that the enlarged diameter portion 22 is fixed to the header 31 or the base 52 of the slide mechanism 3 without having the connecting end portion 24 .

In the above embodiment, 100 columns 11 are arranged in parallel. Needless to say, the number of columns 11 is not limited. Also, the columns 11 may be arranged horizontally in a line. In this case, the drive mechanism 4 does not need to have a lifting function. Also, in the above embodiment, the column 11 is assumed to be a cylindrical body. However, each end of column 11 may be countersunk.

A variation of the liquid chromatograph of the present invention may use a nozzle with a reduced diameter inserted into the end of column 11 to drive the liquid chromatograph without using the nozzle 2 of the present invention. . That is, the nozzles provided in the liquid chromatographs of the variation have only the small-diameter straight portion without the tapered portion 211, or conversely have only the tapered portion without the small-diameter straight portion. good too.

That is, this liquid chromatograph is
A plurality of cylindrical columns 11 arranged side by side having elasticity at least at the inner surfaces of both ends thereof, and a plurality of communication holes 121 continuing to the respective ends of the columns 11 are provided. A column unit 1 comprising a pair of end plates 12 sandwiching each end,
liquid chromatograph nozzles arranged upstream and downstream of the column unit 1;
a slide mechanism 3 for advancing and retreating the liquid chromatograph nozzle facing the column unit 1 on the upstream side;
a driving mechanism 4 for intermittently moving the column unit 1 by the pitch of the columns 11 arranged in parallel;
is equipped with
You may do so.

Further, both nozzles 2 of the fluid chromatograph of the above embodiment are of the same type. However, in the fluid chromatograph, one nozzle 2 has a reduced diameter portion having a tapered portion and a small diameter straight portion, and the other nozzle has only a small diameter straight portion without the tapered portion 211, or conversely, has a small diameter portion. A reduced diameter portion having only a tapered portion without a straight portion may be provided.

In summary, the liquid chromatograph nozzle 2 and the liquid chromatograph to which the present invention is applied are sufficient if they have the following configurations, and can take various embodiments.

The liquid chromatograph nozzle 2 according to the present invention is
A plurality of cylindrical columns 11 arranged side by side having elasticity at least at the inner surfaces of both ends thereof, and a plurality of communication holes 121 continuing to the respective ends of the columns 11 are provided. A pair of end plates 12 sandwiching each end is arranged upstream and downstream of the column unit 1, and faces toward the end plates 12 of the column unit 1 in the same direction as the attitude of the column 11. A liquid chromatograph nozzle 2 that advances and retreats dynamically,
A reduced diameter portion 21 having a portion inserted so as to be pushed into the end of the column 11, and an enlarged diameter portion 22 inserted into the communication hole 121 of the end plate 12,
The diameter-reduced portion 21 has a tapered portion 211 that gradually expands in diameter from the distal edge toward the diameter-enlarged portion 22 .

Since the liquid chromatograph nozzle 2 includes the diameter-reduced portion 21 having the tapered portion 211 , the diameter-reduced portion 21 extends from the communication hole 121 of the end plate 12 to the end of the column 11 . It can be easily inserted into the part. Since the end of the column 11 has elasticity, the liquid chromatograph nozzle 2 is in close contact with the end of the column 11 .

In the liquid chromatograph nozzle 2 according to the present invention,
The communication hole 121 of the end plate 12 is formed as a stepped hole having a small diameter portion continuing to the column 11 and a large diameter portion 23 opening on the surface side of the end plate 12,
The reduced diameter portion 21 has a base that is inserted into the small diameter portion.

In this liquid chromatograph nozzle 2, since the diameter-reduced portion 21 has a base portion that is inserted into the small-diameter portion of the end plate 12, the external force is relieved from the base portion by the small-diameter portion of the end plate 12, and the diameter-reduced portion 21 can be made difficult to join.

In the liquid chromatograph nozzle 2 according to the present invention,
It has a shaft-shaped connection end portion 24 that is connected to the edge of the enlarged diameter portion 22 on the base end portion side.

Since the liquid chromatograph nozzle 2 has the connecting end portion 24, the connecting end portion 24 can be easily fixed to the slide mechanism 3 or the like.

The liquid chromatograph according to the present invention is
A plurality of cylindrical columns 11 arranged side by side having elasticity at least at the inner surfaces of both ends thereof, and a plurality of communication holes 121 continuing to the respective ends of the columns 11 are provided. A column unit 1 comprising a pair of end plates 12 sandwiching each end,
liquid chromatograph nozzles 2 according to the present invention, which are arranged upstream and downstream of the column unit 1;
a slide mechanism 3 for advancing and retreating the liquid chromatograph nozzle 2 facing the column unit 1 on the upstream side;
a driving mechanism 4 for intermittently moving the column unit 1 by the pitch of the columns 11 arranged in parallel;
It has

In this liquid chromatograph, columns 11 arranged in parallel are intermittently moved by a drive mechanism 4, and a liquid chromatograph nozzle 2 can be inserted into and removed from the ends of the columns 11 by a slide mechanism 3.

In the liquid chromatograph according to the present invention,
The column unit 1 arranges the plurality of columns 11 in the vertical direction,
The drive mechanism 4 also moves up and down in the vertical direction.

This liquid chromatograph can have a large number of columns 11 in the column unit 1 by arranging a plurality of columns 11 in the vertical direction. The liquid chromatograph nozzle 2 can also be inserted into and removed from the arranged column 11 .

In the liquid chromatograph according to the present invention,
The slide mechanism 3 includes a horizontal piston 32 having a piston rod 321 and a holder fixed to the piston rod 321 and holding the liquid chromatograph nozzle 2 on the upstream side.

In this liquid chromatograph, the piston rod 321 provided in the piston 32 allows the liquid chromatograph nozzle 2 to be inserted into and removed from the end of the column 11 .

In the liquid chromatograph according to the present invention,
The drive mechanism 4 has a stopper 14 on the side facing the slide mechanism 3,
The slide mechanism 3 has a base plate on which the piston 32 is installed and to which the stopper 14 contacts and separates.

In the liquid chromatograph according to the present invention, when the liquid chromatograph nozzle 2 inserted into the column 11 is moved by the slide mechanism 3 to be removed from the column 11, the stopper 14 provided in the drive mechanism 4 slides. The column unit 1 stops when it hits the mechanism 3 , and the liquid chromatograph nozzle 2 inserted into the end of the column 11 can be reliably removed from the column 11 .

In the liquid chromatograph according to the present invention,
The slide mechanism 3 inserts and removes the reduced-diameter portion 21 of the upstream liquid chromatograph nozzle 2 into and out of the upstream end of the column 11, and slides the column unit 1 into the downstream liquid chromatograph. The liquid chromatograph nozzle 2 on the downstream side is inserted into or removed from the end of the column 11 on the downstream side.

In the liquid chromatograph according to the present invention, a series of operations for inserting and removing the liquid chromatograph nozzle 2 into and out of the column 11 can be continuously performed by the slide mechanism 3, and efficiency can be improved.

Reference Signs List 1 Column unit 11 Column 12 End plate 121 Communication hole 14 Stopper 2 Fluid chromatograph nozzle (nozzle)
21... reduced diameter portion 211... tapered portion 22... expanded diameter portion 24... connection end portion 3... slide mechanism 32... piston 321... piston rod 4... drive mechanism 5... base plate

The present invention relates to a column unit provided in a liquid chromatograph that separates and detects each component of a liquid sample.

The present invention provides a simple liquid chromatograph capable of selecting one column from a plurality of columns arranged in parallel and feeding an eluent, and a column unit provided in this liquid chromatograph. With the goal.

A column unit according to the present invention has a plurality of cylindrical columns arranged in parallel each having an elastic inner surface at least at both ends thereof, and a plurality of communicating holes continuing to the respective ends of the columns. a pair of end plates that sandwich each end of the column of books.

In the column unit,
The communication hole of the end plate is formed as a stepped hole having a small diameter portion continuing to the column and a large diameter portion opening on the surface side of the end plate,
The reduced diameter portion has a base portion that is inserted into the reduced diameter portion.

According to the present invention, a simple liquid chromatograph capable of selecting one column from a plurality of columns arranged in parallel and feeding an eluent, and a column unit provided in this liquid chromatograph are provided. can do.

Claims (8)

A plurality of cylindrical columns arranged side by side having elasticity at least at the inner surfaces of both ends thereof, and a plurality of communicating holes continuing to the respective ends of the columns, wherein the ends of the plurality of columns are connected to each other. A liquid chromatograph that is disposed upstream and downstream of a column unit, and is relatively advanced and retreated toward the end plates of the column unit in the same direction as the posture of the column. a nozzle for
comprising a diameter-reduced portion having a portion that is inserted so as to be pushed into the end of the column, and an enlarged-diameter portion that is inserted into the communication hole of the end plate,
The reduced-diameter portion has a tapered portion that gradually expands in diameter from the distal edge toward the increased-diameter portion,
Nozzle for liquid chromatograph. The communication hole of the end plate is formed as a stepped hole having a small diameter portion continuing to the column and a large diameter portion opening on the surface side of the end plate,
The reduced diameter portion has a base that is inserted into the small diameter portion,
The liquid chromatograph nozzle according to claim 1. Having a shaft-shaped connection end connected to the base end edge of the enlarged diameter portion,
The liquid chromatograph nozzle according to claim 1 or 2. A plurality of cylindrical columns arranged side by side having elasticity at least at the inner surfaces of both ends thereof, and a plurality of communicating holes continuing to the respective ends of the columns, wherein the ends of the plurality of columns are connected to each other. a column unit comprising a pair of end plates sandwiched between;
4. The liquid chromatograph nozzle according to any one of claims 1 to 3, arranged upstream and downstream of the column unit;
a slide mechanism that advances and retreats the liquid chromatograph nozzle facing the column unit on the upstream side;
a driving mechanism for intermittently moving the column unit by the pitch of the columns arranged in parallel;
is equipped with
Liquid chromatograph. The column unit arranges a plurality of the columns in a vertical direction,
The drive mechanism also ascends and descends in the vertical direction,
The liquid chromatograph according to claim 4. The slide mechanism includes a horizontal piston having a piston rod, and a holder fixed to the piston rod and holding the liquid chromatograph nozzle on the upstream side.
The liquid chromatograph according to claim 4 or 5. The drive mechanism has a stopper on the side facing the slide mechanism,
The slide mechanism includes a base plate on which the piston is installed and the stopper contacts and separates,
The liquid chromatograph according to claim 6. The slide mechanism inserts and removes the diameter-reduced portion of the upstream liquid chromatograph nozzle into and out of the upstream end of the column, and slides the column unit toward the downstream liquid chromatograph nozzle. advance/retreat to insert/remove the downstream liquid chromatograph nozzle into/from the downstream end of the column;
The liquid chromatograph according to any one of claims 4 to 7.

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