JP5227253B2 - Separation column for liquid chromatography - Google Patents

Description

  The present invention relates to a separation column for liquid chromatography used when fractionating a protein having physiological activity or a food component having functionality.

  Conventionally, a separation column 101 for liquid chromatography as shown in FIG. 18 is generally used for separating physiologically active proteins and functional food components. The liquid chromatography separation column 101 is configured with a column main body 102 as a center.

  The column main body 102 is formed in a cylindrical shape, and its upper and lower ends are opened. An annular flange 103 is formed around the upper and lower ends of the column main body 102. A perforated plate 104 is disposed on the outer surface side of the flange 103 via a gasket 110. The perforated plate 104 is formed so as to cover the opening of the column main body 102, and the adsorbent cannot pass therethrough. A cover plate 105 is disposed on the outer surface of the perforated plate 104 via a gasket 110. The cover plate 105 is fixed to the flange 103 by a fastening member 120 together with the perforated plate 104. The lid plate 105 forms a hollow portion 105 a between the perforated plate 104. Further, a stock solution conduit 106 passes through the central portion of the cover plate 105. The tip of the stock solution conduit 106 is located in the hollow portion 105 of the lid plate 105.

  Next, sorting operation of each component of the stock solution will be described. First, the interior 102a of the column body 102 is filled with an eluent (not shown). Next, an adsorbent (not shown) is filled in the interior 102 a of the column main body 102. Further, while introducing a predetermined amount of stock solution (not shown) from the upper stock solution conduit 106 into the interior 102 a of the column body 102, the eluent is extracted from the lower stock solution conduit 106.

  Next, the eluent is introduced from the upper stock solution conduit 106 into the interior 102 a of the column body 102. As a result, each component introduced into the adsorbent is moved down the adsorbent layer at a different speed depending on the difference in affinity to the adsorbent while being eluted, and is discharged to the outside from the lower stock solution conduit 106. . At this time, since each component is discharged in order from the component having a weak affinity for the adsorbent, each component is separated using this.

  In the liquid chromatography separation column 101 as described above, a method of filling the inside 102a of the column main body 102 with an adsorbent using a reservoir or a movable stopper has been proposed (see Patent Document 1).

Japanese Patent No. 2707780

  However, when filling the interior 102a of the column body 102 with a reservoir or a movable stopper, the upper fastening member 120, gasket 110, perforated plate 104, and lid plate 105 must be removed from the column body 102 in advance. It is troublesome because it must be done.

  Further, when the adsorbent is extracted from the interior 102 a of the column main body 102, the upper and lower fastening members 120, the gasket 110, the perforated plate 104, and the cover plate 105 must be removed from the column main body 102 in advance, which is troublesome.

  Therefore, there has been a demand for a separation column for liquid chromatography that can easily perform an adsorbent filling operation and an extraction operation.

  This invention is made | formed in view of this conventional subject, and it aims at providing the separation column for liquid chromatography which can perform the filling operation | work and extraction operation | work of an adsorbent easily.

  In order to solve the above-described problems, in the separation column for liquid chromatography of the present invention, the adsorbent conduit is passed through the central portion of one lid plate and the central portion of the perforated plate, and the tip thereof is inside the column body. It protruded and arranged.

  As a result, the adsorbent slurry is introduced into the column body from the adsorbent conduit and the eluent in the adsorbent slurry is discharged to the outside from the other stock solution conduit through the perforated plate and the hollow portion. As a result, the adsorbent in the adsorbent slurry is filled into the column body. Further, by introducing the eluent into the column main body from at least one of the stock solution conduits, the adsorbent filled in the column main body is discharged to the outside from the adsorbent conduit.

Moreover, the separation column for liquid chromatography of the present invention is configured such that the tip of the adsorbent conduit can be projected and retracted with respect to the inside of the column main body. Therefore, by retracting the tip of the adsorbent conduit to the perforated plate side before the stock solution is introduced, the flow of the stock solution can be prevented from being disturbed by the adsorbent conduit when the stock solution is introduced.

In addition, the separation column for liquid chromatography of the present invention is provided with guide means for assisting the operation of moving the tip of the adsorbent conduit. Therefore, it is possible to smoothly retract the tip of the adsorbent conduit.

Further, the separation column for liquid chromatography of the present invention is formed by forming a stock solution conduit on the same side as the adsorbent conduit on the outer peripheral side of the adsorbent conduit to form an adsorbent conduit and a double tube, The stock solution conduit was configured as a guide means. For this reason, it becomes possible to provide a guide means without increasing the number of parts.

Further, the separation column for liquid chromatography of the present invention was provided with a closing plug for closing the adsorbent conduit. Therefore, before the undiluted solution is introduced into the column main body from one undiluted solution conduit, the adsorbent conduit can be closed by closing the adsorbent conduit with a closing plug. Can be kept clean over time.

Further , the separation column for liquid chromatography of the present invention is further arranged by penetrating the adsorbent conduit through the central portion of the other lid plate and the central portion of the perforated plate, and projecting the tip portion into the column body. did. Therefore, the adsorbent can be packed from either the upper or lower side of the column body, and the adsorbent can be discharged from either the upper or lower side of the column body.

In the separation column for liquid chromatography of the present invention , a sealing material is provided between the adsorbent conduit and the through hole of the perforated plate. Therefore, it is possible to prevent the adsorbent slurry introduced into the column main body from leaking from between the adsorbent conduit and the through hole of the perforated plate and flowing toward the hollow portion.

The separation column for liquid chromatography of the present invention is provided with an inlet / outlet hole on the outer peripheral surface of the tip of the adsorbent conduit, and closes the through hole of the perforated plate when the tip is retracted into the end surface of the tip. A blocking part was provided. Therefore, when the distal end portion of the adsorbent conduit is retracted, the closing portion closes the through hole of the perforated plate, whereby the adsorbent conduit and the stock solution conduit are connected via the hollow portion. Therefore, by introducing the eluent from the stock solution conduit in this state, the adsorbent in the adsorbent conduit can be discharged to wash the adsorbent conduit.

  In the separation column for liquid chromatography of the present invention, the adsorbent slurry in the adsorbent slurry is filled into the column main body by introducing the adsorbent slurry into the column main body from the adsorbent conduit. Further, in the separation column for liquid chromatography of the present invention, the eluent is introduced into the column main body from at least one of the stock solution conduits, so that the adsorbent filled in the column main body is removed from the adsorbent conduit. To be discharged. Therefore, the separation column for liquid chromatography according to the present invention can perform the adsorbent filling operation and the extraction operation without removing the perforated plate and the cover plate from the column main body. Can be done.

In addition, the separation column for liquid chromatography of the present invention is designed such that the tip of the adsorbent conduit is retracted to the perforated plate side before the stock solution is introduced, so that when the stock solution is introduced, the stock solution flows through the adsorbent conduit. It can suppress being disturbed. Therefore, the separation column for liquid chromatography of the present invention can efficiently perform the separation work of the stock solution.

Further, the separation column for liquid chromatography of the present invention uses the guide means to assist the operation of the adsorbent conduit, so that the tip of the adsorbent conduit can be withdrawn smoothly. Therefore, the separation column for liquid chromatography of the present invention can quickly perform the washing operation of the adsorbent conduit.

Further, the separation column for liquid chromatography of the present invention is configured as a conduit for raw solution by forming a conduit for raw solution on the outer peripheral side of the conduit for adsorbent and forming a double tube, thereby increasing the number of parts. Without the guide means. Therefore, the separation column for liquid chromatography of the present invention can quickly perform the cleaning operation of the adsorbent conduit while suppressing the cost.

In addition, since the separation column for liquid chromatography of the present invention is configured such that the adsorbent conduit is closed with a closing plug before the stock solution is introduced into the column body, the entire separation column must be kept clean for a long time. Is possible. Therefore, the separation column for liquid chromatography of the present invention can also be used for the separation operation of a stock solution having a property of being easily spoiled when collected in a portion that tends to accumulate in the separation column, such as protein and sugar.

Further, the separation column for liquid chromatography of the present invention can be filled with the adsorbent from either the upper or lower side of the column body when the adsorbent conduits are arranged on the upper and lower sides. It is possible to discharge from either the upper or lower side of the column body. Therefore, the separation column for liquid chromatography of the present invention can further easily perform the adsorbent filling operation and the extraction operation.

In the separation column for liquid chromatography of the present invention, since the sealing material is provided between the adsorbent conduit and the through hole of the perforated plate, the adsorbent slurry introduced into the column main body is used as the adsorbent conduit. And leaking from between the through hole of the perforated plate can be prevented from flowing toward the hollow portion. Therefore, the separation column for liquid chromatography of the present invention can efficiently perform the adsorbent filling operation.

Furthermore, in the separation column for liquid chromatography of the present invention, the adsorbent conduit and the stock solution conduit are connected via the hollow portion when the tip of the adsorbent conduit is retracted. Therefore, by introducing the eluent from the stock solution conduit in this state, the adsorbent in the adsorbent conduit can be discharged to wash the adsorbent conduit. As a result, since the closing plug can be easily inserted into the adsorbent conduit, it is possible to reliably eliminate a liquid pool in a portion having poor cleaning properties in the separation column. Therefore, the separation column for liquid chromatography of the present invention can keep the entire separation column cleaner for a long time.

It is a schematic cross section of the separation column for liquid chromatography showing an embodiment of the present invention. It is an enlarged view centering on the upper part of the column main body of FIG. It is an enlarged view of the principal part of FIG. It is process drawing of the fractionation operation | work of each component of stock solution in the same embodiment. It is a flowchart which shows the process sequence of an adsorbent filling process in the embodiment. It is a figure which shows the filling operation | work of adsorption agent in the same embodiment. It is a flowchart which shows the process sequence of the conduit | pipe washing | cleaning process for adsorption agents in the same embodiment. It is a figure which shows the state which adsorbent has accumulated in the conduit | pipe for adsorbent in the embodiment. It is a figure which shows the raising operation | work of the upper side adsorbent conduit | pipe in the embodiment. It is a figure which shows the washing | cleaning operation | work of the adsorption agent conduit | pipe in the same embodiment. It is a flowchart which shows the process sequence of a stock solution introduction | transduction process in the same embodiment. It is a figure which shows the introduction | transduction operation | work of stock solution in the same embodiment. It is a flowchart which shows the process sequence of a component fractionation process in the embodiment. It is a figure which shows the fractionation operation | work of each component in the embodiment. It is a flowchart which shows the process sequence of an adsorbent discharge | emission process in the same embodiment. It is explanatory drawing which shows the push-down operation | work of the upper adsorption agent conduit | pipe in the same embodiment. It is a figure which shows the discharge | emission operation | movement of adsorption agent in the same embodiment. It is a schematic cross section of the conventional separation column for liquid chromatography.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a schematic sectional view of a separation column 1 for liquid chromatography showing an embodiment of the present invention. In the liquid chromatography separation column 1 of the present embodiment, the same parts as those in the conventional liquid chromatography separation column 101 shown in FIG. I will explain.

  The separation column 1 for liquid chromatography of the present embodiment has a perforated plate 4, a cover plate 5, two reinforcing plates 6, and a double tube installation flange 7 on the upper and lower ends of the column main body 102, respectively. The stock solution conduit 8, the adsorbent conduit 9, and the closing plug 10 are provided. Below, the structure of each member is demonstrated using FIGS. 1-3.

<Perforated plate 4>
As shown in FIG. 1, the perforated plate 4 is disposed on the outer surface of the flange 103 of the column main body 102 via a gasket 110. The perforated plate 4 is formed in a circular shape so as to cover the upper and lower openings of the column main body 102. The perforated plate 4 is configured so that the adsorbent cannot pass therethrough. This will be specifically described with reference to FIG.

  The perforated plate 4 is configured by laminating an eye plate 41 and a wire mesh 42 inside a ring-shaped portion 40 (see FIG. 1) having a water-blocking property. The eye plate 41 constitutes a portion on the outer surface side of the perforated plate 4. A through hole 41 a is provided in the central portion of the eye plate 41. The through hole 41a is formed in a circular shape. In addition, a large number of meshes are formed in portions of the mesh plate 41 other than the through holes 41a. The size of each mesh is set such that the adsorbent does not pass through.

  On the other hand, the wire mesh 42 constitutes a portion on the inner surface side of the perforated plate 4. A through hole 42 a is provided in the central portion of the wire mesh 42. The through hole 42a is formed in a circular shape. The wire mesh 42 is formed by laminating five wire meshes (not shown). The five metal meshes have different mesh sizes, and are usually stacked in the order in which the meshes become coarser in the liquid flow direction. Note that the mesh size of each wire mesh is set so that the adsorbent does not pass through. Further, the mesh size of the mesh with the coarsest mesh among the five meshes is set smaller than the mesh size of the mesh plate 41.

  Further, the size of the through hole 41a of the eye plate 41 and the size of the through hole 42a of the wire mesh 42 are the same, and their positions coincide. And the receiving part 43 is mounted | worn with both the through holes 41a and 42a. The receiving portion 43 is formed in an annular shape, and a through hole 4a of the perforated plate 4 is provided at the center portion thereof. Further, the outer peripheral surface 4b of the through hole 4a is formed in a tapered shape from the outside to the inside.

  On the other hand, the cover plate 5 is arranged on the outer surface of the perforated plate 4 via a gasket 110 as shown in FIG. The cover plate 5 is formed in a circular shape. As shown in FIG. 2, a through hole 5 a is provided in the central portion of the cover plate 5. The through hole 5a is formed in a cylindrical shape. Further, the through hole 5a is opposed to the through hole 4a of the perforated plate 4 so that the center coincides. In addition, a hollow portion 5s is formed between the perforated plate 4 below the through hole 5a. The hollow portion 5s is formed in a cross-sectional mountain shape around the through hole 5a.

<Reinforcement plate 6>
The two reinforcing plates 6 and 6 are each formed in an annular shape. As shown in FIG. 1, the two reinforcing plates 6 and 6 are arranged with the lid plate 5, the perforated plate 4, and the flange 103 interposed therebetween. And these members 4-6 are couple | bonded by the fastening member 12. As shown in FIG.

  Further, as shown in FIG. 2, an installation hole 6 a is provided in the central portion of the outer reinforcing plate 6. The installation hole 6a is formed in a circular shape. The installation hole 6a faces the through hole 5a of the cover plate 5 so that the center coincides with the through hole 5a. Further, the installation hole 6 a is formed larger than the through hole 5 a of the cover plate 5. Therefore, the outer surface 5b of the cover plate 5 is exposed in the installation hole 6a.

<Double pipe installation flange 7>
The double pipe installation flange 7 is formed in an annular shape. As shown in FIG. 2, the double pipe installation flange 7 is placed on the outer surface 5 b of the lid plate 5 through the gasket 13 in the installation hole 6 a of the outer reinforcing plate 6. Further, the double pipe installation flange 7 is fixed to the lid plate 5 by a fastening member 11.

  Further, a through hole 7 a is provided in the central portion of the double pipe installation flange 7. The through hole 7a is formed in a cylindrical shape. Further, the through hole 7 a is opposed to the through hole 5 a of the cover plate 5 so that the center coincides.

<Conduit 8 for stock solution>
As shown in FIG. 2, the stock solution conduit 8 includes a stock solution conduit body 81, a connection conduit 82, and a flange 83.

  The stock solution conduit body 81 is formed in a straight tubular shape. This undiluted solution conduit body 81 is passed through the through hole 7a of the double pipe installation flange 7 and fixed. The distal end portion 811 of the stock solution conduit body 81 is located in the through hole 5 a of the lid plate 5. A plurality of entrance / exit holes 81 a are provided on the outer peripheral surface of the distal end portion 811 so as to be aligned vertically. The plurality of inlet / outlet holes 81 a connect the through passage 81 b of the stock solution conduit body 81 and the through hole 5 a of the lid plate 5.

  The connecting conduit 82 is formed in a straight tubular shape. One end of the connection conduit 82 is coupled to the side surface of the base end of the stock solution conduit body 81. In addition, a through passage 82 a is formed inside the connection conduit 82.

  The flange 83 is provided on the outer periphery of the other end portion of the connection conduit 82. The flange 83 is formed in an annular shape.

  A flow path 8a is formed inside the stock solution conduit 8 configured as described above. The flow path 8 a is configured by connecting the inlet / outlet hole 81 a and the through path 81 b of the stock solution conduit body 81 and the through path 82 a of the connection conduit 82. The flow path 8 a connects the outside of the stock solution conduit 8 and the through hole 5 a of the cover plate 5.

<Adsorbent conduit 9>
The adsorbent conduit 9 has a T-shaped cross section as shown in FIG. The adsorbent conduit 9 includes an adsorbent conduit main body 91, a receiving portion sealing material 92, and a flange 93.

  The adsorbent conduit main body 91 is formed in a straight line. The adsorbent conduit main body 91 is passed through the through passage 81b of the stock solution conduit main body 81, the through hole 5a of the cover plate 5, and the through hole 4a of the perforated plate 4, and can move up and down. The adsorbent conduit main body 91 is provided with a seal 91c between the upper and lower portions of the through passage 81b. Further, the distal end portion 911 of the adsorbent conduit main body 91 is formed so as to be able to appear and retract with respect to the interior 102 a of the column main body 102. As shown in FIG. 3, a closing portion 94 is provided on the end surface of the distal end portion 911. The closing portion 94 is formed so as to close the through hole 4a of the perforated plate 4 when ascending.

  Further, a flow path 9a is formed in the adsorbent conduit main body 91. As shown in FIG. 3, this flow path 9a is comprised from the flow-path main body 91a and the entrance / exit hole 91b. The flow path main body 91a extends from the proximal end of the adsorbent conduit main body 91 toward the distal end portion 911, and the proximal end side is opened. The inlet / outlet port 91b is provided on the outer peripheral surface of the tip end portion 911 and connected to the tip end portion of the flow path body 91a.

  Further, as shown in FIG. 3, the receiving portion sealing material 92 is fitted and fixed to the proximal end side of the distal end portion 911 of the adsorbent conduit main body 91 and is further fixed to the through hole 4 a of the perforated plate 4. It fits inside. The receiving portion sealing material 92 is formed in an annular shape, and its outer peripheral surface 92a is formed in a tapered shape from the outside to the inside. Thereby, the seal material 92 for receiving parts moves up and down following the adsorbent conduit main body 91, so that it can be attached to and detached from the through hole 4 a of the perforated plate 4.

  As shown in FIG. 2, the flange 93 is provided on the outer periphery of the proximal end portion of the adsorbent conduit main body 91. The flange 93 is formed in an annular shape.

<Closed plug 10>
The closing plug 10 is a member for closing the adsorbent conduit 9 as shown in FIG. As shown in FIG. 2, the closing plug 10 has a T-shaped cross section and includes a base portion 10a and an insertion portion 10b.

  The base portion 10 a is a portion that comes into contact with the flange 93 of the adsorbent conduit 9. The base 10a is formed in a circular shape. On the inner surface of the base 10a, a gasket 10c is provided in a portion other than the central portion.

  The insertion portion 10b is a portion that is inserted into the flow path main body 91a of the adsorbent conduit main body 91. The insertion portion 10b is formed in a rod shape with a circular cross section. And one end of the insertion part 10b is couple | bonded with the center part of the inner surface of the base 10a. Further, a sealing material (not shown) is provided on the entire outer peripheral surface of the insertion portion 10b. Furthermore, the length of the insertion part 10b is set so that the connection state between the flow path body 91a and the inlet / outlet hole 91b is cut off when the insertion part 10b is inserted to the root of the flow path body 91a.

  Next, in the separation column 1 for liquid chromatography configured as described above, a fractionation operation of each component of the stock solution will be described. FIG. 4 is a process diagram of the sorting operation of each component of the stock solution. This preparatory work includes an adsorbent filling process (step SA), an adsorbent conduit cleaning process (step SB), a stock solution introducing process (step SC), a component sorting process (step SD), and an adsorbent discharging process (step SE). ) In this order. Below, each process is demonstrated.

<Adsorbent filling process>
The adsorbent filling process will be described with reference to FIGS. FIG. 5 is a flowchart showing the processing procedure of the adsorbent filling step. In this adsorbent filling step, the adsorbent B is filled into the interior 102 a of the column main body 102. In addition, it is desirable to fill the inside 102a of the column main body 102 with the eluent C before filling the adsorbent B. Each procedure will be specifically described below.

(Step SA1)
First, the user opens the upper adsorbent conduit 9 and closes the lower adsorbent conduit 9 with the closing plug 10.

(Step SA2)
Next, the user pulls down the lower adsorbent conduit 9 and locks the receiving portion seal material 92 to the tip of the lower stock solution conduit 8.

(Step SA3)
Next, the user connects one end of the eluent discharge pipe 21 to the flange 83 of the lower stock solution conduit 8. The other end of the eluent discharge pipe 21 is connected to an eluent C storage tank, discharge tank or the like (not shown).

(Step SA4)
Next, the user connects one end of the adsorbent transfer pipe 22 to the flange 93 of the upper adsorbent conduit 9. The other end of the adsorbent transfer pipe 22 is connected to a storage tank (not shown) for the adsorbent slurry A via transfer means (not shown) such as a pump. Note that the adsorbent slurry A is obtained by dispersing the adsorbent B in the eluent C.

(Step SA5)
Next, the user drives the transfer means. As a result, the adsorbent slurry A is introduced from the storage tank into the interior 102a of the column body 102 through the adsorbent transfer pipe 22 and the upper adsorbent conduit 9 in this order, and further on the lower perforated plate 4. Filtered. Specifically, the eluent C in the adsorbent slurry A passes through the lower perforated plate 4, and the adsorbent B in the adsorbent slurry A remains in the interior 102 a of the column main body 102.

  The eluent C that has passed through the lower perforated plate 4 passes through the lower hollow portion 5s, the through hole 5a of the lower lid plate 5, the lower stock solution conduit 8, and the eluent discharge tube 21 in this order. Enter the storage tank, discharge tank, etc. As time elapses, the adsorbent B accumulates and fills the interior 102a of the column body 102.

(Step SA6)
When the adsorbent B is filled in the interior 102a of the column main body 102, the user stops the transfer means. As a method for determining whether or not the adsorbent B is filled in the interior 102a of the column main body 102, a method of visually determining the column main body 102 formed of a transparent member, or an upper adsorbent conduit 9 and a method of judging based on a change in pressure applied to the adsorbent transfer pipe 22.

<Adsorbent conduit cleaning process>
Next, the adsorbent conduit cleaning step will be described with reference to FIGS. FIG. 7 is a flowchart showing the processing procedure of the adsorbent conduit cleaning step. When the adsorbent slurry A transfer means is stopped, the adsorbent B often accumulates in the upper adsorbent conduit 9 as shown in FIG. In this adsorbent conduit cleaning step, the adsorbent B accumulated in the upper adsorbent conduit 9 is extracted after the adsorbent filling step. Each procedure will be specifically described below.

(Step SB1)
First, the user removes the adsorbent transfer pipe 22 (see FIG. 6) used in the adsorbent filling step from the upper adsorbent conduit 9. Next, one end of the adsorbent discharge pipe 23 is connected to the flange 93 of the upper adsorbent conduit 9 as shown in FIG. The other end of the adsorbent discharge pipe 23 is connected to an adsorbent slurry A storage tank, discharge tank or the like (not shown).

(Step SB2)
Next, as shown in FIG. 8, the user connects one end of the eluent transfer pipe 24 to the flange 83 of the upper stock solution conduit 8. The other end of the eluent transfer pipe 24 is connected to a storage tank (not shown) for the eluent C via transfer means (not shown) such as a pump.

(Step SB3)
Next, as shown in FIG. 9, the user pulls up the upper adsorbent conduit 9 and locks the receiving portion sealing material 92 at the tip of the stock solution conduit 8. Accordingly, the distal end portion 911 of the upper adsorbent conduit 9 is retracted toward the perforated plate 4, and the closing portion 94 closes the through hole 4 a of the perforated plate 4. At the same time, the receiving portion sealing material 92 is separated from the receiving portion 43 to form a gap S between the receiving portion 43 and the receiving portion 43. Through this gap S, the hollow portion 5s and the inlet / outlet hole 91b of the adsorbent conduit 9 are connected. As a result, the stock solution conduit 8 and the adsorbent conduit 9 are connected via the hollow portion 5s.

(Step SB4)
Next, the user drives the transfer means. As a result, as shown in FIG. 10, the eluent C passes from the storage tank through the upper stock solution conduit 8, the through hole 5a of the upper lid plate 5, the upper hollow portion 5s, and the gap S in this order. To the adsorbent conduit 9. Then, the adsorbent B in the upper adsorbent conduit 9 is pushed out by the eluent C and discharged from the adsorbent conduit 9 as the adsorbent slurry A, and further passes through the adsorbent discharge pipe 23 and is stored in the storage tank. Enter the discharge tank.

(Step SB5)
The user stops the transfer means when the adsorbent B is not discharged from the upper adsorbent conduit 9. The upper adsorbent conduit 9 may be formed of a transparent member, and it may be visually determined whether or not the adsorbent B is discharged from the upper adsorbent conduit 9.

(Step SB6)
Next, the user closes the upper adsorbent conduit 9 with the closing plug 10. As a result, the upper and lower adsorbent conduits 9 are respectively closed by the closing plugs 10.

<Stock solution introduction process>
Next, the stock solution introducing step will be described with reference to FIGS. 11 and 12. FIG. 11 is a flowchart showing the processing procedure of the stock solution introducing step. In this stock solution introducing step, the stock solution D is introduced into the interior 102 a of the column main body 102 filled with the adsorbent B. Each procedure will be specifically described below.

(Step SC1)
First, the user connects one end of the stock solution transfer pipe 25 to the flange 83 of the upper stock solution conduit 8. The other end of the stock solution transfer pipe 25 is connected to a stock tank (not shown) for stock solution D via a transfer means (not shown) such as a pump. One end of the eluent discharge pipe 21 is connected to the flange 83 of the lower stock solution conduit 8. The other end of the eluent discharge pipe 21 is connected to a storage tank or a discharge tank for the eluent C. And so on (not shown) remain connected.

(Step SC2)
Next, the user drives the transfer means for a predetermined time. Thereby, a predetermined amount of the stock solution D is transferred from the storage tank to the stock solution transfer pipe 25, the upper stock solution conduit 8, the through hole 5a of the upper lid plate 5, the upper hollow portion 5s, and the upper perforated plate 4. They are sequentially introduced into the interior 102a of the column body 102. At this time, the eluent C in the interior 102 a of the column body 102 passes through the lower perforated plate 4, the lower hollow portion 5 s, and the through hole 5 a of the lower lid plate 5, and the lower stock solution conduit. 8 is discharged to a storage tank, a discharge tank or the like of the eluent C.

  Depending on the separation system, the user may need adjustment liquid from the upper raw liquid conduit 8 in order to adjust the state of the adsorbent B to be suitable for separation of the components of the raw liquid D prior to the introduction of the raw liquid D. There may be a large amount. This adjustment liquid flows through the interior 102a of the column main body 102, passes through the lower perforated plate 4, the lower hollow portion 5s, and the through hole 5a of the lower lid plate 5, and passes through the lower stock solution conduit 8. Discharged from. After flowing the necessary amount of the adjustment liquid into the interior 102a of the column main body 102, the washing eluent C is caused to flow into the interior 102a of the column main body 102 and the adjustment liquid remaining in the internal 102a is washed.

<Component preparative process>
Next, the component sorting step will be described with reference to FIGS. FIG. 13 is a flowchart showing the processing procedure of the component sorting step. In this component sorting step, the eluent C is introduced into the interior 102a of the column main body 102, and each component E of the stock solution D introduced into the adsorbent B is taken out. Each procedure will be specifically described below.

(Step SD1)
First, the user connects one end of the sorting transfer pipe 26 to the flange 83 of the lower stock solution conduit 8. A storage tank (not shown) for each component E is connected to the other end of the sorting transfer pipe 26.

(Step SD2)
Next, the user connects one end of the eluent transfer pipe 24 to the flange 83 of the upper stock solution conduit 8. The other end of the eluent transfer pipe 24 is connected to a storage tank (not shown) for the eluent C via transfer means (not shown) such as a pump, as described in step SB2. Yes.

(Step SD3)
Next, the user drives the transfer means. As a result, the eluent C flows from the storage tank in the order of the eluent transfer pipe 24, the upper stock solution conduit 8, the through hole 5a of the upper lid plate 5, the upper hollow portion 5s, and the upper perforated plate 4. And is introduced into the interior 102 a of the column body 102.

  As the eluent C, in addition to using one type of eluent C, many types of eluent C may be used stepwise. Alternatively, the eluent C may be flowed so that the concentration of the component contained in the eluent C changes continuously.

(Step SD4)
When the eluent C is introduced into the interior 102a of the column main body 102, each component E in the stock solution D introduced into the adsorbent B differs depending on the difference in affinity with the adsorbent B while being eluted by the eluent C. The adsorbent B layer is separated by moving at a speed, passes through the lower perforated plate 4, the lower hollow portion 5 s, and the through hole 5 a of the lower cover plate 5, from the lower stock solution conduit 8. It is discharged to the transfer pipe 26 for sorting.

  That is, a component having a weak affinity for the adsorbent B moves quickly through the adsorbent B layer, and a component having a strong affinity for the adsorbent B moves slowly through the adsorbent B layer and is discharged to the sorting transfer pipe 26. . Therefore, when the component E eluted from the adsorbent B layer is discharged to the sorting transfer pipe 26, the user checks each component E in the sorting transfer pipe 26 while checking the discharge timing of each component E. The storage tanks of E are connected alternately, and each component is stored in each storage tank.

(Step SD5)
Then, the user stops the transfer means when the component E having the strongest affinity for the adsorbent B is stored in the storage tank. Thereafter, in order to remove trace components remaining adsorbed by the adsorbent B, the adsorbent B is washed by flowing the eluent C for washing. In addition, this component fractionation process SD and the previous stock solution introduction process SC can be repeatedly performed until the separation performance of the stock solution D by the adsorbent B is lowered.

<Adsorbent discharge process>
Next, the adsorbent discharging process will be described with reference to FIGS. FIG. 15 is a flowchart showing the processing procedure of the adsorbent discharging step. In this adsorbent discharging step, the adsorbent B filled in the interior 102a of the column body 102 is extracted. Each procedure will be specifically described below.

(Step SE1)
First, when the user uses the upper adsorbent conduit 9 for transferring the adsorbent slurry A, the user pushes down the upper adsorbent conduit 9 as shown in FIG. Is inserted into the through hole 4 a of the perforated plate 4. As a result, the tip end portion 911 of the adsorbent conduit 9 protrudes into the interior 102 a of the column main body 102. Therefore, as shown in FIG. 17, the upper adsorbent conduit 9 is connected to the inside 102 a of the column main body 102 and disconnected from the upper stock solution conduit 8.

  Similarly, when the user uses the lower adsorbent conduit 9 for transferring the adsorbent slurry A, the user pushes up the lower adsorbent conduit 9 and pushes the tip end portion 911. It protrudes into the interior 102a of the column body 102. As a result, as shown in FIG. 17, the lower adsorbent conduit 9 is connected to the interior 102a of the column main body 102 and disconnected from the lower stock solution conduit 8.

(Step SE2)
Next, the user connects one end of the eluent transfer pipe 24 to the flange 83 of the lower stock solution conduit 8. The other end of the eluent transfer pipe 24 is connected to a storage tank (not shown) for the eluent C via transfer means (not shown) such as a pump. It is assumed that the eluent transfer pipe 24, the transfer means (not shown), and the eluent C storage tank (not shown) remain connected to the flange 83 of the upper stock solution conduit 8.

(Step SE3)
Next, the user removes the upper and lower closing plugs 10 shown in FIG. 14 from the adsorbent conduit 9 and connects one end of the adsorbent discharge pipe 23 to the flange 93 of each of the upper and lower adsorbent conduits 9. To do. The other ends of the upper and lower adsorbent discharge pipes 23 are connected to an adsorbent slurry A storage tank, discharge tank or the like (not shown) as described in step SB1.

(Step SE4)
Next, the user drives the upper transfer means. As a result, the eluent C is transferred from the storage tank to the upper eluent transfer pipe 24, the upper stock solution conduit 8, the through hole 5 a of the upper lid plate 5, the upper hollow portion 5 s, and the upper perforated plate 4. And are introduced into the interior 102a of the column main body 102. Then, the adsorbent B on the upper side of the inside 102a of the column main body 102 is pushed out together with the eluent C, and is stored as an adsorbent slurry A from the upper adsorbent conduit 9 through the upper adsorbent discharge pipe 23. Enter the discharge tank.

(Step SE5)
When the adsorbent B is not discharged from the upper adsorbent conduit 9, the user stops the upper transfer means. Alternatively, the upper adsorbent conduit 9 may be formed of a transparent member, and it may be visually determined whether or not the upper adsorbent B has been discharged.

(Step SE6)
Next, the user drives the lower transfer means. As a result, the eluent C flows from the storage tank to the lower eluent transfer pipe 24, the lower undiluted solution conduit 8, the through hole 5a of the lower lid plate 5, the lower hollow portion 5s, and the lower side. Are introduced into the interior 102a of the column body 102 through the perforated plate 4 in this order. Then, the adsorbent B remaining on the lower side of the interior 102a of the column main body 102 is pushed out together with the eluent C to form an adsorbent slurry A from the lower adsorbent conduit 9 to the lower adsorbent discharge pipe 23. Pass through the storage tank, discharge tank, etc.

(Step SE7)
When the adsorbent B is no longer discharged from the lower adsorbent conduit 9, the user stops the lower transfer means. As in the case of the upper adsorbent conduit 9, the lower adsorbent conduit 9 is formed of a transparent member, and it is visually determined whether or not the lower adsorbent B is discharged. Also good.

  As described above, in the liquid chromatography separation column 1 of the present embodiment, the tip end portion 911 of the adsorbent conduit 9 is disposed so as to protrude into the interior 102 a of the column main body 102. Thus, in the adsorbent filling step SA, the adsorbent slurry A is introduced into the interior 102a of the column body 102 and the eluent C in the adsorbent slurry A is discharged to the outside, whereby the adsorbent in the adsorbent slurry A is discharged. B fills the interior 102a of the column body 102. Therefore, the adsorbent B can be filled without removing the perforated plate 4 and the cover plate 5 from the column main body 102.

  Furthermore, the separation column 1 for liquid chromatography according to the present embodiment introduces the eluent C into the interior 102a of the column body 102 in the adsorbent discharging step SE, so that the adsorption filled in the interior 102a of the column body 102 is performed. Agent B was discharged outside. Therefore, the adsorbent B can be extracted without removing the perforated plate 4 and the cover plate 5 from the column main body 102.

  Therefore, the separation column 1 for liquid chromatography of the present embodiment can easily perform the filling operation and the extraction operation of the adsorbent B. Further, since the adsorbing agent B is filled from the upper central portion of the column body 102, the adsorbent B can be uniformly filled into the interior 102a of the column body 102.

  In the separation column 1 for liquid chromatography of the present embodiment, the upper and lower adsorbent conduits 9 are closed with the closing plug 10 before the stock solution D is introduced in the stock solution introduction step SC. Thereby, the liquid pool part of the separation column 1 can be eliminated. Therefore, even when the separation operation of the stock solution D is repeated, the entire separation column 1 can be kept clean for a long time. Therefore, the separation column 1 for liquid chromatography according to the present embodiment is also used for the separation operation of a stock solution having a property of being easily spoiled when collected in a portion that tends to accumulate in the separation column, such as protein and sugar. it can.

  In the liquid chromatography separation column 1 of the present embodiment, the adsorbent slurry A is introduced into the interior 102a of the column main body 102 from the upper adsorbent conduit 9, but the adsorbent slurry A is disposed on the lower side. You may make it introduce | transduce into the inside 102a of the column main body 102 from the conduit | pipe 9 for adsorption agents. In this case, the upper adsorbent conduit 9 is closed with the closing plug 10.

  As described above, the separation column 1 for liquid chromatography according to the present embodiment can be filled with the adsorbent B from either the upper or lower side of the column main body 102. Further, since the adsorbent conduits 9 are arranged on the upper and lower sides of the column main body 102, the adsorbent B can be extracted from either the upper or lower side of the column main body 102. Therefore, the separation column 1 for liquid chromatography according to the present embodiment can further easily perform the filling operation and the extraction operation of the adsorbent B.

  Further, in the liquid chromatography separation column 1 of the present embodiment, the receiving portion sealing material 92 is provided between the adsorbent conduit 9 and the through hole 4 a of the perforated plate 4. As a result, in the adsorbent filling step SA, the adsorbent slurry A introduced into the interior 102a of the column body 102 leaks from between the adsorbent conduit 9 and the through hole 4a of the perforated plate 4 toward the hollow portion 5s. Can be prevented from flowing into. Therefore, the separation column 1 for liquid chromatography of the present embodiment can efficiently perform the filling operation of the adsorbent B.

  Further, the separation column 1 for liquid chromatography according to the present embodiment is configured such that the adsorbent conduit 92 is attached to and detached from the through hole 4a of the perforated plate 4 by the receiving portion sealing material 92 fixed to the adsorbent conduit 9 side. 9 is configured such that the tip end portion 911 thereof can be projected and retracted with respect to the inside 102 a of the column main body 102. Therefore, in the adsorbent conduit cleaning step SB, when the tip 911 of the upper adsorbent conduit 9 is retracted to the upper perforated plate 4 side, the upper adsorbent conduit 9 and the upper undiluted solution conduit 8 Is connected. For this reason, by introducing the eluent C from the upper stock solution conduit 8, the adsorbent B in the adsorbent conduit 9 can be discharged to wash the adsorbent conduit 9. As a result, the closing plug 10 can be easily inserted into the adsorbent conduit 9, so that the liquid pool in the portion having poor cleaning properties in the separation column 1 can be reliably eliminated. Therefore, the separation column 1 for liquid chromatography of the present invention can keep the entire separation column 1 clean for a long time.

  Furthermore, in the liquid chromatography separation column 1 of the present embodiment, the tip 911 of the lower adsorbent conduit 9 is retracted to the lower perforated plate 4 side in the adsorbent filling step SA. Therefore, when entering the stock solution introduction process SC, the tip 911 of the upper and lower adsorbent conduits 9 does not protrude into the interior 102a of the column body 102. Thereby, when the stock solution D is introduced, the flow of the stock solution D can be prevented from being disturbed by the upper and lower adsorbent conduits 9. Therefore, the separation column 1 for liquid chromatography according to the present embodiment can efficiently perform the separation work of the stock solution D.

  Further, in the liquid chromatography separation column 1 of the present embodiment, the upper and lower stock solution conduits 8 (stock solution conduit body 81) are formed on the outer peripheral side of the adsorbent conduit 9 to form a double tube. As a result, the adsorbent conduit 9 moves up and down along the stock solution conduit main body 81 so that the tip end portion 911 appears and disappears from the interior 102 a of the column main body 102. That is, since the stock solution conduit 8 serves as a guide means for assisting the operation of the adsorbent conduit, the tip 911 of the adsorbent conduit 9 can be retracted smoothly. Therefore, the separation column 1 for liquid chromatography of the present embodiment can quickly perform the cleaning operation of the adsorbent conduit 9.

  Furthermore, since the undiluted solution conduit 8 is used as a guide means for assisting the operation of the adsorbent conduit 9, the increase in the number of parts can be suppressed. Therefore, the separation column 1 for liquid chromatography according to the present embodiment can quickly perform the cleaning operation of the adsorbent conduit 9 while reducing the cost.

  As mentioned above, although embodiment concerning this invention was illustrated, these embodiments do not limit the content of this invention. Various modifications can be made without departing from the scope of the claims of the present invention.

  For example, in the separation column 1 for liquid chromatography of the present embodiment, the stock solution conduit 8 and the adsorbent conduit 9 constitute a double tube, but it is not always necessary that both conduits 8 and 9 comprise a double tube. Instead, both the conduits 8 and 9 may be arranged in parallel at the central portion on the upper and lower sides of the column main body 102.

  Further, in the liquid chromatography separation column 1 of the present embodiment, the adsorbent conduits 9 are arranged on the upper and lower sides of the column main body 102, respectively, but may be arranged on at least one of the upper and lower sides of the column main body 102. Even in that case, the adsorbent B filling operation and the extracting operation can be easily performed.

  Further, in the liquid chromatography separation column 1 of the present embodiment, the receiving portion sealing material 92 fixed to the adsorbent conduit side is attached to and detached from the through hole 4 a of the perforated plate 4, whereby the adsorbent conduit 9. The tip portion 911 is configured to be able to appear and retract with respect to the interior 102a of the column main body 102. However, the configuration that allows the tip portion 911 to appear and retract relative to the interior 102a of the column main body 102 is limited to the configuration of the present embodiment. You don't have to. For example, when the sealing material for the receiving part is fixed to the through hole 4a of the perforated plate 4, the adsorbent conduit is fitted into the through hole of the sealing material for the receiving part so as to be movable up and down, and the supporting means is The adsorbent conduit may be supported so as to be movable up and down. Even in such a case, by retracting the tip of the adsorbent conduit to the perforated plate 4 before introducing the stock solution, the flow of the stock solution can be prevented from being disturbed by the adsorbent conduit when the stock solution is introduced. Can be efficiently performed.

  In the liquid chromatography separation column 1 of the present embodiment, in the adsorbent discharging step SE, the eluent C is introduced into the interior 102a of the column body 102 from both the upper and lower stock conduits 8 and is filled in the interior 102a. Although the adsorbent B is extracted, the adsorbent B may be extracted by introducing the eluent C into the interior 102a of the column body 102 from one of the stock solution conduits 8.

  In the separation column 1 for liquid chromatography of the present embodiment, various connection pipes are exchanged and connected to the stock solution conduit 8 and the adsorbent conduit 9 for each step. There are methods. One end of the branch pipe is connected to the stock solution conduit 8 and the adsorbent conduit 9, and the other end of each branch tube is connected to a predetermined tank (the tank for the adsorbent slurry A, the tank for the eluent C, the stock solution D A tank, a tank for each component E). Then, by using a valve, the stock solution conduit 8 or the adsorbent conduit 9 and each tank are switched and connected for each process.

  As described above, the separation column for liquid chromatography of the present invention can easily perform the adsorbent filling operation and the extraction operation. Therefore, the separation column for liquid chromatography of the present invention can be fully utilized in the technical field of separation columns for liquid chromatography.

DESCRIPTION OF SYMBOLS 1 Separation column for liquid chromatography 4 Perforated plate 4a Through hole of perforated plate 5 Lid plate 5s Hollow part 8 Conduit for undiluted solution 9 Adsorbent conduit 10 Closure plug 91b Inlet / outlet hole 92 Receiving part sealing material 94 Closure part 102 Column body 102a Inside of column main body 911 End of adsorbent conduit A A Adsorbent slurry B Adsorbent C Eluent D Stock solution

Claims (5)

A cylindrical column body whose upper and lower ends are opened, a pair of perforated plates that are provided so as to cover the upper and lower openings of the column body and cannot pass the adsorbent, and outside the perforated plates. Separation column for liquid chromatography comprising a pair of lid plates provided to form a hollow portion, and a pair of stock solution conduits penetrating through the central portions of both lid plates and having a tip portion located in the hollow portion In
The adsorbent conduit passes through the central part of one lid plate and the central part of the perforated plate, and its tip protrudes into the column body and can be projected and retracted with respect to the column body. And a guide means for assisting the movement of the tip portion. The guide means is formed by forming the stock solution conduit on the same side as the adsorbent conduit on the outer peripheral side of the adsorbent conduit. A separation column for liquid chromatography, which is constituted by forming a double tube with the adsorbent conduit . The separation column for liquid chromatography according to claim 1,
A separation column for liquid chromatography, comprising a closing plug for closing the adsorbent conduit. The separation column for liquid chromatography according to claim 2,
The same adsorbent conduit as the adsorbent conduit passes through the central portion of the other lid plate and the central portion of the perforated plate, and its tip protrudes into the column body. Separation column for liquid chromatography. The separation column for liquid chromatography according to any one of claims 1 to 3,
A separation column for liquid chromatography, wherein a sealant is provided between the adsorbent conduit and the through hole of the perforated plate. The separation column for liquid chromatography according to any one of claims 1 to 4,
An inlet / outlet hole is provided on the outer peripheral surface of the tip portion of the adsorbent conduit, and a blocking portion is provided on the end surface of the tip portion to close the through hole of the perforated plate when the tip portion is retracted. Separation column for liquid chromatography.

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