JP2009216586A - Separation column, and liquid chromatograph using it - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a monolith type separation column having improved separation performance and pressure resistance performance, and a liquid chromatograph using it. <P>SOLUTION: This monolith type separation column has a porous monolith rod 1 formed to have a cylindrical shape, supports 2, 3, 4 for covering the outer circumference of the monolith rod 1, a sealing member 7 provided on the end of the supports, a packing 6 provided between the supports 2, 3, 4 and the sealing member 7, and a filter 5 provided on the center part of the packing 6. The sealing member 7 and the supports 2, 3, 4 are connected together by rotation of the sealing member with respect to the supports, when the center axis of the sealing member 7 is approximately coaxial with the center axis of the supports. The column has a stronger force than a torque of the packing 6 and the filter 5 rotated when the sealing member 7 is rotated, between the end face of the supports and the packing 6. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a separation column that separates components in a liquid sample used in high performance liquid chromatographs and the like, and a liquid chromatograph using the same, and in particular, a separation column suitable for those using a monolith column and the same. It relates to the liquid chromatograph used.

  Conventionally, in high performance liquid chromatographs, etc., instead of the commonly used particle packed column, a monolithic column having a structure in which a three-dimensional network skeleton and its voids (flow channel, macropore, through-pore) are integrated is used. What was used is known (for example, refer to Patent Document 1). By using a monolith column, the surface area is increased, but a column having a large porosity and no increase in flow resistance can be realized. As a result, high performance is achieved by using a monolithic column in which a monolith rod (porous body) is incorporated in a narrow tube.

  The monolithic column has a configuration in which a sealing member is provided at an end of a monolith rod whose outer peripheral surface is covered with a support, and a filter is provided between the monolith rod and the sealing member.

  Since the monolith rod that is a molded body has undulation, warpage, and the like, a gap is easily generated between the thin tube and the monolith rod, and leakage of the mobile phase from the side surface of the monolith rod easily occurs. In order to solve this problem, as disclosed in Patent Document 1, one in which the outer peripheral surface of a monolith rod is covered with a resin coating material is known. In addition, in order to improve the contact between the thin tube main body and the monolith rod, after introducing the monolith rod into the fiber reinforced plastic tube, the tube is heated to make the plastic adhere to the monolith rod. .

JP-A-11-64314

  As in Patent Document 1, a specific example for preventing leakage of the mobile phase from the side surface of the monolith rod has been proposed. However, nothing is known that focuses on the filter structure provided on the end face of the monolith rod.

  As a result of various studies on the monolithic column, the present inventors have found that the following problems occur. That is, in the conventional configuration, (1) when the sealing member is attached to the end of the monolith rod whose outer peripheral surface is covered with the support, the filter provided between the end of the monolith rod and the sealing member rotates. As a result, wear powder is generated between the monolith rod and the filter. Also, (2) clogging occurs when the wear powder fills the gap between the monolith rod and the filter, or when the wear powder enters between the packing provided on the outer periphery of the filter and the support, the sealing performance is deteriorated. Occur. As a result, the separation performance and pressure resistance performance of the monolith type separation column may be reduced.

  An object of the present invention is to provide a monolith type separation column with improved separation performance and pressure resistance performance, and a liquid chromatograph using the same.

(1) In order to achieve the above object, the present invention is provided at a monolith rod formed into a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, and an end of the support. A monolith-type separation column having a sealing member, a packing provided between the support and the sealing member, and a filter provided in a central portion of the packing, the sealing member and the support The body is connected by rotating the sealing member relative to the support when the central axis of the sealing member is substantially coaxial with the central axis of the support, Between the end face of the support and the packing, a holding force larger than the rotational force of the packing and the filter rotated when the sealing member is rotated is provided.
With such a configuration, separation performance and pressure resistance performance can be improved.

  (2) In the above (1), preferably, an uneven portion is provided on at least one of the end surface of the support and at least one of the surfaces of the packing facing the support. is there.

  (3) In the above (1), preferably, at least a part of the end surface of the support and at least a part of the side surface of the packing are held by a positioning guide.

  (4) In the above (3), preferably, at least a part of a surface of the support body held by the positioning guide, at least a part of a surface of the packing held by the positioning guide, and the positioning guide At least one of at least a part of is substantially flat.

  (5) In the above (1), preferably, at least one pin hole is provided in an end surface of the support, and at least one pin hole is provided in the packing. The support and the packing are: It is held by positioning pins inserted into the pin holes of the support and the pin holes of the packing.

  (6) In the above (1), preferably, a positioning guide is provided on an end face of the support, and the positioning guide has a central axis on an axis substantially parallel to and different from the central axis of the support. A round or substantially polygonal opening is provided, and the packing is accommodated in the opening.

(7) In order to achieve the above object, the present invention provides a monolith type separation column having a monolith rod formed into a cylindrical shape with a porous body and a support covering the outer periphery of the monolith rod. A convex concave portion is formed in a part of the end surface of the support.
With such a configuration, separation performance and pressure resistance performance can be improved.

(8) In order to achieve the above object, the present invention provides a monolith rod formed into a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, and an end of the support. In a monolith type separation column having a sealing member provided, a packing provided between the support and the sealing member, and a filter provided in the center of the packing, the support and the packing A spacer is provided between them, and the central part of the spacer has an opening.
With such a configuration, separation performance and pressure resistance performance can be improved.

  (9) In the above (8), preferably, the size of the opening is substantially the same as the end face of the monolith rod or larger than the end face of the monolith rod.

(10) In order to achieve the above object, the present invention provides a monolith rod formed into a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, and an end of the support. In a monolith type separation column having a sealing member provided, a packing provided between the support and the sealing member, and a filter provided at the center of the packing, one end face of the support is provided. The part is joined to the sealing member.
With such a configuration, separation performance and pressure resistance performance can be improved.

(11) In order to achieve the above object, the present invention provides a monolithic rod formed of a porous body in a cylindrical shape, a support covering the outer periphery of the monolith rod, and an end of the support. A liquid chromatograph using a monolith type separation column comprising a sealing member provided, a packing provided between the support and the sealing member, and a filter provided at the center of the packing, The sealing member and the support are connected by rotating the sealing member reversely with the support when the central axis of the sealing member is substantially coaxial with the central axis of the support. And having a holding force larger than the rotational force of the packing and the filter that are rotated substantially simultaneously when the sealing member is rotated between the end surface of the support and the packing. I did Than is.
With such a configuration, separation performance and pressure resistance performance can be improved.

  ADVANTAGE OF THE INVENTION According to this invention, the isolation | separation performance and pressure | voltage resistant performance in a monolith type separation column and a liquid chromatograph using the same can be improved.

Hereinafter, the configuration of a separation column according to the first embodiment of the present invention and a liquid chromatograph using the same will be described with reference to FIGS. 1 and 2.
First, the configuration of the separation column according to the present embodiment will be described with reference to FIG.
FIG. 1 is a configuration diagram of a separation column according to the first embodiment of the present invention. FIG. 1A is an exploded perspective view, and FIG. 1B is a cross-sectional view. FIG. 1 (a) shows components on one side (eg, the inflow side) of the separation column.

  The separation column includes a monolith rod 1, a covering support 2, a filling support 3, a support 4, a filter 5, a packing 6, and a sealing member 7. The monolith rod 1 is a porous body and is formed into a cylindrical shape. The outer peripheral surface of the monolith rod 1 is covered with a covering support 2. The covering support 2 is a heat shrinkable tube made of a fluorine resin having high chemical resistance. The monolith rod 1 covered with the covering support 2 is inserted into a metal support 4. The filling support 3 is filled in the gap between the covering support 2 and the support 4. For example, silicon rubber is used as the filling support 3.

  In the following description, the structure on one side of the separation column will be described, but the other structure is the same. A metal sealing member 7 is attached to the end surface of the support 4. A filter 5 and a packing 6 are sandwiched between the support 4 and the sealing member 7. The filter 5 is press-fitted into the center of the packing 6. The filter 5 is in contact with the end of the monolith rod 1. For example, a filter having a pore diameter of about 2 μm is used. The support 4 and the sealing member 7 are fixed by tightening the support-side screw portion 8 formed on the support 4 and the sealing-member-side screw portion 9 formed on the sealing member 7. The packing 6 is firmly fixed by the above-described screw tightening. As a material of the packing 6, for example, a fluororesin is used.

  Here, in the separation column, the end face of the support 4 does not have a force to hold the packing 6 firmly. Therefore, in the conventional structure, when the sealing member 7 is attached to the support 4 by screw tightening (rotation), the packing 6 and the filter 5 rotate together with the sealing member 7 about the central axis of the support 4. The abrasion powder generated between the monolith rod 1 and the filter 5 due to this rotation causes clogging by filling the gap between the monolith rod 1 and the filter 5 or enters between the packing 6 and the support 4. As a result, the sealing performance was lowered. This caused a decrease in separation performance and pressure resistance.

  In order to solve this problem, in this embodiment, an uneven portion 12 for holding the packing 6 firmly is formed on the end surface of the support 4. The uneven portion 12 is formed by, for example, sandblasting. The roughness of the concavo-convex portion 12 is at least 1 μm or more.

  By forming the uneven portion 12 on the end surface of the support 4, the uneven portion 12 bites into the packing 6, so that the packing 6 does not slide on the end surface of the support 4. That is, between the end face of the support 4 and the packing 6, the packing 6 is slid because it has a holding force larger than the rotational force of the packing 6 and the filter 5 rotated when the sealing member 7 is rotated. Disappear. Therefore, when the sealing member 7 is attached to the support body 4 by screw tightening, the packing 6 and the filter 5 do not rotate. Since the filter 5 does not rotate, no abrasion powder is generated between the monolith rod 1 and the filter 5. Thereby, clogging of the monolith rod 1 and the filter 5 can be prevented. Furthermore, it is possible to prevent a decrease in sealing performance between the packing 6 and the support 4.

  In particular, for a liquid chromatograph that can be used even when the maximum pressure of the mobile phase flowing into the separation column is 5 to 30 MPa or more and can shorten the analysis time, the diameter of the monolith rod 1 is 1.2 to 2.8 mm, preferably 2 mm. The length in the flow direction, that is, the length of the separation column needs to be 30 mm to 200 mm. The diameter and length vary depending on the sample to be separated. Therefore, it is desirable to prepare a monolith rod 1 having a diameter of 2 mm and a length of 30, 50, 75, 100 mm or the like.

  In addition, when the liquid is fed at the same pressure, the liquid feeding amount per unit time (that is, the consumption amount of the mobile phase) is constant as long as the cross-sectional area (that is, the porosity) through which the liquid passes is constant. It is inversely proportional to the cross-sectional area. Therefore, compared with the case where the monolith rod 1 having a diameter of about 4 mm is used, the consumption of the mobile phase can be reduced to a quarter by using the monolith rod 1 having a diameter of 2 mm or less. As a result, it is possible to obtain an easy-to-use separation column that can be used in a flow rate range of 1.0 ml / min or less widely used in general-purpose high performance liquid chromatographs.

  As described above, in the process of manufacturing the separation column, the monolith rod 1 and the filter 5 can be prevented from being clogged, and further, the sealing performance between the packing 6 and the support 4 can be prevented from being lowered. Therefore, a separation column excellent in separation performance and pressure resistance performance can be realized.

  In addition, the structure which covers the outer periphery of the monolith rod 1 is not restricted to what was shown in FIG. For example, the coating layer of the monolith rod 1 may be more or less than three layers. Further, the outer peripheral surface of the covering support 2 or the inner peripheral surface of the support 4 may have a tapered shape or an uneven shape instead of a straight shape. As for the material, for example, a heat-shrinkable tube made of silicone resin can be used for the covering support 2. The filling support 3 may be made of resin, metal, adhesive, fluid rubber, beads having a particle diameter of about 1 to 2 μm (glass beads, ceramic beads, resin beads, metal beads) and the like. Furthermore, glass, ceramic, resin, or the like can be used for the support.

  Further, in the present embodiment, the uneven portion 12 is formed on the end surface of the support 4, but the uneven portion is formed on the packing 6 instead of the support 4, or both the support 4 and the packing 6 are uneven. A part may be formed.

Next, the configuration of the liquid chromatograph according to the present embodiment will be described with reference to FIG.
FIG. 2 is a block diagram showing the configuration of the liquid chromatograph according to the first embodiment of the present invention.

  The mobile phase 13 is sent to the separation column 16 by the pump 14. The separation column 16 is disposed in the thermostatic chamber 17. The configuration of the separation column 16 is as described in FIG. The sample is introduced into the flow path by an autosampler 15 having a switching valve between the pump 14 and the separation column 16.

  As shown in FIG. 1, an inflow pipe (not shown) is connected to the connection portion 10 of the sealing member 7 on the inflow side. The sample to be separated and the mobile phase flow into the separation column 16 from the flow path 11. The sample and the mobile phase that have flowed in pass through the filter 5 and diffused in the radial direction, and then flow into the monolith rod 1 and move to the outflow side while repeating desorption, thereby separating each chemical component constituting the sample.

  Each separated component separated by the separation column 16 is detected by a detector 18.

  As described above, according to the present embodiment, when the sealing member is attached to the end of the monolith rod whose outer peripheral surface is covered with the support, no abrasion powder is generated between the end of the monolith rod and the filter. Therefore, the monolith rod and the gap of the filter are not clogged. Further, the sealing performance is not deteriorated by entering between the packing provided on the outer periphery of the filter and the end face of the support. Therefore, a monolith type separation column and liquid chromatograph excellent in separation performance and pressure resistance performance can be obtained.

Next, the configuration of the separation column according to the second embodiment of the present invention will be described with reference to FIG. The configuration of the liquid chromatograph using the separation column according to the present embodiment is the same as that shown in FIG.
FIG. 3 is a configuration diagram of a separation column according to the third embodiment of the present invention. 3A is an exploded perspective view, and FIG. 3B is a cross-sectional view. The same reference numerals as those in FIG. 1 denote the same parts.

  The separation column of this embodiment is different from the embodiment shown in FIG. 1 in that a positioning guide 19 is provided on the end surface of the support 4. The positioning guide 19 has a semi-cylindrical shape. The positioning guide 19 is disposed in a semicylindrical recess 20 formed on the end surface of the support 4. A flat portion is formed on the side surface of the packing 6. The packing 6 is held by the positioning guide 19 when the flat portion of the positioning guide 19 and the flat portion of the packing 6 face each other. Since the holding force larger than the rotational force of the packing 6 and the filter 5 rotated when the sealing member 7 is rotated is provided between the end surface of the support 4 and the packing 6, the packing 6 slips. Disappear. Therefore, the packing 6 and the filter 5 do not rotate.

  Here, when the sealing member 7 is attached to the support 4 by screw tightening, the sealing property between the packing 6 and the supporting member 4 and the sealing property between the packing 6 and the sealing member 7 are obtained. The protruding amount of the positioning guide 19 from the support 4 is substantially the same as the thickness of the packing 6 or smaller than the thickness of the packing 6.

  In addition, the structure which covers the outer periphery of the monolith rod 1 is not restricted to what was shown in FIG. 3 similarly to embodiment of FIG. The shape of the positioning guide 19 and the number of surfaces holding the packing 6 are not limited to those shown in FIG. Further, the positioning guide 19 may be integrated with the support 4 or the packing 6. Furthermore, the recessed part 20 formed in the end surface of the support body 4, the side surface of the packing 6, and the positioning guide 19 may be tapered.

  Also according to the present embodiment, when attaching the sealing member to the end of the monolith rod whose outer peripheral surface is covered with the support, no abrasion powder is generated between the end of the monolith rod and the filter. There is no clogging of the voids. Further, the sealing performance is not deteriorated by entering between the packing provided on the outer periphery of the filter and the end face of the support. Therefore, a monolith type separation column and liquid chromatograph excellent in separation performance and pressure resistance performance can be obtained.

Next, the configuration of the separation column according to the third embodiment of the present invention will be described with reference to FIG. The configuration of the liquid chromatograph using the separation column according to the present embodiment is the same as that shown in FIG.
FIG. 4 is a configuration diagram of a separation column according to the third embodiment of the present invention. 4A is an exploded perspective view, and FIG. 4B is a cross-sectional view. The same reference numerals as those in FIG. 1 denote the same parts.

  The separation column of the present embodiment is different from the embodiment shown in FIG. 1 in that positioning pins 24 are provided on the end surface of the support 4. The positioning pin 24 has a cylindrical shape. The positioning pin 24 is inserted into a pin hole 25 formed on the end surface of the support 4. A pin through hole 26 is formed in the packing 6 at substantially the same position as the pin hole 25. The positioning pin 24 is inserted into the pin through hole 26 and the pin hole 25. Since the holding force larger than the rotational force of the packing 6 and the filter 5 rotated when the sealing member 7 is rotated is provided between the end surface of the support 4 and the packing 6, the packing 6 slips. Disappear. Thereby, since the packing 6 is hold | maintained at the support body 4, the packing 6 and the filter 5 do not rotate.

  Here, when the sealing member 7 is attached to the support 4 by screw tightening, the sealing property between the packing 6 and the supporting member 4 and the sealing property between the packing 6 and the sealing member 7 are maintained. The protruding amount of the positioning pin 24 from the support 4 is substantially the same as the thickness of the packing 6 or smaller than the thickness of the packing 6.

  In addition, the structure which covers the outer periphery of the monolith rod 1 is not restricted to what was shown in FIG. 4 similarly to embodiment shown in FIG. The shape and number of positioning pins 24 are not limited to those shown in FIG. Further, the positioning pin 24 may have a screw shape. Further, in order to facilitate the insertion of the positioning pin 24 into the pin through hole 26 or the pin hole 25, the positioning pin 24, the pin through hole 26, and the pin hole 25 may be tapered. Furthermore, the positioning pin 24 may be integrated with the support 4 or the packing 6.

  Also according to the present embodiment, when attaching the sealing member to the end of the monolith rod whose outer peripheral surface is covered with the support, no abrasion powder is generated between the end of the monolith rod and the filter. There is no clogging of the voids. Further, the sealing performance is not deteriorated by entering between the packing provided on the outer periphery of the filter and the end face of the support. Therefore, a monolith type separation column and liquid chromatograph excellent in separation performance and pressure resistance performance can be obtained.

Next, the configuration of the separation column according to the fourth embodiment of the present invention will be described with reference to FIG. The configuration of the liquid chromatograph using the separation column according to the present embodiment is the same as that shown in FIG.
FIG. 5 is a configuration diagram of a separation column according to the fourth embodiment of the present invention. 4A is an exploded perspective view, and FIG. 4B is a cross-sectional view. The same reference numerals as those in FIG. 1 denote the same parts.

  The separation column of the present embodiment is different from the embodiment shown in FIG. 1 in that a positioning guide 19 is provided on the end surface of the support 4 as in the embodiment shown in FIG. Further, the difference from the embodiment of FIG. 3 is that the round packing 6 (including the filter 5) is generally attached to the separation column 16 as it is.

  The positioning guide 19 is formed with a semi-cylindrical convex portion 21. The convex portion 21 is disposed in a semicylindrical concave portion 20 formed on the end face of the support 4. A round opening 22 is formed in the positioning guide 19. When the packing 6 is stored in the opening 22, the packing 6 is held by the positioning guide 19.

  Here, the opening central axis 23 of the opening 22 is provided on an axis different from the central axis of the support 4. Since the holding force larger than the rotational force of the packing 6 and the filter 5 rotated when the sealing member 7 is rotated is provided between the end surface of the support 4 and the packing 6, the packing 6 slips. Disappear. Therefore, when the sealing member 7 is attached to the support body 4 by screw tightening, the packing 6 and the filter 5 do not rotate around the central axis of the support body 4.

  Here, in order to obtain the sealing property between the packing 6 and the support 4 and the sealing property between the packing 6 and the sealing member 7, the protruding amount of the positioning guide 19 from the support 4 is the thickness of the packing 6. It is almost the same as or smaller than the thickness of the packing 6.

  In addition, the structure which covers the outer periphery of the monolith rod 1 is not restricted to what was shown in FIG. 5 similarly to embodiment of FIG. The shape of the positioning guide 19 is not limited to that shown in FIG. 5. For example, the positioning guide 19 may be a polygonal shape, and the side surface (curved surface) of the packing 6 has a point contact with a star shape or the like. It may be held by. Further, the positioning guide 19 may be integrated with the support 4 or the packing 6. Furthermore, in order to make the packing 6 easily fit into the opening 22, a taper shape or the like may be formed on the side surface of the packing 6 and the inner peripheral surface of the opening 22.

  Also according to the present embodiment, when attaching the sealing member to the end of the monolith rod whose outer peripheral surface is covered with the support, no abrasion powder is generated between the end of the monolith rod and the filter. There is no clogging of the voids. Further, the sealing performance is not deteriorated by entering between the packing provided on the outer periphery of the filter and the end face of the support. Therefore, a monolith type separation column and liquid chromatograph excellent in separation performance and pressure resistance performance can be obtained.

Next, the configuration of the separation column according to the fifth embodiment of the present invention will be described with reference to FIG. The configuration of the liquid chromatograph using the separation column according to the present embodiment is the same as that shown in FIG.
FIG. 6 is a configuration diagram of a separation column according to the fifth embodiment of the present invention. 6A is an exploded perspective view, and FIG. 6B is a cross-sectional view. The same reference numerals as those in FIG. 1 denote the same parts.

  The separation column of this embodiment is different from the embodiment shown in FIG. 1 in that a spacer 31 is provided between the support 4 and the packing 6. The spacer 31 has a round shape. A round opening 22 is formed at the center of the spacer 31. The size of the opening 22 is almost the same as or larger than the end surface of the monolith rod 1. This opening 22 becomes a flow path. However, since the increase in the volume of the opening 22 causes a decrease in separation performance, the thickness of the spacer 31 is preferably about 0.5 mm or less.

  When the sealing member 7 is attached to the support 4 by screw tightening, the packing 6, the filter 5, and the spacer 31 rotate together with the sealing member 7 about the central axis of the support 4. However, since the opening portion 22 that does not contact the monolith rod 1 is formed in the spacer 31, no abrasion powder is generated between the spacer 31 and the filter 5.

  In addition, the structure which covers the outer periphery of the monolith rod 1 is not restricted to what was shown in FIG. 6 similarly to embodiment of FIG. The shape of the spacer 31 is not limited to that shown in FIG. 6 and may be any shape as long as the space between the support 4 and the sealing member 7 is sealed. Further, the opening 22 does not necessarily have a round shape.

  Also according to the present embodiment, when attaching the sealing member to the end of the monolith rod whose outer peripheral surface is covered with the support, no abrasion powder is generated between the end of the monolith rod and the filter. There is no clogging of the voids. Further, the sealing performance is not deteriorated by entering between the packing provided on the outer periphery of the filter and the end face of the support. Therefore, a monolith type separation column and liquid chromatograph excellent in separation performance and pressure resistance performance can be obtained.

Next, the configuration of a separation column according to the sixth embodiment of the present invention will be described with reference to FIG. The configuration of the liquid chromatograph using the separation column according to the present embodiment is the same as that shown in FIG.
FIG. 7 is a configuration diagram of a separation column according to the sixth embodiment of the present invention. FIG. 7A is an exploded perspective view, and FIG. 7B is a cross-sectional view. The same reference numerals as those in FIG. 1 denote the same parts.

  The separation column of the present embodiment is different from the embodiment shown in FIG. 1 in the method of connecting the sealing member 7 to the support 4. That is, in the embodiment of FIG. 1, the sealing member 7 is connected to the support 4 by rotating about the central axis of the support 4, whereas in the present embodiment, the sealing member 7 rotates. Even if there is not, it is set as the structure which can be connected to the support body 4. FIG. In general, a round packing 6 (including the filter 5) is attached to the separation column 16 as it is. The outer peripheral surface near the end surface of the support 4 is covered with the support outer peripheral surface holding portion 27 of the sealing member 7. A pin through hole 26 is formed in the support outer peripheral surface holding portion 27. A pin hole 25 is formed in the support 4 at substantially the same position as the pin through hole 26. The sealing member 7 is held by the support 4 by inserting the support pin 28 into the pin through hole 26 and inserting the pin hole 25.

  In addition, the structure which covers the outer periphery of the monolith rod 1 is not restricted to what was shown in FIG. 7 similarly to embodiment shown in FIG. The shape and the number of the support pins 28 are not limited to those shown in FIG. 7. For example, screws or the like may be used as the support pins 28. Further, in order to facilitate the insertion of the support pin 28 into the pin hole 25 or the pin through hole 26, the support pin 28, the pin hole 25, and the pin through hole 26 may be tapered.

  Also according to the present embodiment, when attaching the sealing member to the end of the monolith rod whose outer peripheral surface is covered with the support, no abrasion powder is generated between the end of the monolith rod and the filter. There is no clogging of the voids. Further, the sealing performance is not deteriorated by entering between the packing provided on the outer periphery of the filter and the end face of the support. Therefore, a monolith type separation column and liquid chromatograph excellent in separation performance and pressure resistance performance can be obtained.

Next, the configuration of the separation column according to the seventh embodiment of the present invention will be described with reference to FIG. The configuration of the liquid chromatograph using the separation column according to the present embodiment is the same as that shown in FIG.
FIG. 8 is a configuration diagram of a separation column according to the seventh embodiment of the present invention. FIG. 8A is an exploded perspective view, and FIG. 8B is a cross-sectional view. The same reference numerals as those in FIG. 1 denote the same parts.

  Compared with the embodiment shown in FIG. 1, the separation column of this embodiment supports the sealing member 7 without rotating around the central axis of the support 4 as in the embodiment shown in FIG. 7. The difference is that it is configured to be connected to the body 4. In general, a round packing 6 (including the filter 5) is attached to the separation column 16 as it is. On the end surface of the support 4, a round support-side guide recess 29 is formed, and the packing 6 is housed in the support-side guide recess 29. Since the depth of the support side guide recessed portion 29 is shallower than the thickness of the packing 6, a part of the packing 6 protrudes from the end surface of the support 4. On the surface of the sealing member 7 facing the support 4, a round sealing member side guide recess 30 is formed. A portion of the packing 6 protruding from the support 4 is housed in the sealing member guide recess 30. In order to obtain the sealing performance between the packing 6 and the support body 4 and the sealing performance between the packing 6 and the sealing member 7, the support body 4 and the sealing member 7 include the support body 4 and the sealing member 7. In a state where the surfaces facing each other are pressurized, the sealing member 7 is connected to the supporting member 4 by joining the supporting member 4 and the sealing member with an adhesive or the like.

  In addition, the structure which covers the outer periphery of the monolith rod 1 is not restricted to what was shown in FIG. 8 similarly to embodiment shown in FIG. The shapes of the support-side guide concave portion 29 and the sealing member-side guide concave portion 30 are not limited to those shown in FIG. 8, and may be, for example, a polygonal shape. The side surface (curved surface) may be held by a plurality of point contacts. Further, in order to make the packing 6 easily fit into the support side guide recess 29 and the sealing member side guide recess 30, the side surface of the packing 6 or the inner peripheral surface of the support side guide recess 29 and the sealing member side guide recess 30 is tapered. A shape or the like may be formed. Furthermore, in this embodiment, in order to facilitate the positioning of the support 4 and the sealing member 7, a support-side guide recess 29 is formed in the support 4, and the sealing member 7 has a sealing member side. Although the guide recessed part 30 is formed, it does not necessarily need to be formed in both, and any one may be sufficient.

  Also according to the present embodiment, when attaching the sealing member to the end of the monolith rod whose outer peripheral surface is covered with the support, no abrasion powder is generated between the end of the monolith rod and the filter. There is no clogging of the voids. Further, the sealing performance is not deteriorated by entering between the packing provided on the outer periphery of the filter and the end face of the support. Therefore, a monolith type separation column and liquid chromatograph excellent in separation performance and pressure resistance performance can be obtained.

  In addition, the following are mentioned as an embodiment of this invention.

(A) A monolith rod formed into a cylindrical shape with a porous body, a support that covers the outer periphery of the monolith rod, a sealing member that is provided at an end of the support, the support, and the sealing A monolith type separation column having a packing provided between the members and a filter provided at the center of the packing,
The sealing member and the support are connected by rotating the sealing member relative to the support when the central axis of the sealing member is substantially coaxial with the central axis of the support. It is what
Between the end surface of the support and the packing, the packing member rotated when the sealing member is rotated and a holding force larger than the rotational force of the filter,
At least a part of the end surface of the support and at least a part of the side surface of the packing are held by a positioning guide,
Tapered to at least one of at least part of the surface of the support held by the positioning guide, at least part of the surface of the packing held by the positioning guide, and at least part of the positioning guide. A separation column characterized in that a shape is formed.

(B) a monolith rod formed into a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, a sealing member provided at an end of the support, the support and the sealing A monolith type separation column having a packing provided between the members and a filter provided at the center of the packing,
The sealing member and the support are connected by rotating the sealing member relative to the support when the central axis of the sealing member is substantially coaxial with the central axis of the support. Which is
Between the end surface of the support and the packing, the packing member rotated when the sealing member is rotated and a holding force larger than the rotational force of the filter,
At least a part of the end surface of the support and at least a part of the side surface of the packing are held by a positioning guide,
One or both of the said support body and the said packing are integrated with the said positioning guide, The separation column characterized by the above-mentioned.

(C) a monolith rod formed into a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, a sealing member provided at an end of the support, the support and the sealing A monolith type separation column having a packing provided between the members and a filter provided at the center of the packing,
The sealing member and the support are connected by rotating the sealing member relative to the support when the central axis of the sealing member is substantially coaxial with the central axis of the support. Which is
Between the end surface of the support and the packing, the packing member rotated when the sealing member is rotated and a holding force larger than the rotational force of the filter,
A positioning guide is provided on an end surface of the support, an opening is provided in the positioning guide, and the packing is held at a plurality of points formed inside the opening, The separation column is characterized in that the central axis of the packing is on a different axis that is substantially parallel to the central axis of the support.

(D) a monolith rod formed into a cylindrical shape with a porous body, a support body covering the outer periphery of the monolith rod, a sealing member provided at an end of the support body, the support body and the sealing body A monolith type separation column having a packing provided between the members and a filter provided at the center of the packing,
The sealing member and the support are connected by rotating the sealing member relative to the support when the central axis of the sealing member is substantially coaxial with the central axis of the support. Which is
Between the end surface of the support and the packing, the packing member rotated when the sealing member is rotated and a holding force larger than the rotational force of the filter,
At least one pin hole is provided in an end surface of the support, and at least one pin hole is provided in the packing. The support and the packing are the pin hole of the support and the packing of the packing. Held by at least one positioning pin inserted into the pin hole;
A separation column, wherein at least a part of the positioning pin has one or both of a substantially cylindrical shape and a spiral shape.

(E) A monolith rod formed into a cylindrical shape with a porous body, a support body that covers the outer periphery of the monolith rod, a sealing member provided at an end of the support body, the support body, and the sealing A monolith type separation column having a packing provided between the members and a filter provided at the center of the packing,
The sealing member and the support are connected by rotating the sealing member relative to the support when the central axis of the sealing member is substantially coaxial with the central axis of the support. Which is
Between the end surface of the support and the packing, the packing member rotated when the sealing member is rotated and a holding force larger than the rotational force of the filter,
At least one pin hole is provided in an end surface of the support, and at least one pin hole is provided in the packing. The support and the packing are the pin hole of the support and the packing of the packing. Held by at least one positioning pin inserted into the pin hole;
At least one of the pin holes of the support, at least a part of the pin holes of the packing, and at least one of the positioning pins are tapered. Separation column.

(F) a monolith rod formed into a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, a sealing member provided at an end of the support, the support and the sealing A monolith type separation column having a packing provided between the members and a filter provided at the center of the packing,
The sealing member and the support are connected by rotating the sealing member relative to the support when the central axis of the sealing member is substantially coaxial with the central axis of the support. Which is
Between the end surface of the support and the packing, the packing member rotated when the sealing member is rotated and a holding force larger than the rotational force of the filter,
At least one pin hole is provided in an end surface of the support, and at least one pin hole is provided in the packing. The support and the packing are the pin hole of the support and the packing of the packing. Held by at least one positioning pin inserted into the pin hole;
One of the said support body and the said packing is integrated with the said positioning pin, The separation column characterized by the above-mentioned.

(G) In a monolith-type separation column comprising a monolith rod formed into a cylindrical shape with a porous body, and a support that covers the outer periphery of the monolith rod,
A separation column, wherein a convex or concave positioning member is provided on at least a part of an end surface of the support.

(H) In a monolith-type separation column comprising a monolith rod formed into a cylindrical shape with a porous body, and a support that covers the outer periphery of the monolith rod,
A positioning guide is provided on an end surface of the support, and the positioning guide is provided with a substantially round or substantially polygonal opening having a central axis on a different axis that is substantially parallel to the central axis of the support. Separation column characterized by

(I) A monolith rod formed into a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, a sealing member provided at an end of the support, the support and the sealing In a monolith type separation column comprising a packing provided between the members and a filter provided at the center of the packing,
At least a part of the outer peripheral surface of the support is covered with the sealing member,
The separation column, wherein the sealing member and the support are held by a support member on a surface where the outer peripheral surface of the support and the sealing member face each other.

  (J) The separation column according to (I), wherein at least a part of the support member has one or both of a substantially cylindrical shape and a spiral shape.

(K) a monolith rod formed into a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, a sealing member provided at an end of the support, the support and the sealing In a monolith type separation column comprising a packing provided between the members and a filter provided at the center of the packing,
At least a part of the end surface of the support is bonded to the sealing member;
At least one of the end surface of the support member that covers the outer periphery of the monolith rod and the surface of the sealing member that faces the support member is provided with a recess, and the packing is accommodated in the recess portion. Separation column characterized by that.

  (L) In (K), a tapered shape is formed in at least one of the concave portion of the support, at least a portion of the concave portion of the sealing member, and at least a portion of the packing. Separation column characterized by being made.

(M) a monolith rod formed into a cylindrical shape with a porous body, a support member that covers the outer periphery of the monolith rod, a sealing member that is provided at an end of the support member, the support member, and the sealing member In a monolith type separation column comprising a packing provided between the members and a filter provided at the center of the packing,
A spacer is provided between the support and the packing, and the center of the spacer has an opening,
The separation column, wherein the opening has a substantially round shape.

(N) a monolith rod formed in a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, a sealing member provided at an end of the support, the support and the sealing In a monolith type separation column comprising a packing provided between the members and a filter provided at the center of the packing,
The sealing member and the support are connected by rotating the sealing member relative to the support when the central axis of the sealing member is substantially coaxial with the central axis of the support. And having a holding force larger than the rotational force of the packing and the filter rotated when the sealing member is rotated between the end surface of the support and the packing. ,
A separation column, wherein at least a part of the support is a heat-shrinkable tube made of fluororesin or silicone resin.

(O) a monolith rod formed into a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, a sealing member provided at an end of the support, the support and the sealing In a monolith type separation column comprising a packing provided between the members and a filter provided at the center of the packing,
The sealing member and the support are connected by rotating the sealing member relative to the support when the central axis of the sealing member is substantially coaxial with the central axis of the support. And having a holding force larger than the rotational force of the packing and the filter rotated when the sealing member is rotated between the end surface of the support and the packing. ,
At least a part of the support is made of silicon rubber, glass, ceramic, resin, metal, adhesive, fluid rubber, or the like.

(P) a monolith rod formed into a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, a sealing member provided at an end of the support, the support and the sealing In a monolith type separation column comprising a packing provided between the members and a filter provided at the center of the packing,
The sealing member and the support are connected by rotating the sealing member relative to the support when the central axis of the sealing member is substantially coaxial with the central axis of the support. And having a holding force larger than the rotational force of the packing and the filter rotated when the sealing member is rotated between the end surface of the support and the packing. ,
A separation column, wherein at least a part of the support comprises glass beads, ceramic beads, resin beads, metal beads, or the like.

(Q) a monolith rod formed into a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, a sealing member provided at an end of the support, the support and the sealing In a liquid chromatograph using a monolith type separation column consisting of a packing provided between the members and a filter provided at the center of the packing,
At least a part of the outer peripheral surface of the support is covered with the sealing member, and the outer peripheral surface of the support and the sealing member are opposed to the sealing member and the support. A liquid chromatograph characterized by being held by a support member on a surface.

(R) a monolith rod formed into a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, a sealing member provided at an end of the support, the support and the sealing In a liquid chromatograph using a monolith type separation column consisting of a packing provided between the members and a filter provided at the center of the packing,
The liquid chromatograph, wherein the support and the sealing member are connected by bonding.

(S) a monolith rod formed into a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, a sealing member provided at an end of the support, the support and the sealing In a liquid chromatograph using a monolith type separation column consisting of a packing provided between the members and a filter provided at the center of the packing,
A liquid chromatograph, wherein a spacer is provided between the support and the packing, and a central portion of the spacer has an opening.

It is a block diagram of the separation column by the 1st Embodiment of this invention. It is a block diagram which shows the structure of the liquid chromatograph by the 1st Embodiment of this invention. It is a block diagram of the separation column by the 2nd Embodiment of this invention. It is a block diagram of the separation column by the 3rd Embodiment of this invention. It is a block diagram of the separation column by the 4th Embodiment of this invention. It is a block diagram of the separation column by the 5th Embodiment of this invention. It is a block diagram of the separation column by the 6th Embodiment of this invention. It is a block diagram of the separation column by the 7th Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Monolith rod, 2 ... Covering support body, 3 ... Filling support body, 4 ... Support body, 5 ... Filter, 6 ... Packing, 7 ... Sealing member, 8 ... Supporting body side screw part, 9 ... Sealing member side screw , 10 ... connection part, 11 ... flow path, 12 ... uneven part, 13 ... mobile phase, 14 ... pump, 15 ... autosampler, 16 ... separation column, 17 ... thermostat, 18 ... detector, 19 ... positioning guide , 20 ... concave part, 21 ... convex part, 22 ... opening part, 23 ... central part of opening part, 24 ... positioning pin, 25 ... pin hole, 26 ... pin through hole, 27 ... support outer peripheral surface holding part, 28 ... support Pins 29 ... support side guide recesses, 30 ... sealing member side guide recesses, 31 ... spacers

Claims (11)

A monolith rod formed into a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, a sealing member provided at an end of the support, and the support and the sealing member. A monolith-type separation column having a packing provided therebetween and a filter provided in the center of the packing,
The sealing member and the support are connected by rotating the sealing member relative to the support when the central axis of the sealing member is substantially coaxial with the central axis of the support. Which is
A separation column having a holding force larger than a rotational force of the packing and the filter rotated when the sealing member is rotated between an end surface of the support and the packing. The separation column according to claim 1, wherein
A separation column, wherein a concavo-convex portion is provided on at least one part of an end surface of the support and at least one part of a surface of the packing facing the support. The separation column according to claim 1, wherein
At least a part of the end surface of the support and at least a part of the side surface of the packing are held by a positioning guide. The separation column according to claim 3,
At least one of the surfaces of the support held by the positioning guide, at least one of the surfaces of the packing held by the positioning guide, and at least one of the positioning guides is substantially flat. Separation column characterized by being. The separation column according to claim 1, wherein
At least one pin hole is provided on the end surface of the support,
The packing is provided with at least one pin hole,
The separation column, wherein the support and the packing are held by positioning pins inserted into the pin holes of the support and the pin holes of the packing. The separation column according to claim 1, wherein
A positioning guide is provided on the end surface of the support,
The positioning guide is provided with a substantially round or substantially polygonal opening having a central axis on a different axis that is substantially parallel to the central axis of the support,
The separation column, wherein the packing is accommodated in the opening. A monolith type separation column having a monolith rod formed into a cylindrical shape with a porous body and a support covering the outer periphery of the monolith rod,
A separation column, wherein a convex and concave portion is formed on a part of an end surface of the support. A monolith rod formed into a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, a sealing member provided at an end of the support, and the support and the sealing member. A monolithic separation column having a packing provided therebetween and a filter provided in the center of the packing,
A spacer is provided between the support and the packing,
The separation column, wherein the central portion of the spacer has an opening. The separation column according to claim 8,
The separation column is characterized in that the size of the opening is substantially the same as the end face of the monolith rod or larger than the end face of the monolith rod. A monolith rod formed into a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, a sealing member provided at an end of the support, and the support and the sealing member. A monolithic separation column having a packing provided therebetween and a filter provided in the center of the packing,
Part of the end surface of the support is joined to the sealing member. A monolith rod formed into a cylindrical shape with a porous body, a support covering the outer periphery of the monolith rod, a sealing member provided at an end of the support, and the support and the sealing member. A liquid chromatograph using a monolith-type separation column comprising a packing provided in between and a filter provided in the center of the packing,
The sealing member and the support are formed by rotating the sealing member in reverse with respect to the support when the central axis of the sealing member is substantially coaxial with the central axis of the support. To be connected,
A liquid chromatograph characterized by having a holding force larger than the rotational force of the packing and the filter rotated when the sealing member is rotated between the end face of the support and the packing. .

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