NL8501188A - Chromatography column has fused silica tube - with organic polymer external coating and metal, pref. stainless steel, outer wire winding or mesh for heating and reinforcement - Google Patents

Abstract

The chromatography column (1) is provided with a winding (4) of metal wire (5) over at least part of its external surface. It consists of a tube (2) of fused silica with an external organic polymer coating (3; e.g. polyamide, poly-silicone, poly-carbonate, etc.) of which the entire outer surface is covered by the metal wire. The wire covering may be in the form of helical winding(s) or a wire meshwork and may consist of stainless steel. It may be arranged as different (individually connectable) sections.

Description

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Short designation: Chromatographic column.

The invention relates to a chromatographic column which is at least partly wrapped by at least one metal wire.

Such a chromatographic column is known from US patent 3 169 389.

In this known chromatographic column, a separation column, a reference column and a cooling column are jointly wrapped by an electrical resistance wire through which a heating current can be passed via a suitable control device.

When operating a chromatographic column it is particularly important that a certain desired temperature is reached within a certain tidal period and then kept constant for a second time period, whereby no temperature differences occur or a predetermined temperature distribution is maintained along the length of the column. . This means that the thermal inertia of the column must be low while, on the other hand, the column must be mechanically strong enough to withstand the pressures that occur during operation. However, a certain mechanical strength requires a certain minimum wall thickness, which increases the thermal inertia.

Therefore, the chromatographic column known from the above publication cannot satisfactorily satisfy these requirements: the common heating wires arranged around the three columns cannot realize a certain temperature quickly and reproducibly and these are accurately shown. * Λ Λ Q V? V i i 'J 3

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2 maintain. An accurately defined temperature distribution is impossible to achieve.

The object of the invention is to overcome these drawbacks and to provide an improved chromatographic column.

This is achieved according to the invention in that the column consists of a tube of congealed silicon, the outer surface of which is coated with an organic polymer and which is coated with metal wires over the entire outer surface.

These measures provide a number of advantages which make the new chromatographic column considerably better than the ones known per se. The metal wires arranged around the entire outer surface of each column not only provide important mechanical reinforcement so that the wall thickness of the column itself can be less than is possible without these 15 wires, but they also result in a very fast and effective heat transfer, so that the heating of the column is possible within a precisely predetermined time period.

The metal wires can be wound helically around the column 20, but can also be combined into a braid; they preferably consist of stainless steel.

For heating the chromatographic column using the metal wires as a heat transfer medium, the metal wires can be incorporated in an electrical circuit as an electrical resistance, but can also be used as a secondary winding in a high-frequency heating device. It is also conceivable to use the metal jacket as an absorbing element for the wave energy.

The invention is elucidated with reference to the drawing. FIG. 1 shows part of a chromatographic column with wires wound helically around it; Figure 2 shows part of a chromatographic column in which the wires are combined into a braid; Fig. 3 shows a first embodiment in which the wires 35 are used for heat transfer to the column; Fig. 4 shows a second embodiment in which the wires are used for heat transfer to the column.

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Fig. 1 shows a chromatographic column 1 consisting of a tube 2 of solidified silicon (fused silica) with a diameter of eg 150 µm, which is coated with a layer 3 of an organic polymer, a polyamide, a polysilicon, a polycarbonate Around it is arranged a winding 4 formed of a wire 5 which is arranged helically around the tube 2, the ends of which are connected to connections 6 and 6, respectively.

7. The diameter of the wire may be, for example, 180 µm and the wire may consist of stainless steel.

FIG. 2 shows an embodiment of a chromatographic column 10 in which the tube 11 is covered with a metal braid 12 while inserting the same layer as described with reference to FIG. 1. This braid may consist of stainless steel wires. The top of the braid is connected to a connection 13 and the bottom is connected to a connection 14.

The metal jacket, of course, provides substantial mechanical reinforcement to the column so that its wall thickness may be less than without wires, but the jacket may also be used to heat the column directly by circulating an electric current therethrough. For this purpose, a suitable power source (not shown in Figures 1 and 2), optionally controlled according to a specific program, can be connected to connections 6, 7 or 13, 14.

However, it is also possible to divide the reinforcement into different sections, as shown in Fig. 3. Fig.

3 shows a chromatographic column 20 provided with a reinforcement consisting of the adjoining sections 21, 22 and 23. This reinforcement may be, for example, of the type shown in FIG. 1 or may consist of a braid as in FIG. 2 shown. The reinforcement 21 is connected to the power source 26 via connecting wires 24, 25; the reinforcement 22 is connected to the power source 29 via connecting wires 27, 28 and the reinforcement 23 is connected to the power source 32 via the connecting wires 30, 31. The three power sources 26, 29, 32 are controlled in a known manner from a central control circuit 33 which may be suitably programmed to heat the tube according to a particular program.

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It is also possible to heat the chromatographic column by using the metal wires as a secondary winding in a high-frequency heating device. Pig. 4 shows the chromatographic column 10 according to FIG. 2 with the wires united to the braid 5 12 in which a current is not sent from the terminal 13 to the terminal 14, as according to FIG. 2, but is placed within a winding 35. whose terminals 36, 37 are connected to a high-frequency generator, not shown. The braid 12 functions as a short-wound winding which forms the secondary winding of the high-frequency heating device and is heated by the current induced therein.

Due to this metal wire reinforcement, the chromatographic column according to the invention has a particularly flexible structure, which makes it possible to wind the column itself into an easily manageable roll or reel, shows a very good temperature stability and can be quickly brought to a desired temperature. In all embodiments, according to a predetermined program, certain temperatures can be realized in a programmed manner by changing the supplied electric or wave energy, in particular the very fast response being a great advantage.

Of course, depending on the destination of the chromatographic column, tube and wire diameters other than those indicated above may be used.

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Claims (9)

1. Chromatographic column which is at least partly wrapped by at least one metal wire, characterized in that the column consists of a tube of solidified silicon, the outer surface of which is coated with an organic polymer emover and the entire outer surface of which is coated with metal wires. Chromatographic column according to claim 1, characterized in that metal wires are wound helically around the column. Chromatographic column according to claim 1, characterized in that the metal wires are combined into a braid. Chromatographic column according to any one of the preceding claims, characterized in that the metal wires 15 consist of stainless steel. Chromatographic column according to claims 1-4, characterized in that the metal coating is divided into sections. Process for operating a chromatographic column according to one or more of the preceding claims, characterized in that metal wires are used for the heat transfer to and from the column. 7. A method according to claim 6, characterized in that a heating current is passed through the metal wires. 8. Method according to claim 6, characterized in that the metal wires are used as a secondary winding in a high-frequency heating device. 9. A method according to claim 6, characterized in that the metal wires are used as absorbing medium for wave energy. > - \ t * ".. · **" 2 Λ. · - · £ "::> 7 J