DE8202889U1 - Flow cell for a photometric absorption detector - Google Patents

Description

FLOW CUVETTE CUVETTE FOR A PHOTOMETRIC ABSORPTION DETECTOR

The present invention relates to a flow cell for a photometric absorption detector according to the preamble of the claim 1.

Such a flow cell is, for example, from German Utility model 74 23 167 known. The known flow-through cuvette is used for conventional photometric or spectrophotometric measurements where relatively large amounts of liquid are used. In modern liquid chromatography there are there is, on the other hand, a tendency towards smaller and smaller liquid volumes.

The smaller the various dead volumes in the chromatographic system, the higher the resolution. Therefore supply and discharge channel and measuring channel of the flow cell should preferably have a small volume _{. In addition, there are dead zones in the | Avoid currents, which impair the flushability and can lead to a mixing of neighboring liquid components and thus to a broadening of the peaks.

The present invention is based on the object of developing a flow cell of the type mentioned at the outset in such a way that that they are favorable for liquid chromatography Can extremely miniaturize flow behavior. The solution this task is characterized in claim 1.

The flow cell according to the invention can be made very compact will. It has been shown that it has excellent flow properties with very small dimensions. It is preferably made of radio-opaque quartz glass, in which the measuring channel and the supply and discharge channel are incorporated. The windows are with the

Hewlett-Packard GmbH
Int. Az,: DT 70

Klivdttenkörper connected discs made of radiation-permeable Quartz glass.

The development of the invention according to dependent claim 3 results in a kink-free transition between the supply and discharge channel and the subsequent ones, in liquid chromatography usual capillary tubes, which are generally made of chrome-nickel steel (V4A) exist. In addition, a permanent connection between quartz glass and capillary tube can be created.

The diameters of the capillary tubes and channels are thereby expediently selected as characterized in claim 4. This will clog it up with any dirt particles avoided the destruction of the pump at the high delivery pressures used in liquid chromatography the flow-through cuvette.

The preferred embodiment according to claim 5 allows the use of extremely thin and flexible capillary tubes. On the one hand, this contributes to a reduction in volume and, on the other hand, only very little forces are exerted on the flow cell exerted when the capillary tubes are moved. That allows an extremely precise adjustment of the flow cell in the associated optical system. On the other hand, get the flexible Capillary tubes at their ends through the pushed-on sleeves Outer diameter that is the same as in liquid chromatography correspond to usual capillary tubes. This on the one hand facilitates the fastening in the flow cell itself, and on the other hand can at the end of the capillary tube facing away from the flow cell the usual screw connections (fittings) can be used. The sealing required between the sleeve and the capillary takes place expediently according to dependent claim 6. If the sleeve and capillary are made of the same material, the weld seam is Chemically resistant to all solvents commonly used in liquid chromatography.

Hewlett-Packard GmbH
Int. Ref .: DT 70

For optimal fitting of the flow cuvette according to the invention in rias optical system of a spectrophotometer of a liquid chromatograph it is preferably designed according to dependent claim 7. The diaphragm forms the entrance slit of the spectrophotometer, i.e. an aperture at the radiation source is mapped onto the mentioned entrance slit, and this is mapped onto the photodetector of the photometer

The invention is illustrated below with the aid of an exemplary embodiment explained in connection with the accompanying drawing. Show in the drawing

FIG. 1 A shows a flow cell in longitudinal section in an enlarged illustration;

FIG. 1 B shows the flow cell according to FIG Direction of the measuring radiation;

FIG. 2A shows in detail a capillary with a pushed-on sleeve and

FIG. 2B shows a plan view of the welding area on the end faces of capillary and sleeve.

In Figure 1, 11 is a body made of opaque for the measurement radiation Called quartz glass. Transversely through the body 11 leads a measuring channel 13 in the form of a conical bore, which is in The direction of the measurement radiation (arrow a) widens. With the body 11 connected plates 15 and 17 made of transparent for the measurement radiation Quartz glass forms radiation entry and exit windows for the measuring channel 13. The plates 15 and 17 on the one hand and the body 11 on the other hand are fused together and form thus a compact unit.

At the point where the measuring channel 13 from the transparent quartz glass plate 15 is completed, opens a feed channel 19 for the sample liquid. A corresponding discharge channel 21 opens at the end of the measuring channel 13 closed off by the transparent quartz glass plate 17.

Hewlett-Packard GmbH j I :>'···' »j. · '": ":. **"?

Int. Ref .: DT 70

channel 19 and 21 respectively form with the longitudinal axis of the measuring channel an angle 45 ° and intersect these approximately in the planes of the inner surfaces of the quartz glass plates 15 or

The inlet and outlet channels 19 and 21 expand to form receiving bores 23 and 25 for supply and discharge lines for the sample liquid. These supply and discharge lines instruct their ends fitting pieces 27 and 29 with frustoconical ends 31 and 33, which are firmly fitted into the exactly identically shaped receiving bores 23 and 25, respectively. At the point of passage of the fitting pieces 27 and 29 have the quartz glass plates 17 and 15 through openings 35 and 37, respectively, which are made with epoxy resin are filled. As a result, a further fastening of the fitting pieces 27 and 29 is achieved. The fittings 27 and 29 are explained in more detail below together with the further supply and discharge lines designed as capillaries 39 and 41, respectively.

In the illustrated embodiment, the measuring channel 13 has a diameter of 0.6 mm at the narrowest point and at the widest point a diameter of 1.3 mm and a length of about 6 mm results in a volume of the measuring channel 13 of less than 5 μΐ. The feed channel 19 has a diameter of 0.4 mm, and the discharge channel 21 has a diameter of 0.5 mm. The lead 39 has an inner diameter of 0.12 mm, and the Discharge line 41 has an inside diameter of 0.25 mm. The larger diameter compared to the supply side on the discharge side ensure a safe drainage of the sample liquid and prevent blockages. Could be constipated namely lead to a destruction of the flow cell at a pump pressure of about 400 bar. The latter, however, has at least a pressure resistance of about 100 bar,

The direction of flow of the sample liquid is indicated by arrows b and c. Due to the arrangement shown a favorable flow results in the area of the measuring channel 13.

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Hewlett-Packard GmbH

Int. Ref .: DT 70 - 7 -

This becomes one for liquid chromatography in terms of of the resolving power, disadvantageous peak broadening is avoided.

A diaphragm plate 43 is attached to the quartz plate 15 on the input side for the measuring radiation (arrow a). The diaphragm plate 43 has a slit-shaped diaphragm opening in its center 45, which is the entrance slit for the entering into the measuring channel 13 Radiation is used. Inside the photometric absorption detector the DuThfluss cuvette according to Figure 1 is adjusted so that that the aperture of the radiation source on the aperture 45 and this is imaged on a photodetector. The conical shape of the measuring channel is adapted to the radiation cone.

In Figure 2 is the preferred embodiment of a fitting for the supply and discharge lines described above for the Sample liquid shown. Figure 2A shows the fitting in side view and partially in longitudinal section. On a flexible Capillary 51 with one of the above-mentioned inner diameters a sleeve 53 pushed on. Capillary 51 and sleeve 53 are made of the same stainless steel, e.g. V4A. The sleeve 53 has a frustoconical tip 55. On the common end face of capillary 51 and sleeve 53 is located between both an annular gap 57. Along this annular gap, capillary 51 and sleeve 53 are welded to one another, as can be seen from FIG. 2B which shows said common end face enlarged.

Weld points 59 are attached along the annular gap 57. Ins- f overall are 12 mutually overlapping over the circumference

Weld spots evenly distributed. The welding takes place! zv. ^ moderately by means of a laser beam, which ensures precise work

even with the relatively small dimensions. The sweat %

If it is properly executed, the seam is pressure-resistant and;

chemically resistant to those used in liquid chromatography \

common solvents. f

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Hewlett-Packard GmbH

Int. Ref .: DT 70 - 8 -

The use of thin and flexible capillaries as feed and discharge lines for the flow cuvette according to the invention ensures a minimal exertion of force on the cuvette via the Cables. This avoids tasting errors in the optical system. Nevertheless, the fitting pieces have external diameters such as those commonly used in liquid chromatography Capillaries. Be laughing at each other's ends If the capillaries are provided with such fittings, the usual pipe screw connections (fittings) can also be used.

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Claims (7)

PROTECTION APPROACH ΐ. Flow cell for a photometric absorption detector, especially for liquid chromatography, with a substantially conical, in the longitudinal direction from the smaller to the larger cross-section of a measuring radiation translucent measuring channel, each of which has a radiation-permeable channel at its two ends Window is closed and is connected to an inlet and an outlet channel, characterized in that that the longitudinal axes of the supply (19) and discharge channel (21) each form an acute angle with that of the measuring channel (13) and the latter cut essentially in the window planes (15, 17). 2. Flow cell according to claim 1, characterized in that the measuring channel (13), the supply (19) and the discharge channel (21) in a body (11) made of radio-opaque quartz glass are and that the windows (15, 17) connected to the body are notes made of radiation-permeable quartz glass. 3. Flow cell according to claim 2, characterized in that the supply (19) and the discharge channel (21) each on the Measuring channel (13) facing away from each other in a receiving bore (23, 25) for a supply (39) and a discharge capillary tube (41) pass over that each receiving bore is conically pointed on the side facing the associated channel (31, 33) and that the inlet and outlet capillary tube in diameter and conical taper at their ends are adapted to the receiving bores and fitted into them. 4. flow cell according to claim 3, characterized in that the discharge channel (21) has a larger diameter than the supply channel (19) and that the discharge capillary tube (41) has a has a larger inner diameter than the supply capillary tube (39) and that the inner diameter of each capillary tube is smaller than the diameter of the respectively assigned channel. Hewlett-Packard GmbH '.. *: * .. *.: ..' .ι ¹ .: .. Int. Ref .: DT 70 - 2 - 5. flow cell according to claim 3 or 4, characterized in that that the supply (39) and the discharge capillary tube (41) thin Flexible steel capillaries (51) are more common, which are attached to their ends by sleeves (53) pushed onto the outer diameter Steel capillaries are reinforced. 6. flow cell according to claim 5, characterized in that that capillary (51) and sleeve (53) close flush at their end faces and along the annular gap existing between them (57) are welded. 7. Flow cell according to one of claims 1 to 6, characterized characterized in that the window (15) of the measuring channel (13) carries a diaphragm (45) on the input side for the measuring radiation.