DE10322066A1 - Micro flow measurement cell, for a photometer to measure the concentration of peptides/aromatic compounds in a solution, has a holder with the bent glass capillary to align the straight capillary section with a light passage opening - Google Patents

Abstract

A micro flow measurement cell, for a photometer, having a holder with a glass capillary (30) bent into a number of angles as a U-shape with two legs (32,34), is new. A light inlet and outlet opening (58) is in alignment with a straight section (36) between two bends of the capillary. A micro flow measurement cell, for a photometer, having a holder with a glass capillary (30) bent into a number of angles as a U-shape with two legs (32,34), is new. A light inlet and outlet opening (58) is in alignment with a straight section (36) between two bends of the capillary. The holder has an inner (38) and an outer (40) section, with the glass capillary held at the inner section, with the bending points flanking the straight section outside the inner part of the holder. The inner section is fitted into an opening (54) at the outer part, with adjustment to align the optical axis of the light passing through with the capillary straight section.

Description

The The invention relates to a micro-flow measuring cell for photometers, with a holder, into which a multi-angled glass capillary can be inserted, as well as a light entry and a light exit opening in Escape with a straight section between two bending points of the Glass capillary.

Such micro flow cells come as parts of photometers such. B. to determine the concentration of peptides, aromatic compounds and other substances in solutions for use. In this case, a straight section of a certain length is irradiated through the glass capillary, through which the solution flows. B. axially with UV light and can determine the concentration of the dissolved compound from the more or less strong light absorption (cf. EP 0 597 552 A1 ).

at a known micro flow measuring cell a substantially Z-shaped curved glass capillary, the central section of which in its longitudinal direction is irradiated, placed in a rigid holder. The capillary z. B. an outer diameter of about 280μ and an inner diameter of about 75μ. Since the bending of the capillary two places with a small bending radius of 90 ° each a very difficult process, it can be hardly reproduce exactly, so it quite large Differences from cell to cell exist because of the rigid bracket can also not be compensated.

The The invention is therefore based on the object of an inexpensive micro-flow measuring cell to create the kind mentioned at the beginning, with the irregularities the curved glass capillary compensated to a certain degree can be and also an exchange of capillaries of different inner diameters depending on the application requirements.

above The object of the invention solved, that the Bracket consists of an inner and an outer part, the inner part the multi-angled glass capillary holds in such a way that the bending points the ends of the straight section are outside the inner part, and the inner part in a recess of the outer part in an adjustable Position can be determined in which the optical axis in the outer part attached light entry and exit openings with the straight section the glass capillary is aligned.

The Invention has the advantage that the adjustability of the inner part holding the glass capillary relative to that with the Light entry and light exit opening provided the section of the glass capillary to be irradiated axially despite different Position relative to the load-bearing inner part quickly and easily aligned the optical axis of the light entry and exit can be. This possibility of compensation allows greater manufacturing tolerances with the difficult shaping of the glass capillary and thus a lowering the manufacturing cost. Moreover can also differences in diameter of different glass capillaries Adjustment can be compensated.

In the preferred practical embodiment the inner part has the shape of a partially offset Piston, and the glass capillary is essentially U-shaped, with their legs at least partially on the outside of the piston body opposite sides parallel to its longitudinal axis extend and their web straight through a through hole or recess in the piston body extends and in the assembled state with the optical axis of the Light entry and light exit openings are aligned. It is preferably the piston body axially flattened between cylindrical areas on opposite sides, and the legs of the U-shaped Glass capillaries extend partially through a cylindrical one Area and partially in the flattened area outside the piston body, however within the outside diameter of the cylindrical region, wherein the through hole in flattened area.

A simple design of the entire holder is obtained in that the substantially piston-shaped body of the inner part can be inserted into a suitable receiving bore in the outer part until an extension, for. B. comes in the form of a crossbar, on a counter surface of the outer part, and can be clamped in this axial position. Preferably the radial extension, e.g. B. in the form of the crossbar, provided with axially aligned adjusting screws relative to the piston body, the ends of which come to rest on the counter surface. This allows simple adjustment of the section of the glass capillary to be irradiated in the longitudinal direction of its legs. In addition, it is provided in the preferred embodiment that the counter surface be in a depression of the outer part, which offers so much space that for aligning the web on the optical axis of the light inlet and the light exit opening, the inner part before clamping around its longitudinal axis is limited rotation. In view of the precise guidance of the cylindrical areas of the inner part in the receiving bore in the outer part, the adjustment in the axial and rotational directions is sufficient to align the straight section to be irradiated precisely with the optical axis of the light entry and light exit opening, even with differently shaped glass capillaries. A clamping screw is sufficient for fixing in the aligned position be, which can be screwed into the outer part and pressed against the peripheral surface of the inner part.

The The shape of the inner part and the glass capillary as well as the assembly can continue be simplified in that preferably the traverse is no wider than the diameter of the glass capillary holding cylindrical area and its legs on the crossbar past or passed through it become. In this way, it provides for the axial support and Adjustment of the inner part required traverse no obstacle for those easy only U-shaped to bend glass capillaries.

The Light entry and the light exit opening are expedient aligned holes, each between a Countersink in the outer part and the location hole for the Extend inner part, with holders for optical in the depressions Lenses are attachable.

following is an embodiment of the Invention based on the accompanying Drawing closer described. Show it:

1 a side view of the inner part of a micro-flow measuring cell according to the invention;

2 one related to 1 side view of the inner part rotated by 90 °;

3 a side view of the associated outer part of the micro-flow measuring cell, in which the inner part after 1 and 2 can be used from above;

4 a side view of a known micro-flow measuring cell.

In the 4 known, known micro-flow measuring cell of a photometer has a substantially Z-shaped glass capillary 10 whose thighs with 12 and 14 and their web with 16 are designated. The in a known manner with a polyamide layer that at the bending points and the web 16 is removed, coated glass capillary 10 sits in a rigid holder 18 and must therefore be adapted very precisely to the receiving channels provided therein. Aligned with the middle section of the canal, which is the bridge 16 the glass capillary 10 picks up, that's the bracket 18 forming, in the assembled state cuboid housing with a light entry opening with a ball lens attached in front of it 20 and formed on the other side with a light exit opening, behind which another ball lens 22 is appropriate. This optical device focuses the light from a light source 24 to one end of the middle straight section 16 the glass cape lare 10 , so that it is irradiated in the longitudinal direction. At its other end, ie at the bending point between the web 16 and the subsequent leg 12 the glass capillary 10 , the light is through the ball lens attached on this side 22 on a photodiode 26 with the help of which it can be determined how great the absorption of the light is when passing through the sample.

When running after 1 - 3 the glass capillary designated here 30 has essentially the shape of a "U" with two parallel legs 32 . 34 and a bridge connecting them 36 with the two legs 32 . 34 each forms a right angle. The corners are bending points of the glass capillary with very small radii freed from the polyamide layer mentioned.

The holder of the glass capillary 30 consists of an inner part 38 and an outer part 40 , The inner part 38 has essentially the shape of a piston with an upper cylindrical region 42 and a lower cylindrical region 44 , In between there is an area flattened on opposite sides 46 , Above the upper cylindrical area 42 is the inner part 38 with a traverse 48 provided that in 1 in its longitudinal extent and in 2 is shown with its narrow side. The traverse 48 is longer than the diameter of the cylindrical areas 42 . 44 of the inner part 38 , In continuous threaded holes at the ends of the crossbar 48 are parallel to the longitudinal axis of the inner part 38 adjusting screws 50 screwed in more or less far down from the crossbar 48 can protrude out.

How best to look 2 visible, the legs extend 32 . 34 the glass capillary 30 in the axial direction through the upper cylindrical area 42 of the inner part 38 , They are covered with a Teflon tube and z. B. fixed by gluing. The jetty 36 the glass capillary 30 extends through a through hole 52 that are near the bottom of the flattened area 46 located and connects the two flattened side surfaces of the piston body. The free ends of the legs 32 . 34 the glass capillary 30 are sufficient according to 2 through the cylindrical area 42 and the traverse 48 of the inner part 38 through upwards or on the traverse 48 over if it is only about as wide as the width of the flattened area 46 , and are connected in a known manner to a supply line and a drain line for the solution to be examined. Even below the cylindrical area 42 lie the thighs 32 . 34 next to the flat side surfaces of the flattened area 46 outside the inner part 38 , This also applies in particular to the corner regions curved at the transitions from the legs with a small radius 32 . 34 in the jetty 36 ,

The outer part 40 is according to 3 with a mounting hole extending vertically from above 54 provided in the form of a blind hole, the diameter of which corresponds to the diameter of the cylindrical regions 42 and 44 of the inner part 38 fits. The latter can be done together with the attached glass capillary 30 from above into the mounting hole 54 be introduced. The hole is in the upper area 54 expanded by drilling or milling so that the with 56 designated extension the traverse 48 can accommodate and also in the extension 56 so much space next to the traverse 48 is present that this together with the entire inner part 38 still at a certain angle of z. B. is rotatable 10 ° when the is transverse to the longitudinal extension of the cross member 48 extending central axis of the through hole 52 regarding 3 runs perpendicular to the drawing plane. The rectified is the central longitudinal axis of the central longitudinal axis of the receiving bore 54 crossing through hole 58 through the outer part 40 on one side of the location hole 54 forms a light entry opening and on the other side forms a light exit opening.

For the ready-to-use condition, the central longitudinal axis of the web 36 the glass capillary 30 with the central longitudinal axis of the light entry and exit, ie the through hole 58 , cursed. To achieve this, the inner part 38 on the floor surface serving as the counter surface 60 the bore extension 56 supporting adjusting screws 50 so that the central longitudinal axis of the web 36 exactly at the level of the central longitudinal axis of the through hole 58 lies. In addition, the inner part 38 in the hole 54 and with it the traverse 48 in the hole extension 56 be rotated in the limited frame so that the axes of the web are at the same level 36 and the hole 58 to be put into flight. When this position is reached, the inner part 38 by means of a threaded hole in the outer part 40 screw-in clamping screw 62 that are radial against the cylindrical area 42 of the inner part 38 is pressed, fixed in the outer part.

For attaching lenses according to the in 4 shown ball lenses 20 . 22 on the outside of the light entry and exit 58 is this through hole on both sides with a round countersink 64 verse, four threaded holes in the bottom surface 66 are incorporated. The holders of the lenses are attached there using suitable screws 20 . 22 attached.

Further holes 68 . 70 in the outer part 40 are used to attach the micro flow measuring cell shown to the support structure of the photometer.

Finally, it should be pointed out again that there are limited deviations in the glass capillary 40 , especially in the area of the curved transitions from the legs 32 . 34 in the jetty 36 , of the desired optimal shape the clamping of the glass capillary 30 on the inside 38 do not hinder, since the critical corner areas of the glass capillary 30 outside the essentially piston-shaped body of the inner part 38 , next to the flattened area 46 are located. Any deviations in the shape of the glass capillary 30 also have no misalignment of the central longitudinal axes of the web 36 and the light entry and exit 58 in the outer part 40 as a result, since the adjustment options mentioned above by axial alignment by means of the adjusting screws 50 and rotation of the inner part 38 in the location hole 54 before fixing the inner part 38 on the outer part 40 by means of the clamping screw 62 available.

It goes without saying that the invention is not restricted to the exemplary embodiment described. It is only essential that the holder of the glass capillary 30 consists of a part which supports it, but only partially surrounds it, a further part provided with the light entry and exit opening and an adjusting device for changing the relative position of these two parts. The Justierein direction can preferably also in addition to the adjustment options mentioned above 3 have shown further adjustment means that adjust the inclination of the through hole 52 and the footbridge 36 enable. They consist of the outer part 40 on the underside approximately in the vertical plane, in the operational state the longitudinal axis of the straight section to be irradiated 36 the glass capillary 30 is located, with an interval of two from the lower surface to the mounting hole 54 reaching threaded holes 72 has, can be screwed into the adjusting screws through which the inner part within the scope of the game in the mounting hole 54 is tiltable in both directions, in which the inclination of the through hole 52 is changeable. As adjusting screws 74 expediently use tapered grub screws.

Claims (10)

Micro flow measuring cell for photometers, with a holder ( 38 . 40 ) into which a multi-angled glass capillary ( 30 ) can be used, as well as a light entry and a light exit opening ( 58 ) in line with a straight section ( 36 ) between two bending points of the glass capillary ( 30 ), characterized in that the holder consists of an inner part ( 38 ) and an outer part ( 40 ) consists of the inner part ( 38 ) the multiple angled glass capillary ( 30 ) holds in such a way that the bending points at the ends of the straight section ( 36 ) outside the In partly ( 38 ) and the inner part ( 38 ) in a recess ( 54 ) of the outer part ( 40 ) can be fixed in an adjustable position in which the optical axis of the outer part ( 40 ) attached light entry and exit openings ( 58 ) with the straight section ( 36 ) the glass capillary ( 30 ) flees. Micro flow measuring cell according to claim 1, characterized in that the inner part ( 38 ) has essentially the shape of a partially offset flask and the glass capillary ( 30 ) is essentially U-shaped, with its legs ( 32 . 34 ) extend at least partially outside the piston body on opposite sides parallel to its longitudinal axis and its web ( 36 ) straight through a through hole ( 52 ) or recess in the bulb body and in the assembled state with the optical axis of the light entry and light exit opening ( 58 ) flees. Micro flow measuring cell according to claim 2, characterized in that the essentially piston-shaped body of the inner part ( 38 ) axially between cylindrical areas ( 42 . 44 ) is flattened on opposite sides and the legs ( 32 . 34 ) of the U-shaped glass capillary ( 30 ) partly through a cylindrical area ( 42 ) and partly in the flattened area ( 46 ) outside of the piston body, but within the outside diameter of the cylindrical area ( 42 ) and that the through hole ( 52 ) in the flattened area ( 46 ) is located. Micro flow measuring cell according to claim 2 or 3, characterized in that the substantially piston-shaped body of the inner part ( 38 ) in a suitable mounting hole ( 54 ) in the outer part ( 40 ) is insertable until a radial extension attached to its rear end, e.g. B. in the form of a traverse ( 48 ), on a counter surface ( 60 ) of the outer part ( 40 ) comes to rest, and can be clamped in this axial position. Micro flow measuring cell according to claim 4, characterized in that the radial extension, for. B. in the form of a traverse ( 48 ), relative to the piston body ( 38 ) axially aligned adjusting screws ( 50 ) is provided, the ends of which are on the counter surface ( 60 ) come to the plant. Micro flow measuring cell according to claim 4 or 5, characterized in that the counter surface ( 60 ) in a sunken extension ( 56 ) the mounting hole ( 54 ) in the outer part ( 40 ), which offers so much space that it is necessary to align the 36 ) on the optical axis of the light entry and light exit opening ( 58 ) the inner part ( 38 ) can be rotated to a limited extent about its longitudinal axis before clamping. Micro flow measuring cell according to one of claims 4 to 6, characterized in that the inner part ( 38 ) into the outer part ( 40 ) screw-in clamping screw ( 62 ) against the circumferential surface of the inner part ( 38 ) can be pressed, clamped. Micro flow measuring cell according to claim 4, characterized in that the cross member ( 48 ) is at most as wide as the diameter of the glass capillary ( 30 ) holding cylindrical area ( 42 ) and their straight legs ( 32 . 34 ) on the traverse ( 48 ) passed or passed through them. Micro flow measuring cell according to one of claims 4 to 8, characterized in that the light entry and the light exit opening ( 58 ) aligned holes ( 58 ), each between a depression ( 64 ) in the outer part ( 40 ) and the location hole ( 54 ) and that in the depressions ( 64 ) Mounts for optical lenses ( 20 . 22 ) can be attached. Micro flow measuring cell according to one of claims 1 to 9, characterized in that the outer part ( 40 ) on the underside, roughly in the vertical plane, in which, when ready for operation, the longitudinal axis of the straight section to be irradiated ( 36 ) the glass capillary ( 30 ), with an interval of two from the lower surface to the mounting hole ( 54 ) threaded holes ( 72 ) into the adjustment screws ( 74 ) can be screwed in, through which the inner part ( 38 ) as part of the game in the location hole ( 54 ) can be tilted in both directions, in which the inclination of the through hole ( 52 ) is changeable.