DE8907967U1 - Device for reflectance photometric measurement of liquid samples - Google Patents

Description

Device for reflectance photometric measurement of liquid samples

The invention relates to a device for the reflectance-probometric measurement of liquid samples according to the preamble of claim 1.

In conventional devices of the type mentioned above, a transparent continuous plate is usually arranged between the measuring device and the test field in order to protect the measuring device from contamination. This arrangement has the disadvantage that the rays emanating from the light source are partially reflected at the boundary surfaces of the transparent plate and reach the receiver as scattered light, thus distorting the measurement. This effect can be further increased if the transparent plate is dirty.

The invention is based on the object of eliminating interference radiation of the type described above and ensuring that the receiver only receives light remitted from the test field.

This object is achieved according to the invention in that a wall is arranged between the light source and the receiver in such a way that it prevents the incidence of interference radiation that does not originate from the test field of the test strip, for example by passing through the plate made of transparent material. This means that light reflected at the boundary surfaces of the transparent plate can no longer reach the receiver directly. The latter only receives light that has been remitted from the test field, regardless of whether the plate is dirty on the side facing the measuring window or not.

The disadvantage of the known devices, which was initially mentioned, becomes particularly noticeable when the measuring device of the device is to be checked using a so-called white or gray standard. The reflected scattered light then simulates a much higher remission value.

According to the invention, a first reference body defining a brightness standard is mounted on the strip holder in such a way that it rests against the measuring window when a test strip is missing and is separated by a measuring window when a test strip is inserted. In this way, the measuring device can always be checked using the reference body before a test strip is inserted, whereby only the light that was remitted by the reference body actually falls on the receiver.

Preferably, two light sources and two receivers are provided, whereby the measuring window is divided into two sections by a web, which allow the light from one light source to fall on the

receiver belonging to the other light source. In this way, either two different test fields can be measured or the measured values obtained from the same text field from the two individual measuring devices can be compared and averaged.
to detect local differences within the test field
to be able to equalize.

This double measuring device also makes it possible to
In conjunction with two fields of different reflectivity on the reference body, each of which is assigned to a section of the measuring window, two reference measurements can be carried out simultaneously. This has the advantage that the device function can be checked much better than with a simple measuring device.
The device usually has at least one reference curve stored in it, which shows a relationship between the purification values and the desired measured values &Ggr;

i is produced. Sometimes several such references are |

ence curves are stored. You can now use the reference &iacgr;

renskörper measure two different remission values |

and assigns these to two different suitable references.

limit curves. For example, the same ge- |

The desired measurement value can be displayed. Conversely, with |

a single reference curve not only one measured value |

but determine two measured values and thus check, |

whether the device works properly in the various measuring ranges |

functions properly. 1

This device check can be further improved if a second measuring window is added to the strip support surface.
is intended, a second reference body with
a purification capacity different from the first reference body, whereby the second
KeBfeiiSter - in the direction of thrust of the Stxreifenaufnannie

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in the device slot - in front of the first measuring window. For example, if the strip holder is only half inserted, the second measuring window together with the second reference body is in front of the measuring device. A so-called white standard can be used as the first measuring body and a black or gray standard as the second reference body, depending on the maximum and minimum remission capacity. If the values measured correspond to the expected values, a reliable measurement can be assumed.

To make cleaning the strip holder easier, the second reference body is pivotably mounted on the strip holder and the first reference body is connected to the second reference body. This means that both reference bodies can be folded away from the strip holder. The measuring window is therefore easily accessible and can always be kept clean.

In order to bring the reference bodies into a position corresponding to the test field during the reference measurement, the reference bodies are pre-tensioned by a pressure device so that they can be elastically deflected in the direction of the strip support. In a preferred embodiment, the pressure device comprises a spring-loaded rocker which is pivotably mounted in the middle and which rests with one end on the first reference body and with the other end on the second reference body.

Further features and advantages of the invention emerge from the following description, which, in conjunction with the accompanying drawings, explains the invention using an exemplary embodiment. They show:

t · 1

Fig. 1 is a schematic perspective view of a device according to the invention and

Fig. 2 is a horizontal partial section along line H-II in Fig. 1.

Fig. 1 shows a measuring device 10 which has an opening 12 at one end into which a test strip 14 can be inserted. The opening 12 is located in a slide 16 which is detachably connected to a strip holder (Fig. 2) which is inserted into a receiving slot 20 of the device 10.

The strip holder 18 comprises a strip support surface 22 with a first measuring window 24 and a second measuring window 26, which are separated from one another by a web 28, which simultaneously serves as a stop for positioning a test strip 14. The positioning is carried out in such a way that a test field 30 on the test strip 14 lies exactly above the first measuring window 24 when it hits the stop 28. The second measuring window 26 cannot be reached by the test strip 14.

If the strip holder 18 is in the fully inserted position shown in Fig. 2, the measuring window 24 is opposite a measuring device 32. This comprises two light sources 34 in the form of light-emitting diodes, each of which is connected to a light guide 36 made of a transparent plastic that extends in the direction of the measuring window 24. Each light source 34 is assigned a receiver 38 that is covered by a window 40. The window 40

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is separated from the light guide 36 by a wall 42. In this way, the light emitted by the respective light-emitting diode 34 and guided via the light guide 36 to the test field 30 of the test strip 14 can only reach the receiver 38 from the test field 30. The incidence of scattered light on the receiver is reliably avoided. So that only the light emitted by the associated light source 34 reaches the respective receiver 38, the measuring window 24 is divided into two equal sections by a web 44.

A first reference body 46 is arranged opposite the measuring window 24, which is referred to as the so-called white standard and has two reference surfaces 48 and 50, which cover the two sections of the measuring window 24 when the test strip 14 is missing. The reference body 46 is pivotably connected to one end of a second reference body 52 about an axis 54. The second reference body 52 is arranged opposite the second measuring window 26 and is pivotably mounted on the strip holder 18, whereby a bolt 54 connected to the strip holder 18 engages in an elongated hole 56 formed in the second reference body 52. Both reference bodies 46, 52 are preloaded by a rocker 58 in the direction of the strip support surface 22. The rocker 58 is pivotably mounted about a central axis 60, whereby the associated axle stub is displaceably mounted in a housing groove or a housing slot 62 perpendicular to the strip support surface 22, so that the rocker 58 can not only pivot about the axis 60 but can also be adjusted perpendicular to the strip support 22. The rocker 58 is in turn pressed against the reference bodies 46 and 52 by means of a spring 64, whereby the load is selected so that

the pressure before a"iif»»a acts on the section that rests against the reference body 52. This is to ensure that the rocker 58 and thus also the first reference body 46 can give way when a test strip 14 is inserted.

The device according to the invention described so far works in the following way: Before starting a measurement, the tire holder 18, which is detachably attached to the slide 16, is pulled halfway out of the device shaft 20 so that the second measuring window 26 is opposite the measuring device 32. The second reference body 52 has a different reflectance than the first reference body 46. This reflectance value is measured first. The tire holder 18 is then pushed completely into the device so that the second reference body 46 is opposite the measuring device 32. Its reflectance is now measured. The device function can be checked using the known reflectance values of the two reference bodies 46 and 52. Now the test strip 14 is inserted into the device through the contactor 12 until it hits the stop 28. In this position it is held by the rocker 58 and the first reference body 46, with the test field 30 lying flat above the measuring window 24. The test field can now be measured.

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Claims (8)

Protection claims 1. Device for the reflection photometric measurement of liquid samples, each of which is applied to a test field of a test strip which can be inserted into the device, comprising a strip holder which can be inserted into a shaft of the device and has a strip support surface in which a measuring window is arranged, a stop for positioning the test strip in its inserted position and an optical measuring device arranged in the inserted position of the strip holder opposite the measuring window with at least one light source and a receiver assigned to it , characterized in that a wall (42) is arranged between the light source (34) and the receiver (38) in such a way that it prevents the incidence of interference radiation which does not originate from the test field (30) of the test strip (14). 2. Device according to claim 1, characterized in that a first reference body (46) defining a brightness standard is adjustably mounted on the strip holder (18) in such a way that it rests against the measuring window (24) when the test strip (14) is missing and is separated from the measuring window (24) by the test strip (14) when the test strip (14) is inserted. 3. Device according to claim 1 or , characterized in that two light sources (34) &ugr;&eegr;&aacgr; two receivers (38) are provided and that the measuring window (24) is divided into two sections by a web {44}, which prevents the light from one light source (34) from falling on the receiver (38) belonging to the other light source. 4. Device according to one of claims 1 to 3, characterized in that the first reference body (46) has two fields (48, 50) of different reflectance, which are each assigned to a section of the measuring window (24). 5- Device according to one of claims 1 to 4, characterized in that a second measuring window (26) is provided in the strip support surface (22), to which a second reference body (52) with a different reiaissance than the first reference body (46) is assigned, the second measuring window (26) - viewed in the direction of insertion of the strip holder (18) into the device shaft (20) - being located in front of the first measuring window (24). 6. Device according to claim 5, characterized in that the second reference body (52) is pivotally mounted on the strip holder (18) and that the first reference body (46) is articulated to the second reference body (52). 7. Device according to claim 5 or 6, characterized in that the two reference bodies (46, 52) are prestressed by a pressure device (58) so as to be elastically deflectable in the direction of the strip support surface (22). 8. Device according to claim 7, characterized in that the pressure device comprises a spring-loaded, centrally pivoted rocker (58) which rests with one end on the first reference body and with its other end on the second reference body.