JPS62245141A - Apparatus for measuring reflection density - Google Patents

Abstract

PURPOSE:To continuously measure reflection density by deforming a bundle fiber, by connecting a measuring head to a light source with the bundle fiber of optical fibers and allowing light to pass through the bundle fiber to irradiate a chemical analysis slide to perform measurement. CONSTITUTION:A plurality of chemical analysis slides 1 are housed in an incubator 2 and a light source 3 is connected to a measuring head 6 by a bundle fiber 4 of optical fibers. Light is allowed to pass through the bundle fiber 4 to be sent to the measuring head 6 and irradiates the chemical analysis slides 1. The reflected light from each slide 1 is received by the optical sensor 5 of the measuring head 6 to analyze the specimen on the chemical analysis slide 1. At this time, a fibers having a small diameter are used to minimize the loss of light due to bending and the bundle fiber 4 is deformed to allow the measuring head 6 to move as shown by an arrow in opposed relation to the slide 1 to perform measurement. Because the measuring head is moved by deforming the bundle fiber, the chemical analysis slide can be measured continuously.

Description

Detailed Description of the Invention (Field of the Invention) The present invention irradiates a measurement surface of a chemical analysis slide containing a sample with irradiation light, and receives reflected light from the measurement surface with an optical sensor. The present invention relates to a reflection densitometer that measures the reflection density of a measurement surface, and more particularly to a reflection densitometer that can sequentially perform the above measurements on a plurality of chemical analysis slides.

(Technical Background and Prior Art of the Invention) In recent years, it has become possible to determine specific chemical components or organic components contained in a sample liquid, such as blood or urine, by simply applying small droplets of the sample liquid. A dry type chemical analysis slide capable of analysis has been developed (Japanese Patent Publication No. 53-21677, Japanese Patent Application Laid-open No. 55-164356, etc.) and has been put into practical use.

To analyze the chemical components in a sample solution using such a chemical analysis slide, the sample solution is dotted onto the chemical analysis slide and then kept at a constant temperature (incubation) for a predetermined period of time in an incubator. A color reaction (dye-forming reaction) is carried out, and the resulting color optical density is optically measured. This chemical analysis slide is irradiated with a measurement irradiation light containing a wavelength and its reflected optical density is measured, thereby constantly analyzing the content of the substance to be measured mainly based on the principle of colorimetry.

The reflection optical density is measured using a reflection density measuring device. Such a reflection density measuring device includes an incubator that can house the chemical analysis slide, and a measurement head that can be placed in the incubator at a position facing the measurement surface of the chemical analysis slide, and the incubator in the device After storing the chemical analysis slide in a chamber and incubating it, a measurement head is placed facing the measurement surface, and the measurement head is used to irradiate the measurement surface of the chemical analysis slide with measurement irradiation light. The reflection density of the measurement surface is measured by receiving the reflected light from the surface with an optical sensor in the measurement head.

In this case, especially in analyzes conducted at medical institutions, laboratories, etc.
It is necessary to analyze a large number of samples, and it is desirable to be able to perform this analysis continuously. For this reason, various proposals have been made regarding chemical analysis apparatuses that are capable of continuously analyzing samples using a plurality of the chemical analysis slides described above.

For example, as disclosed in JP-A-56-77746, chemical analysis slides are sandwiched between two rotatable disks at equal intervals in the circumferential direction. A heater is provided to keep the temperature constant, and the chemical analysis slide, which has been kept at constant temperature for a predetermined period of time, is positioned opposite the measuring head located below the disk by rotating the disk. There is a chemical analysis apparatus in which a measuring head irradiates a chemical analysis slide with light through an opening in the lower surface of a disk and measures the reflected optical density thereof. If this device U is used, multiple chemical analysis slides can be placed circumferentially between two discs, allowing for efficient and quick analysis, but it is large and heavy. However, the rotation system for rotating a large disk and its control system tend to become complicated, which poses some problems in terms of miniaturization and cost reduction of the device.

(Object of the Invention) The present invention has been made in view of the above-mentioned problems, and has a structure in which the measuring head has a simple structure suitable for movement, and the chemical analysis slide side is fixed while the measuring head is moved. The object of the present invention is to provide a reflection 11EI degree measuring device that can continuously measure a plurality of chemical analysis slides without using a complicated mechanism.

(Structure of the Invention) The reflection density measuring device of the present invention includes an incubator capable of storing a plurality of chemical analysis slides on the same plane, a light source arranged outside the incubator, and a plurality of optical fibers bundled around the light source. The measurement head is movable while deforming the bundle fiber so that the measurement head can take a position facing any of the chemical analysis slides housed in the incubator. It is characterized by this.

In the apparatus of the present invention, since the light source is separate from the measurement head, the measurement head is light and compact, making it suitable for movement. Furthermore, since the measurement head and the light source are connected by the bundle fiber, even if the measurement head moves while deforming the bundle fiber, the chemical analysis slide can always be irradiated with a stable amount of irradiation light.

In other words, in order to sufficiently transmit the light emitted from the light source to the measurement head, it is necessary to use an optical fiber with a relatively large diameter, but a single, large-diameter optical fiber has a large loss in light transmission due to bending. Therefore, it is unsuitable for use in a reflection density measuring device. On the other hand, when optical fibers with a small diameter are bundled together, the total diameter is 7? The bundle fiber, which has been made into a fiber, has a small loss in light transmission due to bending, so even if the measurement head moves while deforming the bundle fiber, the amount of light emitted from the measurement head is always approximately constant. By moving the measuring head while deforming the bundle fiber in this way, it is possible to continuously measure a plurality of chemical analysis slides without using a complicated mechanism.

(Embodiments) Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a side view schematically showing a reflection density measuring device according to an embodiment of the present invention.

The illustrated device δ includes an incubator 2 that can accommodate four chemical analysis slides 1 containing a sample liquid on the same plane, an incubator 2 fixed at a predetermined position outside the incubator 2, and the chemical analysis slides A light source 3 such as a halogen lamp that emits irradiation light suitable for measuring the reflection density of the measurement surface 1a of 1, and the irradiation light transmitted by the bundle fiber 4 is connected to the light source 3 via a bundle fiber 4. The measuring head 6 includes an optical sensor 5 such as a silicon photodiode which receives the reflected light incident on the measurement surface 1a of the chemical analysis slide and which is reflected by the measurement surface 1a. In the figure, reference numeral 7 denotes a condenser lens for efficiently inputting the irradiation light emitted from the light source lamp into the bundle fiber 4, and the lens 6a in the measurement head 6 converts the irradiation light emitted from the bundle fiber 4 into a condenser lens. Place 4 on the measurement surface 1a of the analysis slide! This lens is used to achieve a beam diameter of .

In the above device, the measurement head 6 includes the incubator 2
The fiber bundle 4 is movable while being deformed so as to take a position facing any chemical analysis slide 1 housed therein. That is, the measuring head 6 moves over the range shown by arrow A between the position shown by the solid line in the figure and the position shown by the broken line in the figure. The movement of this measuring head 6 will be explained below.

As mentioned above, the measurement head 6 is capable of transmitting the irradiation light emitted from the external light source 3 via the bundle fiber 4, and is lighter and smaller than a measurement head with a built-in light source. It is suitable for being moved by simple transportation means. Also light +1
In order to efficiently transmit the irradiation light emitted from the 1i3 to the measurement head 6, a relatively large-diameter optical fiber is required, and it is said that a large-diameter optical fiber consisting of a single fiber has a large loss in light transmission due to bending. Although there are some drawbacks, this device uses a bundle fiber 4 made up of a plurality of small-diameter optical fibers 48 bundled together as shown in FIG. 2, so light loss due to bending is minimized. be able to.

By the way, even though the bundle fiber 4 has a relatively small loss due to bending as described above, if the bending radius changes suddenly when the measurement head 6 is moved, there will be a difference in the light transmission efficiency, making it unsuitable for highly accurate measurement. Therefore, when moving the measurement head 6, be sure to
It is desirable to deform the bending radius so that the bending radius does not change as much as possible. Therefore, in the device of this embodiment,
- For example, a circular moving means such as a pulley 8 is used to deform the bundle fiber 4 and control its bending radius. That is, the bundle fiber 4 is mounted on a rotatable pulley 8, and the pulley 8 is biased and pulled in the direction of arrow B by a spring 9.

Therefore, even if the measurement head 6 is moved in the direction of the arrow C or in the force direction of the arrow C' by a moving means (not shown) and stopped at a position facing an arbitrary slide 1 in the incubator 2, the bending radius of the bundle fiber 4 is is pulley 8
The radius R is maintained at

Note that when moving the measuring head 6 as described above, if you want to control the bending radius of the connecting part of the bundle fiber 4 to the measuring head 6 to be correct and constant,
As shown by the dashed line in the figure, a circular support means 10 having a desired radius is disposed in contact with the connecting portion of the bundle fiber 4, and is moved in conjunction with the displacement of the connecting portion of the bundle fiber 4. Bye.

As a means for keeping the bending radius of the bundle fiber 4 constant, in addition to using a pulley as in the above-mentioned actual ms, as shown in FIG. Plates 20a and 20b may be provided to maintain a constant bending radius of the bundle fiber 4.

Further, the number and arrangement of chemical analysis slides within the incubator are not limited to those shown in the above-mentioned actual IN embodiment.

(Effects of the Invention) As explained above, according to the reflection density measuring device of the present invention, the light source is made separate from the measurement head, so that the measurement head is made smaller than the pumice stone, making it suitable for movement. Furthermore, by connecting the light source and the measurement head with the bundle fiber, even if the measurement head moves while deforming the bundle fiber, loss in light transmission can be minimized. Therefore, according to the apparatus of the present invention, by fixing a plurality of chemical analysis slides and moving the measurement head, it is possible to continuously measure a plurality of chemical analysis slides without complicating or increasing the size of the entire apparatus. becomes possible.

[Brief explanation of drawings]

FIG. 1 is a side view showing an outline of a reflection density measuring device according to an IA aspect of the present invention, FIG. 2 is a schematic perspective view showing a bundle fiber used in the device, and FIG. 3 is another embodiment of the present invention. FIG. 2 is a schematic plan view of a reflection density measuring device according to an embodiment.

Claims (1)

[Claims] 1) An incubator capable of storing a plurality of chemical analysis slides containing materials on the same plane, a light source disposed outside the incubator, and a plurality of optical fibers bundled around the light source. The measurement surface of the chemical analysis slide is connected with a bundle fiber, and the measurement surface of the chemical analysis slide is irradiated with irradiation light, and the reflected light reflected from the measurement surface is received by an optical sensor to measure the reflection density of the measurement surface. A reflection density measuring device comprising a measurement head, which is movable while deforming the bundle fiber so that the measurement head can take a position facing any of the chemical analysis slides housed in the incubator. 2) The reflection density measuring device according to claim 1, wherein the bundle fiber is deformed so that the bending radius does not change when the measurement head is moved.