KR19990025817A - Fluorescent material optical property measuring device - Google Patents

Abstract

Disclosed is a fluorescent material optical characteristic measuring apparatus. The fluorescent material optical property measuring apparatus includes a support on which a sample having a fluorescent layer is mounted, a light emitting part for emitting predetermined light to the fluorescent layer of the sample mounted on the support, and a fluorescent layer of the sample mounted on the support. And a light-receiving unit for transmitting the light or receiving the reflected light, and transfer means for transferring the light-emitting unit and the light-receiving unit to emit or receive light at a predetermined angle with respect to the sample mounted on the support.

Description

Fluorescent material optical property measuring device

The present invention relates to an optical property measuring device for a fluorescent material, and in particular, to measure the transmittance, reflectance and luminance of light by transmitting or reflecting predetermined light to the fluorescent material, and at an arbitrary angle with respect to the fluorescent material to be evaluated. The present invention relates to an apparatus for measuring optical properties of fluorescent materials, which is improved to transmit or reflect predetermined light.

In general, a method for evaluating the optical characteristics of a fluorescent material is to measure the transmittance and luminance of the transmitted light by transmitting predetermined light to the fluorescent material to be evaluated, or by measuring the reflectance of the reflected light by reflecting the predetermined light to the fluorescent material. A comparative evaluation method is used.

1A and 1B are schematic configuration diagrams illustrating an optical property measuring device of a fluorescent material for measuring optical properties of the fluorescent material as described above.

FIG. 1A illustrates a schematic configuration of an optical material measuring apparatus for a fluorescent material for a transmissive measuring method for measuring optical properties such as transmittance and luminance of transmitted light by transmitting predetermined light to the fluorescent material. ) A pedestal (12a) is arranged, a light emitting portion (13a) for outputting a predetermined light to the fluorescent material (11a) disposed on the pedestal (12a), and a light receiving portion for receiving the light transmitted through the fluorescent material (11a) 14a).

1B illustrates a schematic configuration of a fluorescent material optical property measuring apparatus for a reflective measurement method for reflecting predetermined light to a fluorescent material and measuring optical properties such as reflectance of reflected light. ) Receives the light reflected by the light emitting portion 13b and the fluorescent material 11b which emit light at a predetermined angle with respect to the pedestal 12b on which the light is disposed, and the fluorescent material 11b disposed on the pedestal 12b. It is comprised including the light-receiving part 14b.

In the fluorescent material optical property measuring apparatus as shown in FIGS. 1A and 1B, a light source for generating predetermined light is typically connected to the light emitting units 13a and 13b to emit light through the light emitting units 13a and 13b. The light emitter 14a, 14b is connected to, for example, a monochromator for extracting monochromatic light, and the like to analyze the received light.

However, in the related art, in order to implement a transmissive measuring method and a reflective measuring method for measuring optical characteristics of a fluorescent material, an optical property measuring apparatus of the fluorescent material as shown in FIGS. 1A and 1B is separately configured. It was used by. In the optical property measuring apparatus of the fluorescent material having the above-described configuration, the light emitting parts 13a and 13b and the light receiving parts 14a and 14b are attached to the fluorescent materials 11a and 11b disposed on the pedestals 12a and 12b. It is installed in a fixed state with respect to the fluorescent materials 11a and 11b, which has a limitation in receiving and transmitting a predetermined light at a precise angle. In particular, in the reflective measuring method for the fluorescent material 11b, since the light emitting part 13b and the light receiving part 14b are fixedly installed, the reflectance of the light with respect to the fluorescent material cannot be measured at an angle other than the initial setting. There is a problem that the shape is not measured.

The present invention was created in view of the above-mentioned problems, and is an apparatus for measuring optical characteristics by transmitting or reflecting predetermined light to a fluorescent material, and adjusting various angles of incidence and reflection angle of light applied to the fluorescent material. It is an object of the present invention to provide a fluorescent optical properties measuring apparatus that can measure the optical properties of the fluorescent material.

1A and 1B are schematic configuration diagrams showing an apparatus for measuring optical properties of a conventional fluorescent substance;

Figure 2 is a schematic block diagram showing an apparatus for measuring the optical properties of the fluorescent material according to the present invention,

3A and 3B are perspective views illustrating a transmissive sample holder and a reflective sample holder respectively used in the fluorescent material optical property measuring apparatus of FIG. 2;

4 is a schematic view of the structure of the first transfer unit and the second transfer unit of FIG.

5A to 5B are diagrams illustrating a state of measuring a transmissive measuring method and a reflective measuring method for fluorescent materials using the fluorescent material optical property measuring apparatus according to the present invention.

Explanation of symbols for main parts of the drawings

100.Support 110.Sample

121. Transmissive sample holder 122. Reflective sample holder

130 holder holder 200 light emitting unit

300.Receiver 210,310 Lens

Lens mount 230,330

400.Guide part 410.Guide rail

411. First Gear 412. Scale

420. First transport unit 421. Body

422.Second Gear 423.Drive Motor

424.Roller 430.Second transport unit

In order to achieve the above object, the present invention provides a fluorescent material optical property measuring apparatus comprising: a support on which a sample having a fluorescent layer is mounted, a light emitting part for emitting predetermined light to the fluorescent layer of the sample mounted on the support; The light-receiving unit that transmits or receives the fluorescent layer of the sample mounted on the support or receives the reflected light, and the light emitting unit and the light-receiving unit may be transported to emit or receive light at a predetermined angle with respect to the sample mounted on the support. It includes a conveying means.

And in the present invention, the conveying means, a circular guide rail having a radius of a predetermined radius around the support and the first gear portion formed on the outer circumference, and the first conveying portion is moved along the guide rail and the light emitting portion is mounted And a second transfer part which is moved along the guide rail and on which the light receiving part is mounted.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view showing an embodiment of an optical properties measuring apparatus of a fluorescent material according to the present invention, the configuration is as follows.

As illustrated, the optical property measuring apparatus of the fluorescent material includes a support 100 on which the sample 110 is mounted, and a light emitting unit 200 for emitting predetermined light to the sample 110 mounted on the support 100. And the light receiving unit 300 for transmitting the fluorescent layer of the sample mounted on the support 100 or receiving the reflected light, and emitting or receiving light at a predetermined angle with respect to the sample mounted on the support 100. It comprises a transport means 400 for transporting the light emitting unit 200 and the light receiving unit 300 to be able to.

The supporter 100 includes a sample holder 120 in which a sample 110 having a fluorescent layer coated or filled with a fluorescent material is installed, and a holder support 130 in which the sample holder 120 is installed in a detachable manner. ). Here, the sample holder 120 is divided into a transmission type sample holder 121 and a reflection type sample holder 122 in which a plurality of samples 110 are installed. Shown in 3b respectively.

3A illustrates a state in which the transmissive sample holder 121 is installed in the holder support 130, and the holder support 130 is provided with a mounting groove having a predetermined depth and width, and the holder support 130 is disposed in the mounting groove. A transmissive sample holder 121 is installed, in which a sample is installed perpendicularly to an upper surface of the. The transmissive sample holder 121 has a plurality of seating portions 121a formed therein so that a plurality of samples can be mounted thereon, and the holder holder 130 is installed to be detachable. In addition, the transmissive sample holder 121 is slidably installed with respect to the holder pedestal 130 so that the position of the plurality of samples mounted on the transmissive sample holder 121 can be adjusted with respect to the holder pedestal 130.

In addition, FIG. 3B illustrates a state in which the reflective sample holder 122 is installed in the holder support 130, and the specimen is placed in the seating groove of the holder support 130 in parallel with the upper surface of the holder support 130. The reflective sample holder 122 is installed. In addition, the reflective sample holder 122 has a plurality of seating portions 122a formed thereon so that a plurality of samples can be mounted, similarly to the transmissive sample holder 121 described above. It is possible to install. In addition, the reflective sample holder 122 is slidably installed with respect to the holder support 130 so that the position of the plurality of samples mounted on the reflective sample holder 122 can be adjusted with respect to the holder support 130. . In addition, the holder support 130 is preferably installed to enable fine movement in the width direction and the longitudinal direction of the upper surface.

In addition, the light emitting unit 200 and the light receiving unit 300 are connected to a light transmission line 21 made of an optical transmission path, for example, a lens unit 210 including a plurality of lenses constituting an optical system for condensing scattered light. And the lens mounting portions 220 and 320 on which the lens portions 210 and 310 are installed. In addition, the adjusting means for adjusting the working distance of the light emitted through the lens unit (210, 310) by adjusting the direction of the lens unit (210, 310) in the lens mounting unit (220, 320) ( 230 and 330. The adjusting means 230 and 330 are finely adjusted in a predetermined direction to the lens unit 210 and 310 installed in the lens mounting unit 220 and 320 to be emitted from the lens unit 210 or to the lens unit 310. It is desirable to be able to adjust the working distance of the received light.

In addition, the conveying means 400 is a circular guide rail 410 and a guide rail 410 is installed to have a predetermined radius orbit around the support 100, and moves along the guide rail 410, the light emitting unit 200 And a first transfer unit 420 and a second transfer unit 430 on which the light receiving unit 300 is mounted. Here, the first gear portion 411 of a predetermined shape is formed on the outer circumferential surface of the guide rail 410, the support 100 when the first transfer portion 420 and the second transfer portion 430 moves along the guide rail 410 A scale 412 is displayed to indicate an angle so as to measure an angle formed therewith. The first transfer unit 420 and the second transfer unit 430 described above include, for example, a main body 421 in which the light emitting unit 200 or the light receiving unit 300 is installed, and the main body 421 as shown in FIG. 4. A plurality of rollers 424 installed in the guide rail 410 and rolling contact with the guide rail 410, and installed in the main body 421 and coupled to the first gear 411 of the guide rail 410 to rotate the main body 421. It includes a second gear portion 422 for transferring along the guide rail 410. Here, the drive motor 423 is connected to the second gear portion 422, the second gear portion 422 is rotated or stopped depending on the presence or absence of operation to move or stop the main body 421. In addition, the plurality of rollers 424 in contact rolling motion with the inner circumferential surface and the outer circumferential surface of the guide 410, respectively, when the first conveying part 420 and the second conveying part 430 move along the guide rail 410. It serves to improve stability.

5A to 5B illustrate a state of measuring a transmissive measuring method and a reflective measuring method for fluorescent materials using the fluorescent material optical property measuring apparatus according to the present invention.

First, in order to implement a transmissive measuring method for measuring optical characteristics by transmitting a predetermined light to a fluorescent material, a transmissive sample holder equipped with a plurality of samples having a fluorescent layer formed of a fluorescent material to be measured as shown in FIG. 4A. (121) is installed on the holder support 130. Then, the light emitting unit 200 and the light receiving unit 300 are moved along the guide rail 410 so as to face each other in a right angle direction with respect to the sample mounted on the transmissive sample holder 121 and positioned at a predetermined position. Then, the predetermined light is emitted to the sample through the light emitting unit 200 and then the light transmitted through the light receiving unit 300 is received. Here, the transmissive sample holder 121 is a plurality of samples are mounted and is slidably installed with respect to the holder support 130, each sample by moving the transmissive sample holder 121 with respect to the holder support 130 by a predetermined interval Optical characteristic measurement can be performed easily.

In order to implement a transmissive measurement method for measuring optical characteristics by transmitting a predetermined light to the fluorescent material, a reflective sample equipped with a plurality of samples having a fluorescent layer formed of a fluorescent material to be measured, as shown in FIG. 4B. The holder 122 is installed in the holder support 130. Then, the light emitting unit 200 and the light receiving unit 300 are moved along the guide rail 410 so as to form a predetermined measurement angle with respect to the sample mounted on the reflective sample holder 122 and positioned at a predetermined position. Then, the predetermined light is emitted to the sample through the light emitting unit 200 and then the reflected light is received through the light receiving unit 300. And, in order to measure the optical characteristics by varying the incident angle and the reflection angle of the light applied to the fluorescent material, to move the light emitting unit 200 and the light receiving unit 300 along the guide rail 410 to achieve an arbitrary angle with respect to the sample. Since it can be positioned, it is possible to measure the optical properties of the fluorescent material by applying various incident angles and reflection angles to the sample.

The fluorescent material optical property measuring apparatus according to the present invention has the following effects.

First, since the light emitter and the light receiver are movable at a predetermined angle with respect to the support on which the fluorescent material is disposed, the optical characteristics of the developer may be measured by setting an arbitrary incident angle and a reflection angle.

Second, since the sample holder is divided into a transmissive sample holder and a reflective sample holder and is mounted on and detachable from the holder support, the transmissive measurement and the reflective measurement for fluorescent materials are simple by installing a suitable sample holder on the holder support. Can be implemented.

Claims (5)

A support on which a sample having a fluorescent layer is mounted; A light emitting unit for emitting a predetermined light to the fluorescent layer of the sample mounted on the support; A light receiving unit for transmitting the fluorescent layer of the sample mounted on the support or receiving the reflected light; And And transfer means for transferring the light emitting part and the light receiving part so as to emit or receive light at a predetermined angle with respect to the sample mounted on the support. The method of claim 1, The transfer means, A circular guide rail having a radius of a predetermined radius around the support and having a first gear portion formed on an outer circumferential surface thereof; A first transfer part moved along the guide rail and mounted with the light emitting part; And a second transfer part mounted along the guide rail and mounted with the light receiving part. The method of claim 2, The first transfer unit and the second transfer unit, A main body provided with the light emitting part or the light receiving part; A plurality of rollers installed in the main body and in rolling contact with the guide rails; And a second gear part installed in the main body and coupled to the first gear part of the guide rail to transfer the main body along the guide rail when rotated. The method of claim 1, The support is, A sample holder in which a plurality of samples having the fluorescent layer are provided; And a sample holder is provided with a holder support to which the sample holder is detachably installed. The method of claim 1, And the light emitting unit and the light receiving unit include a lens unit forming an optical system for condensing scattered light.