JPH0443809Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Field of Application] The present invention relates to a curved prism type liquid refractometer, and particularly improves the structure of the curved prism.

[Conventional technology and problems]

In general, a curved prism type liquid refractometer is basically configured as shown in Figure 5, and the light p emitted from a light emitting element, such as a light emitting diode (hereinafter abbreviated as LED) 1, has a refractive index n ₁ liquid 2
It passes through the inside and reaches the curved prism surface 3a of the curved prism 3, and there, due to the difference between the refractive index n ₂ of the curved prism 3 and the refractive index n ₁ of the liquid 2, the prism of the curved prism 3 at the incident angle θ When the light is incident on the surface 3a, it is refracted at a refraction angle θ' (sin θ/sin θ'=n ₂ /n ₁ ) based on Snell's law, and is further transmitted through the curved prism 3 to a light receiving element, such as a photodiode. The light is incident on the light receiving surface 4a of No.4.
Thus, on the light-receiving surface 4a of the photodiode 4, there is a bright part where the light from the LED 1 enters, and
A dark area is created where the light from LED 1 does not enter. Such a bright/dark boundary line is the prism surface 3a.
It is formed by light incident tangentially to the curved prism 3 and extends parallel to the longitudinal direction of the prism surface 3a of the curved prism 3, that is, in a direction perpendicular to the paper plane of FIG.

According to the curved prism type liquid refractometer with such a configuration, according to the value of the refractive index n ₁ of the liquid 2,
Since the refraction angle θ ₀ of the light q emitted from the LED 1 and incident tangentially on the prism surface 3a is determined, the bright/dark boundary line on the light receiving surface 4a of the photodiode 4 is aligned in the direction of the arrow X in FIG. Since the photodiode 4 outputs a current that is approximately proportional to the amount of light it receives, the position of the bright/dark boundary line can be obtained by measuring this current. Therefore, based on the position of this bright and dark boundary line, the refraction angle θ ₀
is determined, and the refractive index n ₁ of the liquid 2 is calculated using the formula sin(π/2)/sinθ ₀ =n ₂ /n ₁ .

However, in such a curved prism type liquid refractometer, the light indicated by the symbol r, for example, travels through the liquid 2 and reaches the curved prism surface 3a, and after being refracted by the prism surface 3a based on Snell's law. , reaches the bottom surface 3b of the curved prism 3, and is reflected from this bottom surface 3b to the photodiode 4.
It will be incident on . Therefore, the light emitted from the LED 1 is refracted by the curved prism surface 3a of the curved prism 3 and then directly enters the photodiode 4.
The bright and dark zones formed on the light-receiving surface 4a, that is, the bright and dark boundaries between the bright and dark areas, are
The light emitted from the LED 1, refracted by the prism surface 3a of the curved prism 3, reflected by the bottom surface 3b of the curved prism 3, and incident on the photodiode 4 is blurred by the light (for example, the above-mentioned light r). Furthermore, since the bottom surface 3b of the curved prism is in contact with the liquid 2, the amount of reflected light at the bottom surface 3b changes depending on the refractive index _n1 of the liquid 2.
Since disturbance light such as sunlight and illumination lights enters from the bottom surface 3b of the curved prism, the bright and dark boundary line is blurred by these disturbance lights, so that its position cannot be easily and reliably detected. The drawback is that it disappears.

Furthermore, in the curved prism type liquid refractometer having the above configuration, when positioning the photodiode 4 with respect to the curved prism 3, the mounting position affects the measurement accuracy of the curved prism type liquid refractometer. Although positioning is required, adjustment of the mounting position of the photodiode 4 is difficult to automate and requires a great deal of effort and time. Therefore, there was a problem in terms of productivity of this type of refractometer.

Furthermore, when fixing the curved prism 3 to a case (not shown), it is fixed with adhesive, but since the adhesive surface cannot be large, the adhesive strength is not very high, and therefore there is a problem in terms of reliability. It was hot.

[Purpose of invention]

In view of the above points, the present invention enables accurate measurement of the refractive index of a liquid by preventing undesirable reflection of light at the bottom surface of a curved prism, and eliminates the need to adjust the mounting position of a photodiode. Another object of the present invention is to provide a curved prism for a liquid refractometer, which can be securely fixed to a case.

[Means and actions for solving problems]

According to the present invention, the curved prism has a bottom surface provided with a recess for receiving a light absorption plate for preventing light reflection on the bottom surface, and a light receiving element of the curved prism. For a liquid refractometer, the end face on which the light receiving element is arranged is provided with a guide for guiding the light receiving element to its mounting position and a stopper for stopping and maintaining the light receiving element guided along the guide at the mounting position. Achieved by a curved prism.

According to this invention, when a liquid refractometer is configured by receiving a light absorption plate in a recess provided in the bottom surface of a curved prism and arranging the light absorption plate in contact with the bottom surface, the curved prism Reflection of light at the bottom surface of the light-receiving element is prevented, thereby preventing indirect light reflected from the bottom surface from entering the light-receiving surface of the light-receiving element, other than direct light that forms a bright-dark boundary line on the light-receiving surface of the light-receiving element. be done. In this way, the light and dark zones formed on the light-receiving surface of the light-receiving element by the light directly incident on the light-receiving element after being refracted by the curved prism surface of the curved prism, that is, the bright-dark boundary line between the bright and dark areas, are The light that is refracted on the prism surface of the curved prism, reflected on the bottom surface, and incident on the light receiving element is not blurred, and the position of the bright/dark boundary line can be easily and reliably detected.

In addition, since the light receiving element is guided along the guide to the mounting end surface of the curved prism and stopped at the mounting position by the stopper, it is extremely easy to accurately position the light receiving element against the curved prism without making adjustments for positioning. can be positioned.

Furthermore, if an adhesive flange for fixing the curve prism to the case is provided adjacent to the end surface where the light receiving element of the curve prism is arranged, the curve prism can be securely attached to the case through the adhesive flange. Since it is adhered to the case, the adhesive strength is increased because the adhesive surface is large.

〔Example〕

Hereinafter, the present invention will be described in detail based on an embodiment shown in the drawings.

1 to 3 are diagrams showing an embodiment of a curved prism according to the present invention. curve prism 1
0 has a curved prism surface 10a and a bottom surface 10.
b and the end surface 10c to which the light receiving element is to be attached.
Basically, it has the same structure as a conventional curved prism.

In the curved prism 10 according to the present invention,
Further, a recessed portion 12 is formed on the bottom surface 10b to receive a light absorption plate 11 (shown by phantom lines in FIG. 2) for preventing reflection of light on the bottom surface 10b.

Moreover, on the end surface 10c of the curved prism 10,
Move the light receiving element (not shown) to its mounting position, and
Guide 1 guiding from above in Figures and Figure 2
3 and 13' are provided along both side edges, and stoppers 14 and 14' for stopping the light receiving element guided by the guides 13 and 13' at the mounting position are provided below the end surface 10c. provided at both ends.

Furthermore, the curved prism 10 has an end surface 10
Adhesive flange 15 protrudes to surround the curved prism body on the opposite surface adjacent to c.
is formed.

The curved prism 10 formed in this way is
As shown in Figure 4, as a light emitting element.
LED1, photodiode 4 as a light receiving element
The liquid refractometer 20 is constructed by being attached to a predetermined position in the case 16, and the optical positional relationship between these is the same as that of the conventional curved prism type liquid refractometer shown in FIG. In this liquid refractometer 20, the curved prism 10 receives the light absorption plate 11 in the recessed part 12 provided on the bottom surface 10b, and thus the curved prism 10
A light absorption plate 11 is disposed in contact with the bottom surface 10b of the light absorbing plate 11. Furthermore, by using the guides 13, 13' and stoppers 14, 14' provided on the end surface 10c of the curved prism 10, the photodiode 4 can be easily and accurately positioned at a predetermined mounting position without any adjustment. Ru. Further, when the curved prism 10 is fixed in the case 16, the curved prism 10 is fixed by applying adhesive to the adhesive flange 15 formed on the opposite surface adjacent to the end surface 10c.
is securely fixed to the case 16.

If the liquid refractometer 20 is configured using the curved prism 10 according to the embodiment of the present invention, the photodiode 4 can be easily and accurately configured without any special position adjustment with respect to the curved prism 10. When fixing the curved prism 10 to the case 16, an adhesive flange 1 formed near the end surface 10c of the curved prism 10 is used.
5, the curved prism 10 is adhesively fixed to the case 16.

Furthermore, in the liquid refractometer 20 configured in this way, the light emitted from the LED 1 passes through the liquid 2 and enters the curved prism surface 10a of the curved prism 10, as indicated by the symbol p, for example. It is refracted based on Snell's law, passes through the curved prism 10, reaches the light receiving surface 4a of the photodiode 4, and forms a bright/dark boundary line on the light receiving surface 4a as in the conventional case. However, the light r emitted from the LED 1, refracted by the curved prism surface 10a of the curved prism 10, and then incident on the bottom surface 10b is absorbed by the light absorption plate 11 disposed in contact with the bottom surface 10b. Therefore, the light is not reflected by the bottom surface 10b and therefore does not reach the light receiving surface 4a of the photodiode 4. Furthermore, since the light absorption plate 11 is received on the bottom surface 10b, no disturbance light enters from the bottom surface 10b.

[Effect of idea]

As described above, according to the present invention, the bottom surface of the curved prism is provided with a concave portion for receiving a light absorption plate for preventing light reflection on the bottom surface, and the curved prism in which the light receiving element is arranged is On the end face,
Since the curved prism for a liquid refractometer is configured to include a guide for guiding the light-receiving element to its proper mounting position and a stopper for stopping the light-receiving element guided along the guide at the mounting position, the curved prism By receiving the light absorption plate in the recess formed on the bottom surface of the curved prism, the light absorption plate can be easily and accurately disposed in contact with the bottom surface, and a liquid refractometer can be constructed using this curved prism. When this occurs, reflection of light on the bottom surface of the curved prism is prevented, and as a result, indirect light reflected from the bottom surface, other than direct light that forms a bright-dark boundary line on the light-receiving surface of the light-receiving element, is prevented from reaching the light-receiving surface of the light-receiving element. is prevented from entering. In this way, the bright and dark zones formed on the light-receiving surface by the light that is refracted by the curved prism surface of the curved prism and then directly incident on the light-receiving element, that is, the bright-dark boundary line between the bright and dark parts, are the curved prism. There is no possibility that the light will be blurred by the light that is refracted on the prism surface and then reflected on the bottom surface and incident on the light receiving element.
Therefore, the position of the bright/dark boundary line can be easily and reliably detected, and the refractive index of the liquid can be accurately measured.

In addition, the light-receiving element is guided along the guide to the mounting end surface of the curved prism, and is stopped at a preset appropriate mounting position by the stopper, so that the difficult manual adjustment of the mounting position of the light-receiving element is required. The light-receiving element can be positioned accurately relative to the curved prism in a very simple manner without needing to do so. Productivity in assembling the liquid refractometer is thus improved.

In addition, if an adhesive flange for fixing the curve prism to the case is provided adjacent to the end face where the light receiving element of the curve prism is arranged, the curve prism is attached to the case via this adhesive flange. Since the adhesive is reliably bonded, the adhesion surface becomes larger, which increases the adhesive strength, and thus improves the reliability of the liquid refractometer as a product.

As described above, by using the curved prism according to the present invention, an extremely excellent curved prism type liquid refractometer can be provided.

[Brief explanation of the drawing]

FIG. 1 is an end view showing an embodiment of the curved prism according to the present invention, FIG. 2 is a sectional view taken along the line -- in FIG. 1, FIG. 3 is a view taken in the direction of arrow A in FIG. 2, and FIG. 2 is a schematic cross-sectional view showing a liquid refractometer using the curved prism according to FIG. 1. FIG. FIG. 5 is a schematic side view of a conventional curved prism liquid refractometer. 1... LED, 2... Liquid, 4... Photodiode, 10... Curved prism, 10a... Prism surface, 10b... Bottom surface of curved prism, 1
0c... End face of curved prism, 11... Light absorption plate, 12... Concave portion, 13, 13'... Guide,
14, 14'... stopper, 15... adhesive flange, 16... case, 20... liquid refractometer.

Claims (1)

[Claims for Utility Model Registration] (1) A concave portion is provided on the bottom surface of the curved prism to receive a light absorbing plate for preventing light reflection on the bottom surface, and a recessed portion is provided on the bottom surface of the curved prism to receive a light absorbing plate for preventing light reflection on the bottom surface, and A liquid refractive index characterized in that the end face of the curved prism is provided with a guide for guiding the light receiving element to its mounting position and a stopper for stopping the light receiving element guided along the guide at the mounting position. Curved prism for measurement. (2) Claims for registration of a utility model, characterized in that an adhesive flange for fixing the curved prism to the case is provided adjacent to the end surface of the curved prism where the light receiving element is arranged. The curved prism for liquid refractometer according to item 1.