JP2999799B2 - Radiation thermometer - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION << Industrial application field >> The present invention detects infrared rays radiated from an object to be measured,
The present invention relates to a radiation thermometer for measuring the temperature of an object to be measured based on the amount of infrared rays, and particularly to a radiation thermometer having an aiming function for displaying a minute measurement point.

<< Conventional Technology >> A radiation thermometer detects infrared rays emitted from an object to be measured and does not come into contact with the object to be measured. Therefore, a radiation thermometer that measures the temperature of a small portion or the like has an aiming function that indicates the measurement position.

As a radiation thermometer capable of aiming at a portion to be measured, for example, a radiation thermometer using a Cassegrain optical system disclosed in Japanese Utility Model Laid-Open No. 55-175835 is known.

This radiation thermometer has a concave mirror as a primary mirror into which infrared rays radiated from a measurement point are incident, and a convex mirror as a sub-mirror smaller than the concave mirror as opposed to the concave mirror. A detector is located at the center of the mirror. An aiming light source having a smaller diameter than that of the convex mirror and an aiming lens for forming an image of the aiming light source on the measurement point are arranged on the rear surface side of the convex mirror.

This radiation thermometer clearly forms an image of an aiming light source at a measurement position of an object to be measured, that is, focuses and displays a measurement point. Then, infrared light radiated from the measured object located at the measurement point is incident on the concave mirror,
The infrared light reflected from the concave mirror is incident on the detector by the convex mirror.

<< Problems to be Solved by the Invention >> In the conventional radiation thermometer, since the aiming light source is imaged at the measuring point by the aiming lens, even if the portion to be measured is minute, the aiming light is focused on. , It is easy to eliminate the displacement of the aiming position in the radial direction of the aiming lens.

However, the aperture angle from the measurement point to the aiming lens is much smaller than the aperture angle from the measurement point to the concave mirror. Therefore, it is difficult to find out the focus shift of the aiming light in the optical axis direction of the aiming lens, and there is a problem that it is difficult to adjust the focus to severe. In addition, if the aiming light is out of focus in the optical axis direction of the aiming lens, the difference in the measurement diameter due to the displacement of the measuring point is much larger than the out-of-focus, so that the measurement can be performed on a minute measurement target. There is also a problem that it is difficult to accurately locate points.

The present invention has been made to solve the above-described problems, and it is an object of the present invention to provide a radiation thermometer having an aiming mechanism capable of accurately matching measurement points even to a minute measurement target. Aim.

<< Means for Solving the Problems >> The invention according to claim 1 of the present application is directed to a measuring concave mirror into which infrared rays radiated from a measuring point are incident, and the infrared ray reflected by the measuring concave mirror is focused on a central portion thereof. In a radiation thermometer comprising a convex concave mirror having a smaller diameter than the measuring concave mirror that forms an image on the light receiving surface of the detector disposed in the rear side of the convex mirror, an aiming light source for visible light with a smaller diameter than that is disposed, and The aiming concave mirror for imaging the aiming light emitted in the radial direction of the measuring concave mirror from the aiming light source at the measurement point is arranged on the back side of the convex mirror outside the optical path of the infrared light emitted from the measurement point. It is a feature.

Further, the invention according to claim 2 of the present application is a measurement concave mirror into which infrared light emitted from a measurement point is incident, and the infrared light reflected by the measurement concave mirror, a detector arranged at the center thereof. In a radiation thermometer comprising a convex mirror having a smaller diameter than the measuring concave mirror to be imaged on the light receiving surface, a collimating light source of visible light having a smaller diameter than the convex mirror is disposed on the back side of the convex mirror, and the light of the measuring concave mirror from the collimating light source An aiming convex mirror that reflects the aiming light emitted in the axial direction is arranged, and the aiming concave mirror that forms the reflected light reflected by the aiming convex mirror on the measurement point is located outside the optical path of the infrared light emitted from the measurement point. It is characterized by being arranged on the back side of a convex mirror.

An LED or the like is used as the aiming light source. Then, the aiming concave mirror arranges a ring-shaped mirror or a plurality of independent mirrors at predetermined positions.

<Operation> In the radiation thermometer of the present invention, infrared rays emitted from the object to be measured located at the measurement point are incident on the measurement concave mirror. The infrared light reflected by the concave measuring surface is made incident on a detector by a convex mirror, and the temperature of the measuring position of the object to be measured is measured. Then, when measuring the temperature of the minute measurement section of the object to be measured, the measurement section is irradiated with the aiming light, and by focusing, the measurement point coincides with the minute measurement section. is there.

The aiming concave mirror for imaging the aiming light of the aiming light source is disposed outside the optical path of the infrared light emitted from the measurement point, so that the measurement point is smaller than the aperture angle from the measurement point to the measurement concave mirror. Therefore, since the aperture angle of the aiming concave mirror becomes larger, it is easy to confirm the defocus of the aiming light in the optical axis direction of the aiming concave mirror, and it is possible to adjust the focus to severe.

<< Embodiment >> A first embodiment of the radiation thermometer of the present invention will be described with reference to FIGS.

1 and 2, reference numeral 1 denotes a case, in which a radial column 2 is provided. Reference numeral 3 denotes a concave measuring mirror as a primary mirror in the Cassegrain optical system, and a hole 4 is provided at the center thereof.
Is provided. Reference numeral 5 denotes a convex mirror as a sub-mirror attached to the column 2 opposite to the concave concave mirror 3, and has a smaller diameter than the concave concave mirror 3. Reference numeral 6 denotes a pipe-shaped holder attached to the hole 4 of the measurement concave mirror 3, and an infrared detector 7 is attached to the holder.

Reference numeral 8 denotes a back side of the convex mirror 5, which is an aiming light source composed of an LED mounted on the column 2 and positioned on the optical axis thereof, and configured to emit light in the radial direction of the measuring concave mirror 3.
Reference numeral 9 denotes a ring-shaped concave concave mirror, which is arranged on the back side of the convex mirror 5. The aiming convex mirror 9 has an inner diameter located outside the optical path of infrared light incident on the measurement concave mirror 3 from the set measurement point 10, and is arranged so that its optical axis coincides with the optical axis of the convex mirror 5. I have. The aiming concave mirror 9 has a light emitting portion of the aiming light source 8 as a first focus and a measurement point 10 as a second focus, and measures the aiming light incident on the aiming concave mirror 9 from the aiming light source 8 in the measurement. An image is formed on the point 10 so that the measurement point 10 is displayed.

Numeral 11 denotes a spring for supporting the aiming concave mirror 9 and a plate or other spring disposed on the back side thereof or a spring member capable of elastic deformation such as rubber or plastic, and 12 denotes a case 1 facing the front side of the aiming concave mirror 9. There are three optical axis adjusting screws which are screwed in at a regular interval. This optical axis adjustment screw 12
Is arbitrary. Reference numeral 13 denotes a window attached to the end of the case 1, which is made of BaF ₂ , a polyethylene film or the like that transmits visible light and infrared light. 14 is the column 2
The lead wire 15 of the aiming light source 8 is arranged in this groove.

16 is an optical path of aiming light emitted from the aiming light source 8, 17 is an optical path of infrared light emitted from the object to be measured located at the measurement point 10, and 18 is an object to be measured.

In this radiation thermometer, as described above, the aiming light of the aiming light source 8 is imaged on the measuring point 10 by the aiming concave mirror 9. Therefore, when measuring the temperature of the object to be measured, by irradiating the imaged aiming light to the surface of the object to be measured 18 and focusing on the measurement position, the measurement point 10 is positioned at the measurement position of the object to be measured. It is possible to position it accurately.

Since the aiming concave mirror 9 is arranged outside the optical path 17 of the infrared ray emitted from the measuring point 10, the aiming concave mirror 9 can be moved from the measuring point 10 to the measuring concave mirror 3 in comparison with the opening angle from the measuring point 10 to the measuring concave mirror 3. The opening angle to is larger.

Therefore, it is easy to confirm the focus shift (blurring of the image) of the aiming light in the optical axis direction of the aiming concave mirror 9, and it is possible to sharply adjust the focus of the aiming light. Even if it occurs, the difference in the measured diameter due to the displacement of the measuring point is smaller than the defocus. Therefore, even when the measured object is small or the measured portion is minute, if the aiming light is focused on this, the measuring point 10 can be accurately positioned on the minute measured object or the measured portion. This makes it possible to accurately measure the temperature of a minute object to be measured or a portion to be measured.

The optical axis of the aiming concave mirror surface 9 is adjusted by the optical axis adjusting screw 12.
The aiming concave mirror 9 is partially moved in the optical axis direction by the expansion and contraction of the spring portion 11 due to the advance and retreat of the lens.

FIG. 3 shows a second embodiment, which relates to the aiming concave mirror.

In this embodiment, the aiming light emitted from the aiming light source 8 is formed into an image at the measurement point 10 by the independent aiming concave mirrors 9a and 9b. And the aiming concave mirrors 9a, 9b
Also, it is arranged outside the optical path (not shown) of the infrared light emitted from the object to be measured located at the measurement point 10. Reference numeral 16 denotes an optical path of aiming light emitted from the aiming light source 8.

Since the amount of reflection of the aiming light by the aiming concave mirrors 9a and 9b is smaller than that of the first embodiment, the aiming light source 8 having a light amount corresponding to the amount is used.

4 and 5 show a third embodiment, which also relates to an aiming concave mirror.

In this embodiment, the aiming concave mirrors 9a and 9b are integrally formed of plastic through ring-shaped supports 20a and 21b which are elastically deformable. Reference numeral 22 denotes a bracket (see FIG. 5) protruding from the back surface of the support 20. The back surface of the aiming concave mirrors 9a and 9b is pushed and displaced by an optical axis adjusting screw 23 screwed into the bracket to displace the optical axis. It is configured to be able to make adjustments.

As described above, since the support 20 and the aiming concave mirrors 9a and 9b are integrally formed, the cost can be easily reduced.

 FIG. 6 shows a fourth embodiment.

In FIG. 6, reference numeral 25 denotes an aiming convex mirror disposed between the aiming light source 8 and the window 13. The aiming light of the aiming light source 8 is incident on the aiming concave mirror 9 via the aiming convex mirror 25, and the aiming light is measured. It is configured to form an image at point 10. Accordingly, in this embodiment, the aiming light source 8 that emits light in the optical axis direction of the measurement concave mirror 3 can be used.

The other configuration is the same as that of the first embodiment, so that the same reference numerals are given.

<< Effect of the Invention >> As described above, the radiation thermometer of the present invention reflects infrared light radiated from an object to be measured by the concave and convex measurement mirrors as Cassegrain-type optical systems and enters the light-receiving surface of the detector. In the radiation thermometer, an aiming light source is arranged on the back side of the convex mirror, and an aiming concave mirror for imaging the aiming light emitted from the aiming light source in the radial direction of the measuring concave mirror at the measuring point is provided at the measuring point. It is arranged on the back side of the convex mirror outside the optical path of infrared rays emitted from the measurement object. In the present invention, on the back side of the convex mirror, an aiming light source of visible light with a smaller diameter than that is arranged, and an aiming convex mirror that reflects aiming light emitted from the aiming light source in the optical axis direction of the measurement concave mirror is arranged. An aiming concave mirror for forming an image of the reflected light reflected by the aiming convex mirror on the measurement point is disposed on the back surface of the convex mirror outside the optical path of infrared rays emitted from the measurement point.

Therefore, since the aperture angle from the measurement point to the aiming concave mirror is larger than the aperture angle from the measurement point to the measurement concave mirror, it is easy to confirm the defocus of the aiming light in the optical axis direction of the aiming concave mirror. , It is possible to focus the aiming light in a severe manner. In addition, even if the above-described focus shift occurs in the aiming light, the difference in the measured diameter due to the displacement of the measurement point is smaller than the shift. For this reason, by focusing the aiming light, it is possible to accurately position the measurement point even on a minute measurement object or measurement position and accurately measure the temperature of the measurement object or measurement position. .

[Brief description of the drawings]

1 and 2 show a first embodiment of the present invention. FIG. 1 is a sectional front view, FIG. 2 is a sectional side view, FIG. 3 is a perspective view of the second embodiment, and FIGS. 4 shows a third embodiment, FIG. 4 is a perspective view,
FIG. 5 is a sectional view of a main part, and FIG. 6 is a sectional front view of the fourth embodiment. 3: measuring concave mirror, 5: convex mirror, 7: detector, 8: aiming light source, 9: aiming concave mirror, 10: measuring point, 25: aiming concave mirror.

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-55-31976 (JP, A) JP-A-63-255630 (JP, A) Actually open Showa 55-175835 (JP, U) Actually open 95635 (JP, U) (58) Field surveyed (Int. Cl. ⁷ , DB name) G01J 5/00-5/62

Claims (2)

(57) [Claims] 1. A measuring concave mirror into which infrared light emitted from a measuring point is incident, and a measuring concave mirror for forming an image of the infrared light reflected by the measuring concave mirror on a light receiving surface of a detector arranged at the center thereof. In a radiation thermometer composed of a convex mirror having a smaller diameter, an aiming light source of visible light having a smaller diameter than the backside of the convex mirror is arranged, and the aiming light emitted from the aiming light source in the radial direction of the measurement concave mirror is used. A radiation thermometer, wherein an aiming concave mirror for forming an image at the measurement point is disposed outside the optical path of infrared rays emitted from the measurement point and on the back side of the convex mirror. 2. A measuring concave mirror on which an infrared ray emitted from a measuring point is incident, and a measuring concave mirror for forming an image of the infrared ray reflected by the measuring concave mirror on a light receiving surface of a detector arranged at the center thereof. In a radiation thermometer comprising a convex mirror having a smaller diameter than the convex mirror, an aiming light source of visible light having a smaller diameter is disposed on the back side of the convex mirror, and the aiming light emitted from the aiming light source in the optical axis direction of the measuring concave mirror. Aiming convex mirror for reflecting the light is arranged, the aiming concave mirror for imaging the reflected light reflected by the aiming convex mirror at the measurement point is disposed on the back side of the convex mirror outside the optical path of the infrared light emitted from the measurement point. A radiation thermometer, characterized in that: