JP2002081994A - Infrared condensing lens and portable radiation thermometer using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To visually confirm a measuring region accurately by forming a light spot to the center of the measuring region of an object to be measured. SOLUTION: An infrared condensing lens 1 receives infrared rays from the opposed object W to be measured on its entire surface thereof. The received infrared rays transmit through an infrared transmission mirror 14 to be condensed to the infrared detection part 13 provided at the position separated from the back surface 3 of the condensing lens by a focal distance. The condensed infrared rays are converted to an electric signal in the infrared detection part 13 to be outputted to a signal processing part 15. In the signal processing part 15, the temperature of the measuring region A is calculated on the basis of the electric signal. Laser beam is reflected by the infrared transmission mirror 14 and the light path L thereof is altered by 90 deg. to conincide with the optical axis G of the infrared condensing lens 1. The laser beam transmits through the laser pervious window of the infrared condensing lens 1 to be positioned at the center of the measuring region A of the object W to be measured to form a light spot S.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an infrared condensing lens for condensing received infrared rays to the back side, and a portable type for measuring temperature from infrared rays radiated from a measuring object using the infrared condensing lens. BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radiation thermometer, and more particularly to a portable radiation thermometer for clarifying a measurement area of a measurement object.

[0002]

2. Description of the Related Art FIG. 5 shows a conventional portable radiation thermometer. This portable radiation thermometer 50 includes a Fresnel lens 51.
The infrared rays condensed in step (1) are received by the thermopile 52, and the temperature of the measurement object W is detected. In addition, Fresnel lens 5
The laser light source 53 irradiates a laser beam from the laser light source 53 to the measurement object W from outside the optical axis G of the first optical axis G to form a light spot S so that the measurement position can be visually recognized.

However, the optical path L of the laser light emitted from the laser light source 53 does not coincide with the optical axis G of the Fresnel lens, and the light spot S shifts from the center of the measurement area A of the measuring object W. As a result, it is formed outside the measurement region A. On the other hand, if a laser light source 53 is provided on the optical axis G in order to form a light spot S at the center of the measurement area A of the measurement object W, infrared light is shielded by the laser light source 53 in the portable radiation thermometer 50, All the infrared rays from the measurement area A cannot be efficiently collected, and an error occurs in the temperature measurement.

[0004]

SUMMARY OF THE INVENTION Accordingly, the present invention relates to a measurement method for emitting infrared light by receiving infrared light from an object to be measured over the entire surface of an infrared condensing lens and emitting laser light from the center of the surface. An object of the present invention is to form a light spot at the center of a measurement region of an object to accurately visually recognize the measurement region.

Another object of the present invention is to form a light spot more clearly by improving the transmittance of laser light when the laser light passes through an infrared condensing lens. In particular, an object of the present invention is to form a light spot at an accurate position by suppressing the attenuation and scattering of a laser beam by vertically entering the laser beam into a spherical infrared condenser lens.

It is another object of the present invention to efficiently condense the infrared light from the object to be measured, which is received on the entire surface of the infrared condensing lens, and to improve the accuracy of temperature measurement.

Another object is to form a light spot at the center of a measurement area of a measurement object that emits infrared light without providing an obstacle that shields infrared light between the infrared condenser lens and the infrared detection unit. To direct the laser light.

[0008]

The infrared condensing lens according to claim 1 is an infrared condensing lens for receiving infrared rays on the entire surface 2 and condensing the infrared rays on the rear surface 3 side. the laser light emitted to the surface 2 side is formed integrally with the peripheral edge 4 to the optical axis center 2a that passes, characterized by having a laser beam transmitting window 5 formed thinner than the thickness t ₂ of the peripheral edge .

According to a second aspect of the present invention, in the infrared condensing lens according to the first aspect, the infrared condensing lens is formed in a curved shape with the optical axis center 2a on the surface 2 as a top. .

According to a third aspect of the present invention, there is provided an infrared condensing lens according to the second aspect, wherein the laser light incident surface 5a and / or the laser light emitting surface 5b of the laser light transmitting window 5 is provided with the optical axis. It is characterized by being formed orthogonal to G.

A portable radiation thermometer according to a fourth aspect is a portable radiation thermometer for measuring the temperature of the object to be measured W from infrared rays radiated from the object to be measured W. And a laser light source 12 provided outside the optical axis G for irradiating the laser beam, and provided on the optical axis G of the infrared light focusing lens 1 and focused. Infrared detector 13 for receiving the infrared light
Provided between the infrared condensing lens 1 and the infrared detecting unit 13 to reflect laser light from the laser light source 12, transmit the laser light through the laser light transmitting window 5, An infrared transmission mirror 14 that irradiates the center of the measurement area A of the measurement object W facing the condenser lens 1 and transmits only the infrared light is provided.

The infrared condensing lens 1 receives infrared light from the opposing measuring object W over the entire surface 2. The received infrared light passes through the infrared transmission mirror 14 and is collected on the infrared detection unit 13 located at a position away from the rear surface 3 by a focal distance. The infrared detecting unit 13 converts the collected infrared light into an electric signal and outputs the electric signal to the signal processing unit 15. The signal processing unit 15 calculates the temperature of the measurement area A based on the electric signal. Further, the laser light is reflected by the infrared transmitting mirror 14 to change the optical path L, and coincides with the optical axis G of the infrared condenser lens 1. Then, the laser light passes through the laser transmission window 5 of the infrared condensing lens 1 and is located at the center of the measurement area A of the measurement target W, and a light spot S is formed.

[0013]

FIG. 1 is a schematic perspective view showing an infrared condenser lens 1 according to a first embodiment of the present invention, and FIG.
It is the same side sectional view. The infrared condensing lens 1 is a lens that receives infrared rays on the entire surface 2 and condenses the infrared rays on the rear surface 3 side. The infrared condensing lens 1 is made of a high-density polyethylene made of a single lens having a curved back surface divided into a large number of concentric rings 4a, and discontinuous boundaries of the respective rings 4a to reduce the overall thickness. It is a Fresnel lens having a curved shape with an optical axis center 2a passing through the optical axis G on the front surface 2 as a top.

As shown in FIG. 2, a pair of laser transmission windows 5 are formed at the center 2a of the optical axis of the infrared condensing lens 1 as the peripheral edge 4 composed of each orbicular zone 4a. The laser transmission window 5 is formed to be thinner than the peripheral edge 4, that is, the thickness t ₂ from the imaginary coupling surface 4 b where the coupling portion of each ring zone 4 a is continuous to the surface 2 of the infrared condensing lens 1. I have. The laser transmission window 5 has a diameter larger than the thickness of the transmitted laser light. In this embodiment, the thickness t ₁ of the laser transmitting window 5, the thickness of the peripheral edge 4 t ₂ (e.g. 0.4m
m) (for example, 0.2 mm), and the diameter of the laser transmission window 5 is 4 mm. The laser transmission window 5 has a laser light incident surface on the back side of the infrared condenser lens 1 and a laser light emission surface on the front side of the infrared condenser lens 1.

In this embodiment, an example has been described in which the infrared converging lens 1 is curved in order to reduce aberration. However, the present invention is not limited to the curved shape and may be a plate shape. As shown in FIG. 3, the laser light incident surface 5a and / or the laser light emitting surface 5b of the laser light transmitting window 5 is
It may be formed orthogonal to the optical axis G. Thereby, attenuation and diffusion of the laser light can be suppressed.

Next, a portable radiation thermometer according to a second embodiment of the present invention will be described with reference to FIG. FIG.
As shown in (a), the portable radiation thermometer 10 includes a main body 1.
1, the infrared condensing lens 1 described in the first embodiment
, A laser light source 12, an infrared detection unit 13, an infrared transmission mirror 14, a signal processing unit 15, an input unit 16, and a display unit 17 are provided.

The infrared condenser lens 1 is attached to an opening 11a of the main body 11. A thermal type (for example, thermopile, bolometer, pyroelectric element) infrared detecting unit 13 is provided at the bottom of the opening groove 11b at a position on the back surface 3 side that is separated from the optical axis center 2a of the infrared condensing lens 1 by a focal length. Have been.
The electric signal converted by the infrared detection unit 13 is processed by a signal processing unit 15 at the subsequent stage, and the measured temperature of the measurement target W is displayed on a display unit 17 such as a liquid crystal screen.

The laser light source 12 is fitted outside the optical axis G of the infrared condensing lens 1, for example, in a fitting hole 11d formed in the inner peripheral wall 11c of the opening groove bottom 11b. The emission port 12a of the laser light source 12 is directed upward such that the optical path L of the laser light and the optical axis G of the infrared condensing lens 1 are orthogonal to each other.

An infrared transmitting mirror 14 is provided at a position where the optical path L of the laser beam and the optical axis G of the infrared condensing lens 1 are orthogonal to each other. The infrared transmitting mirror 14 is a mirror made of an infrared transmitting material whose surface is coated with, for example, ZnS, Ge, or the like, for example, Si. Both ends of the infrared transmitting mirror 14 are supported by one support piece 11e protruding from the inner peripheral wall 11c and the other support piece 11f protruding from the opening groove bottom 11b. The infrared transmission mirror 14 is provided at an inclination of, for example, 45 degrees with respect to the optical axis G of the infrared condensing lens 1, and is further provided at an inclination of 45 degrees with respect to the optical path L of the laser light. .

The input section 16 is composed of switches, buttons, and the like. The signal processing unit 15 calculates the temperature of the measurement area A from the electric signal detected and converted by the infrared detection unit 13. In addition, the signal processing unit 15 receives the laser light source 12, the infrared detection unit 13,
The power of the display unit 17 is turned on / off. Display 1
Reference numeral 7 includes, for example, a liquid crystal display or the like, and displays the measured temperature output from the signal processing unit 15, and the like.

Next, the operation of the present embodiment will be described. First, the power is turned on. Then, the infrared condensing lens 1 is directed toward the measurement target W, and the infrared ray from the surface 2 of the infrared condensing lens 1 projected on the measurement target W, that is, the measurement area A is reflected by the infrared condensing lens 1. Light is received on the entire surface 2. The infrared light received is the infrared transmitting mirror 1
4 and is condensed on the infrared detector 13. The infrared detecting section 13 converts the collected infrared rays into thermoelectric signals and outputs an electric signal to the signal processing section 15. The signal processing unit 15 calculates the temperature of the measurement area A based on the electric signal.

When the input section 16 is operated to turn on the laser light source 12, a laser beam is emitted from the emission port 12a. The laser light is reflected by the infrared transmitting mirror 14 to change the optical path L by 90 degrees, and coincides with the optical axis G of the infrared condenser lens 1. Then, the laser light is transmitted through the laser transmission window 5 of the infrared condensing lens 1 and is applied to the center of the measurement area A of the measurement target W as shown in FIG. Is done.

In the above-described embodiment, a thermal type (for example, a thermopile, a bolometer, a pyroelectric element) is used as the infrared detector 13, but a quantum type (for example, InG
a, PbS, Si).

As described above, in the present embodiment, the infrared light of the measuring object W is received by the entire surface 2 of the infrared condensing lens 1. There is no obstacle between the infrared condenser lens 1 and the infrared detector 13 that blocks infrared rays.
Therefore, infrared rays from the measurement area A can be efficiently collected, and an accurate temperature can be measured.

Further, the laser light source 12 is provided outside the optical axis G,
Since the infrared transmitting mirror 14 that matches the optical path L of the laser beam with the optical axis G is provided on the optical axis G, an obstacle that shields infrared light is provided between the infrared condensing lens 1 and the infrared detecting unit 13. Instead, the light spot S can be formed at the center of the measurement area A.

Further, since the laser transmission window 5 is formed in the infrared condenser lens 1, the surface 2 of the infrared condenser lens 1
Infrared rays can be received as a whole, and attenuation and diffusion of laser light can be suppressed.

[0027]

According to the present invention, the entire surface of the infrared condensing lens receives infrared light from the object to be measured, and emits a laser beam from the center of the surface. Is formed, and the measurement region can be visually recognized accurately.

Further, by improving the transmittance of the laser beam when the laser beam passes through the infrared condenser lens, a light spot can be formed more clearly. In particular, by causing the laser light to be perpendicularly incident on the spherical infrared condenser lens, attenuation and scattering of the laser light can be suppressed, and the light spot can be formed at an accurate position.

Further, infrared rays from the object to be measured, which are received on the entire surface of the infrared ray condensing lens, can be efficiently collected, and the accuracy of temperature measurement can be improved.

Further, without providing an obstacle for shielding infrared rays between the infrared condenser lens and the infrared detector, a light spot is formed at the center of the measurement area of the measurement object which emits infrared rays. Laser light can be directed.

[Brief description of the drawings]

FIG. 1 is a schematic perspective view showing an infrared condenser lens of the present invention.

FIG. 2 is a side sectional view showing an infrared condenser lens of the present invention.

FIG. 3 is a side sectional view showing a modification of the infrared condenser lens of the present invention.

FIG. 4 is a schematic side sectional view showing a portable radiation thermometer of the present invention.

FIG. 5 is a schematic side sectional view showing a conventional portable radiation thermometer.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Infrared condensing lens 2 ... Front surface 3 ... Back surface 2a ... Optical axis center 4 ... Peripheral edge 5 ... Laser light transmission window 5a ... Laser light incident surface 5b ... Laser light emission surface 12 ... Laser light source 13 ... Infrared detector 14 ... Infrared transmitting mirror G ... optical axis W ... thickness of the measurement object a ... measured region t ₂ ... peripheral

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Tsutomu Shoji 1515 Ranagawa, Oji, Tendo City, Yamagata Prefecture Inside Chino, Yamagata Co., Ltd. (Reference) 2G066 BA01 BA08 BA09 BA22 BA60 BC30

Claims (4)

[Claims] 1. An infrared condensing lens for receiving infrared light over the entire surface and condensing the infrared light on a rear surface side, comprising a peripheral portion near a center of an optical axis through which laser light emitted from the rear surface side to the surface side is transmitted. An infrared condensing lens having a laser light transmitting window formed integrally and thinner than the thickness of the peripheral edge. 2. The infrared condensing lens according to claim 1, wherein the infrared condensing lens is formed in a curved shape with the optical axis center on the surface as a top. 3. The infrared condensing lens according to claim 2, wherein a laser light incident surface and / or a laser light emitting surface of the laser light transmitting window is formed orthogonal to the optical axis. . 4. A portable radiation thermometer for measuring the temperature of the measurement object from infrared light radiated from the measurement object, wherein the infrared condenser lens according to claim 1, and the optical axis. A laser light source that is provided outside and irradiates the laser light; an infrared detection unit that is provided on the optical axis of the infrared condensing lens and receives the condensed infrared light; A measurement area of the object to be measured provided between the infrared light detection unit, reflects the laser light from the laser light source, transmits the laser light through the laser light transmission window, and faces the infrared condenser lens. A portable radiation thermometer, comprising: an infrared transmitting mirror that irradiates the center of the object and transmits only the infrared light.