JPH0694523A - Infrared image pickup apparatus - Google Patents

Abstract

PURPOSE:To obtain an image pickup apparatus where an image pickup element is not subjected to unnecessary infrared rays even if a condenser lens is replaced by providing a variable opening means (aperture) for limiting an incident angle of infrared rays to the image pickup element. CONSTITUTION:An infrared image pickup element (CCD for example) 1 is placed on a cold head 3 cooled by a cooling means. A condenser lens 8 and a column 9 are provided in front of an incident window 4. A variable aperture 2a is fixed under an aperture attaching part formed at the upper end of a cold shield 2. A size of an opening of the aperture attaching part is set to the smallest size with which a field of view is not eclipsed when a lens 8 having the largest infrared ray incident angle theta is attached. When the lens 8 is replaced with a one having a smaller incident angle theta, heat radiation is made incident on the image pickup element 1 from the lower end face on the column 9, the aperture 2a is stopped down to limit the infrared rays to the image pickup element 1 only to transmitted light of the lens 8. Thus, only the infrared rays from a subject are made incident, preventing external infrared rays from being recorded.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an infrared imaging device,
In particular, the present invention relates to a high-precision infrared imaging device that is not affected by the temperature of the lens barrel of the device.

[0002]

2. Description of the Related Art A main part of a conventional infrared image pickup device is schematically shown in FIG. As shown in the figure, an infrared image pickup device (for example, CCD device) 1 is arranged on a cold head 3 cooled by a cooling means such as liquid nitrogen or a Stirling cooler, and an incident angle of infrared rays 10 entering the image pickup device 1 is defined. A cylindrical cold shield 2 having an opening 200 for opening is provided from the cold head 3 so as to surround the image sensor 1, and a dual structure of an inner cylinder 6 and an outer cylinder 5 for accommodating the image sensor 1 is provided in front thereof. The infrared incident window 4 is provided so as to be connected to the outer cylinder 5 of the vacuum container 7.

Further, a condenser lens 8 for condensing infrared rays to be detected by the image pickup device 1 in front of the entrance window 4 and a lens barrel 9 for holding the condenser lens 8 at the peripheral portion of the condenser lens 8 are provided. It is provided. The lens barrel 9 has a male mount M1 and is attached to the device body 100 by engaging the male mount M1 with a female mount M2 fixed to the device body 100.

The cold shield 2 described above mainly limits the incident infrared light by defining the incident angle of the infrared light which is incident on the image pickup device 1 from the condenser lens 8. The light is limited, but in addition to this, the image pickup device 1 does not detect infrared rays radiated from an object other than the lens surface of the condenser lens 8, such as the lens barrel 9 of the condenser lens 8. There is.

When the image pickup device 1 detects a part of the device other than the lens surface of the condenser lens 8, for example, infrared rays emitted from the lens barrel 9, the temperature of the lens barrel 9 changes due to the fluctuation of the outside air temperature. When the infrared ray to be detected is incident on the image pickup device 1, the infrared ray to be detected is affected by the infrared ray emitted from the lens barrel 9 and fluctuates, so that the temperature change of the object to be imaged. Even though there is no signal, the output signal from the image sensor 1 changes,
There is an inconvenience that the temperature fluctuation of the object cannot be detected with high accuracy.

Therefore, in order to solve this problem, the image pickup device 1 is configured so that the dimensions of the cold shield 2 and the condenser lens 8 and their respective arrangements are matched with each other.
Only the light incident from the lens surface is detected by looking only at the surface.

[0007]

However, in the conventional device, since the shape of the opening of the cold shield 2 is fixed, the condensing lens 8 used in, for example, the image pickup device is different in type (focal length and brightness). If the incident angle of the incident infrared ray 10 is changed for each lens when used by exchanging different ones, the condenser lens 8 and the cold shield 2 cannot be matched, and the image sensor 1 is the condenser lens. The lens barrel 9 and the like other than the lens surface of No. 8 were foreseen and received infrared rays (radiation) from the lens barrel 9.

An object of the present invention is to obtain an infrared imaging device in which the infrared imaging device does not receive unnecessary infrared rays even if the condenser lens is replaced with another type.

[0009]

In order to solve the above problems, the present invention provides a variable aperture means capable of changing the size of the aperture for limiting the angle of incidence of infrared rays on the infrared imaging device. Therefore, even when the condensing lens is replaced with a different type, the aperture is easily changed to limit the incident angle of infrared rays to the infrared imaging element to only the light transmitted through the condensing lens.

[0010]

In the present invention, since the size of the aperture that determines the incident angle of infrared rays incident on the infrared image pickup element can be changed, even if the condenser lens of the apparatus is changed to a different type, the infrared rays can be changed. The image sensor can be configured so that only the light transmitted through the condenser lens is incident.

[0011]

Embodiments of the present invention are shown in FIGS. 1, 2, 3 and 4.
Will be described. 1 and 3 are schematic explanatory views of the optical path of the embodiment, and FIGS. 2 and 4 are plan views mainly showing the variable aperture. 2 and 4, the right side of the break lines l ₁ and l ₂ is seen through the cold shield 2, and the left side thereof shows a state in which the upper end of the cold shield 2 is removed. The same members as those of the conventional technique shown in FIG. 5 are designated by the same reference numerals and the description thereof will be omitted. As shown in FIG. 1, FIG.
The difference from is that a variable diaphragm 2a that can change the size of the aperture of the cold shield 2 is provided.

The variable diaphragm 2a is fixed to the lower side of the diaphragm mounting portion formed at the upper end of the cold shield 2, and the size of the aperture when the diaphragm opening is most opened (the state shown in the drawing) is the opening of the diaphragm mounting portion. Is configured to be approximately equal in size. The size of the aperture of the diaphragm mounting portion is set to the minimum size that does not cause the vignetting when the condensing lens 8 is mounted as the condensing lens having the largest incident angle θ of the infrared rays incident on the image sensor 1.

As shown in FIG. 2, the variable aperture 2a has a plurality of aperture blades 2e attached to an annular cam plate 2b by pins (not shown), and a lever 2c is fixed to the cam plate 2b. , A pin 2d is attached to the lever 2c. A cam groove 2f is formed in the cam plate 2b, and a pin 2g of a fixed portion is fitted therein to limit rotation. Since the annular cam plate 2b is rotatably fitted to the main body of the variable diaphragm 2a with the central axis as the center of rotation, the cam plate 2b is moved by the movement of the lever 2c so that the central axis of the cam plate 2b (substantially coincides with the optical axis of the condenser lens 8). It is assembled so that the center of rotation is the center of rotation, and the aperture blades can be opened and closed. This diaphragm blade structure has been well known as a diaphragm of a photographic lens for a long time.

A part of the outer cylinder 5 of the vacuum container 7 whose height is substantially the same as the position where the lever 2c is provided has a first wall surface 5a and a moving direction of the lever 2c which substantially match the moving direction of the lever 2c. A notch having a substantially L-shaped cross section is formed having a second wall surface 5b that is substantially orthogonal to the second wall surface 5b. A flexible thin metal bellows 13 is fixed to one end surface of the second wall surface 5b. On the other end face of the bellows 13, a cap 12 having a female screw protruding inside the bellows 13 is formed.
Is stuck.

A feed screw rod 14 having a male screw threaded to the female screw of the cap 12 passes through the center of the bellows 13,
It penetrates the second wall surface 5b and projects to the outside of the outer cylinder 5, and has a knob 15 at the end. To maintain the vacuum in the vacuum container 7,
Welding between the second wall surface 5b and the feed screw rod 14, packing and bellows 13 and the second wall surface 5b, and bellows 13
And the cap 12 are welded together. Cap 1
The heat insulating material 11 is fixed to the surface opposite to the surface on which the bellows 13 of FIG.
A recess 11a that engages with the pin 2d attached to c is formed.

Next, the restriction of the incident angle of the infrared rays 10 on the image pickup device 1 by the variable diaphragm 2a will be described. Image sensor 1
In the upper opening of the cold shield 2 that covers the infrared rays 10 emitted from the subject and condensed by the condenser lens 8.
Is incident. However, since infrared rays are radiated by heat near room temperature, there are other infrared rays that pass through the infrared ray entrance window 4 and reach the upper opening of the cold shield 2, and the infrared rays 10 are the largest and the infrared rays 10 from the vicinity of the condenser lens 8. It is the lens barrel 9 that emits light.

Therefore, instead of the condenser lens 8 of FIG.
Consider a case where a condenser lens 8 ′ having an incident angle θ ′ smaller than the incident angle θ of the condenser lens 8 is attached (FIG. 3). In this case, if the diameter of the diaphragm 2a is the same as that in FIG. 1, thermal radiation from the lower end surface of the lens barrel 9'will enter the image pickup element 1, so the diaphragm 2a is narrowed down. That is, in this case, the knob 15 shown in FIG.
When 4 is rotated, the cap 12 having a female screw threadedly engaged with the male screw of the feed screw rod 14 is fixed to the end face of the bellows 13 and therefore goes straight without rotating. At this time, since the other end surface of the bellows 13 is fixed to the second wall surface 5b of the outer cylinder 5 of the vacuum container 7, the bellows 13 extends without rotating.

When the cap 12 goes straight, the cap 12
The heat-insulating material 11 fixedly adhered to the vehicle goes straight along with this.
When the heat insulating material 11 goes straight, the concave portion 1 formed therein
Since 1a is engaged with the pin 2d fixed to the cam plate 2b via the lever 2c, the pin 2d rotates about the central axis of the cam plate 2b and thus the cam plate 2b rotates. A plurality of blades attached to the cam plate 2b by pins (not shown) move to predetermined positions, and the diameter of the variable diaphragm 2a can be narrowed down to a size suitable for the condenser lens 8'installed. (Figs. 3 and 4)

That is, the variable aperture 2a has a predetermined diameter of the infrared ray 10 condensed by the condenser lenses 8 and 8 '.
Are incident, but the infrared rays from the lens barrel 9 are set so as not to reach the image sensor 1.

At this time, the knob 15 is the outer cylinder 5 of the vacuum container 7.
It is provided outside of and is almost the same as the temperature of the outside air. The heat conducted from the knob 15 via the feed screw rod 14 and the cap 12 is blocked by the heat insulating material 11,
d, lever 2c, cam plate 2b and a plurality of blades (not shown)
To the cold shield 2 and does not increase the temperature of the cold shield 2.

The adjustment of the variable diaphragm 2a is performed by the image pickup device 1
The screen of a display device such as a CRT that visualizes an infrared image based on the signal from can be made the clearest, but the type of lens that can be mounted around the feed screw rod 14 of the second wall surface 2c is selected. In addition to displaying, an index is formed on the feed screw bar 14, and the index of the feed screw bar 14 is adjusted to the display corresponding to the mounted lens, so that the aperture diameter corresponding to the mounted lens can be obtained, The variable diaphragm can be controlled by a ring motor to perform electrical control without mechanical transmission, and to automatically detect the type of lens attached (for example, the identification configuration of the shooting lens of a single-lens reflex camera). It is also possible to control the rotation of the ring motor so as to obtain a predetermined aperture diameter based on the detection result. Further, the variable diaphragm 2a can not only change the incident angle, but can also perform the original diaphragm function.

Further, although the diaphragm structure using diaphragm blades like the diaphragm of a photographic lens is described as an example, other types of diaphragm means capable of changing the size of the aperture can be used. Furthermore, the position of the stop does not have to be fixed directly to the cold shield, but may be placed anywhere between the condenser lens and the image sensor. However, it goes without saying that it must be cooled. Further, the image pickup device may be a point sensor that receives mechanically scanned infrared light, in addition to a device that electrically scans like a CCD.

Needless to say, the airtightness of the feed screw portion can be maintained by other known sealing means.

[0024]

As is apparent from the above description, according to the present invention, even if the attached condenser lenses are replaced with different types (focal length and brightness), the aperture can be easily opened by the variable diaphragm. Since it changes, only the collected infrared rays emitted from the subject always enter the infrared imaging element, and are not affected by the disturbance infrared rays. Further, since the variable diaphragm is driven from the driving unit through the heat insulating material and the temperature of the variable diaphragm at the opening does not rise, it is not affected by the infrared rays of the disturbance.

[Brief description of drawings]

FIG. 1 is a schematic explanatory view of an optical path according to an embodiment of the present invention.

FIG. 2 is a schematic plan view for explaining a variable diaphragm according to an embodiment of the present invention.

FIG. 3 is a schematic explanatory diagram of an optical path according to an embodiment of the present invention.

FIG. 4 is a schematic plan view for explaining a variable diaphragm according to an embodiment of the present invention.

FIG. 5 is a schematic explanatory view of an optical path of a conventional example.

[Explanation of symbols]

 1 Infrared Imaging Device 2 Cold Shield 2a Variable Aperture 2b Cam Plate 2c Lever 2d Pin 3 Cold Head 4 Infrared Incident Window 5 Outer Cylinder 6 Inner Cylinder 7 Vacuum Container 8 Condensing Lens 9 Lens Cylinder 10 Incident Infrared 11 Heat Insulation Material 11a Recess 12 12 Cap 13 Bellows 14 Feed screw rod 15 Knob

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Naoyuki Kawakami 3 2-3 Marunouchi, Chiyoda-ku, Tokyo Inside Nikon Corporation

Claims (3)

[Claims] 1. A variable aperture means for changing the size of an aperture for limiting an incident angle of infrared rays to an infrared imaging device for converting infrared rays from a condenser lens into an electric signal is provided. Infrared imaging device. 2. A mount element that engages with a mount element provided on the condenser lens in order to replace the condenser lens with a different type, is formed in an apparatus main body, and an opening of the variable aperture means is formed. The infrared imaging device is characterized in that the size of the lens corresponds to the condenser lens engaged with the mount element of the device body. 3. The infrared imaging device further comprises a cold shield having an opening formed between the condenser lens and the infrared imaging device to prevent unwanted infrared rays from entering the infrared imaging device. The variable aperture means is a variable diaphragm device provided at the aperture position formed in the cold shield, and an operating member attached to the outside of the vacuum container containing the infrared imaging element and the cold shield via a heat insulating member. And an interlocking member that adjusts the size of the diaphragm diameter of the variable diaphragm device by operating the operation member.