JPH0259710A - Object optical microscope - Google Patents

Abstract

PURPOSE:To make the microscope freely usable by leading the light from a light source to a desired location in the periphery of a lens, specimen, etc., by means of an optical fiber, etc., in a state where the optical fiber, etc., is united with the microscope main body. CONSTITUTION:A 1st-order light of a light source is led to the bottom section of the lens barrel of this microscope by means of an optical fiber 1 in a refraction-free state. The terminal of the optical fiber 1 is set so that the fiber 1 can surround the outer periphery of the object lens 15 provided at the center bottom of the lens barrel so that a specimen 5 to be inspected can be irradiated uniformly by rays of light from the above. At the time of microscopic inspection, the distance between the object lens 15 and an objective surface 13 at which the microscope is brought into contact with the specimen 5 to be inspected is fixed to a specific interval by changing the object lens 15 in accordance with a required magnification so that a required focused state can be set when the surface 13 is lightly pressed against the specimen 5. Therefore, the part which cannot be inspected with a microscope under the present condition can be inspected.

Description

[Detailed Description of the Invention] [Objective of the Invention] (Industrial Application Field) The present invention integrates light from a light source into a microscope body at a desired position, such as around a lens or around a specimen, using glass fibers, plastic fibers, etc. By guiding the microscope in a refracting manner, the microscope can be moved and operated freely, making it easy to perform actual microscope work in locations that were previously impossible or extremely difficult. This invention relates to an actual optical microscope characterized by being able to transfer images to a television camera located at a long distance and to print the necessary screen.

(Problems to be Solved by the Invention) The present invention does not require the specimen itself to be collected and processed as a specimen piece during microscopy activities of animals, plants, minerals, fibers, foods, etc. It is possible to use a microscope up to approximately 400x magnification both in two-dimensional and three-dimensional environments in various environments such as air, gas, water, and liquids such as salt water, as well as in narrow spaces and by remote control. This makes it possible to easily view parts that require microscopic examination. It also realizes the function of transmitting images of narrow spaces or areas requiring remote control to a television screen, or printing them as necessary.

In other words, it will be possible to perform microscopy activities in places where it would have been impossible or extremely difficult to microscopy the real object at high magnification (conventional technology).With conventional optical microscopes, During microscopy, a common method is to collect a specimen from an object, place it on a microscope surface, and irradiate the specimen with transmitted light from below, which severely limits microscopy activities.

Also, there are simple magnifying glasses that have the function of directly viewing the actual object, but they either use external light or a separate light source, so these also Its microscopic activity is extremely limited.

In other words, optical microscopes have the flexibility of being able to be used in gases or liquids in both a two-dimensional and three-dimensional view, inserted into narrow spaces, and used remotely. not exist.

[Structure of the invention]

(Means for Solving the Problems) The present invention is constituted by the following main technologies in order to realize the object.

(1) The first method is to refractably guide the primary light from the light source to the lower part of the lens barrel of the microscope using an optical fiber such as a glass fiber or a transparent plastic fiber.

(2) Next, the optical fin (-) terminal is installed so as to surround the outer periphery of the objective lens placed at the bottom of the center of the lens barrel, allowing light to be uniformly irradiated onto the subject from each direction at the top. Do it like this.

(3) Thirdly, in order to receive the primary light emitted from the end of the optical fiber, a light diffusing device is installed further below the end of the optical fiber so that it is vertically opposite to the end of the optical fiber (-). to obtain secondary light suitable for

(4)Fourthly, the distance from the objective lens to the object surface in contact with the subject is fixed at a constant interval according to the required magnification during microscopy, so that it can be mounted on a general optical microscope. Eliminates fine adjustment mechanism. That is, the distance is adjusted by changing the objective lens according to the required magnification. Therefore, during microscope work, the necessary focus can be obtained simply by lightly pressing the object surface against the subject.

(5) Also, in order to enhance the light irradiation effect, the end portion of the optical fiber should be focused at 2 degrees with respect to the center point of the object surface.
It is tilted about 5 degrees from the center line of the lens barrel.

(6) At the top of the lens barrel, provide a mounting area for an eyepiece or small camera.

(7) *A remote control handle can be detachably attached to the outer periphery of the unit, making it possible to use the microscope in liquids or in narrow spaces.

(8) C, (!, D (Ckmrg
When a small camera such as eCoupleDθvice) is attached, the image of the small camera is transferred from the camera controller to the television via a signal cable to obtain a screen.

(9) The camera controller, television, and video printer will be integrated, and the system will be configured so that necessary screens can be printed out each time.

aOt Since the real microscope according to the present invention is constructed using the above-mentioned techniques, coarse movement devices, fine movement devices, mirror stands, etc. are eliminated, and the microscope only has a lens barrel. Therefore, it is possible to perform microscope work that is suitable for a wider range of environments.

(Operations and Effects) The functions and effects of the present invention are as follows: (1) Peripheral devices such as a mirror stand and a coarse focusing device are eliminated and only the lens barrel is used, and light is guided by optical fibers, so the lens barrel can be moved freely. things become possible,
Changes in viable germs and hair roots in areas that were previously impossible to work with a microscope or were extremely solid, such as the back of conveyor belts in the food industry, the behind-the-scenes parts of machinery, human and animal hair roots, etc. etc. can be viewed through a microscope.

(2) Since the distance 4 between the objective lens and the object surface of the object to be examined is fixed and the mechanism is designed to achieve the desired magnification, the operator only needs to lightly push the tip of the lens barrel against the object to be examined. You can perform microscopy by.

(3) By making the entire lens barrel, including the small camera, airtight, equipped with a remote control handle, and using highly corrosion-resistant materials, it can be A wide range of microscopy activities becomes possible.

(4) By transmitting signals from a small camera to a TV screen, it is possible to grasp the current situation and its changes in each of the environments mentioned in (3) above in real time from a long distance using a high magnification of about 400x. Can be done.

(5) Furthermore, it is possible to realize a number of highly useful functions, such as being able to print out necessary screens at the same magnification as used.

(Example) Embodiments of the present invention will be described with reference to FIGS. 1 to 3.

Figure 1 is an external view of the microscope. ① is an optical fiber cable, which consists of a large number of glass fibers or highly transparent plastic fibers tied together, and the outer periphery of the cable is protected by a flexible tube. ■ is a light guide, and according to this embodiment, approximately 90 optical fibers are bundled together.
It has the function of arranging wires at approximately equal intervals around the circumference of the lens barrel and further wiring them to the bottom of the lens barrel.

■ is the outer wall of the lens barrel. Depending on the application, stainless steel or plastic surfaces may be used to provide corrosion resistance.
Electroless plating method using various corrosion-resistant materials such as titanium ceramic,
Process by vacuum ion deposition method etc.

■ is the lens barrel tip cover, which is usually molded from the same material as the lens barrel outer wall. Also, the lower part becomes the contact surface. ■ is the subject.

■ is a remote control handle attachment ring, and ■ is a remote control handle. ■ is a cable guide, O, O, D
(Charqe Couple Device) Fix the signal cable of the small camera ■ or the optical fiber cable. ■ is a fastening ring.

FIG. 2 is a sectional view of the inside of the lens barrel, and @ is a light diffusing device, which in this embodiment is molded integrally with the lens barrel tip cover 〇.

■ is the contact surface, which is constructed by polishing the lower surface of the lens barrel tip cover 〇.

＠ is a kissing transparent plate, which acts as a light passage hole and also serves as an airtight seal inside the lens barrel.■ is an objective lens, @ is an objective lens frame, and ■ is a ring that converts into an objective lens. , change the objective lens depending on the required magnification. ■ is the inner barrel of the lens barrel, in which the objective lens is attached and an optical fiber is passed between it and the outer wall of the lens barrel (■). ① is the primary light, which is sent from the light source by an optical fiber, but it is not suitable for a microscope in this state, so it is passed through a light diffusion device and used as the diffused light ①. [F] is an optical fiber terminal fixing device, which is installed between the lens barrel outer wall ■ and the lens barrel Shirataki ■.

FIG. 3 is an enlarged view of the optical fiber terminal fixing device (2), in which the optical fiber is fixed in such a manner that the optical fiber has a condensing inclination angle of 0 with respect to the center of a circular mirror. In this embodiment, the inclination angle θ is about 2° to 5°.

Figure 4 is a system configuration diagram for taking out a microscope image.0 (The image captured by the 3D small camera ■ is transferred from the signal cable ■ to the camera controller ■ via the camera controller signal input section ■. The turbidity that appears is on the top of the controller. @ is the camera controller signal output section, and the camera controller signal output cable [
input to the video printer [phase] via [phase].

Furthermore, the signal is transmitted to the television (2) via the video printer signal output cable and output as an image screen. ■ is an AC adapter, and ■ is an outlet, which is input by Aatoov as power for the camera controller. AOloov also for video printers and televisions separately
The power is human powered.

[Brief explanation of the drawing]

FIG. 1 is an external view of the microscope main body related to the present invention, and FIG.
The figure is a sectional view showing the inside of the lens barrel. FIG. 3 is an enlarged view of the optical fiber terminal fixing device inside the lens barrel, and FIG. 4 is a diagram showing the system configuration for taking out a microscope image.

Claims (4)

[Claims] (1) An optical fiber such as glass fiber or plastic fiber is placed around the objective lens attached to the bottom of the lens barrel, and a light diffusion device made of frosted glass, colored plastic, etc. is placed at a position vertically opposite to the end of the optical fiber. The lower tip of the lens barrel is equipped with a lens barrel tip cover that encloses the entire objective lens, optical fiber terminal, and light diffusion device, and forms a contact surface at the lower end. A real optical microscope. (2) Optical fibers such as glass fibers or plastic fibers are placed around the objective lens attached to the bottom of the lens barrel, and light diffusion is formed by molding frosted glass, colored plastic, etc. at positions that are vertically opposite to the ends of the optical fibers. The device is attached, and a lens barrel tip cover is attached to the lower tip of the lens barrel, which encloses the entire objective lens, optical fiber terminal, and light diffusion device, and forms a contact surface at the lower end. , an actual optical microscope characterized by having a handle for remote control attached to either part of the lens barrel or lens barrel accessories. (3) Optical fibers such as glass fibers or plastic fibers are placed around the objective lens attached to the bottom of the lens barrel, and light diffusion is formed using frosted glass, colored plastics, etc. at positions that are vertically opposite to the ends of the optical fibers. The device is attached, and a lens barrel tip cover is attached to the lower tip of the lens barrel, which encloses the entire objective lens, optical fiber terminal, and light diffusion device, and forms a contact surface at the lower end. A small camera is installed at the upper tip of the lens barrel.
A physical optical microscope characterized in that it is capable of transmitting a signal of a microscope image to a television and simultaneously transmitting a signal to a video printer via the small camera controller. (4) Optical fibers such as glass fibers or plastic fibers are placed around the objective lens attached to the bottom of the lens barrel, and light diffusion is formed by molding fogged glass, colored plastic, etc. at positions that are vertically opposite to the ends of the optical fibers. The device is attached, and a lens barrel tip cover is attached to the lower tip of the lens barrel, which encloses the entire objective lens, optical fiber terminal, and light diffusion device, and forms a contact surface at the lower end. A small camera is installed at the upper tip of the lens barrel.
Through the small camera controller, signals can be transmitted from the microscope image to the television and at the same time to the video printer. A physical optical microscope that is constructed by sealing all the joints to make the inside of the lens barrel airtight, and applying corrosion-resistant treatment to the outside of the lens barrel.