KR20060005458A - Auto collomator apparatus having cartridge prism - Google Patents

Abstract

The present invention provides a first and second objective lens formed at the front end of the barrel housing, a focusing lens fixed to the rear side of the first and second objective lenses of the barrel housing and condensing the light passing through the first and second objective lenses, and the barrel housing. It is formed so as to vertically project from the rear side of the focusing lens to the top of the light source having the illumination side focusing mirror and the condenser lens, and has a fixed hole on one side and a pinhole of a small hole through the other side, A CCD camera for capturing a separate cartridge prism, a semi-transmissive prism formed at the rear side of the light source on the focal lens extension line of the barrel housing, an eyepiece formed at the rear side of the semi-transmissive prism, and an image formed at an appropriate amount of light fixed to the rear side of the eyepiece. And a cart comprising a monitor that displays an image as an image through a signal transmitted from the CCD camera, and an image controller that controls the monitor and the CCD camera. It relates to an auto-collimator device having not a prism.

The present invention is inexpensive and harmful to the human body, while excluding the light rays located in the wavelength range of red or more, such as X-rays and gamma rays, while maintaining the sharpness, the flat tilt and perpendicularity of the specimen, the alignment and tilt of the optical lens being stewed on the plane It is possible to inspect several parts at the same time at the same time, and by forming pinholes with scales on the prism, grasping the positions of the scale lines that are changed according to the variation of the inclination of the item measured on the fixed scale lines marked finely. By calculating the scale, you can know the exact inclination value, so you can not only measure precisely but also make the weight lighter, which is easy to carry and improves mobility.

Cartridge Prism, Pinhole, Starting Scale, Fixed Scale, Light Source, CCD Camera, Monitor

Description

Auto collomator apparatus having cartridge prism             

1 is a plan view showing a state of an embodiment of the present invention,

2 is a front view of an embodiment of the present invention;

3 is a left side view of an embodiment of the present invention;

Figure 4 is an enlarged front cross-sectional view showing a structure of an embodiment of the present invention,

5 is a block diagram of an embodiment of the present invention,

6 is an explanatory diagram showing an operating state of the embodiment of the present invention;

FIG. 6A is an explanatory diagram showing incident light on a monitor when a subject is a good product; FIG.

6B is an explanatory diagram showing the appearance of incident light on the monitor when the subject is defective product A;

6C is an explanatory diagram showing the appearance of incident light on the monitor when the subject is a defective product B;

7 is a configuration diagram showing a detailed configuration of an embodiment of the present invention,

8 is an enlarged perspective view showing main parts of a cartridge prism according to an embodiment of the present invention;

* Description of the symbols for the main parts of the drawings *

10: cartridge prism 11: pinhole

12: movable scale 13: fixed scale

20: light source 21: condenser lens

22: illumination focusing mirror 30: focusing lens

41,42: first and second objective lens 50: barrel housing

60: transflective prism 70: eyepiece

80: CCD camera 81: Monitor

90: image control unit

The present invention relates to a collimator for collimating incident light beams in parallel, and more particularly, it is possible to maintain clarity while eliminating light rays located in a wavelength band of red or higher such as X-rays and gamma rays, which are inexpensive and harmful to the human body. It is possible to inspect several parts at the same time such as plane tilt and right angle of water, alignment and tilt of optical lens being stewed on the plane at the same time. Cartridge prism that is easy to carry and improved mobility because it is possible to precise measurement by knowing the exact inclination value by grasping the position of the grid line that is variable according to the variation of the inclination of the item to be measured on the grid line. It relates to an auto collimator device having a.

Collomator is an optical system that makes parallel bundles of rays, which are bundles of parallel rays by the lens system, by injecting the bundles of light beams into narrow gaps. It is used for measuring the focal length of the lens and the position of the optical axis.

As shown in FIG. 1, the collimator includes a lamp 110 generating light in a predetermined housing 100A and a flower plate 120 through which light emitted from the lamp 110 passes. And a collimating lens (Collomator L-dun) 130 for converging the divergent light of the lamp 110 passing through the flower plate 120 into parallel light, and assuming that the collimating lens 130 is formed. A test lens 140 for making parallel light by focusing in up / down reciprocating movement, a mirror 150 for reflecting parallel light formed by the test lens 140, and reflected by the mirror 150 The beam splitter 160 is formed such that two right angle prisms are arranged in close proximity to each other so that the path of which the path is reversed is reflected in the horizontal direction, and the light whose path is changed by the beam splitter 160 is changed through vision. Eye equipped to check the phase It consists of an optical unit 100 including a piece (170), and the support portion 200 is fixedly supported by the optical unit (100).

Looking at the optical path of the collimator configured as described above, after the light generated from the lamp 110 passes through the floral plate 120, the incident light beam beam splitter (Beal Splitter) made by placing two rectangular prisms close to each other Proceeding to 160, the P wave parallel to the incident surface passes. As described above, the incident light having passed through the beam splitter 160 is assumed by the collimating lens 130 having a predetermined focal length. At this time, the test lens 140 is reciprocated to move up and down to the test lens. When the focal position of 140 is assumed by the collimating lens 130, the light is focused in parallel and reflected by the mirror 150. At this time, the polarization plane of the reflected light reflected by the mirror 150 becomes an S-wave 90 ° different from the polarization plane of the incident tube and is incident on the beam splitter 160, and then is reflected 90 ° to the left to the IP. It is sent to the case 170, the user can check the image of the flower plate 120 through the eye 170 visually.

However, the conventional collimator configured as described above has a problem in that the accuracy is lowered by simply inspecting and measuring the arrangement of the optical device through human vision, thereby causing an error in the inspection of the precise optical device.

In addition, not only the optical part is fixed to a predetermined position of the support part, but also the optical part configured in the optical part is fixed to the housing, so that the clear image of the door cannot be obtained and the optical part cannot be obtained without changing the alignment state of the optical system. By assembling the assembly can not check the alignment of the optical axis has a problem that the work process is complicated to cause a decrease in productivity.

In order to solve this conventional problem, the first objective lens for condensing the light irradiated from the laser unit provided on one side of the housing is disposed below the laser unit, the light collected by the first objective lens The reflection angle is adjusted according to the state of the incident light focused by the collimating lens and the collimating lens for focusing the pinhole of the small hole which is passed through, the diverging light of the laser portion passing through the pinhole into parallel light, and the collimating lens. And a movable prism 1 for reflecting the light reflected by the movable reflector and transversely changed in the opposite direction and adjusting a fixed angle according to the state of the light. The right screen of the right prism 1 is a screen on which an image is formed so that the image reflected on the light reflected from the prism 1 can be visually identified. A right angle prism 2 is disposed between the screen and the right angle prism 1 so that the light reflected by the right angle prism 1 can be upwardly reflected and the fixed angle can be adjusted according to the state of the light. A second objective lens for allowing light to be driven up and down according to a measurement magnification, a variable filter for adjusting the amount of light introduced from the second objective lens through a filter selected from several rotating filters, and the variable filter An optical unit in which a camera for capturing an image formed by an appropriate light amount by the filter is arranged in series upwards; A support portion extended vertically and long by a rod to support the optical portion; A movable connection part which supports and connects the optical part to the support part so as to be movable up and down and pivotally; An optical collimator (Auto Collimator) device for adjusting the optical axis, characterized in that it comprises a monitor that displays the image as an image through the signal transmitted from the optical unit, and an image control unit comprising a computer for operating and controlling the monitor and the camera. It was published as public application 96-8906 of January 16.

However, such a conventional auto collimator device may be harmful to the human body when it is used for a long time by using a laser which is a beam that is harmful to the human body, and the laser park is operated by driving the current, so the cost of purchasing the laser and the power supply for driving the laser Due to the additional cost, the production cost is expensive, it is difficult to spread to the public, there was a problem that is not easy to popularize.

In addition, the conventional auto collimator device that uses the laser beam as a light source is used to determine whether the product is good or defective by looking at the distribution of dots rather than accurate calculation by displaying the laser beam on the screen separately from the fixed grid line. As a result, it was possible to reduce the inspection time of the product with a comprehensive plate, but could not calculate the exact calculation value, so there was a problem in that the value of the slope was not known.

In addition, the conventional auto collimator device has a problem that the mobility is inferior because the overall weight, including the device and the power supply device is heavy, uncomfortable to carry.

The present invention is to solve the above-mentioned problems, the light source using a low-cost halogen lamp rather than an expensive laser, while the laser is excluded in the wavelength band of red or more inexpensive and harmful to the human body, such as X-rays, gamma rays Auto Collimator keeps the sharpness of expression as it is, and enables you to measure the focal length and optical axis while checking the magnified image, and to sequentially align the center of the optical component on the optical axis. Collimator) The purpose is to provide a device.

In addition, an object of the present invention is to provide an auto collimator device capable of simultaneously inspecting a plurality of parts at a time such as the tilt and perpendicularity of the specimen, the alignment and the tilt of the optical lens being stewed on the plane.

In addition, by forming a pinhole with a scale on the prism, by grasping the position of the grid line that is variable according to the variation of the inclination of the article to be measured on the fixed grid line, which is minutely displayed, the scale can be calculated by accurately calculating the scale. Not only is this possible, but it is also designed to be light in weight and easy to carry and to improve the mobility of the auto collimator device.

In order to achieve the above object, the present invention provides an auto collimator device, wherein the first and second objective lenses formed at the front end of the barrel housing and the first and second objective lenses fixed to the rear side of the barrel housing are fixed. A focusing lens for condensing the light passing through the light source, a light source having an illumination side focusing mirror and a condenser lens vertically projecting from the rear side to the upper side of the focusing lens of the barrel housing, and a small hole having a fixed scale on one side and a hole on the other side. A cartridge prism having a pinhole and fitted or separated at the bottom of the light source, a semi-permeable prism formed at the rear side of the light source on an extension line of the focusing lens of the barrel housing, and an eyepiece lens formed at the rear side of the semi-permeable prism on an extension line of the barrel housing; Through the CCD camera and the signal transmitted from the CCD camera And a monitor for controlling an image as an image, and an image controller for controlling the monitor and the CCD camera.

The pinhole of the cartridge prism is further provided with a movable scale so that the purified slope of the product is reproduced as an image on the monitor.

As the light source, a low-cost halogen lamp is used to exclude high-light rays, such as X-rays and gamma rays, which are harmful to the human body, while maintaining high clarity.

The image control unit uses a notebook or a personal computer.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

1 is a plan view showing the embodiment of the present invention, Figure 2 is a front view of the embodiment of the present invention, Figure 3 is a left side view of the embodiment of the present invention, Figure 4 is an enlarged front sectional view showing the structure of the embodiment of the present invention, Figure 5 is a configuration diagram of an embodiment of the present invention.

The auto collimator device having the cartridge prism of the present invention includes the first and second objective lenses 41 and 42 formed at the tip of the barrel housing 50 and the first and second objective lenses 41 of the barrel housing 50 ( 42) a focusing lens 30 fixed to the rear side to focus light passing through the first and second objective lenses 41 and 42, and vertically upward from the rear side of the focusing lens 30 of the barrel housing 50; A light source 20 that is a halogen lamp formed to protrude and has an illumination side focusing mirror 22 and a condenser lens 21, and a pinhole 11 of a small hole having a fixed scale 13 on one side and a hole on the other side. The cartridge prism 10 which is inserted into or separated from the lower part of the light source, the semi-transparent prism 60 formed on the rear side of the light source on the extension lens 30 of the barrel housing 50, and the barrel housing 50 The eyepiece 70 formed on the rear side of the semi-transparent prism 60 on the extension line and fixed to the rear side of the eyepiece 70 is formed with an appropriate amount of light. The CCD camera 80 which captures an image, the monitor 81 which shows an image as an image through the signal transmitted from the CCD camera 80, and the personal computer or notebook which controls the monitor 81 and the CCD camera 80. The image control unit 90 is configured.

The pinhole 11 of the cartridge prism 10 may be used by forming a movable scale 11, or the cartridge prism 10 may be used in which the movable scale 11 is not formed in the pinhole 11. Further, the purified slope of the product is reproduced as an image on the monitor.

6 is an explanatory view showing an operating state of the embodiment of the present invention, Figure 6a is an explanatory view showing the incident light on the monitor when the subject is good, Figure 6b is a view showing the incident light on the monitor when the subject is defective A 6C is an explanatory diagram showing the appearance of incident light on the monitor when the subject is a defective article B, and FIG. 7 is a block diagram showing the detailed configuration of an embodiment of the present invention.

FIG. 8 is an enlarged perspective view of a main portion of the cartridge prism according to the embodiment of the present invention. A pinhole 11 is formed at a lower end of the light source 20 and has a fixed scale 13 formed at one side and a hole formed at the other side thereof. The movable hole 912 is formed in the pinhole 11 and is fitted and separated from the lower part of the light source 20 by the handle.

 As described above, the present invention can maintain the clarity of the laser as it is, while excluding the light rays located in the wavelength band of red or more, such as X-rays and gamma rays, which are inexpensive and harmful to the human body, using an inexpensive halogen lamp instead of an expensive laser. It is possible to measure the focal length and the optical axis while checking the image, and at the same time, align the center of the optical component to the optical axis and squeeze them sequentially.

In addition, there is an effect that can be inspected several parts at the same time in the plane tilt and perpendicularity of the specimen, the alignment and the tilt of the optical lens being stewed on the plane.

In addition, by forming a pinhole with a scale on the prism and grasping the position of the grid line that is variable according to the variation of the tilt of the article to be measured on the fixed grid line, which is minutely displayed, the scale can be calculated by accurately calculating the scale. Not only is this possible, but it is light in weight, making it easy to carry and improving mobility.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

Claims (4)

An auto collimator device; First and second objective lenses 41 and 42 formed at the tip of the barrel housing 50; A focusing lens 30 fixed to the rear side of the first and second objective lenses 41 and 42 of the barrel housing 50 to condense the light passing through the first and second objective lenses 41 and 42; A light source 20 which is formed to protrude vertically from the rear side of the focusing lens 30 of the barrel housing 50 and has an illumination side focusing mirror 22 and a condenser lens 21; A cartridge prism 10 having a fixed scale 13 at one side and a pinhole 11 having a small hole through the other side, and fitted or separated at the bottom of the light source; A semi-transmissive prism 60 formed on the rear side of the light source on an extension line of the focusing lens 30 of the barrel housing 50; An eyepiece 70 formed on the rear side of the transflective prism 60 on an extension line of the barrel housing 50; A CCD camera 80 fixed to the rear side of the eyepiece 70 to capture an image formed with an appropriate light amount; A monitor 81 which displays an image as an image through a signal transmitted from the CCD camera 80; An auto collimator device having a cartridge prism characterized by comprising an image controller (90) for controlling a monitor (81) and a CCD camera (80). The method of claim 1; An auto collimator device having a cartridge prism, characterized in that the pinhole (11) of the cartridge prism (10) further comprises a movable scale (12). The method of claim 1; The light source (20) is an auto collimator device having a cartridge prism, characterized in that the halogen lamp. The method of claim 1; The image control unit (90) is an auto collimator device having a cartridge prism, characterized in that the notebook or personal computer.

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