KR20190079091A - Slide-driving shutter and optical coherence tomography device having the same - Google Patents

Abstract

Disclosed are a slide-driving shutter capable of preventing distortion of a shutter due to shock, and an optical coherence tomography device having the same. The slide-driving shutter comprises: a shutter block (30) including a shutter plate (32) inserted in a light path and changing or blocking the light path, and a moving block (34) in which the shutter plate (32) is fixed and mounted to be moved with the shutter plate (32); a guide block (40) formed with a guide groove (42) slidingly moved by allowing the moving block (34) of the shutter block (30) to be caught; and a shutter block drive unit (50) reciprocating the shutter block (30) along the guide groove (42).

Description

[0001] Slide-driving shutter and optical coherence tomography device having same [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a slide driving shutter and an optical coherence tomography apparatus having the same, and more particularly, to a slide driving shutter and an optical coherence tomography apparatus having the same, .

Optical coherence tomography (OCT) has been used for the purpose of ophthalmologic operations such as corneal surgery, cataract surgery, and non-invasive imaging of a 2-dimensional tomographic image of the patient's eye. When the optical coherence tomography apparatus is used, a tomographic image of a living tissue can be obtained with a resolution of a wavelength of light incident on the living tissue, and the internal image of the living tissue can be photographed at a high resolution of a submicron unit.

1 is a block diagram of a configuration of a conventional optical coherence tomography apparatus. 1, a conventional optical coherence tomography apparatus includes a light source 10 for emitting a broadband low-coherence light L so as to have a short interference distance, a light source 10 for emitting the broadband light L A beam splitter 12 for dividing the reference beam R and the measurement beam S1 into a reference beam R and a reference mirror 14 for reflecting the reference beam R, (interference light, C) superimposed on the signal light S2 reflected from the reference mirror 14 and the reference light R reflected from the reference mirror 14 is detected And a shutter 20 for blocking the path of the measuring light S1 or the signal light S2. The shutter 20 performs interception and opening operations of the optical path very frequently in order to pass the measuring light S1 and shut off the signal light S2 or cut off the measuring light S1 and pass the signal light S2 .

As a driving method of the shutter 20, a rotary driving method in which a blocking plate is hinged, tilted or swinged to enter or exit an optical path is generally used. However, in the case of the shutter that performs such rotational movement, the stopper controls the closing of the shutter, so that when the shutter is opened and closed, an impact with the stopper occurs. Therefore, when the shutter is used for a long period of time, the shutter is twisted, and an error may occur in blocking the light by the shutter. Normally, such a twist of the shutter is very fine, so that it is not a problem to cut off a general optical path. However, in an optical coherence tomography apparatus that obtains an internal tomographic image of a living tissue using light interference, a slight distortion of the optical path may cause a large error in the measurement result. Therefore, it is necessary to prevent the shutter from being distorted by the shutter impact have.

Patent Publication No. 10-2013-0026502 Patent Publication No. 10-2014-0107831

An object of the present invention is to provide a slide driving shutter having excellent durability and precision and an optical coherence tomography apparatus having the same.

Another object of the present invention is to provide a slide driving shutter and an optical coherence tomography apparatus having the same that can prevent a shutter from being twisted even when using for a long period of time.

In order to accomplish the above object, the present invention provides a light source device comprising: a shutter plate inserted into an optical path to change or shut off an optical path; a shutter plate fixedly mounted to move along with the shutter plate, A shutter block (30) comprising a block (34); A guide block (40) having a guide groove (42) through which the moving block (34) of the shutter block (30) slides and moves; And a shutter block driving part (50) reciprocating the shutter block (30) along the guide groove (42).

The present invention also includes a light source (10) for irradiating measurement light (S1) to an object to be detected (18); A beam splitter 12 for dividing the measurement light S1 into a reference light R and a measurement light S1; A reference mirror 14 for reflecting the reference light R; A photodetector 16 for detecting an interference light C formed by superposing the signal light S2 obtained by reflecting the measurement light S1 at the detection object 18 and the reference light R reflected by the reference mirror 14 ); And a signal light (S2) inserted into any one of paths of the measuring light (S1), the reference light (R) and the signal light (S2) to pass or block the measuring light (S1), the reference light And a slide driving shutter (22, 24).

INDUSTRIAL APPLICABILITY The slide shutter and the optical coherence tomography apparatus having the same according to the present invention are excellent in durability and precision and can prevent the shutter from being distorted due to impact even in long-term use.

1 is a block diagram of a configuration of a conventional optical coherence tomography apparatus.
FIGS. 2 to 4 are respectively an upper perspective view, a lower perspective view, and a lower exploded perspective view of the slide driving shutter according to the embodiment of the present invention.
5 is a block diagram of an optical coherent tomography apparatus to which a slide drive shutter according to an embodiment of the present invention is applied.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In the accompanying drawings, components that perform the same or similar functions as those of the conventional configuration are given the same reference numerals. 2 to 4 are an upper perspective view, a lower perspective view, and a lower exploded perspective view of the slide driving shutter according to the embodiment of the present invention, respectively. 2 to 4, the slide driving shutter according to the present invention includes a shutter block 30, a guide block 40, and a shutter block driving portion 50. As shown in FIG.

The shutter block 30 includes a shutter plate 32 inserted in the optical path to change or shut off the optical path and a moving block 34 fixedly mounted with the shutter plate 32 and moving together with the shutter plate 32. [ . The shutter plate 32 is positioned vertically with respect to the optical path (A in Fig. 2) to block the light incident on the shutter plate 32 or to tilt the optical path (A in Fig. 2) at a predetermined angle So as to change the path of the light incident on the shutter plate 32 or to depart from the optical path A. [ An elongated hole 38 may be formed at one end, preferably the lower end, of the moving block 34 in a direction perpendicular to the moving direction of the shutter block 30, One or more guide holes 36 may be formed in a direction parallel to the moving direction of the shutter plate 32. [

The guide block 40 is formed with a guide groove 42 in which the moving block 34 of the shutter block 30 is inserted and slidably moved. The width of the guide groove 42 is substantially equal to the width of the moving block 34 and the length of the guide groove 42 is substantially equal to the sliding distance of the moving block 34, The moving block 34 is inserted into the guide groove 42 and reciprocally slid in the longitudinal direction of the guide groove 42. One or more guide rods 44 may be attached to the guide grooves 42 of the guide block 40 along the movement direction (longitudinal direction) of the movement block 34 as needed. 3 and 4, the guide rod 44 is slidably inserted into the guide hole 36 formed in the moving block 34 through the guide rod fixing hole 46 formed in the guide block 40 Possibly fitted. Therefore, not only the moving block 34 in which the guide rod 44 is inserted can slide more stably along the guide groove 42 and the guide rod 44 but also the moving block 34 is moved from the guide groove 42 It is possible to prevent separation.

The shutter block driving part 50 includes driving means for reciprocating the shutter block 30 along the guide groove 42 and includes a step motor 52 rotated and rotated at a predetermined angle, A driving arm 54 which rotates and rotates in a pivoting manner in accordance with the driving of the driving block 54 and a driving block 54 protruding from the end of the driving block 54, And a driving pin 56, which is fitted in the formed elongated hole 38 and moves along the elongated hole 38. The position of the step motor 52 is fixed and fixed to the guide block 40 by fastening means such as a screw 58, for example.

Next, the operation of the slide drive shutter according to the present invention will be described with reference to Figs. 2 to 4. Fig. 3, in a state in which the driving pin 56 of the shutter block driving part 50 is fitted to the lower end of the elongated hole 38 formed in the moving block 34 of the shutter block 30, The block 30 is located on the optical path A formed at one end (left end in FIGS. 2 and 3) of the guide block 40, blocking light or changing the path of light. When the optical path A is to be opened thereafter, the stepping motor 52 and the driving arm 54 coupled thereto are rotated clockwise (referring to FIG. 3) 56 also move clockwise to the upper end of the slot 38 and the moving block 34 also slides to the right along the guide groove 42. When the shutter block 30 moves to the other end of the guide block 40 (the right end in Figs. 2 and 3), the shutter block 30 is detached from the optical path A and blocks the optical path A Do not. Since the moving distance of the moving block 34 depends on the rotating angle of the stepping motor 52 and the rotating radius of the driving arm 54 coupled to the stepping motor 52, The rotation angle of the step motor 52 and the length of the driving arm 54 can be appropriately set according to the distance. Thereafter, when the optical path A is to be blocked again, the stepping motor 52 and the driving arm 54 coupled thereto are rotated in the counterclockwise direction (reference in FIG. 3) (42). The shutter block 30 is inserted and removed from the optical path A by sliding the moving block 34 and controlling the sliding movement of the moving block 34 by the swing drive of the stepping motor 52 The process can be performed without impact.

5 is a block diagram of an optical coherence tomography apparatus to which a slide driving shutter according to an embodiment of the present invention is applied. 5, the optical coherent tomography apparatus according to the present invention includes a light source 10 that irradiates a measurement light S1 with a detection object 18, a light source 10 that irradiates the measurement light S1 with reference light R, A reference mirror 14 for reflecting the reference light R, a signal light S2 obtained by reflecting the measurement light S1 from the detection object 18, and a beam splitter 12 for splitting the measurement light S1 into the reference light R, A photodetector 16 for detecting an interference light C formed by superimposing the reference light R reflected from the mirror 14 and a photodetector 16 for detecting either the path of the measuring light S1, And includes slide drive shutters 22 and 24 which are inserted into one path and pass or block the measurement light S1, the reference light R or the signal light S2 (including the change of the optical path). For example, the slide driving shutter 22 is positioned in the path of the measurement light S1 and the signal light S2 to guide the measurement light S1 to the detection object 18, It is possible to separate the signal light S2 from the path of the signal light S2 and to guide the signal light S2 to the photodetector 16. [

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.

Claims (5)

A shutter block (30) including a shutter plate (32) inserted into an optical path for changing or blocking an optical path and a moving block (34) fixedly mounted with the shutter plate (32) );
A guide block (40) having a guide groove (42) through which the moving block (34) of the shutter block (30) slides and moves; And
And a shutter block driving part (50) reciprocating the shutter block (30) along the guide groove (42). 2. The shutter block according to claim 1, wherein a long hole (38) is formed at one end of the moving block (34) in a direction perpendicular to the moving direction of the shutter block (30)
The shutter block driving part 50 includes a step motor 52 which is rotated and rotated in a predetermined angle, a driving arm 54 which pivots and rotates reversely in accordance with the driving of the step motor 52, And a driving pin 56 protruding from the distal end of the arm 54 and fitted in the slot 38 formed in the moving block 34 of the shutter block 30 and moving along the slot 38 In slide shutter. The shutter block according to claim 1, wherein at least one guide hole (36) is formed in the moving block (34) in a direction parallel to the moving direction of the shutter plate (32) One or more guide rods 44 are mounted along the moving direction of the moving block 34 and the guide rods 44 are slidably fitted in the guide holes 36 formed in the moving block 34 Slide shutter. A light source (10) for irradiating measurement light (S1) to the detection object (18);
A beam splitter 12 for dividing the measurement light S1 into a reference light R and a measurement light S1;
A reference mirror 14 for reflecting the reference light R;
A photodetector 16 for detecting an interference light C formed by superposing the signal light S2 obtained by reflecting the measurement light S1 at the detection object 18 and the reference light R reflected by the reference mirror 14 ); And
A slit drive circuit which is inserted into any one of paths of the measurement light S1, the reference light R and the signal light S2 to pass or block the measurement light S1, the reference light R or the signal light S2, A shutter (22, 24)
The slide driving shutters 22 and 24 include a shutter plate 32 inserted in the optical path to change or shut off the optical path and a shutter plate 32 fixedly mounted on the shutter plate 32, A shutter block (30) including a shutter (34); A guide block (40) having a guide groove (42) through which the moving block (34) of the shutter block (30) slides and moves; And a shutter block driving part (50) for reciprocating the shutter block (30) along the guide groove (42). The apparatus according to claim 4, wherein the slide shutter (22) is located on the path of the measurement light (S1) and the signal light (S2) to guide the measurement light (S1) to the detection object (18) ) And the signal light (S2), and guides the signal light (S2) to the photodetector (16).

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