JP5003404B2 - Microscope illumination system - Google Patents

Description

The present invention relates to a microscope illumination device , and more particularly to a microscope illumination device suitable for use in a microscope that performs total reflection illumination.

  In recent years, microscopes capable of performing illumination using total reflection (hereinafter referred to as total reflection illumination or TIRF (Total Internal Reflection Fluorescence)) have been widely used. In a microscope that performs total reflection illumination (hereinafter also referred to as total reflection illumination fluorescence microscope), total reflection is performed on the sample side surface of the cover glass that protects the sample on the image side focal plane (hereinafter also referred to as pupil plane) of the objective lens. The total reflection illumination is performed by condensing the illumination light within a range that satisfies the conditions to be satisfied (hereinafter also referred to as a TIRF range) and irradiating the sample with parallel light (see, for example, Patent Document 1).

Japanese Patent Laid-Open No. 2004-85796

  However, in a conventional total reflection illumination fluorescence microscope, once the state (irradiation angle, irradiation position, etc.) of illumination light for total reflection illumination (hereinafter also referred to as total reflection illumination light) is set, the state is changed. Had to be adjusted again by the user. Therefore, for example, when performing time-lapse imaging without an attendant, it is difficult to capture a sample while switching the state of total reflection illumination.

  The present invention has been made in view of such a situation, and makes it possible to easily change the state of total reflection illumination.

An illumination device for a microscope according to an aspect of the present invention is an illumination device for a microscope that performs total reflection illumination via an objective lens, and at least one of optical components constituting an illumination optical system of total reflection illumination is electrically driven to a set position. To move the condensing position of the illumination light of the total reflection illumination on the image side focal plane of the objective lens in the left-right direction with respect to the observation position of the microscope provided with the microscope illumination device . Moving means, movement control means for controlling the first moving means to move the optical component to a designated setting position, and manually moving the optical component to thereby focus the image side focus of the objective lens. 2nd moving means for moving the condensing position of the illumination light on the surface in the front-rear direction with respect to the observation position of the microscope .

In one aspect of the present invention, at least one of the optical components constituting the illumination optical system of the total reflection illumination is electrically moved by the first moving unit, so that the total reflection illumination on the image side focal plane of the objective lens is achieved. The illumination light condensing position is moved in the left-right direction with respect to the observation position of the microscope in which the microscope illumination device is provided, and the optical component is moved to the designated setting position. The moving means is controlled, and the optical component is manually moved by the second moving means, so that the illumination light condensing position on the image side focal plane of the objective lens is moved back and forth with respect to the observation position of the microscope. Moved in the direction.

  According to the present invention, the state of total reflection illumination can be easily changed.

  Embodiments to which the present invention is applied will be described below with reference to the drawings.

  1 to 3 are diagrams schematically showing an embodiment of a microscope to which the present invention is applied. 1 is a perspective view of the microscope 10, FIG. 2 is a left side view of the microscope 10, and FIG. 3 is a top view of the microscope 10 (A arrow view).

  Hereinafter, in the microscope 10, the binocular tube 13 is provided, and the side on which the user looks into the microscope 10 when using the microscope 10 (the right side in FIGS. 1 and 2 and the upper side in FIG. 3) is referred to as the user side. Hereinafter, in the microscope 10, the user side is the forward direction, the opposite side to the user side is the backward direction, the left side from the user side toward the microscope 10 is the left direction, and the right side from the user side toward the microscope 10 is the right direction. . That is, the front-rear direction with respect to the observation position of the observer of the microscope 10 is the front-rear direction of the microscope 10, and the left-right direction with respect to the observation position is the left-right direction of the microscope 10.

  The main body 11 is composed of units 11A to 11F. On the upper surface of the unit 11A, a lens barrel base unit 12, a filter block turret 20, and a unit 11E are provided in this order from the user side. Further, a unit 11B is provided on the rear side surface of the unit 11A and is integrated. A camera 21 is attached to the left side surface of the unit 11A. A unit 11C is provided on the upper surface of the unit 11B, and a unit 11D is provided on the upper surface of the unit 11C. The unit 11C is a component to which the epi-illumination device is attached from the rear side. Further, an inverted L-shaped transmission illumination column 17 including a vertical column 17A and a horizontal column 17B is provided on the upper surface of the unit 11D. A unit 11F is provided on the upper surface of the unit 11E. A revolver 15 is provided at the front end of the upper surface of the unit 11F. The unit 11E is a part that moves up and down, and moves up and down by a vertical movement mechanism. The unit 11 </ b> F is a support base portion of the revolver 15 and is a part of the revolver 15.

  The binocular tube 13 is configured to be detachable from the lens barrel base unit 12. That is, the binocular tube 13 can be attached to or detached from the lens barrel base unit 12. The user can observe the specimen placed on the stage 14 through the eyepieces 31L and 31R provided on the binocular tube 13.

  The stage 14 is supported by the front end of the upper surface of the unit 11 </ b> D and the uppermost surface of the lens barrel base unit 12 so as to be substantially parallel to the bottom surface of the microscope 10. The stage 14 can be moved back and forth and left and right by a drive mechanism (not shown), and the position of the specimen on the stage 14 can be adjusted.

  The revolver 15 is rotatably supported at the front end of the upper surface of the unit 11F. By rotating the revolver 15 in the left or right direction, the user can select a plurality of objective lenses attached to the revolver 15 to be used for observing the specimen. In FIG. 2, only one objective lens 16 is shown for easy understanding of the drawing.

  Transmitted illumination lamps 18 are provided at the corners of the transmitted illumination column 17 (the upper surface of the column 17A and the rear surface of the column 17B), and the tip of the lower surface of the column 17B of the transmitted illumination column 17 and the stage 14 A condenser lens 19 is provided above.

  Illumination light (hereinafter also referred to as transmitted illumination light) emitted from the transmitted illumination lamp 18 is applied to the specimen placed on the stage 14 from above via the condenser lens 19. And the image by the transmitted illumination light which permeate | transmitted the sample is imaged with the camera 21, or is observed by the user via eyepieces 31L and 31R.

  In FIGS. 1 and 2, the condenser lens 19 is described in a considerably simplified manner. Actually, for example, the condenser lens 19 is supported by a support member (not shown) so as to be movable in the optical axis direction (vertical direction in FIG. 1), and the position of the condenser lens 19 in the optical axis direction can be adjusted. is there. Further, for example, an optical element such as a ring diaphragm to be used can be switched using a turret (not shown).

  The filter block turret 20 can be equipped with a plurality of filter blocks (not shown) on which an excitation filter, an absorption filter, and a dichroic mirror can be mounted, and can be switched to and removed from the optical axis. Total reflection illumination light, epi-illumination light, Or the function etc. which change the advancing direction of transmitted illumination light or extract only a predetermined wavelength component are provided.

  The total reflection illumination device 22 is an illumination device for performing total reflection illumination and epi-illumination with respect to a sample installed on the stage 14. The total reflection illumination device 22 includes a total reflection illumination light source unit 41, an epi-illumination device unit 42, and a connection unit 43. The total reflection illumination light source unit 41 and the epi-illumination device unit 42 are connected via the connection unit 43. It is connected. The total reflection illumination device 22 is attached to the main body 11 by inserting the connection unit 43 into the units 11C and 11E from the rear of the microscope 10.

  An optical fiber 23 is connected to the total reflection illumination light source unit 41. A laser light source (not shown) is connected to the other end of the optical fiber 23 that is different from the one connected to the total reflection illumination light source unit 41, and the total reflection illumination light that is laser light emitted from the laser light source is The light is incident on the total reflection illumination light source unit 41 through the optical fiber 23. The traveling direction of the total reflection illumination light incident on the total reflection illumination light source unit 41 is changed by the connection unit 43 or the like, and finally irradiated onto the specimen placed on the stage 14 via the objective lens 16. Then, a fluorescent image emitted from the specimen by irradiating the total reflection illumination light is captured by the camera 21 or observed by the user via the eyepieces 31L and 31R.

  The total reflection illumination light source unit 41 is provided with a micrometer 51 and an operation lever 52. As will be described later with reference to FIGS. 4 and 5, the user can adjust the condensing position of the total reflection illumination light on the pupil plane of the objective lens 16 in the front-rear direction by operating the micrometer 51. . As will be described later with reference to FIGS. 4 and 5, the user can adjust the condensing position of the total reflection illumination light in the optical axis direction by operating the operation lever 52.

  The epi-illumination unit 42 receives epi-illumination light that is illumination light emitted from the epi-illumination light source 24. The incident illumination light incident on the incident illumination unit 42 is changed in its traveling direction by the connection unit 43 or the like, and finally irradiated onto the specimen placed on the upper surface of the stage 14 via the objective lens 16. Then, an image of light emitted or reflected by the specimen by irradiating the epi-illumination light is captured by the camera 21 or observed by the user through the eyepieces 31L and 31R.

  The connection unit 43 is provided with a field stop adjusting lever 61, and the user can adjust the fields of the totally reflected illumination light and the incident illumination light by operating the field stop adjusting lever 61.

  4 and 5 are diagrams showing details of the configuration of the total reflection illumination light source unit 41. FIG. 4 is a schematic cross-sectional view of the total reflection illumination light source unit 41 as viewed from above, and FIG. 5 is a schematic cross-sectional view of the total reflection illumination light source unit 41 (as viewed from the arrow B).

  A collimator lens 102 is attached to the tip of the straight tube 103 inside the total reflection illumination light source unit 41. The straight tube 103 is supported by the light source unit body 101 so as to be slidable in the optical axis direction of the collimator lens 102 (vertical direction on the paper surface of FIG. 4). Although not shown in FIG. 4, the user can move the straight tube 103 in the optical axis direction of the collimator lens 102 by operating the operation lever 52 (FIGS. 1 and 2) provided on the straight tube 103. it can. That is, the user can adjust the position of the collimator lens 102 in the optical axis direction and adjust the condensing position of the total reflection illumination light in the optical axis direction.

  The base plate 104c is supported so as to be movable in the Y direction (vertical direction of the microscope 10) with respect to the base plate 104b by a moving mechanism 107 using a steel ball and a V groove. The base plate 104b is supported so as to be movable in the X direction (front-rear direction of the microscope 10) with respect to the base plate 104a by a moving mechanism (not shown) using a steel ball and a V groove similar to the moving mechanism 107. . Further, the base plate 104 a is fixed to the light source unit body 101. Therefore, the laser light exit port of the optical fiber 23 connected to the total reflection illumination light source unit 41 via a fiber connector (not shown) disposed on the base plate 104c is made X by the base plate 104b and the base plate 104c. It is possible to move in the direction and the Y direction.

  The linear motor 105 is attached to the base plate 104a so that the end of the direct coaxial is brought into contact with the base plate 104b via a spring (not shown). Therefore, by controlling the linear motor 105, the positions of the base plate 104b and the base plate 104c in the X direction can be adjusted. As a result, the position of the exit port of the optical fiber 23 in the X direction can be adjusted. it can.

  Further, the micrometer 51 fixed to the base plate 104c is provided such that the tip thereof is in contact with the base plate 104c via a spring (not shown). Therefore, by operating the micrometer 51, the position in the Y direction of the base plate 104c can be adjusted, and as a result, the position in the Y direction of the exit port of the optical fiber 23 can be adjusted.

  That is, the emission position of the total reflection illumination light can be moved in the X direction and the Y direction via the linear motor 105 and the micrometer 51. The condensing position of the total reflection illumination light on the pupil plane of the objective lens 16 is moved in the left-right direction of the microscope 10 by moving the emission position of the total reflection illumination light in the X direction, and the total reflection illumination light is emitted. By moving the position in the Y direction, the microscope 10 is moved in the front-rear direction.

  As described above, the linear motion motor 105 is used for the movement in the X direction, and the user's manual micrometer 51 is used for the movement in the Y direction. This is to prevent irradiation of illumination light to the user due to movement not intended by the user.

  In addition, parts other than the light source unit body 101 of the total reflection illumination light source unit 41 are protected by the covers 106a and 106b.

  FIG. 6 is a diagram illustrating an example of the configuration of an illumination optical system for total reflection illumination and epi-illumination of the microscope 10. In FIG. 6, the illustration of the illumination optical system related to transmitted illumination is omitted for the sake of simplicity.

  The illumination optical system of the microscope 10 includes an optical fiber 23, a collimator lens 102, an ND (Neutral Density) filter 201, a relay lens 202, a mirror 203, a condenser lens 204, a field stop 205, a condenser lens 206, a dichroic mirror 207, an objective. The lens 16, the mercury lamp 208, the collimator lens 209, the electric shutter 210, the relay lens 211, the excitation filter 212, the half mirror 213, the barrier filter 214, and the second objective lens 215 are configured.

  Among them, the optical fiber 23, the collimator lens 102, the ND filter 201, the relay lens 202, the mirror 203, the condenser lens 204, the field stop 205, the condenser lens 206, the dichroic mirror 207, and the objective lens 16, a total reflection illumination optical system. The epi-illumination optics is composed of a mercury lamp 208, a collimator lens 209, an electric shutter 210, a relay lens 211, an excitation filter 212, a half mirror 213, a field stop 205, a condensing lens 206, a dichroic mirror 207, and the objective lens 16. A system is constructed.

  In FIG. 6, the specimen 231 to be observed by the microscope 10 is immersed in the solution 233 in the slide glass 232 and protected by the cover glass 234. Further, oil 235 is filled in a portion of the objective lens 16 that is in contact with the cover glass 234.

  For example, laser light, for example, is incident on the optical fiber 23 as total reflection illumination light from a laser light source (not shown). The total reflection illumination light incident on the optical fiber 23 is emitted from the exit of the optical fiber 23, converted into a parallel light beam by the collimator lens 102, transmitted through the ND filter 201 for adjusting the light amount, and the relay lens 202, and mirrored. It is incident on 203.

  The total reflection illumination light incident on the mirror 203 is reflected by the mirror 203 in the direction of the condensing lens 204, passes through the condensing lens 204, the field stop 205, and the condensing lens 206, and is reflected by the dichroic mirror 207. And is condensed on the image side focal plane (pupil plane) BF of the objective lens 16. Then, the total reflection illumination light condensed on the image side focal plane (pupil plane) BF of the objective lens 16 irradiates the sample 231 by the objective lens 16.

  On the other hand, the epi-illumination light emitted from the mercury lamp 208 is converted into a parallel light flux by the collimator lens 209, and only a predetermined wavelength component is selectively transmitted by the electric shutter 210, the relay lens 211, and the excitation filter 212. The incident illumination light transmitted through the excitation filter 212 is reflected by the half mirror 213 in the direction of the condenser lens 206, reflected by the dichroic mirror 207 in the direction of the objective lens 16, transmitted through the objective lens 16, and irradiated on the sample 231. Is done. The electric shutter 210 can be opened and closed from the outside, and the incident illumination light can be switched on or off.

  Fluorescence emitted from the specimen 231 by irradiation with total reflection illumination light or epi-illumination light, or reflected light reflected from the specimen 231 is collected by the objective lens 16, and only a wavelength component necessary for observation is obtained by the dichroic mirror 207. Transmitted and unwanted wavelength components are reflected. Then, light having a predetermined wavelength among the light transmitted through the dichroic mirror 207 passes through the barrier filter 214 and forms an image on the image plane IM by the second objective lens 215.

  The half mirror 213 can be switched to a position indicated by a solid line or a position indicated by a dotted line. When the half mirror 213 is set at the position of the solid line, the intensity of the total reflection illumination light is weakened by the half mirror 213 to about 60%. Accordingly, in this case, the sample 231 is irradiated with the total reflection illumination light whose intensity is weakened to 60% and the epi-illumination light. In this case, it is possible to irradiate the specimen 231 with only incident illumination light by closing a shutter of a laser light source (not shown). On the other hand, when the half mirror 213 is set to the position of the dotted line, only the total reflection illumination light is irradiated to the sample 231 without reducing the intensity.

  Further, as described above, the total reflection illumination light on the pupil plane BF of the objective lens 16 is obtained by moving the exit of the optical fiber 23 in the XY direction (direction perpendicular to the optical axis direction of the total reflection illumination light). The light condensing position moves. By moving the condensing position of the total reflection illumination light on the pupil plane BF of the objective lens 16 and changing the incident angle of the total reflection illumination light, the total reflection is performed not only from the normal total reflection illumination but also from the normal total reflection illumination. It is possible to increase the amount of illuminating light and to perform epi-illumination with total reflection illumination light.

  7 and 8 are diagrams showing examples of a remote control pad for operating the microscope 10. FIG. 7 is an external view of the remote control pad 301, and FIG. 8 is a diagram illustrating an example of a screen displayed on the liquid crystal touch panel 311 of the remote control pad 301.

  The remote control pad 301 is connected to the microscope 10 via a cable, and transmits and receives various signals to and from the microscope 10. A user can perform a predetermined operation of the microscope 10 via the remote control pad 301. Communication between the microscope 10 and the remote control pad 301 may be wireless communication using infrared rays or the like.

  The remote control pad 301 includes a liquid crystal touch panel 311 and laser position storage buttons 312-1 to 312-6. Hereinafter, the laser position storage buttons 312-1 to 312-6 are simply referred to as laser position storage buttons 312 when it is not necessary to distinguish them individually.

  As shown in FIG. 8, a plurality of buttons for operating the microscope 10 are displayed on the liquid crystal touch panel 311. The user can operate each part of the microscope 10 or switch the screen displayed on the liquid crystal touch panel 311 by pressing each button on the liquid crystal touch panel 311.

  In the example of the screen in FIG. 8, buttons including a laser position adjustment button 321 and a mirror switching button 322 are displayed. The user operates the laser position adjustment button 321 to control the linear motor 105 and move the condensing position of the total reflection illumination light on the pupil plane BF of the objective lens 16 in the left-right direction of the microscope 10. it can.

  Further, the user can switch the position of the half mirror 213 to either the position indicated by the solid line or the position indicated by the dotted line in FIG. 6 by operating the mirror switching button 322. Thereby, it can switch to either the state which performs 100% intensity | strength total reflection illumination, or the state which performs 60% intensity | strength total reflection illumination and epi-illumination.

  The initialization position when the power is turned on can be set to a position that substantially matches the optical axis at the pupil position of the objective lens 16.

  Returning to FIG. 7, the laser position storage button 312 is used to store and read the irradiation position of the total reflection illumination light. Specifically, when the position of the exit of the optical fiber 23 is being adjusted, by pressing any of the laser position storage buttons 312-1 to 312-6, the irradiation of the optical fiber 23 at the time of pressing is performed. The position of the exit is stored in association with the pressed button.

  When the position of the exit of the optical fiber 23 is not adjusted, any one of the laser position storage buttons 312-1 to 312-6 is pressed, and the exit of the optical fiber 23 is pressed to the pressed button. When the positions are associated with each other, the position of the exit of the optical fiber 23 is controlled to move to the associated position.

  FIG. 9 is a block diagram showing a part of the functional configuration of the remote control pad 301. The remote control pad 301 is configured to include the functions of the operation unit 351, the laser position adjustment unit 352, and the storage unit 353. The operation unit 351 includes a liquid crystal touch panel 311 and laser position storage buttons 312-1 to 312-6. Further, the laser position adjustment unit 352 is realized by, for example, a CPU (Central Processing Unit) executing a predetermined program, and includes a laser position control unit 361, a storage control unit 362, and a read control unit 363. Composed. The storage unit 353 is configured by a non-volatile memory such as an EEPROM (Electronically Erasable and Programmable Read Only Memory).

  For example, when the user operates the laser position adjustment button 321 of the liquid crystal touch panel 311 and inputs a command for adjusting the position of the exit of the optical fiber 23, the operation unit 351 sends the command to the laser position control unit 361. Supply. The laser position controller 361 adjusts the position of the exit of the optical fiber 23 by controlling the linear motor 105 based on the acquired command and adjusting the position of the base plates 104a and 104b in the X direction. Thereby, the condensing position of the total reflection illumination light on the pupil plane BF of the objective lens 16 is adjusted.

  In addition, for example, when the user operates any one of the laser position storage buttons 312-1 to 312-6 and inputs a command for storing the current exit position of the optical fiber 23, the operation unit 351 is operated. Supplies the storage control unit 362 with the command and information indicating the operated laser position storage button 312. The storage control unit 362 acquires the current position of the emission port of the optical fiber 23 from the laser position control unit 361 and stores it in the storage unit 353 together with the ID indicating the operated laser position storage button 312.

  Further, for example, the user operates any one of the laser position storage buttons 312-1 to 312-6 and inputs a command for reading the position of the exit of the optical fiber 23 stored in the storage unit 353. In this case, the operation unit 351 supplies the reading control unit 363 with the command and information indicating the operated laser position storage button 312. The read control unit 363 reads the position of the exit of the optical fiber 23 stored together with the ID corresponding to the operated laser position storage button 312 from the storage unit 353. The read controller 363 supplies the read information indicating the position of the exit of the optical fiber 23 to the laser position controller 361. The laser position control unit 361 controls the linear motion motor 105 and adjusts the positions of the base plates 104a and 104b in the X direction, whereby the position of the exit of the optical fiber 23 is read from the storage unit 353. Move to.

  Further, when an instruction for reading the position of the exit of the optical fiber 23 stored in the storage unit 353 is input from the outside, the read control unit 363 stores the optical fiber 23 stored together with the ID indicated in the command. The position of the injection port is read from the storage unit 353. The read controller 363 supplies the read information indicating the position of the exit of the optical fiber 23 to the laser position controller 361. The laser position control unit 361 controls the linear motion motor 105 and adjusts the positions of the base plates 104a and 104b in the X direction, whereby the position of the exit of the optical fiber 23 is read from the storage unit 353. Move to. Thereby, the position of the exit of the optical fiber 23 can be switched by a command from the CPU or the like during time-lapse shooting. As a result, time-lapse photography can be performed while switching a plurality of states of total reflection illumination light.

  As described above, the condensing position of the total reflection illumination light on the pupil plane BF of the objective lens 16 can be moved electrically in the left-right direction of the microscope 10 and manually moved in the front-rear direction of the microscope 10.

  Further, by moving the condensing position of the total reflection illumination light on the pupil plane BF of the objective lens 16 only in the left-right direction of the microscope 10, most users can change the condensing position of the total reflection illumination light. Adjust in the left-right direction. As a result, it is possible to avoid a risk that the total reflection illumination light (laser light) is accidentally incident on the user's eyes in an attempt to adjust the condensing position of the total reflection illumination light in the front-back direction.

  Furthermore, since a plurality of setting positions of the exit port of the optical fiber 23 can be stored and the exit port of the optical fiber 23 can be automatically moved to a designated position from the stored setting positions, total reflection is achieved. Time-lapse photography can be performed while switching a plurality of illumination light states. In addition, by switching the position of the half mirror 213, it is possible to perform time-lapse shooting while switching between the state of total reflection illumination and epi-illumination.

  In the above description, the example in which the position of the exit of the optical fiber 23 is moved electrically is shown. However, by moving the other optical components constituting the illumination optical system of the total reflection illumination electrically, the objective lens 16 can be moved. You may make it adjust the condensing position of the total reflection illumination light in the pupil surface BF. For example, the mirror 203 in FIG. 6 is moved in the optical axis direction of the total reflection illumination light (vertical direction in FIG. 6), or the dichroic mirror 207 is moved in the optical axis direction of the total reflection illumination light (horizontal direction in FIG. 6). It is possible to adjust the condensing position of the total reflection illumination light on the pupil plane BF of the objective lens 16. In addition, the number of optical parts that are electrically moved is not limited to one, and a plurality of optical parts may be electrically moved to adjust the condensing position of the total reflection illumination light.

  In the above description, an example in which laser light is used as total reflection illumination light has been described. However, in the embodiment of the present invention, for example, light from another type of light source such as a xenon lamp or a mercury lamp is reduced. For example, the light beam may be narrowed so as to be sufficiently small.

  The embodiment of the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the gist of the present invention.

It is a perspective view which shows one Embodiment of the microscope to which this invention is applied. It is a left view which shows one Embodiment of the microscope to which this invention is applied. It is a top view (A arrow line view) which shows one Embodiment of the microscope to which this invention is applied. It is sectional drawing at the time of seeing a total reflection illumination light source unit from the top. It is sectional drawing (B arrow view) of a total reflection illumination light source unit. It is a figure which shows the example of a structure of the illumination optical system of the total reflection illumination of the microscope to which this invention is applied, and epi-illumination. It is an external view which shows the example of a remote control pad. It is an example of the screen displayed on the liquid crystal display panel of a remote control pad. It is a block diagram which shows a part of functional structure of a remote control pad.

Explanation of symbols

  10 microscope, 16 objective lens, 22 total reflection illumination device, 23 optical fiber, 24 epi-illumination light source, 41 total reflection illumination light source unit, 42 epi-illumination light source unit, 43 connection unit, 51 micrometer, 52 operation lever, 101 light source Unit body, 102 collimator lens, 103 straight tube, 104a to 104c base plate, 105 linear motion motor, 107 moving mechanism, 203 mirror, 207 dichroic mirror, 301 control pad, 311 liquid crystal touch panel, 312 laser position storage button, 321 laser position adjustment Button, 322 mirror switching button, 351 operation unit, 352 laser position adjustment unit, 353 storage unit, 361 laser position control unit, 362 storage control unit, 363 Read control unit

Claims (3)

In an illumination device for a microscope that performs total reflection illumination through an objective lens,
By electrically moving at least one of the optical components constituting the illumination optical system of the total reflection illumination to a set position, the condensing position of the illumination light of the total reflection illumination on the image side focal plane of the objective lens is determined by the microscope. First moving means for moving in the left-right direction with respect to the observation position of the microscope in which the illumination device for lighting is provided ;
A movement control means for controlling the first moving means to move the optical component to a designated setting position ;
And a second moving unit that moves the optical component manually to move the condensing position of the illumination light on the image-side focal plane of the objective lens in the front-rear direction with respect to the observation position of the microscope. A microscope illumination device characterized by the above. The illumination device for a microscope according to claim 1 , further comprising storage means for storing a plurality of setting positions of the optical component. 2. The microscope illumination apparatus according to claim 1 , wherein the first moving unit electrically moves an emission port that emits the illumination light. 3.

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