JP2006162765A - Inverted type fluorescence microscope - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an inverted type fluorescence microscope suitable for miniaturization and measures against heat when it is surrounded by a case. <P>SOLUTION: The inverted type fluorescence microscope 1 surrounded by the case 2 includes a chassis 35 comprising a top chassis 36 and a bottom chassis 37. A transmissive illumination system 10 is disposed in the top chassis 36, and a vertical illumination system 11 and an imaging system 12 are disposed in the bottom chassis 37. Various power source units are mounted at either side part of the transmissive illumination system 10 and between the transmissive illumination system 10 and the vertical illumination system 11 in addition to various substrates such as a power source substrate inside the chassis 35. The elements are arranged above the vertical illumination system 11. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an inverted fluorescence microscope.

  Microscopes are roughly classified into two types: an upright type in which an objective lens is disposed above the stage, and an inverted type in which the objective lens is disposed below the stage. In the inverted microscope, as disclosed in Patent Document 1, the specimen placed on the stage is observed from below the stage. For this reason, in the inverted type, the transmission illumination system unit is arranged above the stage, and the specimen on the stage is irradiated with light from above. The sample image obtained by the transmitted illumination light is observed through an objective lens or the like disposed below the stage.

  As one type of microscope, a fluorescence microscope for observing fluorescence emitted from a specimen is known. The fluorescence microscope includes an epi-illumination unit that irradiates the sample with excitation light and a fluorescence observation unit that forms an image of the fluorescence emitted from the sample and observes the fluorescence observation unit. The system and / or an imaging unit such as a CCD camera, and the excitation light from the epi-illumination unit irradiates the specimen through a filter.

  By the way, the fluorescence microscope has been generally installed in a dark room to perform fluorescence observation in the dark room. In recent years, an image of an image pickup unit attached to the fluorescence microscope is displayed as an image display device such as a CRT or an LCD. In many cases, the image data is displayed and observed, or image data is processed by a personal computer.

In this type of usage, in addition to problems such as inconvenient operation of a personal computer in a dark room, the light emitted by a CRT or the like penetrates around the stage of the fluorescence microscope and deteriorates the quality of the fluorescence image. There is a possibility of causing it. In order to solve such problems, Patent Document 2 proposes to provide a stage on which a specimen is placed and a wall that shields the periphery of the objective lens. According to this proposal, there is an advantage that it is not necessary to work in a dark room for fluorescence observation.
Japanese Patent Laid-Open No. 10-268208 JP 2002-207177 A

  When it becomes possible to observe with a fluorescence microscope without using a dark room, it is inevitable that there will be a demand to place the fluorescence microscope on a private desk in a laboratory where daily work is performed. Therefore, downsizing of the fluorescence microscope is required. In addition, the appearance of the fluorescence microscope is required to be a clean design.

  As the fluorescence microscope is miniaturized, there is a problem that the sample is killed when the heat from the light source is propagated to the sample, and the optical components are affected by thermal expansion and the like. It is a problem to avoid a gap in the general relationship. In particular, in order to improve the appearance of the fluorescent microscope, when the fluorescent microscope is entirely surrounded by a case, countermeasures against heat inside the case become a very important technical issue. In addition, in the conventional fluorescence microscope, the power supply unit related to the fluorescence microscope is disposed outside the fluorescence microscope. However, when this is housed in a case, the above-described technology for making countermeasures against heat more difficult. It becomes a subject.

  An object of the present invention is to provide an inverted fluorescence microscope that is suitable for measures against heat when downsized and surrounded by a case.

  A further object of the present invention is to provide an inverted fluorescent microscope that is suitable for heat countermeasures when it is miniaturized and surrounded by a case, and all devices and substrates such as related power supply units are accommodated in the case. .

According to the present invention, the above technical problem is
A transmission illumination light source that emits transmission illumination light in a horizontal direction, a transmission illumination system that irradiates transmission illumination light from above toward the specimen on the stage by directing the transmission illumination light emitted by the light source downward;
Light emitted from a light source for excitation light illumination that emits light in a lateral direction is passed through a heat absorption filter and then converted into excitation light of a specific short wavelength band, and then directed upward and directed from below to a specimen on the stage. An epi-illumination system that emits excitation light;
An imaging system that captures an image of the specimen obtained by irradiating the specimen on the stage with an imaging mirror and that is reflected in the lateral direction, and is taken in the lateral direction;
A transmission illumination power supply unit for supplying power to the light source of the transmission illumination system;
An epi-illumination power unit for supplying power to the light source of the epi-illumination system;
A power supply board related to the transmission illumination power supply unit and the epi-illumination power supply unit, a chassis on which the transmission illumination system, the epi-illumination illumination system, the imaging system, the transmission illumination power supply unit, and the epi-illumination power supply unit are mounted When,
A case surrounding the chassis,
In the chassis, the imaging system, the epi-illumination system, and the transmission illumination system are arranged in order from the bottom to the top. The transmission illumination power unit, the epi-illumination power unit, and the power substrate Is provided above the epi-illumination system, and is achieved by providing an inverted fluorescence microscope.

  According to the present invention, the transmitted illumination power supply unit and the reflected illumination power supply unit that are heat sources are arranged above the epi-illumination system, and the heat of the transmitted illumination power supply unit and the epi-illumination power supply unit rises upward. These heat sources can suppress the thermal influence on the transmission illumination system. Further, when various substrates are arranged in the chassis, these substrates are surrounded by the chassis, which is suitable for noise countermeasures.

  In a preferred embodiment of the present invention, an electric fan unit is attached to the chassis via a vibration damping member, and the inside of the case is forcibly ventilated by the electric fan unit. Such forced ventilation with an electric fan was previously not allowed in microscopes, but it is possible to prevent the influence of vibration caused by the electric fan unit by attaching the electric fan unit to the chassis via a damping member. In addition, the heat in the case can be forcibly discharged to the outside by ventilation with an electric fan. Therefore, various parts can be arranged at high density inside the case, which facilitates miniaturization.

  In a preferred embodiment of the present invention, the light sources of the epi-illumination system and the transmission illumination system are surrounded by a heat insulating housing, and the heat insulating housing is forcibly ventilated by the electric fan unit. That is, by surrounding the light source of the illumination system, which is a heat source, with the heat insulating housing, while suppressing the heat of the light source from flowing into the chassis, the heat in the heat insulating housing is discharged outside by the electric fan, Ventilation makes it possible to cool the light source.

  If the epi-illumination system and the transmission illumination system prevent heat from being propagated to the specimen together with the light by the heat absorption filter disposed adjacent to the front of the light source included in each illumination system, this heat is used. By housing the absorption filter in the heat insulating housing and air-cooling the heat absorption filter together with the light source, it is possible to prevent the heat absorption filter from being saturated with heat.

  In the most preferred embodiment of the present invention, the imaging system and the epi-illumination system are arranged in a V shape when viewed in plan. As a result, the imaging system and the epi-illumination system can be arranged close to each other in the vertical direction, and accordingly the height dimension of the fluorescence microscope can be easily reduced.

  FIG. 1 is a perspective view showing the appearance of an inverted fluorescence microscope. In FIG. 1, an inverted fluorescent microscope 1 has a specimen cover 3 on the front surface of a main body case 2, and the specimen cover 3 extends along a lower cover 4 that substantially constitutes a part of the lower main body case 2. Thus, the specimen can be taken in and out. Then, when the sample cover 3 is in the state shown in FIG. The main body case 2, the specimen cover 3, and the lower cover 3 are made of a plate member formed of a metal or plastic material.

  The inverted fluorescence microscope 1 includes a power supply unit, a power supply board, a controller, and the like in addition to a bright-field transmission illumination system, an epi-illumination system, and an imaging system. The inverted fluorescent microscope 1 is connected to the monitor 6 via the personal computer PC, so that the user can perform various operations and settings using the keyboard 7 and the mouse 8.

  FIG. 3 shows the overall configuration of the bright-field transmission illumination system, the epi-illumination system, and the imaging system included in the fluorescence microscope 1. In FIG. 3, reference numeral 10 indicates a bright field transmission illumination system, 11 indicates an epi-illumination system, and 12 indicates an imaging system. The bright field transmission illumination system 10 is disposed at a level higher than the height position of the stage 13, and the epi-illumination system 11 and the imaging system 12 are disposed at a level lower than the height position of the stage 13.

  The bright-field transmitted illumination system 10 used for observation by transmitted light has a transmitted illumination lamp 15 typically composed of a halogen lamp as a light source, and those skilled in the art will pay attention first. The halogen lamp 15 is arranged in the horizontal direction. The light 16 emitted from the halogen lamp 15 is directed downward in the vertical direction by the inclined mirror 17 and irradiates the sample S on the stage 13 through a condenser lens (not shown).

  The epi-illumination system 11 used for observation by fluorescence typically includes an epi-illumination lamp 20 made of a mercury lamp, and the mercury lamp 20 is arranged in the horizontal direction. The light emitted from the mercury lamp 20 passes through the heat absorption filter unit 21 and the collector lens, and then passes through the excitation filter to become excitation light of a specific short wavelength band, and then is applied to the sample S by an inclined dichroic mirror. The sample S is directed upward in the vertical direction, and the sample S is irradiated from below through the objective lens 28.

  The excitation filter and the dichroic mirror described above are incorporated in the filter cassette 22, and in the example of FIG. 3, four types of filter cassettes 22 having different characteristics are arranged linearly adjacent to each other in the horizontal direction. That is, the selection of the filter cassette 22 is a direct-acting type, and in order to select an arbitrary filter cassette 22 from the plurality of filter cassettes 22, the user rotates the operation dial 23 to move the filter cassette 22 by the rack and pinion gear 24. This is performed by linearly displacing along the guide rail 25. For this operation, an electric motor may be used instead of the operation dial 23.

  The fluorescent microscope 1 shown in FIG. 1 employs a rotating type shown in FIG. 4 instead of the above-mentioned direct acting type. The rotary filter cassette system has a horizontal disc 26 on which four filter cassettes 22 having different characteristics are detachably mounted, and the filter cassettes 22 are equidistant from each other (90 ° interval). Placed in. The horizontal disk 26 is rotationally driven around the vertical shaft 27 by an electric motor related thereto. By rotating the horizontal disk 26, the filter cassette 22 having desired characteristics can be selected. As a modification, the horizontal disk 26 may be manually rotated like the operation dial 23 described in FIG.

  Returning to FIG. 3, the stage 13 disposed adjacent to the upper side of the objective lens 28 individually moves in the X and Y axis directions crossing the optical axis, and is fixed in the vertical direction. Can be adjusted in the Z-axis direction to adjust the relative position of the stage 13 and the objective lens 28. In addition to the X and Y-axis directions, the stage 13 can be adjusted in the Z-axis direction. By moving independently, the relative distance with the objective lens 28 can be adjusted. Such a relative position adjustment between the stage 13 and the objective lens 28 may be performed manually, but in this embodiment, it is performed by an electric motor described later.

  The imaging system 12 includes an imaging mirror 30 disposed immediately below the filter cassette 22, an imaging cylinder 31 that faces the imaging mirror 30 and extends in the horizontal direction, and an imaging device 32 (attached to the end of the imaging cylinder 31 ( For example, a CCD camera).

When the epi-illumination system 11 and the imaging system 12 both extending horizontally in the lower region of the stage 13 are viewed in plan, the horizontal axis L1 of the epi-illumination system 11 and the horizontal axis L2 of the imaging system 12 are at an angle θ _0. Therefore, as can be best understood from FIG. 4, the mercury lamp 20 and the CCD camera 32 are arranged in an offset state to the left and right when viewed from above. Yes.

  In this way, by arranging the epi-illumination system 11 and the imaging system 12 extending in the horizontal direction in a V shape, the mercury lamp 20 and the CCD camera 32 are arranged offset from each other on the left and right sides. Without taking into account the interference between the large mercury lamp 20 and the CCD camera 32, the vertical distance between the epi-illumination system 11 and the imaging system 12 positioned below it is set as small as possible, The height dimension of the microscope 1 can be reduced. In other words, when the mercury lamp 20 and the CCD camera 32 are arranged vertically in the same vertical plane, the interval between the epi-illumination system 11 and the imaging system 12 is the distance between the mercury lamp 20 and the CCD camera 32. Limited by interference.

  As in the embodiment, the epi-illumination system 11 and the image-capturing system 12 both extending in the horizontal direction are arranged in a V-shape so that the distance between the epi-illumination system 11 and the image-capturing system 12 positioned below it is as much as possible. When set to a small value, the distance between the filter cassette 22 and the imaging mirror 30 is also reduced, so that the length dimension of the imaging cylinder 31 can also be reduced.

This point will be described in detail with reference to FIG. 5. Reference numeral A in FIG. 5 indicates the distance between the objective lens 28 and the imaging mirror 30, and reference numeral B indicates the imaging mirror 30 and the CCD camera 32. The distance from the CCD light receiving surface is shown. Between the objective lens 10 and the imaging mirror 30 is a diffusion system, and between the imaging mirror 30 and the CCD camera 32 is a condensing system. The light spread angle θ ₁ in the diffusion system is equal to the light collection angle θ ₂ in the light collection system. Therefore, as the distance A is shorter, the length of the distance B is smaller as the distance A is shorter. Therefore, the length dimension of the imaging cylinder 31 can be reduced.

  The transmitted illumination system 10 and the epi-illumination system 11 are selectively used. When the transmission illumination system 10 is selected, the transmission illumination light 16 emitted from the halogen lamp 15 arranged in the horizontal direction is reflected by the inclined mirror 17 to illuminate the sample S from above. The obtained image of the sample S passes through the objective lens 28, the dichroic mirror of the filter cassette 22, the absorption filter, the imaging mirror 30, and the like, and is taken into the CCD camera 32 arranged in the horizontal direction.

  On the other hand, when the epi-illumination system 11 is selected, the light emitted from the mercury lamp 20 arranged in the horizontal direction passes through the heat absorption filter, the collector lens, the excitation filter of the filter cassette 22, and the dichroic mirror, and the objective lens. Through 28, the sample S is irradiated with excitation light from below. The fluorescent material contained in the specimen S by the pretreatment receives excitation light and emits fluorescence. The fluorescent image is taken into the CCD camera 32 through the objective lens 28, dichroic mirror, absorption filter, and the like.

  1 has a chassis 35 shown in FIG. 6 as its skeleton, and the chassis 35 has a two-part structure of an upper chassis 36 and a lower chassis 37. Both the upper chassis 36 and the lower chassis 37 are aluminum alloy die-cast products or cast articles that are lightweight and have a relatively low coefficient of thermal expansion. Referring to FIG. 7, the transmission illumination system 10 is disposed in the upper chassis 36, and the epi-illumination system 11 and the imaging system 12 are disposed in the lower chassis 37. Further, in the chassis 35, in addition to various substrates such as a controller and a power supply substrate, various power supply units are provided between one side portion of the transmitted illumination system 10 and the transmitted illumination system 10 and the incident illumination system 11. Is installed. A plurality (three in the embodiment) of electric fan units 38 are attached to the rear surface of the chassis 35 side by side. Heat generated inside the chassis 35, for example, heat generated from the halogen lamp 15, the mercury lamp 20, various power supply units, motors, etc. that generate a large amount of heat, is forcibly discharged from the rear of the chassis 35 to the outside. .

  As seen in FIG. 6, a large number of openings 35 a are formed in the side wall of the chassis 35. These openings 35a are provided for the purpose of assembling components for weight reduction, and are provided for introducing outside air as will be understood from the following description.

  FIG. 8 shows some of the parts incorporated in the chassis 35. In FIG. 8, reference numeral 40 is a power supply unit for supplying power to the mercury lamp 20 of the epi-illumination system 11, and 41 is a power supply for controlling a system such as a motor incorporated in the fluorescent microscope 1. 42 is a power supply unit for supplying power to the halogen lamp 15 of the transmission illumination system 10, and 43 is a motor drive for driving various motors incorporated in the fluorescent microscope 1. Circuit board. The motor drive circuit board 43 drives, for example, a motor 45 for driving the stage 13 in the X and Y axis directions, a motor (not shown) for driving the electric zoom mechanism of the imaging system 12, and a diaphragm of the mercury lamp 20. A motor (not shown) for controlling the motor is controlled. A motor for adjusting the position of the stage 13 in the Z-axis direction is mounted on a common motor base 46 adjacent to the motor 45 for adjusting the position of the stage 13 in the X- and Y-axis directions. 8 is not shown in the drawing because it is covered with the cover 47.

  As can be understood from FIG. 8, the stage 13, the motor 45 that drives the stage 13, and the objective lens 28 are unitized, and this unit is assembled to the lower chassis 37.

  FIG. 9 shows the rotary filter cassette system described above. The central vertical shaft 27 of the horizontal disk 26 is assembled to the base plate 50. A circular ring gear 51 is attached to the peripheral surface of the horizontal disk 26, and a drive gear 52 that meshes with the circular ring gear 51 is driven by a motor 53 fixed to the base plate 50. When the motor 53 is rotationally controlled by the motor drive circuit board 43 of FIG. 8, the desired filter cassette 22 is positioned at a predetermined position, and the light emitted from the mercury lamp 20 is filtered as described above. The sample S is irradiated through the excitation filter 55 and the dichroic mirror 56 as the excitation light. The system for driving the stage 13 shown in FIG. 8 and the rotary filter cassette system of FIG. 9 are assembled to the front portion of the lower chassis 37, as can be seen from FIG.

  A unit 60 of the transmission illumination system 10 is mounted on the upper end portion of the upper chassis 36 at the center in the width direction. FIG. 11 is a perspective view of the transmitted illumination unit 60, and FIG. 12 is a plan view of the transmitted illumination unit 60. The transmissive illumination unit 60 includes a transmissive illumination housing 61 extending in the horizontal direction. The transmissive illumination housing 61 includes a halogen lamp 15 and a heat absorption filter (shown in the drawing) disposed adjacent to the front of the halogen lamp 15. Not built-in). A pivot shaft 62 extending in a direction crossing the housing 61 is rotatably provided on the upper portion of the front end portion of the transmitted illumination housing 61, and the transmitted illumination optical unit 64 is attached to the pivot shaft 62. The transmitted illumination optical unit 64 can rotate upward about the pivot shaft 62. The transmitted illumination optical unit 64 includes the tilt mirror 17, the condenser lens 66, and the like. The transmitted illumination optical unit 64 also has a plate 67 that can be slid in the horizontal direction, and the user can select a unit for each observation of phase observation and bright field observation by manually operating the plate 67. .

  A damper 69 is attached to one end of the pivot shaft 62 via a link 68, and the base end of the damper 69 is rotatably attached to the rear end of the transmission illumination housing 61. When the user applies a force to lift the transmitted illumination optical unit 64 upward with a finger, the damper 68 gently turns upward and takes a flip-up position (FIGS. 13 and 14) inclined almost 45 degrees. Can do. Conversely, when a force is applied to push down the transmitted illumination optical unit 64 in the flip-up position shown in FIGS. 13 and 14, the damper 69 gently turns downward to correspond to FIGS. 11 and 11. Return to the normal position in FIG.

  As described above, the light source 15 of the transmission illumination system 10 is arranged in the horizontal direction, so that the height dimension of the fluorescence microscope 1 can be significantly reduced, and the retraction operation of the transmission illumination optical unit 64 by flipping up is performed. Can be adopted. Then, the transmitted illumination optical unit 64 is flipped up to retreat upward from the normal position, so that the compact fluorescent microscope 1 does not impair the compactness, and the transmitted illumination is maintained while maintaining a good appearance. The optical unit 64 can be moved away from the stage 13 and the objective lens 28.

  11 and 13, a proximity switch 70 is fixed to the front end portion of the transmission illumination housing 61 extending in the horizontal direction so as to face the link 68. The proximity switch 70 functions as a sensor that detects the jump-up position and the normal position of the transmission illumination optical unit 64. When the jump-up position (FIG. 13) of the transmission illumination optical unit 64 is detected, the proximity switch 70 outputs a halogen signal based on the output signal. Control is performed to forcibly turn off the lamp 15 or lower the lamp 15 to the minimum light quantity.

  The transmitted illumination optical unit 64 can be moved away from the stage 13 and the objective lens 28 by taking the flip-up position (FIG. 14) in which the transmitted illumination optical unit 64 is rotated about 45 degrees upward from the normal position. The user displaces the transmitted illumination optical unit 64 to the flip-up position, and displaces the specimen cover 3 described in detail later to expose the stage 13 to expose the specimen S, specifically, the specimen S. The work to put in and out petri dishes and preparations with can be done easily. The stage 13 has a ring plate 13a (for example, see FIG. 10) having a light passage opening through which the objective lens 28 faces from below. The stage 13 can be attached to the petri dish for positioning the petri dish containing the specimen S. For example, when the ring plate 13a is placed on the stage 13, it is convenient to place the transmitted illumination optical unit 64 in the flip-up position.

  In addition, by moving the transmitted illumination optical unit 64 to the flip-up position and moving the transmitted illumination optical unit 64 away from the objective lens 28, the work for exchanging the objective lens 28 or cleaning around the stage 13 can be performed easily. Can do. Further, when the transmitted illumination optical unit 64 is displaced from the normal position to the flip-up position, the transmitted illumination light source (halogen lamp) 15 is forcibly turned off or lowered to the minimum light amount in conjunction with this. It is possible to prevent the user from receiving the light from the halogen lamp 15 and feeling dazzling.

  In the above example, the transmission illumination optical unit 64 is rotated upward, but the transmission illumination optical unit 64 may be retracted from the normal position by sliding along the front surface of the main body case 2. FIG. 15 shows an example in which the transmitted illumination unit 64 is linearly retracted upward from the normal position, and FIG. 16 shows an example in which the transmitted illumination unit 64 is linearly retracted laterally from the normal position.

  As can be understood from FIGS. 17 and 18, the halogen lamp power supply unit described above is provided on the side of the transmissive illumination housing 61 containing the halogen lamp 15 and the heat absorption filter related thereto, that is, on the side of the upper chassis 36. 42, a system power supply unit 41 is disposed, and in the upper chassis 36, a power supply board 71, a drive circuit 72 for a drive motor in the Z-axis direction of the stage 13, a mercury lamp power supply, below the transmission illumination housing 61. A unit 40 is provided. On the other hand, as can be understood from FIG. 19, a main control board (controller) 73 is disposed on the side of the lower chassis 37, and the main control board 73 penetrates to the upper chassis 36.

  FIG. 20 shows an outline of the air cooling structure of the epi-illumination system 11, and it should be understood that this air cooling structure is substantially the same in the transmissive illumination system 10.

  The mercury lamp 20 that is a light source of the epi-illumination system 11 and a plurality of heat absorption filters 75 arranged in front of the mercury lamp 20 are accommodated in an epi-illumination housing 76 made of a plastic material that is a heat insulating material. The epi-illumination housing 76 has an air cooling passage 77 extending rearward from the heat absorption filter 75, and the rear end of the air cooling passage 77 is opened toward the lowermost electric fan unit 38.

  Around the mercury lamp 20, a partition wall 78 having a rectangular cross section is preferably provided adjacent to the mercury lamp 20, and a second air cooling passage 79 is formed around the mercury lamp 20 by the partition wall 78. ing. The epi-illumination housing 76 includes an air introduction port 80 in a region below the heat absorption filter 75. Air is introduced into the epi-illumination housing 76 through the air introduction port 80, and the air flowing into the epi-illumination housing 76 is After the heat absorption filter 75 is cooled, it is discharged to the outside by the electric fan unit 38 through the main air cooling passage 77. The air introduced into the epi-illumination housing 76 is discharged to the outside by the electric fan unit 38 through the main air-cooling passage 77 after the mercury lamp 20 is air-cooled through the second air-cooling passage 79.

  The heat absorption filter 75 whose heat absorption capability is lost due to heat saturation and the mercury lamp 20 that becomes high heat are surrounded by a heat insulating housing 76 to prevent the heat of the heat absorption filter 75 and the mercury lamp 20 from flowing into the chassis 35. However, since the heat in the heat insulating housing 76 is forcibly discharged to the outside by the electric fan unit 38 together with the air introduced into the heat insulating housing 76, the heat of the mercury lamp 20 or the like is It is possible to prevent the mercury lamp 20 from being carried to the specimen S through the saturated heat absorption filter 75 and to be prevented from flowing into the chassis 35.

  A heat sink may be used for the light source of the transmission illumination system 10 and the epi-illumination system 11 and the cooling structure of the heat absorption filter described above. For example, a heat sink may be attached to the heat absorption filter of the transmission illumination system 10 or the epi-illumination system 11, thereby preventing heat saturation of the heat absorption filter 75.

  In the fluorescent microscope 1 of the embodiment, the mercury lamp 20 as a heat source and various power supply units are surrounded by the main body case 2, and the focus slightly changes due to thermal expansion of the chassis 35 or the like due to the heat of the internal components, Moreover, there is a risk of weakening or killing the organism of the specimen S. In order to cope with this, the fluorescent microscope 1 of the embodiment is provided with the electric fan unit 38 on the rear end surface of the chassis 35, and the air vent 81 is provided on the side surface of the main body case 2 as can be understood from FIG. Thus, the heated air inside the main body case 2 is ventilated by the outside air flowing in through the vent 81, and the mercury lamp 20, the halogen lamp 15 and the heat absorption filter 75 associated therewith are provided in a heat insulating housing. The mercury lamp 20 and the halogen lamp 15 can be air-cooled by being surrounded by 76 and 61 and exhausted by the electric fan unit 38 while preventing the heat generated by the mercury lamp 20 or the like from flowing into the chassis 35. .

  Further, with respect to a light source that becomes high temperature like the mercury lamp 20, the second air cooling passage 79 having a relatively small passage cross-sectional area is formed around the mercury lamp 20 by the partition wall 78 surrounding the light source. Air passes around the mercury lamp 20 at a relatively high flow rate, and a large amount of heat generated by the mercury lamp 20 can be discharged to the outside.

  Further, since the heat absorption filter 75 related to the mercury lamp 20 and the like is also air-cooled, it is possible to prevent the heat absorption capability of the heat absorption filter 75 from being lost or lowered due to heat. The heat saturation of 75 can prevent heat from being propagated to the specimen S together with light emitted from a light source such as the mercury lamp 20.

  In the embodiment, the three electric fan units 38 are attached to the rear end surface of the main body case 2. However, as shown in FIG. 21, the three electric fan units 38 include a plurality of vibration damping members 85 such as gel or rubber. It is mounted on the main body case 2 via Conventionally, it has been supposed that an electric fan unit serving as a vibration generation source should not be provided in a device such as the fluorescence microscope 1 that is extremely hated of vibration. The vibration due to the fan unit 38 can be prevented from being transmitted to the chassis 35. The electric fan unit 38 is preferably a unit of a relatively low rotation type, for example, 3000 rpm.

  With respect to the vibration damping member 85, the first vibration damping member 38a (FIG. 17) is formed on the upper and lower surfaces of the electric fan unit 38 in order to absorb the vibrations of the vertical, lateral, and front-rear components of the electric fan unit 38. ), A second damping member 38b (FIG. 17) is provided on both side surfaces of the electric fan unit 38, and a third damping member 38c (on the front and / or rear surface of the electric fan unit 38 is provided. FIG. 21) is preferably provided. That is, the damping member 85 is provided between the electric fan unit 38 and the fan cover 38 a attached thereto and between the chassis 37.

  When the upper and lower three electric fan units 38 mounted on the back surface of the fluorescent microscope 1 of the embodiment are called the uppermost fan 38T, the middle fan 38M, and the lowermost fan 38B in order from the top, the uppermost fan 38T is shown in FIG. As can be understood from the air flow indicated by the arrow, it contributes to air cooling of the halogen lamp 15 for transmitted illumination and the heat absorption filter related thereto and air cooling of the upper portion of the upper chassis 36 such as the halogen power supply unit 42 located on the side thereof. To do.

  The middle fan 38M is provided with a mercury lamp power supply unit 40, a system power supply unit 41, and the like, as can be understood from the air flow shown by the arrow in FIG. 23, which is a bottom view of the upper chassis 36 viewed from below. This contributes to air cooling of the lower portion of the upper chassis 36.

  As can be understood from the air flow indicated by the arrows in FIG. 20, the lowest fan 38B contributes to air cooling of the mercury lamp 20 and the heat absorption filter 75 associated therewith disposed in the lower chassis 37.

  As a modification, the uppermost fan 38T and the middle fan 38M may be configured by one common fan, and the upper and lower portions of the upper chassis 36 may be forcedly cooled by this common fan.

  Further, since the main control board (controller) 73 and the like are surrounded by the chassis 35, noise resistance can be ensured.

  The specimen cover 3 described above can be displaced downward along the outer surface of the lower cover 4 below it. For example, the sample cover 3 may have a width W1 (FIG. 24) slightly larger than the width W2 of the lower cover 4. That is, the specimen cover 3 has a U-shaped cross section surrounding both sides and the front of the stage 13, has a shape similar to the lower cover 4, and has a slightly larger cross sectional shape than the lower cover 4. You may have. As a modification, if the lower cover 4 has a cross-sectional shape protruding in a convex arc shape toward the front, the specimen cover 3 is similar to the lower cover 4 and slightly larger in crossing than the lower cover 4. It may be formed into a surface shape.

  The sample cover 3 can be displaced downward along the front surface and both side surfaces of the lower cover 4 (FIG. 26). When the sample cover 3 is displaced downward, the front and both sides of the stage 13 are open. . Thereby, the sample S can be set on the stage 13 or the sample S on the stage 13 can be removed. At that time, if necessary, the transmission illumination optical unit 64 may be rotated to the flip-up position shown in FIG.

  The specimen cover 3 and the lower cover 4 preferably have a trapezoidal cross section in a plan view in which the width on the near side is smaller than the width on the far side, as can be seen from FIG. In the illustrated example, the specimen cover 3 and the lower cover 4 have a trapezoidal cross section in plan view with a width of about 220 mm on the front side and a width of about 280 mm on the back side. That is, the specimen cover 3 and the lower cover 4 have tapered side surfaces that taper toward the front. By this, the specimen cover 3 is once moved forward and downward by the parallel link structure described below, and then moved downward along the outer surface of the lower cover 4 in front of the lower cover 4. The specimen cover 3 can be lowered along the front surface of the lower cover 4 without causing the specimen cover 3 to interfere with the lower cover 4. Thereby, since the sample cover 3 and the lower cover 4 have the same outer shape, the appearance can be improved.

  As shown in FIG. 27, the specimen cover 3 is provided between a first bracket 90 provided at the rear end of both side portions and a second bracket 91 provided at the front end of both side portions of the main body case 2. The upper and lower links 92 and 93 that are parallel to each other are connected to the main body case 2. By adopting the parallel links 92 and 93, the specimen cover 3 can move up and down along the front surface and both side surfaces of the lower cover 4 while moving in parallel.

  27 and 28, the first bracket 90 has a metal piece 95 extending along the rear edge, and the second bracket 91 faces the metal piece 95 when the specimen cover 3 is closed. Permanent magnets 96 are provided at the positions. Thus, when the specimen cover 3 is displaced to the upper position and closed around the stage 13, the metal piece 95 is attracted by the permanent magnet 96, and the closed position of the specimen cover 3 is held by the magnetic force of the permanent magnet 96. Can do.

  The specimen cover 3 described with reference to FIG. 27 is manually opened and closed. As shown in FIG. 28, an electric motor 98 is provided on the second bracket 91 on the main body case 2 side. For example, the specimen cover 3 can be opened and closed electrically by connecting the upper link 92 with the gear 99 and rotating the electric motor 98 forward or backward.

  When the specimen cover 3 is in the upper position, the upper area of the specimen cover 3 is covered with the heel plate 100, and thus the stage 13 is in a dark room state. The horizontally extending eaves plate 100 is fixed to the lower end of the transmission illumination optical unit 64 in the embodiment, but as a modification, it may be detachably attached to the main body case 2.

  By making the sputum plate 100 detachable, depending on the type of the specimen S, strict light shielding may not be necessary. In such a case, only the specimen cover 3 is moved upward with the sputum plate 100 removed. The image of the specimen S may be captured in a semi-dark room state at the position, that is, the closed position.

  As described above, since the specimen cover 3 is moved up and down along the surface of the lower cover 4, the specimen cover 3 can be used even when the specimen cover 3 is opened and the stage 13 is opened. Since it overlaps with the lower cover 4 in the front-rear direction, the opened specimen cover 3 does not narrow the user's work space.

  As a modification of the embodiment shown in FIG. 26, the specimen cover 3 may be displaced upward to open around the stage 13. Further, as shown in FIG. 29, the periphery of the stage 13 may be opened by moving the specimen cover 3 in a circular arc downward.

  In FIG. 30, a lid 102 that covers the entire upper region of the lower cover 4 is provided, and the rear edge of the top plate 102 a of the lid 102 is hinged to the body case 2 to open and close the lid 102. You may do it.

  Further, as shown in FIG. 31, the specimen cover 3 in which the top plate 102 is integrated may be inserted and removed from the front of the stage 13. That is, the specimen cover 3 with the top plate 102 is detachably attached to the main body case 2 from the front, and when the specimen S is taken in and out, the specimen cover 3 is pulled out from the main body case 2 so that the stage 13 is opened. Also good.

  Further, as shown in FIG. 32, when the specimen cover 3 is divided into left and right, a left divided cover 3L and a right divided cover 3R, and when the periphery of the stage 13 is opened, the left divided cover 3L is temporarily displaced to the left. The right split cover 3R may be displaced once in the right direction and then displaced rearward along the side surface of the main body case 2.

  As shown in FIG. 33 and FIG. 34, a rectangular horizontal tray 105 larger than the stage 13 is provided below and adjacent to the stage 13 as shown in FIGS. A horizontal guide rail 106 extending in the direction may be slidably fitted so that the horizontal tray 105 can be removed forward. As can be seen from FIGS. 33 and 34, the horizontal tray 105 has a slit 105a extending in the front-rear direction toward the side that interferes with the objective lens 28 in order to avoid interference with the objective lens 28. The same width). As a result, the horizontal tray 105 can be disposed deeper than the objective lens 28.

  By providing a detachable horizontal tray 105 below the stage 13, when the specimen S is placed on the stage 13, for example, the specimen culture solution or specimen S is directly below the stage 13 through the light transmission opening of the stage 13. It is possible to prevent the member in the lower region of the stage 13, for example, the objective lens 28 from being contaminated. By providing the horizontal tray 105, when the culture solution or the like is dropped, it is received by the horizontal tray 105. Therefore, the specimen S can be removed simply by pulling out the horizontal tray 105. Thereby, contamination of the objective lens 28 can be prevented, and thereby the maintainability of the microscope 1 can be improved.

  As can be seen from the above description, in the fluorescence microscope 1 of the embodiment, the light source 15 of the transmissive illumination system 10 is disposed sideways, the tilted mirror 17 is provided in the transmissive illumination system 10, and the transmissive illumination light 16 is moved downward along the way. Since the light is refracted, the height dimension of the fluorescence microscope 1 can be greatly reduced. In addition to the imaging system 12 and the transmission and epi-illumination systems 10 and 11, all the power supply units 40, 41 and 42, a power supply board 71, a board such as the controller 73, etc. associated therewith are provided inside the main body case 2. It is mounted with high density. There has never been such a layout of a fluorescence microscope. The fluorescent microscope 1 according to the embodiment includes the above-described V-shaped arrangement of the epi-illumination system 11 and the imaging system 12, and between the trans-illumination system 10 and the epi-illumination system 11 in which the light sources 15 and 20 are disposed sideways. Efforts have been made to reduce the overall dimensions, particularly the height dimension, by devising various places such as arranging the power supply units 40 to 42 in the gap.

  For example, when the power supply units 40 to 42 are arranged under the imaging system 12, not only the height of the fluorescent microscope 1 is increased, but also the heat damage caused by the heat of the power supply units 40 to 42 rising upward. More problems will be added. Further, when the power supply units 40 to 42 are arranged on the sides of the imaging system 12, the transmission illumination system 10, and the epi-illumination illumination system 11, the width dimension of the fluorescence microscope 1 is increased.

  On the other hand, in the fluorescence microscope 1 of the Example which has arrange | positioned the power supply units 40-42 in the clearance gap between the transmission illumination system 10 and the epi-illumination illumination system 11, as mentioned above, the width dimension and height of the fluorescence microscope 1 are mentioned. In addition to the advantage that the size can be reduced, the heat of the power supply units 40 to 42 rises upward, so that the thermal influence of the power supply units 40 to 42 on the epi-illumination system 11 that needs the most heat countermeasures located below it is reduced. Can be minimized.

  Further, the chassis 35 is divided into upper and lower parts and mounted on the power supply units 40 to 42 on the upper chassis 36, while the epi-illumination system 11 surrounded by a heat insulating housing 76 with air cooling measures is mounted on the lower chassis 37. Thus, the thermal expansion of the lower chassis 37 can be minimized. In addition to this, since the unit of the objective lens 28 and the stage 13 is assembled to the lower chassis 37, it is possible to prevent the out-of-focus blur of the objective lens 28 in fluorescence observation over a long period of time. .

  As described above, the fluorescent microscope 1 according to the embodiment employs the transmission illumination system 10 including the light source 15 oriented in the lateral direction, and the epi-illumination system 11 and the imaging system 12 are arranged in a V shape in plan view. The body case 2 having the minimum volume necessary to enclose these three basic components has a compactness that is not comparable to the conventional case, as will be readily understood by those skilled in the art. In addition, in this way, in addition to the imaging system 12, the transmission and epi-illumination systems 10 and 11, the power supply units 40 to 42 that serve as heat sources, the power supply board 71, and the like inside the main body case 2 with a particularly small height. It will be surprising to those skilled in the art that these are mounted at high density. This is practically impossible unless advanced heat countermeasures are taken. In response to this heat countermeasure, an electric fan 38 that has been considered to be avoided in conventional fluorescence microscopes is intentionally adopted to perform forced ventilation. In addition, the halogen lamp 15 and the mercury lamp 20 that generate a large amount of heat are surrounded by the heat insulating housings 61 and 76, and the heat generated by the lamps 15 and 20 is confined, and a large amount of heat in the heat insulating housings 61 and 76 is electrically driven. The air is discharged to the outside by a fan 38. Similarly, the heat absorption filter 75 related to the lamps 15 and 20 is surrounded by the heat insulating housings 61 and 76 so as to be cooled by the air flow generated by the electric fan 38 related to the heat insulating housings 61 and 76. Therefore, thermal saturation of the heat absorption filter 75 can be prevented.

  Further, the interior of the main body case 2 is divided into three regions, upper and lower, and the lowest electric fan 38B is provided for the epi-illumination system 11 and the imaging system 12 located in the lowermost layer, and the power supply unit 40 located in the intermediate layer. ~ 42 are provided with the middle electric fan 38M, and the uppermost electric fan 39T is provided with respect to the transmission illumination system 10 located in the uppermost layer so as to perform forced ventilation in each layer. The thermal effect of can be minimized.

It is an external view of the inverted fluorescence microscope of an Example, and is a perspective view which shows the state which closed the sample cover. It is a figure for demonstrating the usage condition of the fluorescence microscope of an Example. It is a perspective view for demonstrating the layout of the illumination system and imaging system which are included in the inverted fluorescence microscope of an Example. It is a top view for demonstrating the rotation type filter cassette change mechanism contained in the inverted fluorescence microscope of an Example. It is a figure for demonstrating the effect accompanying the planar view V-shaped arrangement | positioning with the epi-illumination system and imaging system which the inverted fluorescence microscope of the Example employ | adopted. It is a disassembled perspective view of the 2 division type chassis which constitutes the frame of the fluorescence microscope of an example. It is a figure for demonstrating arrangement | positioning of the transmission illumination system mounted in a chassis, an epi-illumination illumination system, an imaging system, and various power supply units. It is a figure for demonstrating the specific arrangement | positioning of the power supply unit mounted in a chassis. It is a perspective view which shows the specific structure of the rotary filter cassette change mechanism demonstrated in FIG. It is a perspective view which shows the state which incorporated the rotation type filter cassette change mechanism in the chassis. It is a perspective view of the transmission illumination unit incorporating the heat insulation housing and the optical unit flip-up mechanism included in the transmission illumination system, and is a view of the optical unit in a normal position. It is a top view of the transmission illumination unit of FIG. It is a perspective view corresponding to FIG. 11, and is a figure which shows the state which the optical unit bounced up. It is a perspective view corresponding to FIG. 1 which shows the external appearance of the fluorescence microscope of an Example, and is a figure which shows the state which the transmission illumination optical unit bounced up. It is a figure for demonstrating the modification of the flip-up type | formula transmission illumination optical unit disclosed in FIG. It is a figure for demonstrating the other modification of the flip-up type | formula transmission illumination optical unit disclosed by FIG. It is a figure for demonstrating the specific arrangement | positioning of the various power supply units integrated in an upper chassis. It is a figure for demonstrating the specific arrangement | positioning of the various power supply units and various board | substrates integrated in an upper chassis. It is a figure which shows the state which incorporated the controller in the chassis. It is a figure for demonstrating the structure for forcibly air-cooling the light source contained in an epi-illumination system, and the heat absorption filter adjacent to this. It is a figure for demonstrating the electric fan unit assembled | attached to the rear-end surface of a chassis, and the damping member relevant to this. It is a top view for demonstrating forced air cooling of the upper part of an upper side chassis. It is a bottom view for demonstrating forced air cooling of the lower part of an upper chassis. It is a figure for demonstrating the sample cover contained in the fluorescence microscope of an Example. It is a side view corresponding to FIG. 24 of the fluorescence microscope of an Example. It is a figure for demonstrating the state which displaced the sample cover of the fluorescence microscope of an Example below, and opened the stage periphery. It is a figure for demonstrating the mechanism for displacing a sample cover below. FIG. 28 is a diagram for explaining that opening and closing of a specimen cover can be automated by assembling an electric motor to a mechanism for displacing the specimen cover downward in relation to FIG. 27. It is a figure for demonstrating the modification of the method of displacing a sample cover below. It is a figure for demonstrating the example which replaces with a sample cover and covers the upper area | region of a stage with an opening-and-closing lid. It is a figure for demonstrating the example which displaces a sample cover ahead and opens the stage periphery. It is a figure for demonstrating the example which makes the stage cover open | release by once displacing the sample cover divided into 2 to the side once, and then displacing this backward. It is a figure which shows the example which has arrange | positioned the tray which can be inserted or extracted back and forth under the stage in order to prevent the contamination of the lower area | region of a stage, and is a perspective view which shows the state which installed the tray under the stage. FIG. 34 is a diagram showing an example in which a tray that can be inserted / removed back and forth is disposed below the stage in order to prevent contamination of the lower region of the stage in relation to FIG. It is a perspective view shown.

Explanation of symbols

S Specimen 1 Fluorescence microscope 2 Main body case 3 Specimen cover 10 Transmission illumination system 11 Epi-illumination system 12 Imaging system 13 Stage 15 Halogen lamp (transmission illumination lamp)
Reference Signs List 16 Transmitted illumination light 17 Inclined mirror 28 Objective lens 30 Imaging mirror 31 Imaging cylinder 32 Imaging device (CCD camera)
35 Chassis 36 Upper chassis 37 Lower chassis 38 Electric fan unit 40 Power supply unit for mercury lamp 41 Power supply unit for system 42 Power supply unit for halogen lamp 43 Motor drive circuit board 60 Transmission illumination unit 61 Transmission illumination housing 71 Power supply board 75 Heat absorption filter 76 Epi-illumination housing 85 Damping member (gel, rubber)

Claims (7)

A transmission illumination light source that emits transmission illumination light in a horizontal direction, a transmission illumination system that irradiates transmission illumination light from above toward the specimen on the stage by directing the transmission illumination light emitted by the light source downward;
Light emitted from a light source for excitation light illumination that emits light in a horizontal direction is passed through a heat absorption filter and then converted into excitation light of a specific short wavelength band, and then directed upward and directed from below to a sample on the stage. An epi-illumination system that emits excitation light;
An imaging system that captures an image of the specimen obtained by irradiating the specimen on the stage with an imaging mirror and that is reflected in the lateral direction, and is taken in the lateral direction;
A transmission illumination power supply unit for supplying power to the light source of the transmission illumination system;
An epi-illumination power supply unit for supplying power to the light source of the epi-illumination system;
A power supply board related to the transmission illumination power supply unit and the epi-illumination power supply unit, a chassis on which the transmission illumination system, the epi-illumination illumination system, the imaging system, the transmission illumination power supply unit, and the epi-illumination power supply unit are mounted When,
A case surrounding the chassis,
In the chassis, the imaging system, the epi-illumination system, and the transmission illumination system are arranged in order from the bottom to the top. The transmission illumination power unit, the epi-illumination power unit, and the power substrate Is disposed above the epi-illumination system.   The inverted fluorescence microscope according to claim 1, wherein an electric fan unit is attached to the chassis via a vibration damping member, and the inside of the case is forcibly ventilated by the electric fan unit. A system power supply unit for supplying power to the entire fluorescence microscope system;
The inverted fluorescence microscope according to claim 1 or 2, wherein the system power supply unit is disposed above the epi-illumination system.   The inverted fluorescent microscope according to claim 2, wherein light sources of the epi-illumination system and the transmission illumination system are surrounded by a heat insulating housing, and the heat insulating housing is forcibly ventilated by the electric fan unit. The epi-illumination system and the transmission illumination system further include a heat absorption filter disposed adjacent to the front of the light source included in each illumination system,
The inverted fluorescence microscope according to claim 4, wherein the heat absorption filter is accommodated in the heat insulating housing. The chassis has a two-part structure that is vertically divided into an upper chassis and a lower chassis;
In the upper chassis, the transmission illumination system, the transmission illumination power supply unit, the epi-illumination power supply unit, the power supply board, and the front power supply unit are disposed,
The inverted fluorescence microscope according to claim 5, wherein the imaging system and the epi-illumination system are disposed in the lower chassis.   The inverted fluorescent microscope according to claim 1, wherein the imaging system and the epi-illumination system are arranged in a V shape when viewed in plan.

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