DE102021121696A1 - Sliding unit for positioning an optical element of a microscope and microscope device with the same - Google Patents

Abstract

The present disclosure relates to a sliding unit (10) for positioning an optical element. The slide unit (10) comprises: a handle (110) capable of pivoting at one end thereof about a pivot axis; an intermediate shaft (120) disposed at an end of the handle adjacent the pivot axis and connected to the handle in a relatively non-rotatable manner, the intermediate shaft being capable of rotation about the pivot axis in conjunction with pivoting of the handle ; a pivot rod (130) disposed at an end of said intermediate shaft remote from said handle and connected to said intermediate shaft in a relatively non-rotatable manner; and a slider (140) supporting and holding the optical element (20), the slider being connected to an end of the pivot rod remote from the intermediate shaft so that when the pivot rod (130) pivots, the slider is driven to to move it linearly on a predetermined slide path to bring the optical element held in the slide (140) to different positions. The present disclosure also relates to a microscope device having the slide unit.

Description

technical field

The present disclosure relates to the technical field of a microscope apparatus, and more particularly to a slide unit for positioning an optical element and a microscope apparatus having the slide unit such as. B. an inverted microscope.

background

It is well known that microscope devices, particularly inverted microscopes, have a wide range of applications in medical examination, biological research, and school education.

A conventional inverted microscope typically consists of a top light source, a condenser lens, a stage, an objective lens, a tube lens, a bottom reflector, a phase contrast ring plate, and an eyepiece. These optical lenses form optical paths which are folded forward to form a V-shaped or U-shaped optical path as a whole. The sample on the stage is illuminated through the condenser lens and imaged through the objective lens, and then the image further passes through the tube lens, turns from the bottom reflector to the eyepiece observation tube obliquely above the front of the subject, and then to the human eyes after passing through the eyepiece goes through. The area between the condenser lens and the eyepiece observation tube is an operable space for microscope observation.

Currently, digital devices are widely used in a microscope device for better human-computer interaction. A digital device such as B. a tablet PC can be provided, for example, on a microscope stand to output computer images. Customers can set the location of the digital device according to their own needs. However, the addition of a digital device occupies part of the operable space and inevitably increases the difficulty of operating some components.

In the case where the tablet PC is mounted on an area of the tripod adjacent to the condenser lens, when the tablet PC is adjusted to its lowest position (e.g. along the in 2 Z-direction shown), the slider for supporting the phase contrast ring placed in the condenser lens is completely blocked and the user cannot visualize the position of the slider, nor can he directly perform switching and locating operations on it while the position of the slider needs to be constantly switched during use of the microscope to accommodate different ways of observation in the condenser lens. Therefore, such blockage and interference occurring during use of the microscope apparatus may cause great inconvenience to the user's observation and operation, and reduce the user's convenience.

Accordingly, the present disclosure is intended to solve one or more of the problems in the prior art described above.

Summary of the Invention

In order to solve the problems in the prior art, the present disclosure proposes a slide unit for positioning an optical element, the slide unit making it possible to greatly improve the flexibility of operation of the microscope apparatus as well as the finesse of operation, thus increasing the convenience and improves the convenience of use.

According to an aspect of the present disclosure, there is provided a slide unit for positioning an optical element of a microscope, comprising: a grip capable of pivoting at one end thereof about a pivot axis; an intermediate shaft disposed at an end of the handle adjacent to the pivot axis and connected to the handle in a relatively non-rotatable manner, the intermediate shaft being capable of rotating about the pivot axis in conjunction with pivoting of the handle; a pivot rod disposed at an end of the intermediate shaft remote from the handle and connected to the intermediate shaft in a relatively non-rotatable manner; and a slider that supports and holds the optical element, the slider being connected to an end of the swing rod remote from the intermediate shaft so that when the swing rod pivots, the slider is driven to move linearly on a predetermined slide path, to bring the optical element held in the slider into different positions.

With the slide unit according to the present disclosure, the user-operable handle can be arranged in an appropriate position to obtain a sufficient operable space. In addition, the sliding unit in the present disclosure facilitates the conversion of a large pivoting movement of the user into a fine linear movement of the slider, which increases the flexibility and delicacy of the Improved operation and consequently increased user comfort and convenience.

Advantageously, the slider is connected to the pivot rod by a first connecting structure, the first connecting structure including a first sliding groove and a first key extending into the first sliding groove for engagement therewith. The keyway fit structure is used to form an active connection between the slider and the pivot rod, allowing a driving force to be applied to the slider by pivoting of the pivot rod to cause the slider to move linearly only along the direction of the predetermined sliding track moves. Advantageously, the first sliding groove is provided on the slider and the first key is provided on the pivot rod.

With this configuration, the mass of the slider is reduced, and the whole connection structure is simpler and more compact.

Advantageously, the pivot rod is a variable length telescopic rod.

Advantageously, the pivot rod is pivotally connected to an anchor point on the slider.

Advantageously, the pivot axis of the handle is coaxial with an axis of rotation of the intermediate shaft.

In an advantageous embodiment according to the present disclosure, the handle pivots to rotate the intermediate shaft and the intermediate shaft rotates to pivot the pivot rod, the pivot rod pushing the slider to move it by the first key located in the first sliding groove is to move linearly on a predetermined sliding path.

Advantageously, different positions into which the optical element can be brought include a central position of a beam path of a condenser lens of the microscope.

Advantageously, the intermediate shaft is connected to the pivot rod via a second connection structure, the second connection structure including a second groove and a second key interposed between opposite side walls of the second groove.

Advantageously, the second connection structure is arranged to enable adjustment of a position of the pivot rod relative to the intermediate shaft in a longitudinal direction of the pivot rod. The keyway fitting structure not only allows connection between the intermediate shaft and the pivot rod in a relatively non-rotatable manner, but also adjustment of the position of the pivot rod in the longitudinal direction of the pivot rod relative to the intermediate shaft.

Advantageously, the second groove is located on the pivot bar, extends along the longitudinal direction of the pivot bar and is generally U-shaped, and the second key is located on the intermediate shaft.

Advantageously, the slide unit includes a force adjustment mechanism for adjusting an operating force to be applied to the handle.

Advantageously, the force adjustment mechanism comprises: a stationary housing that receives the intermediate shaft, a first end of the housing being provided with a first stepped hole designed to retain an end flange of the intermediate shaft, an opposite second end of the housing being provided with a second stepped hole is provided with the intermediate shaft protruding from the second stepped hole of the housing; an adjustment nut attached to the intermediate shaft in the second stepped hole, an internal thread of the adjustment nut cooperating with a corresponding external thread on the intermediate shaft to change a relative longitudinal position of the adjustment nut on the intermediate shaft; and an elastic member interposed between a stepped surface of the second stepped hole and a corresponding end surface of the adjusting nut. With the force adjustment mechanism, it is advantageous to prevent the user from inadvertently touching the handle to initiate movement of the slider and to facilitate the user's perception and control of the amount of operating force applied during operation.

Advantageously, the handle is connected to the intermediate shaft on an axial outside of the adjustment nut and the pivot rod is connected to the intermediate shaft on an axial outside of the end flange.

Advantageously, the handle is connected to the intermediate shaft by a third connection structure, the third connection structure including a third sliding groove and a third key extending into the third sliding groove for engagement therewith, the third connection structure being constructed to enable the intermediate shaft moves in a longitudinal direction of the intermediate shaft relative to the handle.

Advantageously, the sliding unit includes a positioning device for holding the Slider in a predetermined position on the sliding track. The positioning device facilitates the user's perception of the actual position of the slider and thus facilitates its precise control over the microscope setting.

Advantageously, the positioning device comprises a positioning groove arranged at a predetermined portion of the slider, and an elastic projection arranged on an outer side of the slider and engaged with the positioning groove.

According to another aspect of the present disclosure, there is provided a microscope apparatus including an optical element and a slide unit for positioning the optical element, the slide unit being the slide unit as described above.

The microscope device is advantageously an inverted microscope.

The optical element is advantageously a phase contrast ring and/or an optical filter and/or a DIC polarizer and/or a plus DIC slot and/or an iHMC module.

The slide unit according to the present disclosure greatly increases the flexibility and finesse of operation of the microscope device, and improves the comfort and convenience of the microscope device. Besides, it adds more possibilities for the structural design of the microscope device.

character list

• 1 ein schematisches Diagramm einer Mikroskopvorrichtung gemäß Ausführungsformen der vorliegenden Offenbarung ist;
• 2 ein teilweises schematisches Diagramm eines Kopfs, an dem ein Tablet-PC installiert ist, eines Stativs der Mikroskopvorrichtung gemäß Ausführungsformen der vorliegenden Offenbarung ist;
• 3 ein schematisches Diagramm einer Kondensorlinsenfassung einer Mikroskopvorrichtung gemäß Ausführungsformen der vorliegenden Offenbarung ist, wobei sich der Schieber in einer ersten Position befindet, in der er von der Kondensorlinsenfassung hervorragt;
• 4 eine Querschnittsansicht einer Schiebeeinheit gemäß Ausführungsformen der vorliegenden Offenbarung ist;
• 5 eine vergrößerte Ansicht eines lokalen Details O in 4 ist;
• 6 eine Draufsicht der Mikroskopvorrichtung gemäß Ausführungsformen der vorliegenden Offenbarung ist, wenn sich der Schieber für den Phasenkontrastring in einer Grenzposition befindet, und
• 7 eine Draufsicht einer Mikroskopvorrichtung gemäß Ausführungsformen der vorliegenden Offenbarung ist, wobei der Schwenkstab als Teleskopstab gestaltet ist.

Preferred embodiments of the present disclosure are described below with reference to the accompanying drawings, in which:

• 1 Figure 12 is a schematic diagram of a microscope device according to embodiments of the present disclosure;
• 2 12 is a partial schematic diagram of a tablet PC installed head of a tripod of the microscope apparatus according to embodiments of the present disclosure;
• 3 12 is a schematic diagram of a condenser lens barrel of a microscope apparatus according to embodiments of the present disclosure, with the slider in a first position protruding from the condenser lens barrel;
• 4 Figure 12 is a cross-sectional view of a slide unit according to embodiments of the present disclosure;
• 5 an enlarged view of a local detail O in 4 is;
• 6 12 is a top view of the microscope apparatus according to embodiments of the present disclosure when the phase contrast ring slider is in a limit position, and
• 7 12 is a top view of a microscope apparatus according to embodiments of the present disclosure, wherein the pivot rod is configured as a telescopic rod.

In order to make the drawings concise, only the parts related to the disclosure are shown schematically in the drawings, but they do not represent the actual structure of the product. In addition, in order to make the drawings simple and easy to understand, in some drawings only one of the components having the same structure or function is shown schematically or only one of them is indicated.

Detailed description of the embodiments

A general diagram of the microscope device 1 (particularly an inverted microscope) according to the present disclosure is shown in FIG 1 shown. The inverted microscope shown comprises a base 30 and a support 40, the support 40 being located at the rear part of the base 30 and arranged in one piece with the base 30 and having a light source 50 provided at its upper end. A condenser lens 60 is provided under the light source, and the condenser lens mount is secured to the support 40 by fasteners such as fasteners. B. Screws suspended. A table 70 is located under the condenser lens 60. An objective lens and a fluorescent light source (not shown) are provided under the table to form an optical path. An eyepiece 80 is provided in front of the base 30 .

Regarding 1 and 2 is a digital device 90 such as e.g. B. a tablet or a display screen in the upper end of the carrier 40 is provided. The position of the digital device 90 can be adjusted as needed in the positions indicated by the arrows R and Z in 2 shown directions. In order to appropriately adjust the position of the phase contrast ring for the condenser lens, the inverted microscope is provided with a sliding unit 10 in the present disclosure. How out 2 As can be seen, even when the digital device 90 is set at the lowest position along the Z-direction, the handle 110 is exposed to the operable space and thus can be seen from the viewpoint seen by the user can still be operated by the user.

With specific reference to 3 According to the disclosure, the main portion of the sliding unit 10 is embedded in the wall of the condenser lens barrel. The exposed portion includes the handle 110 and a slider 140 which slides in the direction over the lens barrel (as indicated by arrow X in Fig 3 shown).

As in 4 , 5 and 6 As shown, the slide unit 10 of the disclosure further comprises: a handle 110 capable of pivoting at one end thereof about a pivot axis; an intermediate shaft 120 disposed at an end of the handle 110 adjacent the pivot axis and connected to the handle in a relatively non-rotatable manner, the intermediate shaft being capable of rotating about the pivot axis in conjunction with pivoting of the handle; a pivot rod 130 disposed at an end of intermediate shaft 120 remote from handle 110 and connected to the intermediate shaft in a relatively non-rotatable manner, and a slider 140 supporting optical element 20 (e.g., a phase contrast ring) and stops, wherein the slider 140 is connected to an end of the pivot rod 130 remote from the intermediate shaft 120, so that when the pivot rod 130 pivots, the slider 140 is driven by the pivot rod to move linearly on a predetermined sliding path to achieve the to bring optical element 20, which is held in the slide, in different positions. Therefore, the slide assembly 10 of the present disclosure allows the handle to be located in a position convenient for operation, as required, while converting the pivotal motion of the handle 110 to linear motion of the slider through the power transmission of the intermediate shaft 120 and pivot rod 130

In the embodiment shown, the pivot axis of the handle 110 is coaxial with an axis of rotation of the intermediate shaft 120 . The handle 110 pivots to rotate the intermediate shaft 120, and the intermediate shaft 120 rotates to pivot the pivot rod 130, which pushes the slider 140 to linearly move it by the first key 152 arranged in the first sliding groove 151 to move on a predetermined sliding track.

in the in 4 and 5 In the embodiment shown, the handle 110 is positioned at the lower end of the housing of the condenser lens mount. The pivot rod 130 extends over the slider 140. The first connection structure 150 between the slider 140 and the pivot rod 130 is a keyway fitting structure having a first sliding groove 151 and a first key 152 extending into the first sliding groove for engagement therewith. In the embodiment shown, the first slide groove 151 is positioned on the slide 140 and the first key 152 which extends into the first slide groove is positioned on one end of the pivot rod 130 . As in 6 As shown, the first wedge 152 moves in the first slide groove 151 in the Y direction while the slide moves in the X direction. The actual trajectory of the first wedge 152 relative to the stationary lens frame actually has an X component and a Y component, with the X component driving the slider 140 to move it in the X direction.

In the embodiment shown, the second connecting structure 160 between the pivot rod and the intermediate shaft is designed to include a second groove 161 and a second key 162 extending into the second groove and being clamped by the opposite side walls of the second groove. and the second connecting structure 160 is constructed to allow adjustment of the position of the pivot rod 130 relative to the intermediate shaft 120 in the longitudinal direction of the pivot rod, thereby adjusting the length of the effective working portion of the pivot rod and the range of movement of the slider 140 in the X-direction. Owing to the adjustability of the second link structure, it is possible to meet the need of adjusting the stroke of a different spool during spool replacement. In the embodiment shown, the second groove 161 is arranged on the pivot rod 130, to be precise, the second groove 161 is designed as a U-shaped groove with two opposite clamping pieces, the U-shaped groove extending along the longitudinal direction of the pivot rod, and the corresponding second key 162 is provided on the intermediate shaft 120 . To avoid relative rotation between the pivot rod and the intermediate shaft, the second key 162 is configured to have flat side surfaces that are designed to abut the corresponding inner side walls of the second groove. In the embodiment shown, the second wedge is tightly clamped by the opposite side walls of the second groove by tightening the fastener (e.g., screw) that passes through the hole located in the opposite side walls of the second groove. A variety of notch positions can of course be provided in the second groove and in each notch position the tight clamping of the second wedge by the second groove can be achieved by an interference fit and consequently the length of the effective working portion of the pivot rod can be adjusted using different notch positions in response be adjusted to different slide strokes.

The drawings show the first connection structure 150 between the pivot rod 130 and the slider 140 and the second connection structure 160 between the pivot rod 130 and the intermediate shaft 120. However, those skilled in the art would readily appreciate that in the keyway fitting structures of the first and second connection structures, the special Arrangements of the wedge structure and the groove structure can be interchanged without any effect on the working efficiency of these components.

As an alternative embodiment of the pivot rod in the form of a single rigid rod shown in the figures, the pivot rod can also be designed as a variable length telescopic rod 130' as shown in FIG 7 shown. For example, the telescopic rod comprises a rod 1301 and a tubular component 1302, with a portion of the rod extending into or moving out of a receiving recess of the tubular component, a resilient member (not shown) interposed between the rod and the tubular component (e.g (e.g., the elastic element is located between an end of the rod that extends into the tubular component and an underside of the receiving recess of the tubular component) and the relative telescoping movement between the rod and the tubular component result in an elastic deformation of the elastic element can; the corresponding end of one of the rod and the tubular component is connected to the slider and the corresponding end of the other of the rod and the tubular component is connected to the intermediate shaft in a relatively non-rotatable manner, for example via the second connection structure. In the case where the pivot rod is designed as a telescopic rod 130', the connection structure 150' between the pivot rod and the slider can be designed as a pivotable connection between the pivot rod and a predetermined anchor point 152' on the slider.

Furthermore, although the drawings show that the pivot rod 130 is positioned above the slider 140, those skilled in the art would readily appreciate that depending on practical needs, the pivot rod 130 may also be positioned below the slider 140, and consequently a driving force on the Slider can be applied from the bottom of the slider.

According to the disclosure, the slide unit 10 further includes a force adjustment mechanism 170 for adjusting the operating force to be applied to the handle. The amount of force that must be applied to the handle can be changed, for example, by providing a device that can change the working length of the handle.

In the embodiment shown, the force adjustment mechanism 170 comprises: a stationary housing 171 which receives the intermediate shaft 120, which housing may be integral with the condenser lens mount or may be integral with the condenser lens mount housing and is fixed to remain stationary or immobile, the upper end 171a of the housing is provided with a first stepped hole 1711 designed to receive an end flange 121 of the intermediate shaft 120, the opposite lower end 171b of the housing is provided with a second stepped hole 1712, with the intermediate shaft 120 differing from the first stepped hole 1711 and the second stepped hole 1712 of the housing 171 and can move longitudinally relative to the housing 171; an adjustment nut 172 joined to the intermediate shaft in the second stepped hole 1712, the internal threads of the adjustment nut 172 engaging the corresponding external threads on the intermediate shaft 120 to change the relative longitudinal position of the adjustment nut on the intermediate shaft; and an elastic member 173 interposed between the stepped surface of the second stepped hole 1712 and the corresponding end surface of the adjusting nut 172. The elastic element can be designed as a coil spring, for example. In the embodiment shown, the coil spring is positioned around the intermediate shaft between the adjustment nut 172 and the stepped surface of the second stepped hole 1712 .

In the embodiment shown, the pivot rod 130 is connected to the intermediate shaft 120 on the axially outer side of the end flange 121 of the intermediate shaft 120 . Of course, those skilled in the art can make changes or variations to the connection position of the pivot rod 130 to the intermediate shaft 120 depending on actual design needs.

The handle 110 is connected to the intermediate shaft 120 on the axial outside of the adjusting nut 172 . The third connection structure 180 between the handle and the intermediate shaft includes a third slide groove 181 and a third key 182 extending into the third slide groove for engagement therewith. In particular, the third sliding groove 181 is arranged on the handle 110 and the third key 182 is arranged on the intermediate shaft 120 . The flat side surface of the key structure on the intermediate shaft 120 fits snugly against the inner side wall of the third sliding groove on the handle 110 to prevent relative rotation between the intermediate shaft and the handle, but this connection structure allows the intermediate shaft 120 to move in the longitudinal direction of the intermediate shaft moved relative to the handle 110.

Regarding 5 the elastic member 173 is designed to be elastically deformed in the longitudinal direction of the intermediate shaft, whereby when the adjusting nut 172 is displaced relative to the intermediate shaft 120 in the direction for pressing the elastic member 173, the elastic force resulting from the deformation of the elastic member 173 results, is increased so that a larger thrust (ie, a reaction force exerted by the elastic member) acts on the upper surface of the adjusting nut, which exerts a greater downward force on the adjusting nut and also the intermediate shaft 120, which causes the adjustment nut 172 to have a tendency to move down with the intermediate shaft 120. Consequently, the end flange 121 formed at the upper end of the intermediate shaft is closer to the annular bottom surface of the first stepped hole 1711, thereby increasing the pressure and friction between the lower annular surface of the end flange and the annular bottom surface of the first stepped hole 1711. In this case, the increased friction means that the resistance to rotation of the intermediate shaft increases, ie, more operator effort is required to turn the handle 110 to drive the intermediate shaft 120 . Consequently, the force adjustment mechanism 170 enables the amount of operating force to be applied to the handle 110 to be controlled.

Regarding 6 the slider unit 10 of the present disclosure further includes a positioning device 190 for holding the slider in a predetermined position on the slider track. The positioning device 190 is designed to produce a clicking sound when the slider is positioned. In the particular embodiment shown, the positioning device 190 includes a positioning groove 191 located at a predetermined portion of the slider and a resilient projection 192 positioned on the outside of the slider and engaging the positioning groove. The projection 192 engages with a positioning groove 191 (not shown) on the slider 140 side, and when the projection 192 enters the positioning groove 191, the user can hear a clicking sound or feel movement resistance with the hand. With this positioning device, it is easy for the user to perceive the moving progress of the slider and make judgments in time.

Although not shown in the drawings, those skilled in the art can readily imagine that the handle 110 could be fitted with a mechanism that adjusts the length of the handle 110, such as a knob. a folding, telescoping or detachable mechanism, according to user preference, the habitual position of use of the digital device 90, e.g. B. a display screen, etc., can be designed.

Although a specific design of the positioning device for generating a click sensation is shown in the drawings, it is readily apparent to those skilled in the art that the positioning device for generating a click sensation can also be located in the connecting structure between the pivot rod and the slider or in the handle, so long a click sensation is generated when the slider reaches a predetermined sliding position, allowing the operator to perceive the moving process.

In the present document, the technical terms "upper" and "lower" refer to the relative positional relationship between the relevant parts in the installed state or operating state of the sliding unit in the particular embodiment shown. However, depending on the specific setup needs or the assembly state of the microscope, those skilled in the art can understand that the slide unit of the disclosure is not limited to the arrangement shown.

In this document, the terms "first", "second", "third", etc. are only used to distinguish one from the other, not to indicate the degree of importance or the order or the prerequisites for their mutual existence, etc.

According to the present disclosure, although the structure of the slide unit is illustrated in the shown embodiment with an example for moving the phase contrast ring, it is readily apparent to those skilled in the art that the slide unit in the present disclosure is not limited to a slider for moving and holding the phase contrast ring is, but also for pushing or moving other optical elements such. B. a light filter can be used.

Industrial Applicability

In order to better understand the present disclosure, the workflow is described below, taking the sliding unit for positioning the phase contrast ring as an example.

In order to improve the resolution of very transparent objects in microscopy, phase contrast is often used to convert phase information of an object into amplitude information through a spatial filter. Consequently, colorless transparent or semi-transparent objects can be clearly seen in the microscope. In particular, the phase contrast ring works on the following principle: Phase contrast imaging means that in the back focal plane of the objective lens or the conjugate position of the back focal plane (where the phase contrast ring is placed), that is, in the position where the angle of light spreads relative to space (the position of the pupil), the light of a certain annular band is selected, the intensity of level 0 light passing through the annular band is reduced to the intensity of level 1 diffracted light, and the phase of the level 0 light µm 180° which is opposite to the phase of the level 1 diffraction light. Consequently, when the light is transformed in phase and intensity at the pupil plane, the lens in the lens frame synthesizes it according to the spatial position and the structural features characterized by the level 1 diffracted light are emphasized in the central image plane and the background becomes darker due to the attenuation of level 0 light.

in the in 6 In the inverted microscope apparatus shown, a phase contrast ring 20 is provided in the right groove of the slider and no phase contrast ring is provided in the left groove 20'. Consequently, a different sliding position of the slider corresponds to a different observation mode of the microscope, and when the phase contrast ring 20 enters the center of the optical path of the condenser lens, the microscope enters the phase contrast observation mode.

When referring to 3-6 the user, facing the tablet PC, pivots the handle 110 in the direction S to the right, as shown in FIG 3 As shown, the intermediate shaft 120 is driven to rotate about the pivot axis, and the rotation of the intermediate shaft drives the pivoting of the pivot rod 130 (a counterclockwise pivot indicated by arrow P in Fig 6 is shown). Pivoting of the pivot rod 130 exerts a thrust on the side wall (i.e. the left side wall of the slide groove shown in 6 shown) of the slider's sliding groove via a wedge structure at the end of the pivot rod, causing the slider to move to the left in the X-direction, and the positioning device 190 produces a clicking sound in the position where the phase contrast ring 20 or a other optical element aligns with the condenser lens, and the operator can hear the clicking sound or feel the resistance to movement with his/her hand to determine where to stop panning the handle. At this time, the relevant optical element such as e.g. B. the phase contrast ring in the center of the beam path of the condenser lens, and the relevant observation mode of the microscope such. B. Phase contrast observation mode is ready.

When it is unnecessary to observe with a phase contrast ring, operating the handle in the opposite direction moves and brings the slider to a position where the groove 20' is aligned with the condenser lens.

Although the phase contrast ring is used as an example in the above embodiments, those skilled in the art will readily appreciate that the sliding unit of the present disclosure can be used to move one or more of the light filter, the DIC polarizer, the plus DIC slit and of the iHMC module.

The foregoing is only a preferred embodiment of the present disclosure and is not intended to limit the disclosure, and those skilled in the art can make various improvements and modifications to the device of the disclosure without departing from the spirit of the disclosure. Other embodiments may also be obtained by persons skilled in the art by considering what is disclosed in the present specification. The present specification and examples should be considered as exemplary only, and the true scope of the disclosure is determined by the appended claims and their equivalents.

Claims (19)

A slide unit (10) for positioning an optical element of a microscope, characterized by comprising: a handle (110) capable of pivoting at one end thereof about a pivot axis; an intermediate shaft (120) disposed at an end of the handle adjacent the pivot axis and connected to the handle in a relatively non-rotatable manner, the intermediate shaft being capable of rotation about the pivot axis in conjunction with pivoting of the handle ; a pivot rod (130) disposed at an end of said intermediate shaft remote from said handle and connected to said intermediate shaft in a relatively non-rotatable manner; and a slider (140) supporting and holding the optical element (20), the slider being connected to an end of the pivot rod remote from the intermediate shaft so that when the pivot rod (130) pivots, the slider is driven to to move it linearly on a predetermined sliding path in order to to bring the optical element held in the slide (140) into different positions. sliding unit (10) after claim 1 , characterized in that the slider (140) is connected to the pivot rod (130) by a first connection structure (150) comprising a first sliding groove (151) arranged on the slider (140) and a first key (152) disposed on the pivot rod (130) and extending into the first slide groove for engagement therewith. sliding unit (10) after claim 1 , characterized in that the swivel rod is a telescopic rod with a variable length. sliding unit (10) after claim 3 , characterized in that the pivot rod is pivotally connected to an anchor point on the slide. sliding unit (10) after claim 1 , characterized in that the pivot axis of the handle is coaxial with an axis of rotation of the intermediate shaft. sliding unit (10) after claim 2 , characterized in that the handle (110) pivots to rotate the intermediate shaft (120) and the intermediate shaft (120) rotates to pivot the pivot rod (130) which pushes the slider (140) to pass it linearly move the first wedge (152) disposed in the first slide groove (151) on the predetermined slide path. sliding unit (10) after claim 1 , characterized in that the different positions in which the optical element is placed include a central position of an optical path of a condenser lens of the microscope. sliding unit (10) after claim 1 , characterized in that the intermediate shaft (120) is connected to the pivot rod (130) via a second connection structure (160) having a second groove (161) and a second key (162) interposed between opposite side walls of the second groove , includes. sliding unit (10) after claim 8 , characterized in that the second connection structure is adapted to allow adjustment of a position of the pivot rod (130) relative to the intermediate shaft (120) in a longitudinal direction of the pivot rod. sliding unit (10) after claim 9 , characterized in that the second groove is provided on the pivot rod, extends along the longitudinal direction of the pivot rod and is approximately U-shaped, and the second spline is provided on the intermediate shaft. Sliding unit (10) according to one of Claims 1 until 10 , characterized in that the sliding unit comprises a force adjustment mechanism (170) for adjusting an operating force to be applied to the handle. sliding unit (10) after claim 11 , characterized in that the force adjusting mechanism (170) comprises: a stationary housing (171) accommodating the intermediate shaft (120), a first end (171a) of the housing being provided with a first stepped hole (1711) designed for supporting an end flange (121) of the intermediate shaft, an opposite second end (171b) of the housing being provided with a second stepped hole (1712), the intermediate shaft (120) protruding from the second stepped hole of the housing; an adjustment nut (172) attached to the intermediate shaft (120) in the second stepped hole (1712), an internal thread of the adjustment nut cooperating with a corresponding external thread on the intermediate shaft to change a relative longitudinal position of the adjustment nut on the intermediate shaft (120). ; and an elastic member (173) interposed between a stepped surface of said second stepped hole (1712) and a corresponding end surface of said adjusting nut (172). sliding unit (10) after claim 12 , characterized in that the handle (110) is connected to the intermediate shaft (120) on an axial outside of the adjusting nut (172), and the pivot rod (130) is connected to the intermediate shaft (120) on an axial outside of the end flange (121). is. sliding unit (10) after claim 12 , characterized in that the handle (110) is connected to the intermediate shaft (120) by a third connection structure (180), the third connection structure (180) having a third sliding groove (181) and a third key (182) located in the third sliding groove extends to engage therewith, the third link structure being constructed to allow the intermediate shaft (120) to move in a longitudinal direction of the intermediate shaft relative to the handle (110). Sliding unit (10) according to one of Claims 1 until 10 , characterized in that the slide unit (10) comprises a positioning device (190) for holding the slide in a predetermined position on the slideway. sliding unit (10) after claim 15 , characterized in that the positioning device (190) has a positioning groove (191) which is arranged on a predetermined portion of the slider (140), and an elastic projection (192) which is positioned on an outer side of the slider and with the positioning groove in Intervention is included. Microscope device (1) with an optical element (20) and a sliding unit (10) for positioning the optical element, characterized in that the sliding unit, the sliding unit (10) according to one of Claims 1 - 16 is. Microscope device (1) after Claim 17 , characterized in that the microscope device is an inverted microscope. Microscope device (1) after Claim 17 , characterized in that the optical element (20) is a phase contrast ring and/or an optical filter and/or a DIC polarizer and/or a plus DIC slot and/or an iHMC module.

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