CN219590612U - Optical microscope digital scanning integrated machine - Google Patents

Abstract

The utility model relates to the technical field of pathological film reading equipment, in particular to an optical microscope digital scanning integrated machine, which solves the problem that the pathological film reading efficiency in the prior art is to be improved. The digital scanning integrated machine of the optical microscope comprises a scanner, a microscope, a reading ocular installed on the microscope and a lens outlet arranged on one side of the scanner, wherein the scanner and the microscope are both installed on a base. According to the utility model, the bidirectional motor is controlled to move so as to enable the side plate to horizontally move along the movable groove, and the movable table horizontally moves relative to the side plate, so that the extending end of the movable table stretches into the scanning groove, after the scanning result of the scanner comes out, the movable table is reset to the position right below the film reading ocular, one-time film reading and scanning of pathological sections are completed, the positioning time of scanning is saved, the positioning time of limiting film reading is shortened, the time of taking and moving pathological sections is saved, and the scanning analysis efficiency of pathological section film reading is improved.

Description

Optical microscope digital scanning integrated machine

Technical Field

The utility model relates to the technical field of pathological film reading equipment, in particular to a digital scanning integrated machine of an optical microscope.

Background

The pathological examination is to check pathological sections through a microscope and scan pathological results by a scanner to obtain characteristic conclusions of the pathological sections. Therefore, when the existing pathological section is read, a microscope is needed, a scanner is needed, and in the actual section reading operation process, after the section is read by the microscope, the section is required to be taken down from the microscope and then moved into the scanner for scanning, so that the section reading time of the pathological section is very influenced.

Therefore, an optical microscope digital scanning all-in-one machine is now proposed, and through combining a microscope and a scanner, the automatic positioning of pathological sections can be realized by improving the film reading fixed table, and the efficient operation of scanning of the microscope and the scanner is realized, so that the efficiency of the existing pathological film reading is improved.

Disclosure of Invention

The utility model aims to provide an optical microscope digital scanning integrated machine, which solves the problem that the efficiency of pathological film reading in the prior art is to be improved.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

the utility model provides an optical microscope digital scanning all-in-one, includes scanner, microscope, installs the reading eyepiece on the microscope and sets up the play piece mouth in scanner one side, scanner and microscope are all installed on the base, still include:

the fixed table is fixedly arranged on the microscope, a movable groove is formed between the bottom of the fixed table and the microscope, and a bidirectional motor is arranged in the movable groove;

the movable table is arranged on the upper end face of the fixed table, the scanner is attached to the side face of the microscope, the scanning groove of the scanner is arranged on one side facing the movable table, the lower end face of the scanning groove is flush with the upper end face of the fixed table, the upper end face of the movable table is provided with a placing groove, two clamping plates are symmetrically arranged in the placing groove, and a sliding plate is arranged on the outer side of the movable table in a limiting sliding manner and is pulled to enable the two clamping plates to clamp a column pathological section;

the side plates are provided with two groups, the two groups are respectively positioned on the front side and the rear side of the fixed table, the inner side end surfaces of the two side plates are attached to the outer wall of the movable table, the bottom ends of the side plates extend into the movable groove, and the two-way motor is fixedly connected with the two side plates so as to drive the side plates to horizontally move in the movable groove and between the movable table and the side plates.

Preferably, the inner groove is formed in the lower end face of the mobile station, so that the lower end face of the mobile station is of an L-shaped structure, the opening of the L-shaped structure faces one side far away from the scanning groove, a plurality of positioning teeth are arranged in the inner groove at equal intervals, the lower end face of the mobile station is attached to the fixed table, a first toothed roller is arranged in the inner groove and is meshed with the positioning teeth, a transmission cavity is formed in the side plate, and two ends of the first toothed roller movably penetrate into the transmission cavity.

Preferably, the two output shafts of the bidirectional motor are respectively connected with a second toothed roller in a transmission way, the extending end of the second toothed roller penetrates into the transmission cavity, the first toothed roller and the second toothed roller are connected through belt transmission, a plurality of limit teeth are arranged on the lower end face of the fixed table at equal intervals, and the second toothed roller is meshed with the limit teeth for transmission.

Preferably, at least two side plates positioned at the front side or the rear side of the moving table are arranged, and the distance from the bidirectional motor to one end of the movable groove is equal to the distance from the first toothed roller to the end of the moving table and is equal to the depth of the scanning groove.

Preferably, the limiting groove is formed in the placing groove, the sliding groove is formed in the side end face of the mobile station, the sliding plate is limited to slide in the sliding groove, one end of the sliding plate penetrates out of the mobile station and is movably connected with the shifting plate through the pin shaft, the positioning protruding blocks are fixedly arranged on the inner side of the shifting plate, a plurality of round holes are formed in the inner side of the sliding groove at equal intervals, the inner diameter of each round hole is larger than the width of the sliding groove, and the positioning protruding blocks are in limiting insertion connection with the round holes to limit the sliding plate to move.

Preferably, the movable table is of a cavity structure, a square rod is fixedly arranged at the position of the axis in the movable table, a first sliding rod and a second sliding rod are symmetrically sleeved on the square rod, the first sliding rod and the second sliding rod are connected through a pull rope, one end of the second sliding rod is fixedly connected with the sliding plate, and accordingly the sliding plate is pulled to move relatively.

Preferably, the bottom of splint runs through the spacing groove, and is connected with corresponding first slide bar or second slide bar, the cover is equipped with the spring on the square pole, and the both ends of spring offset with first slide bar and second slide bar respectively, and the spring is extrusion spring.

Preferably, a limiting wheel is arranged in the mobile station, and the pull rope connected with the first sliding rod is connected with the second sliding rod after bypassing the limiting wheel.

The utility model has at least the following beneficial effects:

1. through placing pathological section in the standing groove of mobile station, realize pathological section's automatic centering location through pulling the slide, observe pathological section back through the reading eyepiece, control two-way motor removal, so that curb plate along movable groove horizontal migration, mobile station is for curb plate horizontal migration simultaneously, when so that the curb plate removes to offset with movable groove one end, the extension end of mobile station stretches into in the scanning groove, scan, at this moment, the operator can at first carry out analysis to the microscope's reading result, the scanning result of scanner comes out the back, the mobile station resets to read under the eyepiece, once read piece and the scanning of pathological section are accomplished, compare in the mode of current manual movement pathological section, the positioning time of scanning has been saved, the spacing positioning time of reading the piece has been shortened, the time of taking the removal pathological section has been saved, optical microscope digital scanning all-in-one, pathological section reads the piece scanning analysis efficiency has been improved.

2. Through utilizing the meshing transmission of two-way motor drive second fluted roller and spacing tooth to realize the removal of curb plate for the fixed station, through utilizing the meshing transmission of first fluted roller and positioning tooth, with the realization mobile station compare in the removal of curb plate, thereby make the mobile station to the time of the removal of scanning groove shorten generally, further improved pathology and read the use operating efficiency of piece scanning all-in-one.

3. Through rotating the shifting plate, sliding the slide plate to make two splint clip pathological section, then rotate the shifting plate, make the inboard location lug of shifting plate spacing in the round hole that corresponds, thereby realized a pathology that can swiftly fix a position pathological section reads the film scanning all-in-one.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings required for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present utility model, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of a front view of a pathology film scanning integrated machine;

FIG. 2 is a schematic side sectional view of a mobile station, a stationary station and a side plate;

FIG. 3 is a schematic diagram of a mating structure of a mobile station and a first toothed roller;

FIG. 4 is a schematic top view of a fixture table;

fig. 5 is a schematic cross-sectional view of a mobile station.

In the figure: 1. a base; 2. a scanner; 3. a microscope; 4. a sheet outlet; 5. a scanning groove; 6. a reading eyepiece; 7. a mobile station; 8. a side plate; 9. a fixed table; 10. a movable groove; 11. an inner tank; 12. positioning teeth; 13. a first toothed roller; 14. a round hole; 15. a transmission cavity; 16. a bi-directional motor; 17. a second toothed roller; 18. limit teeth; 19. a placement groove; 20. a limit groove; 21. a clamping plate; 22. a poking plate; 23. square bar; 24. a first slide bar; 25. a second slide bar; 26. a slide plate; 27. a chute; 28. and positioning the protruding blocks.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Example 1

Referring to fig. 1-5, the optical microscope digital scanning all-in-one machine comprises a scanner 2, a microscope 3, a reading eyepiece 6 arranged on the microscope 3, and a sheet outlet 4 arranged on one side of the scanner 2, wherein the scanner 2 and the microscope 3 are arranged on a base 1, and the optical microscope digital scanning all-in-one machine further comprises:

the fixed table 9, the fixed table 9 is fixedly arranged on the microscope 3, a movable groove 10 is formed between the bottom of the fixed table 9 and the microscope 3, and a bidirectional motor 16 is arranged in the movable groove 10;

the movable table 7 is arranged on the upper end surface of the fixed table 9, the scanner 2 is attached to the side surface of the microscope 3, the scanning groove 5 of the scanner 2 is arranged on one side facing the movable table 7, the lower end surface of the scanning groove 5 is flush with the upper end surface of the fixed table 9, the upper end surface of the movable table 7 is provided with a placing groove 19, two clamping plates 21 are symmetrically arranged in the placing groove 19, a sliding plate 26 is arranged on the outer side of the movable table 7 in a limiting sliding manner, and the sliding plate 26 is pulled to enable the two clamping plates 21 to clamp a column pathological section;

the side plates 8 are provided with two groups, the two groups are respectively positioned at the front side and the rear side of the fixed table 9, the inner side end surfaces of the two side plates 8 are attached to the outer wall of the movable table 7, the bottom ends of the side plates 8 extend into the movable groove 10, and the two-way motor 16 is fixedly connected with the two side plates 8 to drive the side plates 8 to horizontally move in the movable groove 10 and horizontally move between the movable table 7 and the side plates 8;

in this embodiment: through placing pathological section in the standing groove 19 of mobile station 7, realize pathological section's automatic centering location through pulling slide 26, observe pathological section through reading eyepiece 6 after, control bi-directional motor 16 removes, so that curb plate 8 moves along movable groove 10 horizontal migration, mobile station 7 moves for curb plate 8 horizontal migration simultaneously, when so that curb plate 8 moves to offseting with movable groove 10 one end, mobile station 7's extension end stretches into scanning inslot 5, scan, at this moment, the operator can carry out analysis at first to the film reading result of microscope, scanner 2's scanning result comes out the back, mobile station 7 resets to read under the film reading eyepiece 6, accomplish pathological section's one time and read, compare with the mode that current manual work moved pathological section, the positioning time of scanning has been saved, the positioning time of spacing piece has been shortened, read and move pathological section's time has been saved, optical microscope digital scanning all-in-one, pathological section scanning efficiency has been improved.

Example two

Referring to fig. 1-5, the optical microscope digital scanning all-in-one machine comprises a scanner 2, a microscope 3, a reading eyepiece 6 arranged on the microscope 3, and a sheet outlet 4 arranged on one side of the scanner 2, wherein the scanner 2 and the microscope 3 are arranged on a base 1, and the optical microscope digital scanning all-in-one machine further comprises:

the fixed table 9, the fixed table 9 is fixedly arranged on the microscope 3, a movable groove 10 is formed between the bottom of the fixed table 9 and the microscope 3, and a bidirectional motor 16 is arranged in the movable groove 10;

the movable table 7 is arranged on the upper end surface of the fixed table 9, the scanner 2 is attached to the side surface of the microscope 3, the scanning groove 5 of the scanner 2 is arranged on one side facing the movable table 7, the lower end surface of the scanning groove 5 is flush with the upper end surface of the fixed table 9, the upper end surface of the movable table 7 is provided with a placing groove 19, two clamping plates 21 are symmetrically arranged in the placing groove 19, a sliding plate 26 is arranged on the outer side of the movable table 7 in a limiting sliding manner, and the sliding plate 26 is pulled to enable the two clamping plates 21 to clamp a column pathological section;

the side plates 8 are provided with two groups, the two groups are respectively positioned at the front side and the rear side of the fixed table 9, the inner side end surfaces of the two side plates 8 are attached to the outer wall of the movable table 7, the bottom ends of the side plates 8 extend into the movable groove 10, and the two-way motor 16 is fixedly connected with the two side plates 8 to drive the side plates 8 to horizontally move in the movable groove 10 and horizontally move between the movable table 7 and the side plates 8;

an inner groove 11 is formed in the lower end face of the mobile station 7, so that the lower end face of the mobile station 7 is of an L-shaped structure, an opening of the L-shaped structure faces to one side far away from the scanning groove 5, a plurality of positioning teeth 12 are equidistantly arranged in the inner groove 11, the lower end face of the mobile station 7 is attached to the fixed station 9, a first tooth roller 13 is arranged in the inner groove 11, the first tooth roller 13 is meshed with the positioning teeth 12, a transmission cavity 15 is formed in the side plate 8, and two ends of the first tooth roller 13 movably penetrate into the transmission cavity 15; the two output shafts of the bidirectional motor 16 are respectively connected with a second toothed roller 17 in a transmission way, the extending end of the second toothed roller 17 penetrates into the transmission cavity 15, the first toothed roller 13 and the second toothed roller 17 are connected through belt transmission, a plurality of limit teeth 18 are equidistantly arranged on the lower end surface of the fixed table 9, and the second toothed roller 17 is meshed with the limit teeth 18 for transmission; the side plates 8 positioned at the front side or the rear side of the moving table 7 are provided with at least two, and the distance from the two-way motor 16 to one end of the movable groove 10 is equal to the distance from the first toothed roller 13 to the end of the moving table 7 and is equal to the depth of the scanning groove 5;

in this embodiment: the second toothed roller 17 is driven by the bidirectional motor 16 to be in meshed transmission with the limiting teeth 18 so as to realize the movement of the side plate 8 relative to the fixed table 9, and the first toothed roller 13 is utilized to be in meshed transmission with the positioning teeth 12 so as to realize the movement of the mobile table 7 relative to the side plate 8, so that the time for moving the mobile table 7 to the scanning groove 5 is shortened generally, and the use operation efficiency of the pathology film scanning all-in-one machine is further improved.

Example III

Referring to fig. 1-5, the optical microscope digital scanning all-in-one machine comprises a scanner 2, a microscope 3, a reading eyepiece 6 arranged on the microscope 3, and a sheet outlet 4 arranged on one side of the scanner 2, wherein the scanner 2 and the microscope 3 are arranged on a base 1, and the optical microscope digital scanning all-in-one machine further comprises:

the fixed table 9, the fixed table 9 is fixedly arranged on the microscope 3, a movable groove 10 is formed between the bottom of the fixed table 9 and the microscope 3, and a bidirectional motor 16 is arranged in the movable groove 10;

the movable table 7 is arranged on the upper end surface of the fixed table 9, the scanner 2 is attached to the side surface of the microscope 3, the scanning groove 5 of the scanner 2 is arranged on one side facing the movable table 7, the lower end surface of the scanning groove 5 is flush with the upper end surface of the fixed table 9, the upper end surface of the movable table 7 is provided with a placing groove 19, two clamping plates 21 are symmetrically arranged in the placing groove 19, a sliding plate 26 is arranged on the outer side of the movable table 7 in a limiting sliding manner, and the sliding plate 26 is pulled to enable the two clamping plates 21 to clamp a column pathological section;

the side plates 8 are provided with two groups, the two groups are respectively positioned at the front side and the rear side of the fixed table 9, the inner side end surfaces of the two side plates 8 are attached to the outer wall of the movable table 7, the bottom ends of the side plates 8 extend into the movable groove 10, and the two-way motor 16 is fixedly connected with the two side plates 8 to drive the side plates 8 to horizontally move in the movable groove 10 and horizontally move between the movable table 7 and the side plates 8;

an inner groove 11 is formed in the lower end face of the mobile station 7, so that the lower end face of the mobile station 7 is of an L-shaped structure, an opening of the L-shaped structure faces to one side far away from the scanning groove 5, a plurality of positioning teeth 12 are equidistantly arranged in the inner groove 11, the lower end face of the mobile station 7 is attached to the fixed station 9, a first tooth roller 13 is arranged in the inner groove 11, the first tooth roller 13 is meshed with the positioning teeth 12, a transmission cavity 15 is formed in the side plate 8, and two ends of the first tooth roller 13 movably penetrate into the transmission cavity 15; the two output shafts of the bidirectional motor 16 are respectively connected with a second toothed roller 17 in a transmission way, the extending end of the second toothed roller 17 penetrates into the transmission cavity 15, the first toothed roller 13 and the second toothed roller 17 are connected through belt transmission, a plurality of limit teeth 18 are equidistantly arranged on the lower end surface of the fixed table 9, and the second toothed roller 17 is meshed with the limit teeth 18 for transmission; the side plates 8 positioned at the front side or the rear side of the moving table 7 are provided with at least two, and the distance from the two-way motor 16 to one end of the movable groove 10 is equal to the distance from the first toothed roller 13 to the end of the moving table 7 and is equal to the depth of the scanning groove 5;

the limiting groove 20 is formed in the placing groove 19, the sliding groove 27 is formed in the side end face of the mobile station 7, the sliding plate 26 is limited to slide in the sliding groove 27, one end of the sliding plate 26 penetrates out of the mobile station 7 and is movably connected with the shifting plate 22 through a pin shaft, the positioning protruding block 28 is fixedly arranged on the inner side of the shifting plate 22, the inner side of the sliding groove 27 is equidistantly provided with a plurality of round holes 14, the inner diameter of the round hole 14 is larger than the width of the sliding groove 27, and the positioning protruding block 28 is limited to be inserted with the round hole 14 in a limiting mode so as to limit the sliding plate 26 to move; the movable table 7 is of a cavity structure, a square rod 23 is fixedly arranged at the position of the axial line in the movable table 7, a first slide rod 24 and a second slide rod 25 are symmetrically sleeved on the square rod 23, the first slide rod 24 and the second slide rod 25 are connected through a pull rope, one end of the second slide rod 25 is fixedly connected with a slide plate 26, so that the slide plate 26 is pulled, and the first slide rod 24 and the second slide rod 25 move relatively; the bottom of the clamping plate 21 penetrates through the limiting groove 20 and is connected with a corresponding first sliding rod 24 or second sliding rod 25, a square rod 23 is sleeved with a spring, two ends of the spring respectively prop against the first sliding rod 24 and the second sliding rod 25, and the spring is an extrusion spring; a limiting wheel is arranged in the mobile station 7, and a pull rope connected with the first sliding rod 24 bypasses the limiting wheel and is connected with the second sliding rod 25;

in this embodiment: through rotating the poking plate 22, sliding the sliding plate 26 to make two splint 21 clip the pathological section, then rotate the poking plate 22, make the inboard location lug 28 of poking plate 22 spacing in corresponding round hole 14, thereby realized a pathology that can swiftly fix a position pathological section read the film scanning all-in-one.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made therein without departing from the spirit and scope of the utility model, which is defined by the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (8)

1. The utility model provides an optical microscope digital scanning all-in-one, includes scanner (2), microscope (3), installs reading eyepiece (6) on microscope (3) and sets up piece mouth (4) in scanner (2) one side, scanner (2) and microscope (3) are all installed on base (1), its characterized in that still includes:

the fixed table (9), the fixed table (9) is fixedly arranged on the microscope (3), a movable groove (10) is formed between the bottom of the fixed table (9) and the microscope (3), and a bidirectional motor (16) is arranged in the movable groove (10);

the mobile station (7), mobile station (7) sets up at fixed station (9) up end, scanner (2) laminating microscope (3) side sets up, scanning groove (5) of scanner (2) set up in the one side towards mobile station (7), and the lower terminal surface of scanning groove (5) flushes with the up end of fixed station (9), standing groove (19) have been seted up to the up end of mobile station (7), the symmetry is provided with two splint (21) in standing groove (19), the outside limiting slip of mobile station (7) is provided with slide (26), pulls slide (26) to make two splint (21) clamp post pathological section;

curb plate (8), curb plate (8) are provided with two sets of, and two sets of both sides around being located fixed station (9) respectively, the inboard terminal surface of two curb plates (8) is laminated with the outer wall of mobile station (7), in the bottom of curb plate (8) stretches into movable groove (10), bi-directional motor (16) and two curb plate (8) fixed connection to drive curb plate (8) horizontal migration in movable groove (10), and the horizontal migration between mobile station (7) and the curb plate (8).

2. The optical microscope digital scanning all-in-one machine according to claim 1, wherein an inner groove (11) is formed in the lower end face of the mobile station (7) so that the lower end face of the mobile station (7) is of an L-shaped structure, an opening of the L-shaped structure faces to one side far away from the scanning groove (5), a plurality of positioning teeth (12) are equidistantly arranged in the inner groove (11), the lower end face of the mobile station (7) is attached to the fixed station (9), a first toothed roller (13) is arranged in the inner groove (11), the first toothed roller (13) is meshed with the positioning teeth (12), a transmission cavity (15) is formed in the side plate (8), and two ends of the first toothed roller (13) movably penetrate into the transmission cavity (15).

3. The optical microscope digital scanning all-in-one machine according to claim 2, wherein two output shafts of the bidirectional motor (16) are respectively connected with a second toothed roller (17) in a transmission manner, the extending end of the second toothed roller (17) penetrates into the transmission cavity (15), the first toothed roller (13) and the second toothed roller (17) are connected through belt transmission, a plurality of limit teeth (18) are arranged on the lower end face of the fixed table (9) at equal intervals, and the second toothed roller (17) is in meshed transmission with the limit teeth (18).

4. The optical microscope digital scanning all-in-one machine according to claim 1, characterized in that the side plate (8) located at the front side or the rear side of the moving stage (7) is provided with at least two, the distance from the bi-directional motor (16) to one end of the movable slot (10) is equal to the distance from the first toothed roller (13) to the end of the moving stage (7) and is equal to the depth of the scanning slot (5).

5. The optical microscope digital scanning all-in-one machine according to claim 1, wherein the limiting groove (20) is formed in the placing groove (19), the sliding groove (27) is formed in the side end face of the mobile station (7), the sliding plate (26) is limited to slide in the sliding groove (27), one end of the sliding plate (26) penetrates out of the mobile station (7) and is movably connected with the shifting plate (22) through the pin shaft, the positioning protruding blocks (28) are fixedly arranged on the inner side of the shifting plate (22), a plurality of round holes (14) are formed in the inner side of the sliding groove (27) at equal intervals, the inner diameter of the round holes (14) is larger than the width of the sliding groove (27), and the positioning protruding blocks (28) are in limiting insertion connection with the round holes (14) to limit the movement of the sliding plate (26).

6. The integrated digital scanning optical microscope according to claim 1, wherein the mobile station (7) has a cavity structure, a square rod (23) is fixedly installed at the position of the axis in the mobile station (7), a first sliding rod (24) and a second sliding rod (25) are symmetrically sleeved on the square rod (23), the first sliding rod (24) and the second sliding rod (25) are connected through a pull rope, and one end of the second sliding rod (25) is fixedly connected with a sliding plate (26) so as to enable the sliding plate (26) to be pulled, and the first sliding rod (24) and the second sliding rod (25) move relatively.

7. The integrated digital scanning optical microscope machine according to claim 6, wherein the bottom of the clamping plate (21) penetrates through the limiting groove (20) and is connected with the corresponding first sliding rod (24) or second sliding rod (25), springs are sleeved on the square rods (23), two ends of each spring respectively abut against the first sliding rod (24) and the second sliding rod (25), and the springs are extrusion springs.

8. The integrated digital scanning optical microscope according to claim 1, wherein a limiting wheel is installed in the mobile station (7), and the pull rope connected with the first sliding rod (24) bypasses the limiting wheel and is connected with the second sliding rod (25).