CN112629911A - Gynecological tumor sampling device - Google Patents

Abstract

The invention discloses a gynecological tumor sampling device which comprises an outer tube, a sample tube and a piston, wherein the sample tube is arranged in the outer tube in a sliding mode, the piston is arranged in the sample tube in a sliding mode, a rotating rod is fixed at one end of the piston, a push rod is arranged in the sample tube in a sliding mode, a linkage assembly used for driving the sample tube and the rotating rod to rotate is arranged on the push rod, a cutting assembly used for cutting a sample is arranged on the sample tube, the tumor sample can be cut and taken out quickly, and the operation is simple and rapid.

Description

Gynecological tumor sampling device

Technical Field

The invention relates to the technical field of gynecological tumors, in particular to a gynecological tumor sampling device.

Background

Common gynecological tumors include vulvar tumor, vaginal tumor, uterine tumor, ovarian tumor and fallopian tube tumor. The tumors of uterus and ovary are common, and the tumors of vulva and fallopian tube are rare. When the gynecological tumor is determined to be benign or malignant, the gynecological tumor body needs to be sampled and tested by the tumor sampling device, so that the nature of the tumor is judged.

The existing tumor sampling device usually adopts a professional equipment instrument to sample the tumor, and the operation process of the equipment is complex and the production cost is high, so that the improvement space exists.

Disclosure of Invention

The invention aims to provide a gynecological tumor sampling device which can cut and take out a tumor sample quickly and is simple and quick to operate.

The technical purpose of the invention is realized by the following technical scheme:

a gynecological tumor sampling device comprises an outer tube, a sample tube arranged in the outer tube in a sliding manner, and a piston arranged in the sample tube in a sliding manner, wherein a rotating rod is fixed at one end of the piston, a push rod is arranged in the sample tube in a sliding manner, a linkage assembly for driving the sample tube and the rotating rod to rotate is arranged on the push rod respectively, the linkage assembly comprises a first sliding block and a second sliding block which are arranged on the push rod in a sliding manner, rotating discs are arranged in the rotating rod and the sample tube in a rotating manner, the push rod penetrates through the rotating discs of stations where the sample tubes are located, the first sliding block and the second sliding block are located between the two groups of rotating discs, abutting blocks are symmetrically and slidably arranged in the two groups of rotating discs, linkage rods are symmetrically and rotatably arranged on the side walls of the first sliding block and the second sliding block, one ends, far away from the first sliding block, of the two groups, and one ends of the two groups of linkage rods of the station where the second sliding block is located, which are far away from the second sliding block, are in running fit with the two groups of abutting blocks of the station where the sample tube is located, and the sample tube is provided with a cutting assembly for cutting a sample.

By adopting the technical scheme, a worker firstly pushes the push rod to move towards the direction of the sample tube, the push rod can drive the first slide block and the second slide block to move towards the direction of the rotating rod, the first slide block and the second slide block can be pushed to move towards the direction of the rotating rod by the first slide block through the linkage rod, the two groups of abutting blocks of the station where the rotating rod is located can move oppositely on the turntable, the two groups of abutting blocks can gradually abut against the inner wall of the rotating rod by the opposite movement, the two groups of abutting blocks can drive the two groups of abutting blocks of the station where the sample tube is located to move oppositely on the turntable through the linkage rod by the two groups of abutting blocks, the abutting action of the abutting blocks on the inner wall of the sample tube can be cancelled, then the worker rotates the push rod, the first slide block and the second slide block can be driven to rotate by the push rod, the first slide block can drive the turntable of the station where the rotating rod is located to rotate, the rotating rod rotates to drive the piston to rotate, the piston rotates and moves rightwards simultaneously, the piston moves rightwards to draw a sample into the outer tube and enter the sample tube, the slide block rotates to drive the rotary disc of the station where the sample tube is located to rotate through the linkage rod and the abutting block, the abutting block of the station where the sample tube is located does not generate abutting action on the inner wall of the sample tube, therefore, the push rod rotates to not drive the sample tube to rotate, when the sample is drawn into a certain amount, a worker pulls the push rod to move towards the outside of the tube, the push rod moves towards the outside of the tube to drive the slide block I and the slide block to move in the direction away from the rotating rod, the slide block moves in the direction away from the rotating rod to drive the two abutting blocks of the station where the rotating rod is located to move relatively through the push rod, the two abutting blocks move relatively to cancel the abutting action on the inner wall of the rotating rod, and the slide block moves in, two sets of tight blocks of supporting are opposite motions can support tightly to the sample cell inner wall gradually, then the staff rotates the push rod, the push rod rotates and can drive slider one and slider two and rotate, slider one rotates and can drive through the gangbar and support tight block and carousel at the bull stick internal rotation, slider two rotates and can drive the tight block rotation of supporting of sample cell place station through the gangbar, and under the tight effect of supporting of tight block, two sets of tight blocks of supporting can drive the sample cell and rotate, can move right in the outer tube when the sample cell rotates, the sample cell moves right and can drive cutting assembly and cut the intraductal sample of suction outer tube and sample, thereby accomplish the sample action.

Preferably, the cutting assembly comprises a blade groove formed in the side wall of the sample tube and a second moving block rotatably arranged in the outer tube, a knife belt is fixed on the side wall of the second moving block, one end, far away from the second moving block, of the knife belt penetrates through the side wall of the sample tube and is fixed with a cutting blade, and the cutting blade is in sliding fit with the blade groove.

By adopting the technical scheme, when the sample tube moves rightwards in the outer tube, the cutting blade can move along the blade groove towards the direction away from the push rod, so that a sample is cut off, the rotation of the sample tube can drive the moving block II to rotate in the outer tube, the cutting blade and the blade groove are not staggered, and the cutter belt plays a role in connecting the moving block II and the cutting blade.

Preferably, a first moving block is fixed on the side wall of the sample tube, a curved groove is formed in the inner wall of the outer tube, and the first moving block is in sliding fit with the curved groove.

By adopting the technical scheme, when the sample tube rotates, the sample tube can drive the first moving block to do circular arc motion by taking the sample tube as an axis, and the first moving block can move rightwards along the curve groove while doing circular arc motion.

Preferably, two groups of limiting blocks are fixed on the side wall of the push rod, and the two groups of limiting blocks are respectively in sliding fit with the first sliding block and the second sliding block.

By adopting the technical scheme, through the arrangement of the limiting block, when the staff rotates the push rod, the limiting block drives the first sliding block and the second sliding block to rotate.

Preferably, one end of the push rod, which is far away from the sample tube, penetrates through the outer tube and is fixed with the push plate.

By adopting the technical scheme, the push plate assists workers to push and pull the push rod, so that the workers can operate conveniently.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment;

FIG. 2 is a cross-sectional view of an embodiment showing an outer tube;

FIG. 3 is a schematic diagram of an embodiment showing the position of the cutting assembly;

FIG. 4 is a schematic diagram of an exemplary linkage assembly;

FIG. 5 is a schematic diagram of an embodiment showing a first slider and a second slider position structure.

Reference numerals: 1. an outer tube; 2. a sample tube; 3. a piston; 4. a rotating rod; 5. a push rod; 6. a linkage assembly; 7. a first sliding block; 8. a second sliding block; 9. a turntable; 10. a propping block; 11. a linkage rod; 12. a cutting assembly; 13. an insert pocket; 14. a second moving block; 15. a knife belt; 16. cutting the slices; 17. moving a first block; 18. a curved groove; 19. a limiting block; 20. a push plate.

Detailed Description

The following description is only a preferred embodiment of the present invention, and the protection scope is not limited to the embodiment, and any technical solution that falls under the idea of the present invention should fall within the protection scope of the present invention. It should also be noted that modifications and embellishments within the scope of the invention may occur to those skilled in the art without departing from the principle of the invention.

See fig. 1 to 5, a gynecological tumor sampling device, including outer tube 1, slide and set up in outer tube 1 sample cell 2 and slide and set up in sample cell 2 piston 3, the one end of piston 3 is fixed with bull stick 4, slides in sample cell 2 and is provided with push rod 5, is provided with on the push rod 5 to be used for driving sample cell 2 and bull stick 4 pivoted linkage subassembly 6 respectively, and linkage subassembly 6 is including sliding slider one 7 and the slider two 8 that sets up on push rod 5.

The worker firstly pushes the push rod 5 to move towards the sample tube 2, and the push rod 5 moves to drive the first slide block 7 and the second slide block 8 to move towards the rotating rod 4.

The rotating rods 4 and the sample tubes 2 are internally and all rotatably provided with rotary tables 9, the push rods 5 penetrate through the rotary tables 9 of the stations where the sample tubes 2 are located, the first slider 7 and the second slider 8 are located between the two groups of rotary tables 9, the two groups of rotary tables 9 are internally and symmetrically provided with abutting blocks 10 in a sliding mode, the first slider 7 and the second slider 8 are symmetrically and rotatably provided with linkage rods 11 on the side walls, the two groups of linkage rods 11 of the first slider 7 are far away from one end of the first slider 7 and are in running fit with the two groups of abutting blocks 10 of the stations where the rotating rods 4 are located, and the two groups of linkage rods 11 of the second slider 8 are far away from one end of the second slider 8 and are in running fit with the two groups of.

The first slider 7 moves towards the direction of the rotating rod 4 and can push two groups of abutting blocks 10 of a station where the rotating rod 4 is located to move oppositely on the turntable 9 through the linkage rod 11, the two groups of abutting blocks 10 move oppositely and can abut against the inner wall of the rotating rod 4 gradually, the second slider 8 moves towards the direction of the rotating rod 4 and can drive the two groups of abutting blocks 10 of the station where the sample tube 2 is located to move relatively on the turntable 9 through the linkage rod 11, and the two groups of abutting blocks 10 move relatively and can cancel the abutting effect of the abutting blocks 10 on the inner wall of the sample tube 2.

One end of the push rod 5, which is far away from the sample tube 2, penetrates through the outer tube 1 and is fixed with the push plate 20, two groups of limiting blocks 19 are fixed on the side wall of the push rod 5, and the two groups of limiting blocks 19 are respectively in sliding fit with the first sliding block 7 and the second sliding block 8.

A worker grasps the push plate 20 and rotates the push rod 5, through the arrangement of the limiting block 19, when the worker rotates the push rod 5, the limiting block 19 drives the first sliding block 7 and the second sliding block 8 to rotate, the first sliding block 7 can drive the rotary table 9 of a station where the rotating rod 4 is located to rotate through the linkage rod 11 and the abutting block 10, the abutting block 10 drives the rotating rod 4 to rotate under the abutting action of the abutting block 10, the rotating rod 4 can drive the piston 3 to rotate, the piston 3 can move rightwards while rotating, the piston 3 can move rightwards to suck a sample into the outer tube 1 and enter the sample tube 2, the second sliding block 8 rotates to drive the rotary table 9 of the station where the sample tube 2 is located to rotate through the linkage rod 11 and the abutting block 10, and the abutting block 10 of the station where the sample tube 2 is located does not generate abutting action on the inner wall of the sample tube 2 any more, so that the push rod 5 can not drive the.

After the sample is sucked into a certain amount, the worker pulls the push rod 5 to move outwards, the push rod 5 moves outwards to drive the first slider 7 and the second slider 8 to move towards the direction far away from the rotating rod 4, the first slider 7 moves towards the direction far away from the rotating rod 4 to drive the two groups of abutting blocks 10 at the station where the rotating rod 4 is located through the push rod 5 to move relatively, the two groups of abutting blocks 10 move relatively to cancel the abutting effect on the inner wall of the rotating rod 4, the second slider 8 moves towards the direction far away from the rotating rod 4 to drive the two groups of abutting blocks 10 at the station where the sample tube 2 is located through the push rod 5 to move oppositely, and the two groups of abutting blocks 10 move oppositely to gradually abut against the inner wall of the sample tube 2.

Then the staff grasps the push plate 20 to rotate the push rod 5, the push rod 5 rotates to drive the first slide block 7 and the second slide block 8 to rotate, the first slide block 7 rotates to drive the abutting block 10 and the rotary table 9 to rotate in the rotary rod 4 through the linkage rod 11, the second slide block 8 rotates to drive the abutting block 10 of the station where the sample tube 2 is located to rotate through the linkage rod 11, and under the abutting effect of the abutting block 10, the two groups of abutting blocks 10 can drive the sample tube 2 to rotate.

A first moving block 17 is fixed on the side wall of the sample tube 2, a curved groove 18 is formed in the inner wall of the outer tube 1, and the first moving block 17 is in sliding fit with the curved groove 18.

When the sample tube 2 rotates, the sample tube 2 drives the moving block one 17 to do circular motion by taking the sample tube 2 as an axis, and the moving block one 17 moves rightwards along the curved groove 18 while doing circular motion, so that the sample tube 2 is driven to move rightwards.

The sample tube 2 is provided with a cutting assembly 12 for shearing a sample, the cutting assembly 12 comprises a blade groove 13 formed in the side wall of the sample tube 2 and a second moving block 14 rotatably arranged in the outer tube 1, a knife belt 15 is fixed on the side wall of the second moving block 14, one end, far away from the second moving block 14, of the knife belt 15 penetrates through the side wall of the sample tube 2 and is fixed with a cutting blade 16, and the cutting blade 16 is in sliding fit with the blade groove 13.

When the sample tube 2 moves rightwards in the outer tube 1, the cutting piece 16 moves towards the direction far away from the push rod 5 along the blade groove 13, so that a sample is cut off, the moving block II 14 is driven to rotate in the outer tube 1 by the rotation of the sample tube 2, the cutting piece 16 and the blade groove 13 are not staggered, and the knife belt 15 plays a role in connecting the moving block II 14 and the cutting piece 16, so that the sampling action is completed.

Claims (5)

1. The gynecological tumor sampling device comprises an outer tube (1), and is characterized by further comprising a sample tube (2) arranged in the outer tube (1) in a sliding manner and a piston (3) arranged in the sample tube (2) in a sliding manner, wherein a rotating rod (4) is fixed at one end of the piston (3), a push rod (5) is arranged in the sample tube (2) in a sliding manner, a linkage assembly (6) used for driving the sample tube (2) and the rotating rod (4) to rotate respectively is arranged on the push rod (5), the linkage assembly (6) comprises a first sliding block (7) and a second sliding block (8) which are arranged on the push rod (5) in a sliding manner, turntables (9) are arranged in the rotating rod (4) and the sample tube (2) in a rotating manner, the push rod (5) penetrates through the turntables (9) of a station where the sample tube (2) is located, the first sliding block (7) and the second sliding block (8) are located between, two sets of equal symmetry just slides in carousel (9) and is provided with to tight piece (10), slider one (7) with the symmetry just rotates on the lateral wall of slider two (8) and is provided with gangbar (11), slider one (7) one end and two sets of tight piece (10) normal running fit that supports of bull stick (4) place are kept away from in two sets of gangbar (11) of slider one (7) place station, slider two (8) one end and two sets of tight piece (10) normal running fit that supports of sample cell (2) place are kept away from in two sets of gangbar (11) of slider two (8) place stations, be provided with cutting component (12) that are used for cutting the sample on sample cell (2).

2. The gynecological tumor sampling device according to claim 1, wherein the cutting assembly (12) comprises a blade groove (13) formed in the side wall of the sample tube (2) and a second moving block (14) rotatably arranged in the outer tube (1), a blade belt (15) is fixed on the side wall of the second moving block (14), one end of the blade belt (15) far away from the second moving block (14) penetrates through the side wall of the sample tube (2) and is fixed with a cutting blade (16), and the cutting blade (16) is in sliding fit with the blade groove (13).

3. The gynecological tumor sampling device according to claim 1, wherein a first moving block (17) is fixed on the side wall of the sample tube (2), a curved groove (18) is formed on the inner wall of the outer tube (1), and the first moving block (17) is in sliding fit with the curved groove (18).

4. A sampling device for gynecological tumors according to claim 1, characterized in that two sets of limit blocks (19) are fixed on the side wall of the push rod (5), and the two sets of limit blocks (19) are respectively in sliding fit with the first slide block (7) and the second slide block (8).

5. A gynecological tumor sampling device according to claim 1, wherein the end of the push rod (5) remote from the sample tube (2) extends through the outer tube (1) and is fixed with a push plate (20).

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