CN219488289U - Sample detects transfer ware - Google Patents

Abstract

The utility model relates to the technical field of sample detection and transfer, and discloses a sample detection transfer device, which comprises an insulation box, wherein both sides of the bottom of the insulation box are connected with a moving mechanism, the moving mechanism comprises a shaft lever, both sides of the outer part of the shaft lever are connected with the bottom of the insulation box through fixed bearings, the front surface and the back surface of the shaft lever are connected with moving wheels, the inside of the insulation box is connected with a bearing plate in a sliding manner, and the top of the bearing plate is connected with a round arm through a bearing with a seat. This transfer ware that sample detected, the actuating mechanism drive test-tube rack of operation vibrations to drive the sample that its inside was placed and vibrate together, prevent that the sample from depositing, the sample after the deposit reduces its service mass at the in-process of follow-up detection, drive rotary mechanism drives the rotation of round arm, thereby the outside test-tube rack of connection of drive and its inside sample are rotated, thereby cooperate the refrigerator to carry out even heat preservation to the sample, thereby improve sample quality, increase its detection accuracy.

Description

Sample detects transfer ware

Technical Field

The utility model relates to the technical field of sample detection and transfer, in particular to a transfer device for sample detection.

Background

The sample is a portion of the individual observed or investigated, and the population is the entirety of the subject. The elements to be examined, which are extracted from the whole, are called together, and the sample needs to be placed in a placing box and brought to a specified mechanism for sample detection.

The Chinese patent publication No. 2022231621431 discloses a sample placement box which plays a role in fixing samples and avoids sample dumping caused by shaking during transportation.

In the prior art, in the process of transferring liquid samples such as blood, the samples are placed in a test tube rack and do not move for a long time, so that the samples are precipitated, and the use quality of the precipitated samples is reduced in the subsequent detection process.

Disclosure of Invention

(one) solving the technical problems

Aiming at the defects of the prior art, the utility model provides a transfer device for sample detection, which aims to solve the technical problems.

(II) technical scheme

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a sample detects transfer ware, includes the insulation can, the both sides of insulation can bottom all are connected with moving mechanism, moving mechanism includes the axostylus axostyle, the outside both sides of axostylus axostyle are all connected with the bottom of insulation can through fixed bearing, the front and the back of axostylus axostyle all are connected with the removal wheel.

The one end that the axostylus axostyle was kept away from to the removal wheel is connected with actuating mechanism, actuating mechanism includes square groove long piece, square groove sliding connection has the round bar in the inside of square groove long piece, be connected between round bar and the removal wheel, the equal fixedly connected with actuating arm in both sides at square groove long piece top.

The inside sliding connection of insulation can has the bearing plate, the top of bearing plate is connected with the round arm through taking the seat bearing, the outside equidistant test-tube rack that is connected with of round arm, the inside both sides of insulation can all are connected with the refrigerator, the external connection of round arm has rotary mechanism.

The rotary mechanism comprises conical teeth A, the inner parts of the conical teeth A are connected with the outer parts of the round arms, conical teeth B are connected to the left sides of the conical teeth A in a meshed mode, gears are fixedly connected to the left sides of the conical teeth B, toothed plates are connected to the back sides of the gears in a meshed mode, and the bottoms of the toothed plates are connected with the bottoms of the inner parts of the heat preservation boxes.

Preferably, the bottom of the insulation can is connected with long blocks of sliding grooves at equal intervals, one side of each long block of the two sliding grooves, which is opposite, is connected with a sliding block through the sliding groove in a sliding manner, the sliding block is connected with the long blocks of the square groove, and the sliding block guides the long blocks of the square groove, so that the long blocks of the square groove do linear motion.

Preferably, both sides inside the insulation can all are through fixed block fixedly connected with sleeve, and the inside bottom sliding connection of sleeve has the slide bar, and the bottom of slide bar is connected with the top of bearing plate, and sleeve cooperation slide bar makes its rectilinear motion that carries out the direction to the bearing plate.

Preferably, the top of bearing plate has seted up fluting, and grooved inside has been shut and has had the sealing ring, and the inside of sealing ring is connected with the outside of pinion rack, and the sealing ring increases the leakproofness between bearing plate and the insulation can inside, prevents that the air current from leaking outward, reduces refrigerator availability factor.

Preferably, the right side of the conical tooth B is connected with a supporting arm through a bearing with a seat, the bottom of the supporting arm is connected with the top of the bearing plate, and the conical tooth B is supported to operate.

Preferably, both sides at test-tube rack top all through connection has the nut, and the inside threaded connection of nut has the bolt, and the outside of bolt has cup jointed the bearing, and the fixed disk has been cup jointed to the outside of bearing, and nut cooperation bearing can drive the fixed disk and descend cooperation test-tube rack and carry out spacingly with the test tube sample.

(III) beneficial effects

Compared with the prior art, the utility model provides a transfer device for sample detection, which has the following beneficial effects:

according to the sample detection transfer device, in the process of transferring samples, the moving mechanism drives the heat preservation box to move to generate force to drive the driving mechanism to operate, and the driving mechanism operated drives the test tube rack to vibrate, so that the samples placed in the test tube rack are driven to vibrate together, sample precipitation is prevented, and the use quality of the precipitated samples is reduced in the subsequent detection process;

this transfer ware that sample detected, the bearing plate drive the sample through actuating mechanism and shake the in-process that the actuating mechanism drove the round arm and rotate to the test-tube rack of drive outside connection and its inside sample are rotated, thereby cooperate the refrigerator to carry out even heat preservation to the sample, thereby improve sample quality, increase its detection precision.

Drawings

FIG. 1 is a schematic front view of the present utility model;

FIG. 2 is a front cross-sectional view of the present utility model;

FIG. 3 is a schematic front view of a mobile mechanism according to the present utility model;

FIG. 4 is a schematic front view of the driving mechanism of the present utility model;

FIG. 5 is a schematic front view of a rotary mechanism according to the present utility model;

fig. 6 is a front cross-sectional view of the test tube rack of the present utility model.

In the figure: 1. an insulation box; 2. a moving mechanism; 21. a shaft lever; 22. fixing a bearing; 23. a moving wheel; 3. a driving mechanism; 31. a square groove long block; 32. a round bar; 33. a driving arm; 4. a bearing plate; 5. a round arm; 6. a test tube rack; 7. a refrigerator; 8. a rotation mechanism; 81. conical teeth A; 82. conical teeth B; 83. a gear; 84. toothed plate.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The utility model provides a technical scheme, a sample detection transfer device, which comprises an insulation box 1 for transferring samples, wherein the right side of the top of the insulation box 1 is connected with a box cover through a hinge, the top of the box cover is connected with a handle, and both sides of the bottom of the insulation box 1 are connected with a moving mechanism 2 for supporting the insulation box 1 to move.

The moving mechanism 2 comprises a shaft lever 21 of the connecting assembly, both sides of the outer part of the shaft lever 21 are connected with the bottom of the heat preservation box 1 through fixed bearings 22 supporting the shaft lever 21, and the front surface and the back surface of the shaft lever 21 are connected with moving wheels 23 supporting the heat preservation box 1 to move.

One end of the moving wheel 23 far away from the shaft rod 21 is connected with a driving mechanism 3 for driving the bearing plate 4 to move up and down, the driving mechanism 3 comprises square groove long blocks 31 with square grooves formed in the inner portion, the bottoms of the heat preservation boxes 1 are connected with sliding groove long blocks of the connecting assembly at equal intervals, one sides of the two sliding groove long blocks opposite to each other are respectively provided with a sliding block through the sliding grooves in a sliding manner, the sliding blocks are connected with the square groove long blocks 31, and round rods 32 are connected in the inner portion of the square groove long blocks 31 through the square grooves in a sliding manner.

The square groove long block 31 converts the circular arc motion of the round rod 32 into transverse motion and vertical motion through an internal square groove, the round rod 32 moves in the square groove through the transverse motion, the round rod 32 drives the body to move through the vertical motion, the round rod 32 is connected with the movable wheel 23, driving arms 33 are fixedly connected to two sides of the top of the square groove long block 31, and the top of each driving arm 33 is in contact with the bottom of the bearing plate 4.

The inside sliding connection of insulation can 1 has coupling assembling's bearing plate 4, and the inside both sides of insulation can 1 are all through fixed block fixedly connected with coupling assembling's sleeve, and the inside bottom sliding connection of sleeve has the slide bar that makes its rectilinear motion to bearing plate 4 direction, and the bottom of slide bar is connected with the top of bearing plate 4, and the top of bearing plate 4 is connected with coupling assembling's round arm 5 through taking the seat bearing.

The outside equidistant test-tube rack 6 that deposits sample test tube of round arm 5, the equal through-connection in both sides at test-tube rack 6 top have the nut, and the inside threaded connection of nut has the bolt, and the outside of bolt has cup jointed the bearing, and the fixed disk has been cup jointed to the outside of bearing, and the inside both sides of insulation can 1 all are connected with the refrigerator 7 that carries out the heat retaining to the sample, and the outside of refrigerator 7 is provided with the sensor that can control refrigerator 7, and the external connection of round arm 5 has rotary mechanism 8 that can drive round arm 5 rotation.

The rotary mechanism 8 comprises a driven conical tooth A81, the inside of the conical tooth A81 is connected with the outside of the round arm 5, the left side of the conical tooth A81 is connected with a driven conical tooth B82 in a meshed mode, the right side of the conical tooth B82 is connected with a supporting arm for supporting the conical tooth B82 through a bearing with a seat, the bottom of the supporting arm is connected with the top of the bearing plate 4, and the left side of the conical tooth B82 is fixedly connected with a driven gear 83.

The back meshing of gear 83 is connected with the pinion rack 84 that drive gear 83 rotated, and coupling assembling's fluting has been seted up at the top of bearing plate 4, and the inside of fluting has been shut and has had the sealing ring that increases bearing plate 4 gas tightness, and the inside of sealing ring is connected with the outside of pinion rack 84, and the bottom of pinion rack 84 is connected with the inside bottom of insulation can 1.

The working principle of the device is as follows: the in-process that uses opens the case lid at incubator 1 top, in the test tube groove at test-tube rack 6 top is plugged into with the sample test tube, drive the fixed disk through rotatory bolt and descend, fix the outside at test-tube rack 6 with the test tube, start refrigerator 7 and keep warm the inside test tube of incubator 1, promote incubator 1 to transfer the inside sample of test tube, incubator 1 is at the in-process that removes through mobile mechanism 2, it drives square groove long piece 31 up-and-down motion to remove wheel 23 rotation through round bar 32, the in-process of square groove long piece 31 motion passes through actuating arm 33 and drives bearing plate 4 at the inside slip of incubator 1, thereby drive the round arm 5 up-and-down motion at top, make its drive and test-tube rack 6 and inside sample test tube that connects vibrate, prevent the sample deposit.

The gear 83 at the top is driven to move along with the gear 83 at the top in the up-and-down movement process, the gear 83 is meshed with the toothed plate 84 for rotation in the movement process, the rotating gear 83 drives the conical tooth B82 and the conical tooth A81 meshed with the conical tooth B82 to rotate, the rotating conical tooth A81 drives the round arm 5 and the test tube rack 6 to rotate, the rotating test tube rack 6 is matched with the refrigerator 7 to uniformly preserve heat of samples in the test tube rack, and sample quality is improved.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a sample detects transfer ware, includes insulation can (1), its characterized in that: the two sides of the bottom of the heat preservation box (1) are connected with a moving mechanism (2), the moving mechanism (2) comprises a shaft lever (21), two sides of the outer part of the shaft lever (21) are connected with the bottom of the heat preservation box (1) through fixed bearings (22), and the front surface and the back surface of the shaft lever (21) are connected with moving wheels (23);

one end of the movable wheel (23) far away from the shaft lever (21) is connected with a driving mechanism (3), the driving mechanism (3) comprises a square groove long block (31), a round rod (32) is slidably connected in the square groove long block (31) through a square groove, the round rod (32) is connected with the movable wheel (23), and driving arms (33) are fixedly connected to two sides of the top of the square groove long block (31);

the device is characterized in that a bearing plate (4) is slidably connected inside the heat insulation box (1), the top of the bearing plate (4) is connected with a round arm (5) through a bearing with a seat, test tube racks (6) are connected to the outer parts of the round arm (5) at equal intervals, refrigerators (7) are connected to two sides of the inner part of the heat insulation box (1), and a rotating mechanism (8) is connected to the outer parts of the round arm (5);

the rotary mechanism (8) comprises conical teeth A (81), the inner part of the conical teeth A (81) is connected with the outer part of the round arm (5), conical teeth B (82) are connected to the left side of the conical teeth A (81) in a meshed mode, gears (83) are fixedly connected to the left side of the conical teeth B (82), toothed plates (84) are connected to the back side of the gears (83) in a meshed mode, and the bottoms of the toothed plates (84) are connected with the bottom of the inner part of the insulation box (1).

2. A sample testing transfer as claimed in claim 1, wherein: the bottom of the insulation box (1) is connected with sliding groove long blocks at equal intervals, one sides of the two sliding groove long blocks opposite to each other are respectively connected with a sliding block through the sliding grooves in a sliding manner, and the sliding blocks are connected with the square groove long blocks (31).

3. A sample testing transfer as claimed in claim 1, wherein: the two sides of the interior of the insulation box (1) are fixedly connected with sleeves through fixing blocks, the bottoms of the interiors of the sleeves are slidably connected with sliding rods, and the bottoms of the sliding rods are connected with the tops of the bearing plates (4).

4. A sample testing transfer as claimed in claim 1, wherein: the top of the bearing plate (4) is provided with a slot, the inside of the slot is closed to be provided with a sealing ring, and the inside of the sealing ring is connected with the outside of the toothed plate (84).

5. The transport for sample testing according to claim 4, wherein: the right side of the conical tooth B (82) is connected with a supporting arm through a bearing with a seat, and the bottom of the supporting arm is connected with the top of the bearing plate (4).

6. A sample testing transfer as claimed in claim 1, wherein: the both sides at test-tube rack (6) top all are connected with the nut in a run-through way, and the inside threaded connection of nut has the bolt, and the outside of bolt has cup jointed the bearing, and the outside of bearing has cup jointed the fixed disk.