CN218412573U - Sample transfer apparatus - Google Patents
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- CN218412573U CN218412573U CN202220589571.3U CN202220589571U CN218412573U CN 218412573 U CN218412573 U CN 218412573U CN 202220589571 U CN202220589571 U CN 202220589571U CN 218412573 U CN218412573 U CN 218412573U
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Abstract
The utility model provides a sample transfer device, which comprises a workbench, wherein a buffer sample rack is arranged on the workbench; the sample rack conveying and recovering mechanism is used for automatically conveying the first sample rack provided with the test tubes to a tube unloading station, and after the tubes are unloaded, the rack conveying and recovering mechanism is used for recovering the vacant first sample rack; the sample rack conveying mechanism is used for conveying the vacant second sample rack from the second feeding end of the workbench to the pipe placing station; the tube moving mechanism is used for transferring the test tubes on the first sample rack to the cache sample rack and transferring the test tubes in the cache sample rack to the second sample rack; and the sample outlet and rail changing mechanism is used for driving the second sample rack to carry out sample sending detection through a conventional channel or an emergency treatment channel. The utility model provides a sample transfer device, as the transfer station of sample test tube, realizes the conversion of different specification sample framves, can connect the assembly line of multiple different specifications, has improved degree of automation, reduces manpower intensity of labour, improves detection efficiency.
Description
Technical Field
The utility model belongs to the technical field of medical treatment check out test set technique and specifically relates to a sample shifts equipment.
Background
Currently, in vitro diagnosis is a widely used diagnostic method in the medical field, and judges human pathological changes by collecting body fluids, excretions and secretions of a human body to perform chemical composition or chemical reaction analysis. When a large amount of samples are detected, the workload of medical staff is huge, and mistakes are easy to make, so that the transfer efficiency of sample detection needs to be improved.
In addition, the analysis appearance of hospital at the during operation, generally need adopt the sample frame to bear and shift the sample test tube, among the prior art's the detection and analysis equipment, the sample frame that will be equipped with the test tube shifts the test tube position of unloading to and the sample frame recovery after the test tube uninstallation still usually realizes the position transfer of test tube frame through medical personnel's manual operation, and not only work load is big, degree of automation is not high, detection efficiency is low, and make mistakes easily at the manual work transfer in-process.
In addition, the in vitro diagnostic equipment of different manufacturers adopts five-hole sample racks for some sample test tube bearing modes, adopts ten-hole sample racks for some sample test tube bearing modes, adopts single-tube sample racks for some sample test tube bearing modes, and generally only aims at the test tube racks of the same specification in the existing sample test tube transfer equipment, so that the switching between the sample racks of different specifications is troublesome, and the efficiency is low. Therefore, there is a need to provide a sample transfer apparatus that can support connection of a plurality of sample racks with different specifications, has good versatility for transferring samples, and has wide adaptability and high automation degree.
SUMMERY OF THE UTILITY MODEL
The utility model provides a problem, in order to overcome the defect among the prior art, provide a sample transfer apparatus, as the transfer station of sample test tube, realize the conversion of different specification sample framves, can connect the assembly line of multiple different specifications, improved degree of automation, reduce manpower intensity of labour, improve detection efficiency.
In order to solve the problem, the utility model provides a sample transfer device, comprises a workbench, install on the workstation and
the buffer storage sample rack is used for temporarily storing the test tubes;
the sample rack conveying and recovering mechanism is used for conveying a first sample rack provided with test tubes from a first feeding end of the workbench to a tube unloading station, and after the test tubes on the first sample rack are unloaded and transferred to the cache sample rack, the sample rack conveying and recovering mechanism is used for recovering the empty first sample rack;
the sample rack conveying mechanism is used for conveying the vacant second sample rack from the second feeding end of the workbench to the pipe placing station;
the tube moving mechanism is used for transferring the test tubes on the first sample rack to the cache sample rack and transferring the test tubes in the cache sample rack to the second sample rack;
the sample outlet rail changing mechanism is provided with a first channel, a second channel and a sample outlet driving assembly, and the sample outlet driving assembly is used for driving a second sample rack provided with test tubes to move out from the first channel or the second channel when the workbench enters a next detection station.
The utility model discloses a sample transfer device compares with prior art and has following advantage:
the utility model discloses a sample transfer equipment is the transfer station of a sample test tube, through set up the mechanism that is used for transmitting different specification sample framves on the workstation and the automatic structure moves the structure and realizes the automatic quick switching of different specification sample framves to can connect the assembly line of multiple different specifications, improve the commonality; and the utility model discloses a first sample frame that is equipped with the test tube in the transfer equipment realizes the test tube and shifts the back, can also realize the automation of vacant first sample frame and retrieve, further improves degree of automation, guarantees the uninterrupted duty of testing process, improves work efficiency.
Furthermore, the sample rack conveying and recovering mechanism comprises a first mounting rack arranged on the workbench, a channel extending along the length direction of the first mounting rack and a driving mechanism are arranged on the first mounting rack, and the driving mechanism is used for driving the first sample rack to slide in the channel in a reciprocating manner so as to realize the conveying and recovering of the first sample rack; the first mounting frame is further connected with at least one recovery tray for containing the first sample frame and a recovery mechanism for driving the empty first sample frame to move to the recovery tray.
As an improvement, a pressing mechanism is further connected to the position, corresponding to the pipe unloading station, of any one side of the mounting frame in the width direction; hold-down mechanism is including connecting first supporting seat on the first mounting bracket lateral wall, be connected with on the first supporting seat and compress tightly the motor and towards passageway width direction slidable clamp plate, press on be equipped with rather than the first waist type hole of slip direction looks vertically, be connected with first eccentric wheel on compressing tightly the output shaft of motor, the radial one end of first eccentric wheel is connected with first locating shaft, first location cooperation is in the first waist type is downthehole. In the improved structure, the arrangement of the pressing mechanism enables the sample rack to keep better stability when the test tube is unloaded, and the unloading efficiency of the test tube is improved; and the reciprocating motion of the pressure plate in the pressing mechanism towards the sample rack is realized through the rotation of the motor and the eccentric wheel, the structure is simple, the operation is convenient, and the driving force is stable.
It is again improved, retrieve the mechanism including connecting the second supporting seat on first mounting bracket, sliding connection has horizontal push pedal and retrieves drive assembly on the second supporting seat, it is used for the drive to retrieve drive assembly horizontal push pedal horizontal migration realizes retrieving first sample frame propelling movement from the passageway extremely in retrieving the tray.
Further, the sample rack transmission mechanism comprises a second mounting rack for placing a second sample rack, one end of the second mounting rack is connected with the positioning mechanism, and the other end of the second mounting rack is connected with the material pushing mechanism and used for pushing the second sample rack on the second mounting rack to the positioning mechanism until the second sample rack is clamped and limited between the positioning mechanism and the material pushing mechanism; one end of the second mounting mechanism close to the positioning mechanism is further connected with a blanking mechanism used for driving a second sample rack with samples to be separated from the second mounting frame and enter a feeding channel of the sample discharging and rail replacing mechanism.
The discharging mechanism comprises a shifting fork and a discharging driving assembly which are connected to the second mounting frame, a discharging port is formed in one end, close to the positioning mechanism, of the second mounting frame, an avoiding chute extending in the discharging direction is formed in the position, corresponding to the discharging port, of the bottom wall of the second mounting frame, and the upper end of the shifting fork is in sliding fit in the avoiding chute; the blanking driving assembly is used for driving the shifting fork to slide in the avoiding chute, so that the second sample rack is separated from the second mounting rack and enters the sample discharging and rail replacing mechanism.
And the pushing mechanism comprises at least one pushing claw which is slidably arranged on the side wall of the second mounting frame, and the lower end of the second mounting frame is connected with a pushing claw driving assembly which is used for driving the pushing claw to reciprocate along the length direction of the second mounting frame and is used for continuously pushing the vacant second sample frame to a position which is abutted against the positioning mechanism.
Still further, move a tub mechanism and include support frame and test tube chuck, be connected with on the support frame and be used for driving the test tube chuck moves the subassembly along the X axle that the X axle direction removed, moves the subassembly along the Y axle that the Y axle direction removed and moves the subassembly along the Z axle that the Z axle direction removed.
Still further, the sample discharging and rail changing mechanism comprises a third mounting frame, a first channel and a second channel are arranged at one end of the third mounting frame along the X-axis direction, and a conveyor belt assembly used for driving the second sample frame to move in the first channel or the second channel respectively is arranged on the third mounting frame; the other end of the third mounting bracket in the X-axis direction is connected with a rail replacing base used for limiting the sample rack and driving the rail replacing base to move in the Y-axis direction, and the rail replacing drive assembly is used for driving the rail replacing base to drive the corresponding sample rack to move to a position corresponding to the first channel or the second channel to deliver samples.
Still further, still be connected with drawer mechanism and rotatory yard mechanism of sweeping on the workstation, be equipped with the tray that is used for placing the test tube in the drawer mechanism, work as when sample transfer equipment carries out stand-alone mode, it is used for shifting the test tube in the tray to the rotatory yard mechanism of sweeping to move a tub mechanism, works as it sweeps a yard completion back to move a tub mechanism and is arranged in will rotating the test tube of sweeping in the yard mechanism and shift to corresponding second sample frame.
The beneficial effects that the above-mentioned structure in the utility model has are seen in detail in concrete embodiment part content.
Drawings
Fig. 1 is a schematic perspective view of a sample transfer apparatus according to the present invention;
fig. 2 is a top view of the sample transfer apparatus of the present invention;
fig. 3 is a schematic perspective view of the sample rack conveying and recovering mechanism of the present invention;
fig. 4 is another schematic view of the sample rack transport and recovery mechanism of the present invention;
fig. 5 is a schematic structural view of the pressing mechanism of the present invention;
fig. 6 is another schematic view of the pressing mechanism of the present invention;
FIG. 7 is an enlarged view of the structure at X in FIG. 4;
fig. 8 is a schematic perspective view of a sample rack transport mechanism according to the present invention;
fig. 9 is a top view of the sample rack transport mechanism of the present invention;
fig. 10 is a schematic structural view of the positioning mechanism of the present invention;
fig. 11 is a schematic structural view of the blanking mechanism of the present invention;
fig. 12 is a schematic structural view of a pushing mechanism in the present invention;
fig. 13 is another schematic view of the pushing mechanism according to the present invention;
fig. 14 is a schematic structural view of a tube moving mechanism in the present invention;
fig. 15 is a schematic structural view of a sample-discharging rail-changing mechanism according to the present invention;
fig. 16 is a schematic structural view of a rail replacing driving assembly according to the present invention;
fig. 17 is another schematic structural view of the rail-changing driving assembly according to the present invention;
fig. 18 is a schematic structural view of a buffer sample rack according to the present invention;
fig. 19 is a schematic structural view of the drawer mechanism of the present invention;
fig. 20 is a front view of the rotary code scanning mechanism of the present invention.
Description of the reference numerals:
1. a first mounting bracket; 1.1, a channel; 2. a tray is recovered; 3. a material pushing mechanism; 3.1, a second supporting seat; 3.2, horizontally pushing a plate; 3.2.1, a second kidney-shaped hole; 4. a test tube unloading station; 5. a drive motor; 6. a driving wheel; 7. a driven wheel; 8. a conveyor belt; 9. a pressing mechanism; 9.1, a first supporting seat; 9.2, pressing a motor; 9.3, pressing a plate; 9.3.1, a first kidney-shaped hole; 9.4, a first eccentric wheel; 9.5, a first positioning shaft; 10. a material stop mechanism; 10.1, a stop fork; 10.2, a material blocking motor; 11. a code scanner; 12. a material pushing motor; 13. a second eccentric wheel; 14. a second positioning shaft; 15. a second mounting bracket; 15.1, positioning the sliding chute; 15.2, a discharge hole; 15.3, avoiding the chute; 16. a shifting fork; 17. a rail change drive assembly; 18. a support frame; 19. positioning seats; 20. positioning blocks; 21. a pulley assembly; 22. a fork motor; 23. a conveyor belt; 24. a push claw; 25. a pawl pushing motor; 26. a first pulley; 27. a second pulley; 28. a third belt pulley; 29. a first belt; 30. a second belt; 31. a connecting plate; 32. a carriage; 33. a Y-axis moving motor; 34. a first synchronization belt; 35. a sliding seat; 36. an X-axis moving motor; 37. a second synchronous belt; 38. a Z-axis moving motor; 39. a third synchronous belt; 40. a third mounting bracket; 41. a rail replacing base; 42. stopping the motor; 43. rotating the disc; 44. a deflector rod; 45. A blocking lever; 46. a fourth mounting bracket; 47. a tray; 48. a tray floor; 49. a handle;
100. a work table; 101. caching a sample rack; 101.1, a bottom plate; 101.2, an upper supporting plate; 101.3, a lower supporting plate; 102. a sample rack conveying and recovering mechanism; 103. a sample rack transport mechanism; 104. a pipe moving mechanism; 105. a sample outlet rail changing mechanism; 105.1, a first channel; 105.2, a second channel; 105.3, a return visit channel; 106. a drawer mechanism; 107. A rotary code scanning mechanism;
110. a first sample holder; 120. a second sample rack.
Detailed Description
In order to make the aforementioned objects, features and advantages of the present invention more comprehensible, embodiments accompanied with figures are described in detail below.
In the description of the present invention, it should be noted that the terms "front, back", "left, right", "X-axis direction", "Y-axis direction", "Z-axis direction", etc. indicate the directions or positional relationships based on the directions or positional relationships shown in the drawings, and are only for convenience of description and simplification of the description, but do not indicate or imply that the device or element referred to must have a specific direction, be constructed and operated in a specific direction, and thus, should not be construed as limiting the present invention.
In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the term "connected" is to be interpreted broadly, e.g., as a fixed connection, a detachable connection, or an integral connection; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood as a specific case by those skilled in the art.
As shown in FIGS. 1 and 2, the utility model provides a sample transfer device, which comprises a workbench 100, wherein the workbench 100 is respectively provided with a sample transfer device
The buffer memory sample rack 101 is used for temporarily storing the transferred test tubes;
the sample rack conveying and recovering mechanism 102 is used for conveying the first sample rack 110 with the test tubes from the first feeding end of the workbench 100 to the tube unloading station 4, and after the test tubes on the second sample rack 120 are unloaded and transferred to the cache sample rack 101, the sample rack conveying and recovering mechanism 102 is used for recovering the vacant second sample rack 120;
a sample rack transport mechanism 103 for transporting the empty second sample rack 120 from the second feeding end of the working table 100 to the tube placing station;
a tube moving mechanism 104 for transferring the test tubes on the second sample rack 120 to the buffered sample rack 101, and transferring the test tubes in the buffered sample rack 101 to the second sample rack 120;
the sample discharging and rail changing mechanism 105 is provided with a first channel 105.1, a second channel 105.2 and a sample discharging driving assembly, wherein the sample discharging driving assembly is used for driving the second sample rack 120 provided with the test tube to move out of the workbench 100 from the first channel 105.1 or the second channel 105.2, and then enter the next detection station (analyzer).
Among the above-mentioned equipment, realized carrying out the automatic transfer between the sample frame of different standards, the external diagnostic equipment of different producers bears some five hole sample frames of adoption to the sample test tube, some ten hole sample frames of adoption, some adopt single tube sample frame, the sample transfer equipment of this embodiment is then fine the automatic conversion between the sample frame of having realized different specifications to the sample frame of different specifications also is automatic transmission and recovery, effectively reduces labour's cost, improves detection efficiency.
As shown in fig. 18, buffer memory sample frame 101 in this embodiment includes bottom plate 101.1, install many stands on bottom plate 101.1, the upper end of many stands is connected with last backup pad 101.2 and bottom suspension fagging 101.3 that the interval set up, and be equipped with the porous through-hole that is used for supplying the test tube to pass on going up backup pad 101.2, be equipped with the counter bore in the position that the up end of bottom suspension fagging 101.3 corresponds with each through-hole, vertical corresponding through-hole and counter bore form the hole site of putting of inserting that is used for holding the test tube.
As shown in fig. 3 and 4, the sample rack transporting and recovering mechanism 102 includes a mounting rack 1, a channel 1.1 extending along a length direction of the mounting rack 1 and a driving mechanism, wherein the driving mechanism is used for driving the sample rack to slide in the channel 1.1 in a reciprocating manner; specifically, actuating mechanism includes driving motor 5, action wheel 6, follows driving wheel 7 and transmission band 8, and action wheel 6 sets up with following driving wheel 7 along the length direction interval of passageway 1.1 to transmission band 8 is connected in action wheel 6, follows the outside of driving wheel 7 and is in order to form a belt pulley transmission structure, and transmission band 8 is located passageway 1.1, and driving motor 5 is connected with action wheel 6 transmission. The clockwise or anticlockwise operation of the conveying belt 8 can be realized through the forward and reverse operation of the driving motor 5, and as shown in the structure shown in fig. 1, when the conveying belt 8 operates anticlockwise (forward), the sample rack positioned on the right side of the conveying belt 8 can slide from right to left, so that the sample rack provided with the test tubes slides from the feed inlet position on the right side of the mounting frame 1 to the left side; in addition, in this embodiment, a tube unloading station 4 is disposed on the left side of the mounting rack 1, and when the sample rack with the test tubes runs to the position, the test tubes on the sample rack are unloaded by a dedicated manipulator. In addition, in the embodiment, at least one recovery tray 2 for accommodating the sample rack and a recovery mechanism 3 are connected to the mounting rack 1; more specifically, when the sample rack with the test tubes moves from the feed end of the channel 1.1 to the tube unloading station 4 under the action of the driving mechanism for unloading, and until the test tubes are unloaded, the driving mechanism moves along the clockwise direction (reverse direction), so that the vacant sample rack is driven to move to the recovery station, the recovery station at the position is the position corresponding to the recovery tray, and the recovery mechanism 3 is used for pushing the vacant sample rack to enter the recovery tray 2, so that the automatic recovery of the sample rack is realized.
In the structure, in order to further improve the automation efficiency of sample detection, two-dimensional codes of corresponding information are preset on each sample rack; in this embodiment, a first scanner 11 for identifying information of the sample rack is further connected to the mounting rack 1 at a position close to the tube unloading station 4. As shown in fig. 3 and 4, when the sample rack moves up to the tube unloading station 4 in the channel 1.1, the first scanner 11 scans and identifies specific information of the sample rack, so as to control the action of the special manipulator, and transfer the test tube to a corresponding position according to preset information on the sample rack, thereby ensuring that no error occurs in the sample detection process; the automation degree of sample detection is further improved, and the detection efficiency is improved.
As shown in fig. 3, the position corresponding to the tube unloading station 4 on any side of the width direction of the mounting rack 1 is also connected with a pressing mechanism 9 for realizing the pressing limit of the sample rack, so that the sample rack with the test tubes can be guaranteed to have better stability when moving to the position for unloading the test tubes, and the stable unloading of the test tubes is facilitated. More specifically, as shown in fig. 5 and 6, the pressing device 9 includes a first supporting seat 9.1 connected to the rear side wall of the mounting frame 1, a vertically arranged pressing motor 9.2 and a pressing plate 9.3 which can slide in the width direction of the channel 1.1 are connected to the first supporting seat 9.1, a first kidney-shaped hole 9.3.1 perpendicular to the sliding direction of the pressing plate is formed in the pressing plate 9.3, a first eccentric wheel 9.4 is connected to an output shaft of the pressing motor 9.2, a first positioning shaft 9.5 is connected to one radial end of the first eccentric wheel 9.4, and the first positioning shaft 9.5 is matched in the first kidney-shaped hole 9.3.1. In the structure, when the compressing motor 9.2 runs, under the rotating action of the first eccentric wheel 9.4 driving the first positioning shaft 9.5, the pressing plate 9.3 reciprocates along the width direction of the mounting rack 1, so as to drive the pressing plate 9.3 to move towards the sample rack in the channel 1.1 or alternatively move towards the direction far away from the sample rack, and the compressing limit or the releasing limit of the sample rack is realized.
On the other hand, in the embodiment, as shown in fig. 3, the length direction of the recovery tray 2 is perpendicular to the length direction of the channel 1.1, and one end of the recovery tray 2 close to the mounting rack 1 is communicated with the channel 1.1, specifically, one end of the recovery tray 2 close to the mounting rack 1 is open, and a through hole is opened on a side wall of the mounting rack 1 close to the open position, so as to form a channel passing hole for the sample rack to slide from the channel 1.1 to the recovery tray 2. More specifically, the recovery mechanism 3 is connected to the side of the mounting frame 1 opposite to the recovery tray 2, as shown in fig. 1, the recovery tray 2 is located at the front side of the mounting frame 1, and the recovery mechanism 3 is installed at the rear side of the mounting frame 1 at a position corresponding to the recovery tray 2. In the structure, when the empty sample rack with the test tubes unloaded moves from the tube unloading station 4 to the position corresponding to the recovery tray 2, the recovery mechanism 3 acts to drive the sample rack in the channel 1.1 to slide towards the angle vertical to the movement direction of the conveying belt 8 until the sample rack slides into the recovery tray 2, so that the sample rack is conveniently recovered, and the structure form does not influence the normal operation of the conveying belt 8.
In the above structure, as shown in fig. 3, 4 and 7, the recovery mechanism 3 includes a second supporting seat 3.1, a horizontal pushing plate 3.2 and a recovery driving component are slidably connected to the second supporting seat 3.1, and the recovery driving component is used for driving the horizontal pushing plate 3.2 to push the sample rack from the channel 1.1 to the recovery tray 2. More specifically, retrieve drive assembly including retrieving motor 12, be equipped with on the horizontal push pedal 3.2 rather than the perpendicular second waist type hole 3.2.1 of direction of sliding, be connected with second eccentric wheel 13 on retrieving motor 12's the output shaft, the radial one end of second eccentric wheel 13 is connected with second location axle 14, and second location axle 14 cooperation is in second waist type hole 3.2.1. In this structure, the rotation of the recovery motor 12 realizes that the horizontal push plate 3.2 slides back and forth alternately towards the direction vertical to the motion direction of the conveyor belt 8, and the sample rack on the conveyor belt 8 is pushed into the recovery tray 2 in sequence.
On the other hand, as shown in fig. 3, a stop mechanism 10 is arranged at a position, which is far away from one end of the tube unloading station 4 and is close to the recovery mechanism 3, on the mounting rack 1, when the driving mechanism drives the sample rack to reversely recover and move to abut against the stop mechanism 10, the sample rack corresponds to the open end of the recovery tray 2, the position of the sample rack is limited, then the recovery mechanism 3 pushes materials, so that the recovery mechanism 3 can accurately push the sample rack on the transmission band 8 to the recovery tray 2 to recover each time, and the recovery efficiency of the sample rack is effectively improved. More specifically, the stock stop mechanism 10 in the structure comprises a stop fork 10.1 and a stock stop motor 10.2 for the stop fork 10.1 to move horizontally; and when actuating mechanism drive sample frame began reverse motion, keep off material motor 10.2 drive and keep off fork 10.1 horizontal motion to passageway 1.1 in for realize stopping spacing of sample frame, when guaranteeing sample frame reverse motion to the recovery station under the drive of transmission band 8, sample frame and the accurate counterpoint of passageway hole position on the mounting bracket 1, when guaranteeing that recovery mechanism 3 pushes away the material action, sample frame can be fast, accurate entering recovery tray 2.
In addition, as shown in fig. 3, in the embodiment, two recovery trays 2 arranged side by side are connected to the front side of the mounting rack 1, and each recovery tray 2 corresponds to one recovery mechanism 3 and one material blocking mechanism 10, and when one recovery tray 2 is full of sample racks, the other recovery tray 2 starts to recover the sample racks. Of course, in other embodiments, the number of the recovery tray 2, the recovery mechanism 3 and the material blocking mechanism 10 may also be three or more according to the consideration of the actual use condition.
On the other hand, as shown in fig. 8 and 9, the sample rack transport mechanism 103 in this embodiment includes a second mounting rack 15 for placing the second sample rack 120, one end of the second mounting rack 15 is connected with a positioning mechanism, and the other end of the second mounting rack 15 is connected with a material pushing mechanism for pushing the second sample rack 120 on the second mounting rack 15 to move toward the positioning mechanism until the second sample rack 120 is clamped and limited between the positioning mechanism and the material pushing mechanism; in addition, the one end of the second installation frame 15 close to the positioning mechanism is further connected with a blanking mechanism for driving the second sample frame 120 to be separated from the second installation frame 15 and enter the next station, so that the second sample frame 120 with samples is automatically conveyed to the next station without manual operation, and the efficiency is improved.
In the above structure, in order to further improve the automation efficiency of sample detection, a two-dimensional code of corresponding information is preset on each second sample rack 120; in this embodiment, a second code scanner 18 is further disposed at an end of the second mounting frame 15 close to the positioning mechanism, as shown in fig. 8 and 9, when the second sample rack 120 moves to a corresponding position on the second mounting frame 15, the second code scanner 18 scans specific information of the second sample rack 120, so as to control the tube moving mechanism 104 to transfer the test tubes cached in the cached sample rack 101 to the second sample rack 120 according to information preset on the sample rack 2, thereby ensuring that no error occurs in the sample transfer process; on the other hand, the automation degree of the detection process is improved, and the detection efficiency is improved.
More specifically, in this embodiment, as shown in fig. 9, a positioning chute 15.1 extending along the length direction of the second mounting frame 15 and used for horizontally moving the second sample rack 120 is disposed at the upper end of the second mounting frame 15, and a discharge hole 15.2 for moving out the second sample rack 120 is disposed on one side wall of the positioning chute 15.1 near one end of the positioning mechanism, so that a discharge channel perpendicular to the sliding direction of the second sample rack 120 is formed at the position of the discharge hole 15.2; on the other hand, the above structure in which the positioning mechanism is movable in the sliding direction of the second sample rack 120, makes it possible to change the positioning position of the second sample rack 120 in the positioning chute 15.1; namely, the position of the second sample holder 120 corresponding to the discharge hole 15.2 or the position before reaching the discharge hole 15.2 is controlled by the position movement of the positioning mechanism. When the second sample holder 120 is located at the position before the discharge hole 15.2 is reached, the test tube is placed in the hole on the second sample holder 120 through the corresponding operation of the manipulator; when the second sample holder 120 is located at the position corresponding to the discharge hole 15.2, the blanking mechanism drives the second sample holder 120 to separate from the second mounting frame 15 and enter the next station.
As shown in fig. 8 and 10, the positioning mechanism in this embodiment includes a positioning seat 19, a positioning block 20 and a positioning driving component for driving the positioning block 20 to move toward the second sample rack 120 are slidably disposed on an upper end of the positioning seat 19. After the second sample rack 120 is placed in the positioning chute 15.1, the positioning driving assembly drives the positioning block 20 to move towards the position of the second sample rack 120 until the positioning block 20 extends to the set positioning position, then the pushing mechanism pushes the second sample rack 120 to move towards the position of the positioning mechanism until the second sample rack 120 is clamped and positioned between the positioning block 20 and the pushing mechanism, and then the test tube inserting and placing action in the next stage can be performed. The positioning driving assembly in this structure is the same as the aforementioned recovery driving assembly in structure, and drives the eccentric wheel to rotate through the driving motor, so as to realize the reciprocating motion of the positioning block 20, which is not described herein again. On the other hand, in order to further improve the moving stability of the positioning block 20, the upper end of the positioning seat 19 is connected with the positioning block 20 through a linear sliding rail, so that the positioning block 20 is prevented from deflecting in the sliding process.
In addition, as shown in fig. 11, the blanking mechanism includes a shifting fork 16 and a blanking driving assembly connected to the positioning seat 19, an avoiding chute 15.3 extending along the direction of the discharge port 15.2 is arranged at a position corresponding to the discharge port 15.2 at the bottom of the positioning chute 15.1, and the upper end of the shifting fork 16 is in sliding fit in the avoiding chute 15.3; the blanking driving assembly is used for driving the shifting fork 16 to reciprocate in the avoiding chute 15.3 so as to realize automatic blanking of the second sample rack 120. More specifically, the blanking driving assembly comprises a belt pulley assembly 21 and a shifting fork motor 22 for driving the belt pulley assembly 21 to move, the shifting fork 16 is connected to a transmission belt 23 of the belt pulley assembly 21, and the shifting fork 16 moves back and forth along the avoiding chute 15.3 by the reciprocating motion of the belt pulley assembly 21.
More specifically, the pushing mechanism comprises at least one pushing claw 24, the pushing claw 24 is slidably arranged on the side wall of the positioning chute 15.1, and one end of the pushing claw 24 extends into the cavity of the positioning chute 15.1; the lower end of the second mounting frame 15 is connected with a push pawl driving component for driving the push pawl 24 to move back and forth along the positioning sliding groove 15.1. In this embodiment, preferably, there are two push claws 24, and the two push claws 24 are symmetrically disposed on two sides of the positioning chute 15.1, when the second sample rack 120 is placed in the positioning chute 15.1, the push claw driving assembly drives the two push claws 24 to push the second sample rack 120 to move toward the end where the positioning mechanism is located, until the second sample rack 120 is pressed and positioned between the positioning block 20 and the push claws 24, and when the second sample rack 120 is located at the limiting position, the second sample rack 120 has not reached the discharge hole 15.2; at this moment, the tube moving mechanism 104 grabs the test tube on the buffer sample rack 101 and places the test tube into a corresponding vacant position on the second sample rack 120, after the test tube is placed, the positioning block 20 resets towards a position far away from the second sample rack 120, the pushing claw driving assembly continues to drive the two pushing claws 24 to push the second sample rack 120 to move forward by a rack position distance of the second sample rack 120, then the shifting fork driving assembly drives the shifting fork 16 to move, and further the shifting fork 16 drives the second sample rack 120 to be separated from the discharge port 15.2, and the test tube moves to a next station. In the above structure, the pusher dog driving assembly also adopts a belt pulley driving structure, as shown in fig. 12 and 13, a pusher dog motor 25 is connected to a lower portion of one end of the second mounting frame 15, a first belt pulley 26 is connected to an output shaft of the pusher dog motor 25, a second belt pulley 27 is rotatably connected to a position, close to the first belt pulley 26, of a lower portion of one end of the second mounting frame 15, a third belt pulley 28 is further rotatably connected to a lower portion of the other end of the second mounting frame 15, the first belt pulley 26 is in linkage connection with the second belt pulley 27 through a first belt 29, the second belt pulley 27 is in linkage connection with the third belt pulley 28 through a second belt 30, a connecting plate 31 extending in a width direction of the second mounting frame 15 is slidably connected to a lower end of the second mounting frame 15, the connecting plate 31 is connected to the second belt 30, the two pusher dogs 24 are connected to two ends of the connecting plate 31, the first belt pulley 26 is driven to rotate by the pusher dog motor 25, the second belt pulley 27 is driven to rotate, the second belt pulley 27 to rotate, the second belt 30 drives the connecting plate 31 to move, and finally realize the pushing movement of the two pusher dogs 24.
In another aspect, as shown in fig. 1, 2 and 14, the tube moving mechanism 104 in this embodiment includes a supporting frame 18 mounted on the upper end of the worktable 100, a sliding frame 32 slidable along the Y-axis direction is connected to the upper end of the supporting frame 18, and a Y-axis moving assembly for driving the sliding frame 32 to move, where the Y-axis moving assembly includes a Y-axis moving motor 33 and a first synchronous belt 34 moving along the Y-axis direction of the supporting frame 18, and the Y-axis moving motor 33 rotates to drive the first synchronous belt 34 to rotate to drive the sliding frame 32 to move along the Y-axis direction; on the other hand, a sliding seat 35 capable of moving along the X-axis direction and an X-axis moving assembly for driving the sliding seat 35 to move are slidably connected to the sliding frame 32, and specifically, the X-axis moving assembly includes an X-axis moving motor 36 and a second synchronous belt 37 moving along the X-axis direction of the supporting frame 18, in this structure, the operation of the X-axis moving motor 36 drives the second synchronous belt 37 to rotate in parallel, so as to drive the sliding seat 35 to move horizontally along the X-axis direction on the sliding frame 32; in addition, a test tube chuck 19 which can slide along the Z-axis direction and a Z-axis moving assembly for driving the test tube chuck 19 to move are connected to the sliding seat 35; the Z-axis moving assembly includes a Z-axis moving motor 38 and a third timing belt 39 moving along the Z-axis direction of the supporting frame 18; the third timing belt 39 is driven to rotate by the operation of the Z-axis moving motor 38, and the test tube chuck 19 is driven to move up and down along the Z-axis direction on the slide base 35. In the structure, the movement of the test tube chuck 19 at any position in the XYZ coordinate system can be realized through the movement of the X-axis moving assembly, the Y-axis moving assembly and the Z-axis moving assembly, so that the automatic transfer of the test tubes in the first sample rack 110, the buffer sample rack 101 and the second sample rack 120 is realized, and the structure is very convenient. More specifically, test tube chuck 19 in this structure is the electric cylinder clamping jaw, and the centre gripping clearance of clamping jaw is controlled through the electric cylinder promptly, can realize the flexibility of the test tube of different diameters, stably snatch.
As shown in fig. 15, the sample discharging and rail changing mechanism 105 includes a third mounting rack 40, a first channel 105.1 and a second channel 105.2 are provided at one end of the upper portion of the third mounting rack 40, three conveyor belt assemblies extending along the X-axis direction are provided on the third mounting rack 40, and three sample sending channels respectively corresponding to the three conveyor belt assemblies, namely, a first channel 105.1, a second channel 105.2 and a review channel 105.3 are provided at one end of the third mounting rack 40 along the X-axis direction; the third mounting rack 40 is further connected with a track change base 41 for placing the sample rack and a track change driving assembly for driving the track change base 41 to reciprocate along the Y-axis direction, and in this structure, the track change base 41 is substantially a limit stop rack, an avoidance channel for the second sample rack 120 to pass through is opened on the track change base 41, specifically, the track change base 41 can be respectively corresponding to the first channel 105.1, the second channel 105.2 or the review channel 105.3 by driving the track change base 41 to move along the Y-axis direction through the track change driving assembly, and the second sample rack 120 can be discharged from the first channel 105.1 or the second channel 105.2 to the analyzer of the next station through the operation of the corresponding conveyor belt assemblies. In addition, the review channel 105.3 in this structure means that when the samples sent out from the first channel 105.1 and the second channel 105.2 need to be reviewed, the rail changing base 41 moves to the position corresponding to the review channel 105.3, the sample rack is reversely transported from the channel to the avoidance channel on the rail changing base 41, and then the reviewed sample rack is tracked again to be sent out from the first channel 105.1 or the second channel 105.2 for detection according to the requirement. As shown in fig. 15, the rail-changing driving assembly 17 in this structure is also composed of a driving motor, a conveying belt, and the like, and the motor drives the conveying belt to operate to drive the rail-changing base 41 to move, which is not described again.
In the structure of the sample discharging and rail changing mechanism 105, in order to correctly select a corresponding sample feeding channel from the second sample holder 120 on the rail changing base 41, a stopping mechanism is further disposed on the third mounting rack 40, the stopping mechanism includes a stopping motor 42, a rotating disc 43 is connected to an output shaft of the stopping motor 42, a central position of the rotating disc 43 is connected to an output shaft of the stopping motor 42, a shift rod 44 is connected to a radial outer end of the rotating disc 43, a stopping rod 45 is rotatably connected to the third mounting rack 40, a lower end of the stopping rod 45 abuts against the shift rod 44, and when the stopping motor 42 drives the rotating disc 43 to rotate in the forward and reverse directions, the stopping rod 45 rotates around a connection point with the third mounting rack 40, so that an upper end of the stopping rod 45 moves to a position of the first channel 105.1 or a position away from the first channel 105.1. In the structure, a reset element is arranged at a connection point of the stopping rod 45 and the third mounting frame 40, namely, the upper end of the stopping rod 45 is located at a position far away from the first channel 105.1 at an initial position, at this time, the stopping rod 45 cannot stop the sample rack in the first channel 105.1, when the sample rack needs to take out a sample from the second channel 105.2, the stopping motor 42 drives the stopping rod 45 to rotate, so that the upper end of the stopping rod 45 moves to a position corresponding to the first channel 105.1 to stop the sample rack, when a subsequent sample rack needs to take out the sample from the first channel 105.1 again, the stopping motor 42 reversely rotates, and the stopping rod 45 resets and rotates to the initial position under the action of the reset element.
Specifically, the three sample feeding channels and the rail changing mechanism are all of a motor and transmission belt transmission structure. The second sample rack 120 is shifted into the rail changing base 41 under the action of the shifting fork 16 of the blanking mechanism, the rail changing base 41 corresponds to the first channel 105.1 at the initial position, and if the rail changing base is used for conventional detection, the rail changing base directly passes through the first channel; if the emergency detection is performed, the stopping motor 42 drives the upper end of the stopping rod 45 to move to the position of the first channel 105.1 to stop the second sample rack 120, then, under the action of the rail changing driving assembly, the rail changing base 41 moves along the Y-axis direction to drive the corresponding second sample rack 120 to enter the position corresponding to the second channel 105.2, and the second sample rack 120 is conveyed from the second channel 105.2 under the action of the conveyor belt of the second channel 105.2.
As shown in fig. 2 and 19, a drawer mechanism 106 is further provided on the working platform 100, specifically, the drawer mechanism 106 mainly includes a fourth mounting rack 46 and a tray 47, a slide rail for sliding the tray 47 is provided on the fourth mounting rack 46, a tray bottom plate 48 is provided on the slide rail, four trays 47 are placed on the tray bottom plate 48, and the four trays 47 can be functionally divided as required, such as storing emergency samples, routine samples, calibration products, etc., and each tray 47 can store 50 samples. Specifically, a handle 49 is connected to the tray bottom plate 48, and the tray 47 can be pulled out by pulling the handle 49, and then the tray 47 can be taken in and out. The drawer mechanism 106 in this configuration is provided primarily to allow the sample transfer apparatus of this embodiment to be used in stand-alone mode, with the steps of:
first, a calibration material, a quality control material, a sample test tube, and the like are put into the tray 47 of the drawer mechanism 106;
the empty second sample rack 120 is transferred to the positioning mechanism;
the tube moving mechanism 104 moves the test tubes in the drawer mechanism 106 to the rotary code scanning mechanism 107 for code scanning; after the code scanning is completed, the tube moving mechanism 104 moves the test tube to the second sample rack 120;
the feeding mechanism drives the second sample rack 120 to enter the sample-discharging rail-changing mechanism 105, and a corresponding channel is selected according to a required detection mode for sample discharging and inspection.
The rotating code scanning mechanism 107 in the single machine operation mode is a conventional structure, and is mainly used for holding the test tube and performing code scanning identification of the barcode on the sidewall by rotating the test tube, which can be specifically referred to in the patent CN214278957U filed by the same applicant, and the detailed structure is not described herein again.
In another aspect, the transfer device of this embodiment may further perform an online mode in addition to the stand-alone mode:
the specific work flow is
A first sample rack 110 provided with test tubes is fed from the front processing production line and enters a sample rack conveying and recovering mechanism 102 on the workbench 100, a tube moving mechanism 104 transfers the test tubes on the first sample rack 110 to a cache sample rack 101, and then the empty first sample rack 110 is recovered to the recovery tray 2;
the second sample rack 120 is conveyed to the tube placing station, the second code scanner 18 scans the second sample rack 120, and the tube moving mechanism 104 transfers the test tubes on the cached sample rack 101 to the second sample rack 120;
the feeding mechanism drives the second sample rack 120 to enter the sample-discharging rail-changing mechanism 105, and selects a corresponding channel to discharge the sample according to a required detection mode for inspection.
In the online working mode, the first sample rack 110 and the second sample rack 120 are different in specification, automatic transfer of test tubes between sample racks of different specifications is realized through the operation, manual sorting is replaced, the working efficiency is improved, and the transfer error rate is reduced.
The utility model discloses in the description: the first channel 105.1 represents a conventional detection channel and the second channel 105.2 represents an emergency detection channel.
Although the present disclosure has been described above, the scope of the present disclosure is not limited thereto. Those skilled in the art can make various changes and modifications without departing from the spirit and scope of the present disclosure, and such changes and modifications will fall within the scope of the present invention.
Claims (10)
1. A sample transfer apparatus, characterized by: comprises a workbench (100), wherein the workbench (100) is provided with a
A buffer sample rack (101) for temporarily storing test tubes;
the sample rack conveying and recovering mechanism (102) is used for conveying a first sample rack (110) filled with test tubes from the first feeding end of the workbench (100) to the tube unloading station (4), and after the test tubes on the first sample rack (110) are unloaded and transferred to the buffer sample rack (101), the sample rack conveying and recovering mechanism (102) is used for recovering the empty first sample rack (110);
the sample rack conveying mechanism (103) is used for conveying the empty second sample rack (120) from the second feeding end of the workbench (100) to the pipe placing station;
a tube moving mechanism (104) for transferring test tubes on a first sample rack (110) to a buffered sample rack (101) and transferring test tubes in the buffered sample rack (101) to the second sample rack (120);
go out appearance and trade rail mechanism (105), it is equipped with first passageway (105.1), second passageway (105.2) and a drive assembly that appears to go out to appear to trade on rail mechanism (105), it is used for the drive to be equipped with second sample frame (120) of test tube and follows to go out appearance drive assembly first passageway (105.1) or second passageway (105.2) shift out workstation (100) get into next detection station.
2. The sample transfer apparatus of claim 1, wherein: the sample rack conveying and recovering mechanism (102) comprises a first mounting rack (1) arranged on a workbench (100), wherein a channel (1.1) extending along the length direction of the first mounting rack (1) and a driving mechanism are arranged on the first mounting rack (1), and the driving mechanism is used for driving a first sample rack (110) to slide in the channel (1.1) in a reciprocating manner so as to realize conveying and recovering of the first sample rack; the first mounting rack (1) is further connected with at least one recovery tray (2) used for containing the first sample rack (110) and a recovery mechanism (3) used for driving the empty first sample rack (110) to move to the recovery tray.
3. The sample transfer apparatus of claim 2, wherein: a pressing mechanism (9) is further connected to the position, corresponding to the pipe unloading station (4), of any one side of the first mounting frame (1) in the width direction; hold-down mechanism (9) are including connecting first supporting seat (9.1) on first mounting bracket (1) lateral wall, be connected with on first supporting seat (9.1) and compress tightly motor (9.2) and towards passageway (1.1) width direction slidable clamp plate (9.3), be equipped with on clamp plate (9.3) rather than sliding direction looks vertically first waist type hole (9.3.1), be connected with first eccentric wheel (9.4) on the output shaft that compresses tightly motor (9.2), first eccentric wheel (9.4) radial one end is connected with first locating shaft (9.5), first locating shaft (9.5) cooperation is in first waist type hole (9.3.1).
4. The sample transfer apparatus of claim 2 or 3, wherein: retrieve mechanism (3) including second supporting seat (3.1) of connection on first mounting bracket (1), sliding connection has horizontal push pedal (3.2) and retrieves drive assembly on second supporting seat (3.1), it is used for the drive to retrieve drive assembly horizontal push pedal (3.2) horizontal migration realizes retrieving first sample frame (110) propelling movement from passageway (1.1) in retrieve in tray (2).
5. The sample transfer apparatus of claim 1, wherein: the sample rack transmission mechanism (103) comprises a second mounting rack (15) for placing a second sample rack (120), one end of the second mounting rack (15) is connected with a positioning mechanism, and the other end of the second mounting rack (15) is connected with a material pushing mechanism for pushing the second sample rack (120) to move towards the positioning mechanism until the second sample rack (120) is clamped and limited between the positioning mechanism and the material pushing mechanism; one end, close to the positioning mechanism, of the second mounting frame (15) is further connected with a blanking mechanism which is used for driving a second sample frame (120) filled with samples to be separated from the second mounting frame (15) and enter a feeding channel of the sample discharging and rail replacing mechanism (105).
6. The sample transfer apparatus of claim 5, wherein: the blanking mechanism comprises a shifting fork (16) and a blanking driving assembly which are connected to the second mounting frame (15), a discharge hole (15.2) is formed in one end, close to the positioning mechanism, of the second mounting frame (15), an avoiding chute (15.3) extending along the discharge direction is formed in the position, corresponding to the discharge hole (15.2), of the bottom wall of the second mounting frame (15), and the upper end of the shifting fork (16) is in sliding fit with the avoiding chute (15.3); the blanking driving assembly is used for driving the shifting fork (16) to slide in the avoiding chute (15.3), so that the second sample rack (120) is separated from the second mounting rack (15) and enters the sample discharging and rail changing mechanism (105).
7. The sample transfer apparatus of claim 5, wherein: the pushing mechanism comprises at least one pushing claw (24), the pushing claw (24) is slidably arranged on the side wall of the second mounting frame (15), the lower end of the second mounting frame (15) is connected with a pushing claw driving assembly used for driving the pushing claw (24) to reciprocate along the length direction of the second mounting frame (15), and the pushing claw driving assembly is used for continuously pushing the vacant second sample frame (120) to a position abutting against the positioning mechanism.
8. The sample transfer apparatus of claim 1, wherein: move a mechanism (104) and include support frame (18) and test tube chuck (19), be connected with on support frame (18) and be used for driving test tube chuck (19) move the subassembly along the X axle that X axle direction removed, move the subassembly along the Y axle that Y axle direction removed and move the subassembly along the Z axle that Z axle direction removed.
9. The sample transfer apparatus of claim 1, wherein: the sample discharging and rail changing mechanism (105) comprises a third mounting rack (40), a first channel (105.1) and a second channel (105.2) are arranged at one end of the third mounting rack (40) along the X-axis direction, and a conveyor belt assembly for driving the second sample rack (120) to move in the first channel (105.1) or the second channel (105.2) is arranged on the third mounting rack (40); the other end of the third installation rack (40) in the X-axis direction is connected with a rail changing base (41) used for limiting the sample rack and a rail changing driving assembly used for driving the rail changing base (41) to move in the Y-axis direction, and the rail changing driving assembly is used for driving the rail changing base (41) to drive the corresponding sample rack to move to a position corresponding to the first channel (105.1) or the second channel (105.2) to send samples.
10. The sample transfer apparatus of claim 1, wherein: still be connected with drawer mechanism (106) and rotatory yard mechanism (107) of sweeping on workstation (100), be equipped with tray (47) that are used for placing the test tube on drawer mechanism (106), work as when sample transfer device carries out stand-alone mode, move tub mechanism (104) and be arranged in shifting the test tube in tray (47) to rotatory yard mechanism (107) of sweeping, work as the yard mechanism (107) are swept in the rotation and the back is accomplished to the yard, move tub mechanism (104) and be arranged in sweeping the test tube in yard mechanism (107) with the rotation and shift to corresponding second sample frame (120).
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
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CN116699164A (en) * | 2023-07-20 | 2023-09-05 | 成都博奥独立医学实验室有限公司 | Detection sample conveying device |
CN117590008A (en) * | 2023-11-20 | 2024-02-23 | 中元汇吉生物技术股份有限公司 | Sample scheduling method for cascade sample processing device and cascade sample processing device |
CN117686725A (en) * | 2024-02-04 | 2024-03-12 | 烟台艾德康生物科技有限公司 | Sample feeding device for assembly line |
-
2022
- 2022-03-17 CN CN202220589571.3U patent/CN218412573U/en active Active
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN116699164A (en) * | 2023-07-20 | 2023-09-05 | 成都博奥独立医学实验室有限公司 | Detection sample conveying device |
CN116699164B (en) * | 2023-07-20 | 2023-10-10 | 成都博奥独立医学实验室有限公司 | Detection sample conveying device |
CN117590008A (en) * | 2023-11-20 | 2024-02-23 | 中元汇吉生物技术股份有限公司 | Sample scheduling method for cascade sample processing device and cascade sample processing device |
CN117686725A (en) * | 2024-02-04 | 2024-03-12 | 烟台艾德康生物科技有限公司 | Sample feeding device for assembly line |
CN117686725B (en) * | 2024-02-04 | 2024-04-30 | 烟台艾德康生物科技有限公司 | Sample feeding device for assembly line |
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