CN212197470U - Test tube recovery device - Google Patents

Abstract

The utility model discloses a test tube recovery unit, it includes upset portion, drive division and recycling bin, places many test tubes in the upset portion, and the drive division is used for the upset of drive upset portion, and the recycling bin is located the below of upset portion, and when upset portion overturns to certain inclination under the effect of drive division, the test tube breaks away from upset portion, falls into in the recycling bin. The test tube recovery device can realize batch recovery operation of test tubes, and greatly improves the recovery efficiency of the test tubes.

Description

Test tube recovery device

Technical Field

The utility model relates to a sample storage technical field especially relates to a test tube recovery unit.

Background

When a hospital clinical laboratory detects a sample such as blood or urine, the sample is usually placed in a test tube for related operations. After the sample detection is finished, the test tube is placed in an environment with the temperature of 2-8 ℃ for storage for seven days. And selecting samples needing to be subjected to reinspection in the seven-day process. Samples that do not require review and have a shelf life of seven days require recovery processing.

For a common hospital, the daily sample treatment amount is 2000-3000, and for test tubes needing to be recycled, the test tubes need to be recycled and scrapped one by one, so that batch recycling and scrapping of the test tubes cannot be realized, and the test tube recycling process is complicated and the efficiency is low.

The above information disclosed in this background section is only for enhancement of understanding of the background of the application and therefore it may comprise prior art that does not constitute known to a person of ordinary skill in the art.

Disclosure of Invention

In view of this, the utility model provides a test tube recovery unit realizes the batch recovery operation of test tube, improves test tube recovery efficiency.

In order to realize the purpose of the utility model, the utility model adopts the following technical scheme to realize:

the utility model provides a test tube recovery unit, include: a turnover part on which a plurality of test tubes are placed; the driving part is connected with the overturning part and drives the overturning part to overturn; a recovery barrel located below the turning part; the turnover part is in when upset to certain inclination under the effect of drive division, the test tube breaks away from the turnover part, falls into in the recycling bin.

Further, a test tube tray is placed on the turnover part, and the test tube is placed in the test tube tray; be equipped with clamping jaw portion on the upset portion, when the upset portion overturns, clamping jaw portion centre gripping test tube tray.

Further, upset portion includes first curb plate, second curb plate and locates first curb plate with bottom plate between the second curb plate, first curb plate the second curb plate and the bottom plate encloses to become to be used for placing the accommodation space of test tube tray, the test tube tray place in on the bottom plate, the top and the front end of upset portion are open the form, when upset portion overturns to certain inclination, the front end of upset portion is less than the rear end of upset portion.

Furthermore, the clamping jaw part is arranged at the rear end of the overturning part.

Further, clamping jaw portion includes the clamping jaw of two relative settings, two clamping jaw relative motion, centre gripping the lateral wall of test tube tray.

Furthermore, the rear end of the overturning part is provided with a sliding rail part, the clamping jaw is provided with a sliding block, and the sliding block is connected with the sliding rail part in a sliding manner.

Furthermore, a concave part is arranged on the bottom plate, and the bottom of the test tube tray is placed on the concave part.

Furthermore, top plates are respectively arranged at the tops of the first side plate and the second side plate, the distance between the two top plates is smaller than the width of the test tube tray, and the test tubes placed on the test tube tray are exposed out of the space between the two top plates; the test tube tray is placed into the accommodating space from the front end of the overturning part.

Furthermore, the driving part comprises a driving gear and a driven gear meshed with the driving gear, and the output shaft end of the driven gear is fixedly connected with the overturning part.

Further, the diameter of the driving gear is smaller than that of the driven gear.

Compared with the prior art, the utility model discloses an advantage is with positive effect:

the application discloses test tube recovery unit includes upset portion, drive division and recycling bin, places many test tubes in the upset portion, and drive division is used for driving the upset of upset portion, and the recycling bin is located the below of upset portion, and when upset portion overturns to certain inclination, the test tube breaks away from upset portion, falls into in the recycling bin. The test tube recovery device can realize batch recovery operation of test tubes, and greatly improves the recovery efficiency of the test tubes.

Other features and advantages of the present invention will become more apparent from the following detailed description of the invention when read in conjunction with the accompanying drawings.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive labor.

Fig. 1 is a first schematic structural diagram of an embodiment of a sample storage library of the present invention;

fig. 2 is a schematic structural diagram of a sample storage library according to an embodiment of the present invention;

FIG. 3 is a schematic structural view of an embodiment of the capping device for test tubes according to the present invention;

FIG. 4 is a top view of a cap supply assembly in an embodiment of the test tube capping device of the present invention;

FIG. 5 is a schematic structural view of a top cap picking part in an embodiment of the capping device for test tubes according to the present invention;

FIG. 6 is a first schematic structural diagram of an embodiment of the test tube recycling device of the present invention;

FIG. 7 is a schematic structural diagram of a second embodiment of the test tube recycling device of the present invention;

fig. 8 is a schematic structural view of the test tube recycling device shown in fig. 7 from another view angle.

Reference numerals:

01-a sorting library, 011-a first test tube placing area, 012-a second test tube placing area, 013-a third test tube placing area, 014-a temporary storage rack;

02-storage repository, 021-storage rack;

03-test tube conveying line, 031-first test tube fixing portion;

04-test tube conveying platform, 041-track part, 042-sliding platform, 043-second test tube fixing part;

05-a scanning device;

06-drawing frame;

07-test tube trays;

081-first robot, 082-second robot, 083-third robot, 084-fourth robot;

09-framework;

10-test tube capping device;

101-top cover feeding assembly, 1011-top cover feeding part, 1012-top cover conveying line, 1013-top cover separating part, 10131-first separating part, 10132-second separating part, 10133-partition plate, 10134-groove part;

102-top cover pickup assembly, 1021-top cover pickup, 10211-upper frame, 10212-lower frame, 10213-flap, 10214-link, 10215-drive, 10216-pickup lever, 10217-spring, 1022-first horizontal rail portion, 1023-vertical rail portion;

103-a tube placement assembly, 1031-a second horizontal track section, 1032-a platform section;

20-test tube recovery device;

201-turnover part, 2011-first side plate, 2012-second side plate, 2013-bottom plate, 2014-concave part, 2015-stop plate, 2016-top plate, 2017-sliding rail part;

202-drive, 2021-drive gear, 2022-driven gear;

203-recycling bin;

204-jaw part, 2041-jaw, 2042-slider;

30-a top cover;

40-test tube.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

It should be noted that in the description of the present invention, the terms of direction or positional relationship indicated by the terms "upper", "lower", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, which are merely for convenience of description, and do not indicate or imply that the device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and "fourth" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

The utility model discloses a sample repository for the test tube to the splendid attire sample is saved, can be applied to places such as hospital. Fig. 1 is a schematic diagram of a frame structure of the test tube storage device, and a frame 09 is removed to obtain the view shown in fig. 2 in order to more clearly express the internal structure.

The sample storage library comprises a sorting library 01 and a storage library 02, wherein the sorting library 01 is mainly used for warehousing, ex-warehouse, temporary storage, code scanning identification, test tube capping and test tube recovery of test tubes, and the storage library 02 is mainly used for storage of the test tubes. Both the collator 01 and the storage reservoir 02 can provide the cryogenic environment required for test tube storage.

The collation bank 01 has a first test tube port through which test tubes enter the inside of the collation bank 01 or through which test tubes are removed from the inside of the collation bank 01. The inside of arrangement storehouse 01 is equipped with the frame 014 that keeps in that is used for placing the test tube, and the test tube keeps in on the frame 014 that keeps in.

The storage warehouse 02 is provided with a plurality of storage racks 021 for placing test tubes, and the test tubes are temporarily stored in the temporary storage rack 014 for a certain time and then transported to the storage racks 021 for storage.

The sorting library 01 is communicated with the storage library 02 to convey the test tubes between the sorting library 01 and the storage library 02, specifically, a first transfer port is formed in the sorting library 01, a second transfer port is correspondingly formed in the storage library 02, and the first transfer port is communicated with the second transfer port.

The inside of arrangement storehouse 01 is equipped with scanning device 05, and it is used for sweeping the sign indicating number discernment to the test tube to the realization is to the traceable storage of test tube.

The inside of arrangement storehouse 01 is equipped with test tube capping device 10, and it is used for adding the lid to the test tube after the scanning and seals to the storage in later stage.

The inside of the storage 01 is provided with a test tube recovery device 20 for recovering test tubes stored due to expiration so as to prevent the environment from being polluted by the expired samples.

The transport of the test tubes throughout the storage process is achieved by a robot, in particular, three robots are provided in the sample storage magazine, respectively a second robot 082, a third robot 083 and a fourth robot 084. The second manipulator 082 is arranged in the sorting warehouse 01 and used for conveying the test tubes to be warehoused to the scanning device 05 for scanning, and the scanned test tubes are conveyed to the temporary storage rack 014 for temporary storage. The third manipulator 083 is arranged inside the storage warehouse 01 and is used to transport the test tubes among the test tube capping device 10, the temporary storage rack 014, the first transfer port, the first test tube port and the test tube recovery device 20. A fourth robot 084 is provided inside the storage warehouse 02 for transporting the test tubes between the second transfer opening and the storage rack 021.

The sample storage warehouse can realize batch storage of a plurality of test tubes and storage of a single test tube so as to meet different storage requirements of customers.

When a plurality of test tubes are put in a warehouse, the plurality of test tubes enter the interior of the sorting warehouse 01 through the first test tube port; the second manipulator 082 clamps the single test tube one by one and transports to the scanner 05 for code scanning and identification; after all the test tubes are scanned, the third manipulator 083 conveys the test tubes to the test tube capping device 10 for capping; then the third manipulator 083 conveys the covered test tubes to a temporary storage rack 014 for temporary storage; after the test tube is placed in the temporary storage rack 014 for a period of time, the third manipulator 083 conveys the test tube to the first delivery port; because the first transfer port is communicated with the second transfer port, the fourth manipulator 084 can clamp the test tubes through the second transfer port and transport the test tubes to the storage rack 021 for storage, and at this point, the warehousing and storage of a plurality of test tubes are finished.

Aiming at the situation that a single test tube is put in storage, the sample storage warehouse is also provided with a second test tube opening on the sorting warehouse 01, a test tube conveying platform 04 is arranged inside the sorting warehouse 01, and a test tube conveying line 03 and a first manipulator 081 are arranged outside the sorting warehouse 01. The second test tube mouth is used as the import of putting in storage of single test tube, and test tube conveying platform 04 is just right with the second test tube mouth.

When a single test tube is put in a warehouse, the single test tube is conveyed to a second test tube port of the sorting warehouse 01 through the test tube conveying line 03, and the first manipulator 081 clamps the test tube to be put in the warehouse and places the test tube on the test tube conveying platform 04; the test tube conveying platform 04 drives the test tubes to enter the sorting warehouse 01 through the second test tube ports; the second manipulator 082 clamps the test tube and conveys the test tube to the scanning device 05 for code scanning and identification; the third manipulator 083 conveys the test tube after scanning to the test tube capping device 10 for capping; then, the third manipulator 083 conveys the capped test tubes to a temporary storage rack 014 for temporary storage; after the test tube is placed in the temporary storage rack 014 for a period of time, the third manipulator 083 clamps the test tube and conveys the test tube to the first delivery port; because first transfer mouth and second transfer mouth intercommunication, fourth manipulator 084 can press from both sides the test tube clamp through the second transfer mouth, transport the test tube to storage rack 021 and go on storing again, and this moment, the warehouse entry of single test tube is saved completely.

When the test tube is delivered out of the warehouse, the fourth manipulator 084 conveys the test tube to be delivered out of the warehouse on the storage rack 021 to the second delivery port; since the first transfer port is communicated with the second transfer port, the third manipulator 083 can grip the test tube at the first transfer port and transport the test tube to the first test tube port; the test tube is delivered out of the warehouse through the first test tube port.

The batch warehouse entry process of a plurality of test tubes and the warehouse entry process of single test tube of contrast can know, and a plurality of test tubes can get into the inside of arrangement storehouse 01 simultaneously through first test tube mouth, and single test tube gets into the inside of arrangement storehouse 01 through dedicated test tube transfer chain 03 and test tube conveying platform 04, and the test tube is roughly the same at the inside follow-up storage process of arrangement storehouse 01. Through the test tube entry of two differences, be favorable to improving test tube storage efficiency on the one hand, on the other hand also can adapt to the multi-scene user demand in places such as hospital more.

The reason for the design is that, taking a hospital application scene as an example, the checked sample has the possibility of retest in a short time (such as half a day or one day), and temporarily storing the test tube on the temporary storage rack 014 is to quickly find out and take out the test tube from the temporary storage rack 014 when the sample put in storage at the same day is retested, so that the retest efficiency is improved. In this embodiment, after the test tubes are placed on the temporary storage rack 014 for a time period exceeding the system setting time (4 hours), the test tubes are stored in the storage rack 02 for long-term storage under the action of the third manipulator 083 and the fourth manipulator 084. When the test tube on the temporary storage rack 014 needs to be rechecked in the system setting time, the third manipulator 083 clamps the test tube to be rechecked and conveys the test tube to the first test tube outlet for ex-warehouse.

The whole storage process of the sample storage warehouse does not need manual intervention, automatic storage of test tubes is achieved, and test tube storage efficiency is greatly improved. Meanwhile, the sorting library 01 and the storage library 02 are designed in a separation mode, and for test tubes needing to be subjected to reinspection, the test tubes only need to be searched on the temporary storage rack 014, so that the reinspection efficiency is improved; in addition, the design after separation is more helpful to guarantee the low-temperature storage environment of the test tube, and the storage safety of the sample is improved.

When a plurality of test tubes are put in a warehouse, the plurality of test tubes are placed on the test tube tray 07, the second manipulator 082 clamps the single test tube on the test tube tray 07 one by one and conveys the single test tube to the scanning device 05 for scanning, and the subsequent storage process is realized by taking the test tube tray 07 as a unit, which is beneficial to improving the storage efficiency. When a single test tube is put in storage, after the single test tube is scanned, the subsequent storage process is also operated by taking the test tube tray 07 as a unit. In other words, regardless of whether the multiple test tubes are stored in batch or single test tube, after the test tube scanning is completed, the third manipulator 083 and the fourth manipulator 084 will clamp the test tube tray 07 for subsequent storage operation.

As a preferred embodiment, a drawing frame 06 is provided at the first test tube opening, and the drawing frame 06 can move to the inside or outside of the storage 01 through the first test tube opening. The drawing frame 06 can be used for placing a test tube tray 07. When a plurality of test tubes are put in a warehouse in batch, the drawing frame 06 is drawn to the outside of the sorting warehouse 01, and an operator puts the test tube tray 07 provided with the plurality of test tubes on the drawing frame 06; then the drawing frame 06 is pushed into the sorting warehouse 01; and then the test tubes are subjected to subsequent storage operation.

When having the test tube to need the reinspection on the frame 014 of keeping in storage, third manipulator 083 will treat the test tube tray 07 clamp at the test tube place of reinspection and get and transport to pull frame 06 on, operating personnel takes out the outside of taking out to the arrangement storehouse 01 at the outside of arrangement storehouse 01 with pull frame 06, and operating personnel takes out the test tube of treating the reinspection, and then third manipulator 083 transports test tube tray 07 to the frame 014 of keeping in storage again.

Further, the inside of arrangement storehouse 01 is equipped with third test tube and places the district 013, and when many test tubes put in storage, the test tube tray 07 on the pull frame 06 is transported to the third test tube and places the district 013 earlier to third manipulator 083, and second manipulator 082 presss from both sides the test tube on the test tube tray 07 in the third test tube place the district 013 and carries out follow-up yard operation of sweeping. The third placement area 013 is configured to facilitate gripping of a single tube from the tube tray 07 by the second manipulator 082.

Further, in order to reduce the number of times of opening the door of the sorting warehouse 01, improve the storage temperature stability of the sorting warehouse 01, a plurality of test tube trays 07 can be placed simultaneously by the pull rack 06, and thus, an external operator can take out a plurality of test tubes on the plurality of test tube trays 07 simultaneously on the pull rack 06, and the efficiency is improved.

As a preferred embodiment, a first test tube placing area 011 and a second test tube placing area 012 are disposed in the storage 01, the second manipulator 082 places correctly scanned test tubes in the first test tube placing area 011, places incorrectly scanned test tubes in the second test tube placing area 012, and the third manipulator 083 transports the test tubes in the first test tube placing area 011 to the temporary storage rack 014.

Further, test tube trays 07 are respectively arranged in the first test tube placing area 011 and the second test tube placing area 012, and a plurality of test tubes can be placed in the test tube trays 07. The second manipulator 082 presss from both sides and gets a single test tube, and after scanning device scanned a sign indicating number discernment to a single test tube one by one, when placing the test tube (being the correct test tube of scanning) on the test tube tray 07 in the first test tube is placed the district 011 and reach a certain quantity, the third manipulator 083 presss from both sides whole test tube tray 07 clamp, transports to and temporarily stores on the frame 014 of keeping in.

As a preferred embodiment, the interval is equipped with a plurality of first test tube fixed parts 031 on the test tube transfer chain 03 to avoid the test tube to empty in the transportation.

As a preferred embodiment, the test tube conveying platform 04 includes a track portion 041 and a sliding platform 042 slidably disposed on the track portion 041, and the sliding platform 042 is provided with a second test tube fixing portion 043. When having the test tube warehouse entry, the warehouse entry mouth opens, and sliding platform 042 can move to the outside of arrangement storehouse 01, and first manipulator 081 will wait that the single test tube of warehouse entry puts into on the second test tube fixed part 043 on sliding platform 042, then sliding platform 042 is to the inside motion of arrangement storehouse 01 to transport the test tube to the inside of arrangement storehouse 01, so that follow-up storage operation. Second test tube fixed part 043 can avoid the test tube to empty in the transportation.

On the basis of any one of the above embodiments, the sorting library 01 has one storage library 02, the storage libraries 02 have a plurality of storage libraries, two adjacent storage libraries 02 are communicated with each other, and particularly, a transfer port is arranged between the two adjacent storage libraries 02, so that the code scanning and identification operation of test tubes is completed in one sorting library 01, the storage of the test tubes is completed in the plurality of storage libraries 02, and the storage capacity of the whole test tube storage device is greatly improved.

In this embodiment, one bank 01 is provided, and two banks 02 are provided.

After the test tubes are placed in the storage rack 021 for a set time (for example, seven days), the test tubes stored due are discarded. Specifically, the fourth manipulator 084 conveys the test tubes stored in the storage rack 021 due to expiration to the second transfer port; the third manipulator 083 conveys the test tube at the first delivery port to the test tube 20 recovery device; the test tube recovery device 20 performs recovery processing on the expired test tube. This test tube recovery unit 20 is put and can be realized the batch recovery of test tube, and is efficient.

The test tube capping device 10 is described in detail below, and the structural schematic diagram of the test tube capping device 10 is shown in fig. 3 to 5.

Test tube capping device 10 includes a cap supply assembly 101, a cap pick assembly 102, and a test tube placement assembly 103. Wherein the top cover feeding assembly 101 comprises a top cover conveying line 1012 and a top cover separating part 1013 for separating a plurality of top covers 30 on the top cover conveying line 1012; the top cover picking assembly 102 includes a top cover picking part 1021, and the top cover picking part 1021 can simultaneously pick up a plurality of top covers 30 separated by the top cover separating part 1013; the test tube placing assembly 103 is provided with a plurality of test tubes 40, and the top cover picking part 1012 can simultaneously buckle a plurality of top covers 30 into the plurality of test tubes 40 in a one-to-one correspondence manner.

After the test tubes 40 on the test tube tray 07 on the first test tube placement area 011 reach a certain number, the third manipulator 083 conveys the test tube tray 07 to the test tube placement assembly 103, and the top cap picking assembly 102 picks up a plurality of top caps 30 and snaps the top caps 30 onto the test tubes 40 to be capped. This test tube capping device 10 can realize adding the lid operation to many test tubes 40 simultaneously, has improved the test tube greatly and has added lid efficiency.

Referring to fig. 4, the top cover feeding assembly 101 includes a top cover feeding portion 1011, the top cover feeding portion 1011 is a conventional art and not described in detail, and provides the top covers 30 to the top cover conveying line 1012 at uniform intervals. The top cover partition 1013 includes a first partition 10131 and a second partition 10132 arranged oppositely, the first partition 10131 and the second partition 10132 extend along the top cover conveying line 1012, the first partition 10131 and the second partition 10132 can move towards or away from each other, and the first partition 10131 has a plurality of partitions 10133 distributed at intervals. When the first and second separating portions 10131 and 10132 move toward each other, the plurality of partitions 10133 may separate the plurality of top covers 30, so that the top cover pickup portion 1021 picks up the plurality of top covers 30 at the same time.

The first and second partitions 10131 and 10132 may be operated simultaneously to separate the plurality of caps 30, or one of them may be stationary and only the other may be operated. In the present embodiment, the side wall of the second partition 10132 abuts against the top cover 30, and the first partition 10131 moves toward/away from the second partition 10132. When the first partition 10131 moves in a direction approaching the second partition 10132, the second partition 10132 abuts against the top cover 30, so that the top cover 30 is prevented from being positionally displaced by the partition 10133.

Further, a groove portion 10134 is formed between two adjacent partition boards 10133, and when the first partition portion 10131 moves toward a direction approaching the second partition portion 10132, the top cover 30 is located in the groove portion 10134. The profiling design between the groove portions 10134 and the top covers 30 can separate a plurality of top covers 30, and can also play a good positioning role in the positions of the top covers 30, so that the top cover pickup portion 1021 can pick up the top covers 30 conveniently.

In this embodiment, the top cover separating unit 1013 simultaneously separates eight top covers 30, and accordingly, the top cover pickup unit 1021 can simultaneously pick up eight top covers 30 and simultaneously clip the eight top covers 30 into the corresponding test tubes 40.

Referring to fig. 5, the top cover pickup 1021 includes a plate-shaped upper frame 10211 and a plate-shaped lower frame 10212, a link 10214 is disposed between the upper frame 10211 and the lower frame 10212, two links 10214 are disposed at two ends of the upper frame 10211 and the lower frame 10212, and a distance between the upper frame 10211 and the lower frame 10212 is fixed. A plate-shaped movable plate 10213 is slidably disposed on the link 10214, and the movable plate 10213 is moved toward/away from the lower frame 10212 by a driving device 10215 (e.g., a driving motor). A plurality of pickup rods 10216 are disposed on the movable plate 10213, and a through hole (not labeled) for extending the pickup rods 10216 is correspondingly disposed on the lower frame 10212. The pickup lever 10216 is sleeved with a spring 10217, and the spring 10217 is located between the movable plate 10213 and the lower frame 10212.

When the movable plate 10213 moves toward the lower frame 10212, the free end portion of the pickup lever 10216 protrudes from the through hole, and the spring 10217 is compressed by force; the top cover pickup portion 1021 moves above the top cover transfer line 1012 and then descends, and the free end portions of the pickup levers 10216 simultaneously pick up a plurality of top covers 30 while the lower surface of the lower frame 10212 preferably abuts against the upper end surfaces of the top covers 30; then the top cover picking part 1021 moves to the upper part of the test tube placing component 103, the picking rod 10216 is opposite to the test tube 40 to be covered up and down, and the top cover picking part 1021 moves downwards to buckle the top cover 30 into the corresponding test tube 40; the movable plate 10213 moves towards the direction far away from the lower frame 10212, the free end of the pickup rod 10216 is separated from the top cover 30, the spring 10217 is reset, the lower frame 10212 can be always abutted against the top cover 30 under the action of the reset force of the spring, the top cover 30 is prevented from being separated from the test tube 40 along with the pickup rod 10216, and the buckling reliability of the top cover 30 is guaranteed.

As a preferred embodiment, in order to realize the movement of the top cover picking part 1021, the top cover picking assembly 102 further includes a first horizontal guide rail part 1022 extending along the X axis and a vertical guide rail part 1023 extending along the Z axis, wherein the vertical guide rail part 1023 can slide along the first horizontal guide rail part 1022, and the top cover picking part 1021 is disposed on the vertical guide rail part 1023 and can slide up and down along the vertical guide rail part 1023. The movement of the top cover pickup portion 2021 along the X axis can be achieved by the horizontal sliding of the vertical rail portion 1023 along the first horizontal rail portion 1022. By the movement of the top cover pickup assembly 102, the top cover pickup portion 1021 can accurately pick up the top cover 30.

When the top cover pickup portion 1021 picking up the top cover 30 is buckled on the test tube 40, in order to realize accurate positioning between the top cover 30 and the test tube 40, in this embodiment, the test tube placing assembly 103 includes a second horizontal rail portion 1031 extending along the Y axis and a platform portion 1032 slidably disposed on the second horizontal rail portion 1031, the test tube tray 07 is placed on the platform portion 1032, and a plurality of test tubes 40 are placed in the test tube tray 07. The movement of the test tube tray 07 along the Y axis is realized by the sliding of the stage section 1032 along the second horizontal rail section 1031. In this way, under the combined displacement of the top cover pickup portion 1021 and the platform portion 1032, accurate positioning of the top cover 30 and the test tube 40 can be achieved.

In the top cover pickup assembly 102, the upper frame 10211 is fixedly disposed on the vertical rail portion 1023, and the driving unit 10215 is fixedly disposed on the upper frame 10211, so that the structure is reliable and compact.

The top of the top cover 30 has a groove structure (not labeled), and the free end of the pick-up rod 10216 is in interference fit with the groove structure, so that the pick-up rod 10216 can pick up the top cover 30, and the structure is simple and reliable.

The number of test tubes 40 placed in a single column in the test tube tray 07 is the same as the number of caps 30 picked up at a single time by the cap pickup portion 1021. For example, eight caps 30 can be picked up simultaneously by the cap picking portion 1021 in a single time, and the number of test tubes 40 placed in a single row on the test tube tray 07 is eight, so that the cap picking assembly 102 performs the capping operation on the test tubes 40, and performs the row-by-row operation in the row of the test tube tray 07, which can greatly improve the capping efficiency and facilitate the alignment between the caps 30 and the test tubes 40.

When all the test tubes 40 on the test tube tray 07 are completely capped, the third robot 083 moves the test tube tray 07 to the temporary storage rack 014 for temporary storage.

The test tube recovery device 20 is described in detail below, and the structural schematic diagram of the test tube recovery device 20 is shown in fig. 6 to 8.

Referring to fig. 6, the test tube collecting apparatus 20 includes an inverting unit 201, a driving unit 202, and a collecting tank 203, wherein a plurality of test tubes 40 are placed on the inverting unit 201, the driving unit 202 is used for driving the inverting unit 201 to invert, and the collecting tank 203 is located below the inverting unit 201. When the test tubes in the storage warehouse 02 are stored to the end, the test tubes to be recovered on the storage rack 021 are conveyed to the sorting warehouse 01 under the action of the fourth manipulator 084 and the third manipulator 083, the third manipulator 083 conveys the test tubes to be recovered to the turnover part 201, referring to fig. 7 and 8, when the turnover part 201 is turned over to a certain inclination angle under the action of the driving part 202, the test tubes 40 are separated from the turnover part 201 and fall into the recovery barrel 203. This test tube recovery unit 20 can realize the operation of retrieving in batches of test tube, has improved test tube recovery efficiency greatly.

In order to further improve the test tube recovery efficiency, the test tube recovery device 20 is also based on the test tube tray 07 when operating, specifically, the turnover part 201 can place the test tube tray 07, and the third manipulator 083 conveys the test tube tray 07 placed with the test tubes to be recovered onto the turnover part 201. Referring to fig. 6, the turning part 201 is further provided with a clamping jaw part 204, when the turning part 201 turns, the clamping jaw part 204 clamps the test tube tray 07, when the test tube tray 07 turns to a certain inclination angle along with the turning part 201, the test tube 40 can be separated from the test tube tray 07 and fall into the recycling bin 203, and the test tube tray 07 cannot fall off under the action of the clamping jaw part 204.

Referring to fig. 8, turnover part 201 includes first curb plate 2011, second curb plate 2012, and locates bottom plate 2013 between first curb plate 2011 and second curb plate 2012, and first curb plate 2011, second curb plate 2012, bottom plate 2013 enclose the accommodation space that is used for placing test tube tray 07, and test tube tray 07 places on bottom plate 2013, and is located the accommodation space. The top and the front end of the turning part 201 are open, and when the turning part 201 turns to a certain inclination angle, the front end of the turning part 201 is lower than the rear end of the turning part 201. The test tube tray 07 enters/moves out of the inside of the turning part 201 through the front end of the turning part 201, and when the turning part 201 is turned to a certain inclination angle, the test tube 40 falls from the top of the turning part 201.

As a preferred embodiment, referring to fig. 7, a claw portion 204 is provided at the rear end of the inverting portion 201 to achieve gripping fixation of the test tube tray 07 without affecting the movement in/out of the test tube tray 07.

As a preferred embodiment, the clamping jaw portion 204 includes two oppositely disposed clamping jaws 2041, and the two clamping jaws 2041 are relatively movable in real time under the action of a driving device (such as a driving motor) to clamp the side wall of the test tube tray 07, so as to fix the test tube tray 07. When the test tube tray 07 needs to be removed from the turnover part 201, the two clamping jaws 2041 move back to release the test tube tray 07.

Further, referring to fig. 7, a slide rail portion 2017 is arranged at the rear end of the turnover portion 201, a slider 2042 is correspondingly arranged on the clamping jaw 2041, and the slider 2042 is slidably connected with the slide rail portion 2017, so that the clamping jaw 2041 is more stable in movement, and the clamping reliability of the clamping jaw 2041 on the test tube tray 07 is improved.

As a preferred embodiment, referring to fig. 8, a recess 2014 is provided on the bottom plate 2013, and the bottom of the test tube tray 07 is placed on the recess 2014. The recess 2014 makes the test tube tray 07 more reliably placed on the turning part 201 and less likely to slip off. In this embodiment, bottom plate 2013 comprises two relative little flat boards that set up, and bottom plate 2014 is equipped with backstop 2015 near the position department of upset portion 201 front end, can prevent that test tube tray 07 from slipping on upset portion 201 when upset portion 201 overturns.

As a preferred embodiment, with continued reference to fig. 8, the top of the first side plate 2011 and the top of the second side plate 2012 are respectively provided with a top plate 2016, the distance between the two top plates 2016 is smaller than the width of the test tube tray 07, and the test tubes 40 placed on the test tube tray 07 can be exposed from the gap between the two top plates 2016, so that when the turnover part 201 is turned over to a certain inclination angle, the test tubes 40 can fall into the recovery bucket 203 below from the gap between the two top plates 2016. In addition, the top plate 2016 provides some barrier to the test tube tray 07 in the event of a failure of the clamping jaws 2041 to clamp the test tube tray 07.

The third manipulator 083 moves the test tube tray 07 into/out of the accommodating space of the inverting part 201 from the front end of the inverting part 201, facilitating the operation.

Referring to fig. 6, the rotation of the tilting portion 201 is realized by a simple and reliable gear structure in the present embodiment, specifically, the driving portion 202 includes a driving gear 2021 and a driven gear 2022 engaged with the driving gear 2021, and an output shaft end of the driven gear 2022 is fixedly connected to the tilting portion 201. The driving gear 2022 is driven by the driving device to rotate, and the driven gear 2022 rotates, and the driven gear 2022 drives the turning part 201 to rotate together, thereby tilting the turning part 201.

Furthermore, the diameter of the driving gear 2021 is smaller than that of the driven gear 2022, so that the rotation angle of the turning part 201 can be conveniently adjusted, and the controllability and the accuracy are high.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention in its corresponding aspects.

Claims (10)

1. A test tube recovery device, comprising:

a turnover part on which a plurality of test tubes are placed;

the driving part is connected with the overturning part and drives the overturning part to overturn;

a recovery barrel located below the turning part;

the turnover part is in when upset to certain inclination under the effect of drive division, the test tube breaks away from the turnover part, falls into in the recycling bin.

2. The test tube recovery apparatus according to claim 1,

a test tube tray is placed on the turnover part, and the test tube is placed in the test tube tray;

be equipped with clamping jaw portion on the upset portion, when the upset portion overturns, clamping jaw portion centre gripping test tube tray.

3. The test tube recovery apparatus according to claim 2,

upset portion includes first curb plate, second curb plate and locates first curb plate with bottom plate between the second curb plate, first curb plate the second curb plate and the bottom plate encloses to become to be used for placing the accommodation space of test tube tray, the test tube tray place in on the bottom plate, the top and the front end of upset portion are open the form, when upset portion overturns to certain inclination, the front end of upset portion is less than the rear end of upset portion.

4. The test tube recovery apparatus according to claim 3,

the clamping jaw part is arranged at the rear end of the overturning part.

5. The test tube recovery apparatus according to claim 4,

the clamping jaw portion includes two relative clamping jaws that set up, two clamping jaw relative motion, centre gripping the lateral wall of test tube tray.

6. The test tube recovery apparatus according to claim 5,

the rear end of the overturning part is provided with a sliding rail part, the clamping jaw is provided with a sliding block, and the sliding block is connected with the sliding rail part in a sliding mode.

7. The test tube recovery apparatus according to claim 3,

the bottom plate is provided with a concave part, and the bottom of the test tube tray is placed on the concave part.

8. The test tube recovery apparatus according to claim 3,

the top parts of the first side plate and the second side plate are respectively provided with a top plate, the distance between the two top plates is smaller than the width of the test tube tray, and the test tubes placed on the test tube tray are exposed out of the space between the two top plates;

the test tube tray is placed into the accommodating space from the front end of the overturning part.

9. The test tube recovery apparatus according to any one of claims 1 to 8,

the driving part comprises a driving gear and a driven gear meshed with the driving gear, and the output shaft end of the driven gear is fixedly connected with the overturning part.

10. The test tube recovery apparatus according to claim 9,

the diameter of the driving gear is smaller than that of the driven gear.

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