CN213069838U - Gynecological secretion detection device and rotary code scanning device for sample container - Google Patents

Abstract

The utility model discloses a sign indicating number device is swept with the rotation that is used for sample container to gynaecology's secretion detection device, wherein, a sign indicating number device is swept to the rotation that is used for sample container include: sampling mechanism includes: the sample injection driving assembly is arranged on the sample injection frame; the sample introduction frame is used for bearing a sample container, and the sample introduction driving assembly is used for driving the sample introduction frame to move to a position to be subjected to code scanning; a rotation mechanism comprising: the rotary driving component and a driving wheel are arranged at the power output end of the rotary driving component; the rotary driving component is used for driving the driving wheel to rotate so as to drive the sample container to rotate through the driving wheel; and the code scanning mechanism is used for scanning the identification mark on the sample container at the position to be code scanned. The sample container is driven to rotate through the driving wheel so that the code scanning mechanism scans the bar codes on the sample container, the scanning efficiency is improved, and the subsequent detection and analysis operation efficiency is further improved.

Description

Gynecological secretion detection device and rotary code scanning device for sample container

Technical Field

The application relates to the technical field of medical equipment, concretely relates to sign indicating number device is swept with the rotation that is used for sample container to gynaecology's secretion detection device.

Background

The barcode technology is to represent data required by a computer with a barcode and then convert the barcode data into data that can be automatically read by the computer. With the modernization and the improvement of automation degree of the inspection instrument, most inspection instruments have bar code reading capability.

At present, in a batch sample detection and analysis test, in order to facilitate identification and statistics, a barcode is usually attached to a sample container, then the barcode on the sample container is scanned by a scanning device, and after a worker reads barcode information, the subsequent detection and analysis operation can be performed. The bar code scanning method is mainly divided into manual scanning and mechanical scanning, and the manual scanning is performed by a handheld scanner. The workload is large, the efficiency is low, and the statistics is easy to miss or miss. In the conventional mechanical scanning, the position of the code scanning mechanism is relatively unchanged, and if the barcode on the sample container does not correspond to the position of the scanner, the barcode cannot be read. The code scanning efficiency is low, and the efficiency of subsequent detection and analysis operation is further restricted.

SUMMERY OF THE UTILITY MODEL

The application aims at providing a gynaecology's secretion detection device and a yard device is swept in rotation that is used for sample container, drives sample container rotation so that sweep the bar code that a yard mechanism scanned on the sample container through the drive wheel, improves scanning efficiency, and then improves follow-up detection and analysis operating efficiency.

According to a first aspect of the present application, there is provided a rotary code scanning device for sample containers, comprising:

sampling mechanism includes: the sample injection driving assembly is arranged on the sample injection frame; the sample introduction frame is used for bearing a sample container, and the sample introduction driving assembly is used for driving the sample introduction frame to move to a position to be subjected to code scanning;

a rotation mechanism comprising: the rotary driving component and a driving wheel are arranged at the power output end of the rotary driving component; the rotary driving component is used for driving the driving wheel to rotate so as to drive the sample container to rotate through the driving wheel;

and the code scanning mechanism is used for scanning the identification mark on the sample container at the position to be code scanned.

Further, the rotary code scanning device for the sample container is characterized in that the sample injection rack is provided with a plurality of accommodating grooves, and the accommodating grooves are used for accommodating the sample container; notches communicated with the accommodating grooves are formed in the groove walls of the accommodating grooves and used for exposing parts of the sample containers, and the driving wheels drive the exposed parts of the sample containers to rotate; the sample injection driving assembly is used for driving the storage grooves in the sample injection frame to be sequentially transferred to the positions to be subjected to code scanning.

Further, the rotary code scanning device for the sample container further comprises: and the compressing and positioning mechanism is used for moving to the position to be subjected to code scanning, and the sample injection frame is compressed and positioned.

Further, the rotating code scanning device for the sample container, wherein the compressing and positioning mechanism comprises: set up respectively advance the subassembly that compresses tightly of appearance frame both sides and support and lean on the board, compress tightly the subassembly and include: the pressing guide seat, the pressing driving piece, the pressing moving seat, the pressing lug and the elastic buffer piece are arranged on the pressing moving seat; the pressing moving seat is slidably arranged on the pressing guide seat, the pressing driving piece is fixed on the pressing guide seat, the pressing moving seat is provided with a slot, the pressing lug is inserted and embedded in the slot, and the elastic buffer piece is positioned between the pressing lug and the slot bottom of the slot; the compressing driving part is used for driving the compressing movable seat to move towards the direction of the sample feeding frame so as to enable the compressing lug to compress the sample feeding frame under the action of the abutting plate, or to move away from the direction of the sample feeding frame so as to loosen the sample feeding frame.

Further, the rotating code scanning device for the sample container, wherein the compressing assembly further comprises: the limiting pin is arranged in the strip-shaped limiting hole, and two ends of the limiting pin are abutted against the groove wall of the slot.

Further, the rotating code scanning device for the sample container, wherein the rotating mechanism further comprises: the rotary driving assembly is arranged below the fixed frame, and the driving wheel is positioned above the fixed frame; the code scanning mechanism is fixed on the fixing frame and is positioned above the driving wheel.

Further, the rotating code scanning device for the sample container is characterized in that the circumferential direction of the driving wheel is provided with an arc surface and a plane, the rotating driving assembly is further used for driving the driving wheel to rotate so as to switch the arc surface or the plane to face the exposed part of the sample container, the arc surface is used for being tangent to the exposed part of the sample container, and the plane is not in contact with the exposed part of the sample container.

Further, the rotating code scanning device for the sample container is characterized in that an anti-slip layer is arranged on the arc surface.

Further, the rotating code scanning device for the sample container is characterized in that the intersection of the arc surface and the plane is in smooth transition.

According to a second aspect of the present application, there is also provided a gynaecological secretion detection apparatus comprising: the rotary code scanning device for the sample container.

According to the present application, there is provided a sample container and a rotary code scanner for the sample container, wherein the rotary code scanner for the sample container comprises: sampling mechanism includes: the sample injection driving assembly is arranged on the sample injection frame; the sample introduction frame is used for bearing a sample container, and the sample introduction driving assembly is used for driving the sample introduction frame to move to a position to be subjected to code scanning; a rotation mechanism comprising: the rotary driving component and a driving wheel are arranged at the power output end of the rotary driving component; the rotary driving component is used for driving the driving wheel to rotate so as to drive the sample container to rotate through the driving wheel; and the code scanning mechanism is used for scanning the identification mark on the sample container at the position to be code scanned. The sample container is driven to rotate through the driving wheel so that the code scanning mechanism scans the bar codes on the sample container, the scanning efficiency is improved, and the subsequent detection and analysis operation efficiency is further improved.

Drawings

FIG. 1 is a perspective view of a rotary code scanner for sample containers provided herein;

FIG. 2 is an exploded view of FIG. 1;

FIG. 3 is a schematic structural view of a hold-down assembly provided herein;

FIG. 4 is a partial cross-sectional view from a top perspective of a hold-down assembly provided herein;

FIG. 5 is a first schematic view illustrating a position relationship between a sample injection rack and a driving wheel in the present application;

FIG. 6 is a schematic diagram of a second position relationship between the sample injection rack and the driving wheel in the present application;

fig. 7 is a schematic diagram of a position relationship between the sample injection rack and the driving wheel in the present application.

Detailed Description

The present application will be described in further detail below with reference to the accompanying drawings by way of specific embodiments.

Referring to fig. 1 to 7, the present embodiment provides a rotary code scanner for sample containers, including: the sample injection mechanism 10, the rotating mechanism 20, the code scanning mechanism 30, and the compressing and positioning mechanism 40.

The sample injection mechanism 10 includes: the sample injection device comprises a sample injection driving component 11 and a sample injection frame 12, wherein the sample injection frame 12 is used for bearing a sample container 50, and an identification mark is stuck on the sample container 50. The sample injection frame 12 is arranged at the power output end of the sample injection driving assembly 11, and the sample injection driving assembly 11 is used for driving the sample injection frame 12 to move to a position S to be scanned. It can be understood that the position S to be scanned remains unchanged, and the sample driving assembly 11 moves the sample container 50 on the sample rack 12 to the position S to be scanned.

The rotating mechanism 20 includes: a rotary driving assembly (not shown in the figures) and a driving wheel 21, the driving wheel 21 is disposed at a power output end of the rotary driving assembly, and the rotary driving assembly is used for driving the driving wheel 21 to rotate so as to drive the sample container 50 to rotate through the driving wheel 21. Specifically, when the sample container 50 is driven to rotate by the driving wheel 21, the driving wheel 21 is tangent to the outer wall of the sample container 50.

The code scanning mechanism 30 is used for scanning the identification mark on the sample container 50 at the position S to be scanned. The identification mark is specifically a bar code, and the barcode scanning mechanism 30 is specifically a barcode scanner, which scans the barcode while the barcode affixed to the sample container 50 is oriented toward the barcode scanner during the rotation of the sample container 50 by the driving wheel 21.

The pressing and positioning mechanism 40 is used for pressing and positioning the sample injection frame 12 which is moved to the position S to be scanned, so that the sample injection frame 12 is prevented from being toppled in the process of driving the sample container 50 to rotate through the driving wheel 21.

In this embodiment, the sample rack 12 has a plurality of receiving slots, each of which is used for receiving a sample container 50, in other words, the sample rack 12 carries a plurality of sample containers 50. As shown in fig. 5, a notch 121 is disposed on a wall of each receiving groove, and the notch 121 is used to expose a portion of the sample container 50 to form an exposed portion 51. The aforementioned driving wheel 21 is tangent to the exposed portion 51 to drive the exposed portion 51 of the sample container 50 to rotate, thereby rotating the sample container 50. The sample injection driving assembly 11 is configured to drive each receiving groove in the sample injection rack 12 to sequentially transfer to the position S to be scanned, so as to sequentially transfer each sample container 50 received in each receiving groove to the position S to be scanned.

As shown in fig. 1, the sample injection mechanism 10 further includes: the sample rack 13, the aforementioned sample driving assembly 11 is fixed on the sample rack 13, and the sample rack 13 is a supporting structure of the sample driving assembly 11. Specifically, the sample injection drive assembly 11 includes: a driving power source 111 and a guide unit 112 arranged on the sample holder 13, and the sample holder 12 is mounted on the guide unit 112. The driving power source 111 may adopt a power source such as an air cylinder, a motor, etc., the guiding unit 112 may adopt a linear guide pair, etc. for guiding, and the driving power source 111 drives the guiding unit 112 to move so as to drive the sample rack 13 to move.

As shown in fig. 6 and 7, the straight arrow in the figure represents the moving direction of the sample container, in fig. 6, the driving power source 111 drives the guiding unit 112 to move at intervals in sequence to transfer the first sample container 50 to the position S to be code-scanned, and then the rotary driving component drives the driving wheel 21 to rotate to drive the first sample container 50 to rotate, so that the identification mark attached to the first sample container 50 is aligned with the code-scanning mechanism 30 to scan the first sample container 50. In fig. 7, the driving power source 11 drives the guide unit 112 to move sequentially at intervals to transfer the second sample container 50 to the position S with the code scanning position, and then repeats the above operation to perform the code scanning operation on the second sample container 50. The driving power source 111 then sequentially transfers the other sample containers 50 to the position S to be code-scanned by the driving guide unit 112, so as to scan the other sample containers 50.

As shown in fig. 2, the circumferential direction of the driving wheel 21 has a circular arc surface 211 and a plane 212, wherein the intersection of the circular arc surface 211 and the plane 212 is connected in a smooth transition manner. The rotary driving assembly is also used for driving the driving wheel 21 to rotate so as to switch the arc surface 211 or the plane surface 212 towards the exposed part 51 of the sample container 50, the arc surface 211 is used for being tangent to the exposed part 51 of the sample container 50, as shown in fig. 7, the plane surface 212 does not contact the exposed part 51 of the sample container 50, and therefore when the code scanning operation is not needed, the operation is carried out, and the equipment structure is simplified.

The rotation driving assembly can drive the driving wheel 21 to rotate along a rotation direction, or the driving wheel 21 is driven to rotate in a reciprocating manner, and certainly, in order to ensure that the sample container 50 is driven to rotate by the driving wheel 21, the arc surface 211 of the driving wheel 21 is always tangent to the outer wall of the sample container 50 in the rotating process.

In this embodiment, the arc surface 211 on the driving wheel 21 is provided with an anti-slip layer, which may be a convex point, a concave point, etc. on the surface of the arc surface 211 to ensure that the anti-slip layer and the outer wall of the sample container 50 have a friction force enough to drive the sample container 50 to rotate.

In the above embodiment, the driving wheel 21 is preferably made of rubber, and the rubber driving wheel 21 is preferably made of rubber.

With continued reference to fig. 2, the aforementioned rotary mechanism 20 further includes: the fixing frame 22 is fixedly arranged below the fixing frame 22, and the driving wheel 21 is positioned above the fixing frame 22. The code scanning mechanism 30 is fixed on the fixing frame 22 and located above the driving wheel 21, so that the installation space of the device can be saved, and the device structure is compact.

As shown in fig. 3 and 4, the aforementioned pressing positioning mechanism 40 includes: set up respectively and lean on board 42 at the pressure components 41 of advancing sample frame 12 both sides, wherein, pressure components 41 include: the compressing guide seat 411, the compressing driving member 412, the compressing moving seat 413, the compressing protrusion 414, and the elastic buffer 415, the compressing moving seat 413 is slidably disposed on the compressing guide seat 411, and the compressing moving seat 413 and the compressing guide seat are formed as a linear guide pair to output the reciprocating motion toward or away from the sample injection rack 12. The pressing driving member 412 is fixed on the pressing guide seat 411, a slot 416 is provided in the pressing moving seat 413, the pressing protrusion 414 is inserted into the slot 416, and the elastic buffer 415 is located between the pressing protrusion 414 and the slot bottom of the slot 416. The compressing driving member 412 provides power for the reciprocating movement of the compressing moving seat 413 along the linear direction of the compressing guide seat 411, so as to drive the compressing moving seat 413 to move towards the sample injection rack 12, so that the compressing bump 414 and the abutting plate 42 act to compress the sample injection rack 12, or drive the compressing moving seat 413 to move away from the sample injection rack 12, so as to loosen the sample injection rack 12.

In the above embodiment, the pressing assembly 41 further includes: and a limiting pin 417, wherein strip-shaped limiting holes 4141 are distributed on the peripheral wall of the pressing lug 414 positioned in the slot 416, the limiting pin 417 is installed in the strip-shaped limiting holes 417, and two ends of the limiting pin 417 abut against the slot wall of the slot 416, so that the pressing lug 414 is positioned in the slot 416.

Example II,

The embodiment also provides a gynecological secretion detection device, which comprises the rotary code scanning device for the sample container in the first embodiment. All the features and functions of the rotary code scanning device are described in detail in the first embodiment, and are not described herein again.

In conclusion, the gynaecology secretion detection device that this embodiment provided and the rotatory yard device of sweeping that is used for sample container drive the sample container through the drive wheel and rotate so that sweep the bar code on the yard mechanism to sample container and scan, improve scanning efficiency, simultaneously, still can realize sweeping yard operation in batches, and then improve follow-up detection analysis operating efficiency.

The foregoing is a more detailed description of the present application in connection with specific embodiments thereof, and it is not intended that the present application be limited to the specific embodiments thereof. For those skilled in the art to which the present application pertains, a number of simple deductions or substitutions can be made without departing from the inventive concept of the present application.

Claims (10)

1. A rotary code scanning device for sample containers, comprising:

sampling mechanism includes: the sample injection driving assembly is arranged on the sample injection frame; the sample introduction frame is used for bearing a sample container, and the sample introduction driving assembly is used for driving the sample introduction frame to move to a position to be subjected to code scanning;

a rotation mechanism comprising: the rotary driving component and a driving wheel are arranged at the power output end of the rotary driving component; the rotary driving component is used for driving the driving wheel to rotate so as to drive the sample container to rotate through the driving wheel;

and the code scanning mechanism is used for scanning the identification mark on the sample container at the position to be code scanned.

2. The rotary code scanner for sample containers as claimed in claim 1, wherein the sample rack has a plurality of receiving slots for receiving the sample containers; notches communicated with the accommodating grooves are formed in the groove walls of the accommodating grooves and used for exposing parts of the sample containers, and the driving wheels drive the exposed parts of the sample containers to rotate; the sample injection driving assembly is used for driving the storage grooves in the sample injection frame to be sequentially transferred to the positions to be subjected to code scanning.

3. The rotary code-scanning device for sample containers of claim 1, further comprising: and the compressing and positioning mechanism is used for moving to the position to be subjected to code scanning, and the sample injection frame is compressed and positioned.

4. The rotary code-scanning device for sample containers of claim 3, wherein the hold-down positioning mechanism comprises: set up respectively advance the subassembly that compresses tightly of appearance frame both sides and support and lean on the board, compress tightly the subassembly and include: the pressing guide seat, the pressing driving piece, the pressing moving seat, the pressing lug and the elastic buffer piece are arranged on the pressing moving seat; the pressing moving seat is slidably arranged on the pressing guide seat, the pressing driving piece is fixed on the pressing guide seat, the pressing moving seat is provided with a slot, the pressing lug is inserted and embedded in the slot, and the elastic buffer piece is positioned between the pressing lug and the slot bottom of the slot; the compressing driving part is used for driving the compressing movable seat to move towards the direction of the sample feeding frame so as to enable the compressing lug to compress the sample feeding frame under the action of the abutting plate, or to move away from the direction of the sample feeding frame so as to loosen the sample feeding frame.

5. The rotary code-scanning device for sample containers of claim 4, wherein the hold-down assembly further comprises: the limiting pin is arranged in the strip-shaped limiting hole, and two ends of the limiting pin are abutted against the groove wall of the slot.

6. The rotary code-scanning device for sample containers of claim 1, wherein the rotation mechanism further comprises: the rotary driving assembly is arranged below the fixed frame, and the driving wheel is positioned above the fixed frame; the code scanning mechanism is fixed on the fixing frame and is positioned above the driving wheel.

7. The rotary code scanner for sample containers of claim 1, wherein the circumferential direction of the drive wheel has a circular arc surface and a flat surface, the rotary drive assembly further configured to drive the drive wheel to rotate to switch the circular arc surface or the flat surface toward the exposed portion of the sample container, the circular arc surface configured to be tangential to the exposed portion of the sample container, and the flat surface configured to not contact the exposed portion of the sample container.

8. The rotary code-scanning device for sample containers as claimed in claim 7, wherein the arcuate surface is provided with an anti-slip layer.

9. The rotary code-scanning device for sample containers as claimed in claim 7, wherein the intersection of the circular arc surface and the plane is rounded.

10. A gynecological secretion detection device, comprising: the rotary code scanning device for sample containers of any one of claims 1 to 9.

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