CN214398680U - Blood collection tube falling position conveying device - Google Patents

Abstract

The utility model discloses a blood sampling tube falling position conveying device, which comprises a shell and a controller, wherein a plurality of tube storage boxes for placing blood sampling tubes are arranged at the top of the shell side by side, and the outlet ends of the tube storage boxes extend into the shell; a pipe dropping structure is arranged below the outlet end of each storage box, a guide pipe groove which is obliquely arranged with a high front part and a low back part is arranged below the pipe dropping structure and communicated with the pipe dropping structure, and a drainage groove is arranged below the rear end of the guide pipe groove; still including installing the conveying structure that just is located drainage groove below in the casing, the one end and the drainage groove of conveying structure are linked together, and the other end and the delivery chute of establishing below this conveying structure communicate mutually, and the delivery chute is low back high slope before for and establishes on the casing, and the outside that the front end of delivery chute stretches out the casing is connected with a receipts pipe box of installing on the casing. The utility model has the advantages of can alleviate medical staff work load, improve work efficiency and be difficult for the wrong blood sampling tube of selecting.

Description

Blood collection tube falling position conveying device

Technical Field

The utility model relates to the field of medical technology, more specifically say, in particular to heparin tube conveyer that falls to position.

Background

In medical clinical examination, gather blood as the inspection sample with the heparin tube, be the most common mode, at present, the heparin tube has been the medical consumptive material that the hospital must be and use in a large number, and the bulk application of heparin tube makes the blood sampling mode more reliable, also provides very big facility for medical staff's blood sampling work simultaneously.

However, when taking blood to a patient at present, the selection of the blood taking tube is mostly selected by the medical staff, because the blood items of the patient are more and the examination are different, in the tube selecting process, the medical staff is required to select the tube, the workload is large, the working efficiency is low, in addition, the problem that the medical staff easily selects the blood taking tube by mistake due to negligence caused by high-strength work exists, and the practical application requirement is difficult to meet.

Therefore, a new blood collection tube conveying technology is needed to overcome the shortcomings of the prior art.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a heparin tube landing conveyer that can alleviate medical staff work load, improve work efficiency and be difficult for the wrong heparin tube of selecting.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

a blood collection tube falling position conveying device comprises a shell and a controller, wherein a plurality of tube storage boxes for placing blood collection tubes are arranged at the top of the shell side by side, and the outlet ends of the tube storage boxes extend into the shell; a pipe dropping structure is arranged below the outlet end of each storage box, a guide pipe groove which is obliquely arranged in a high front-to-back manner is arranged below the pipe dropping structure and communicated with the pipe dropping structure, and a drainage groove is arranged below the rear end of the guide pipe groove; the pipe collecting box is characterized by further comprising a conveying structure which is arranged in the shell and located below the drainage groove, one end of the conveying structure is communicated with the drainage groove, the other end of the conveying structure is communicated with a conveying groove which is arranged below the conveying structure, the conveying groove is obliquely arranged on the shell in a manner that the front end of the conveying groove is low and the rear end of the conveying groove is high, and the front end of the conveying groove extends out of the shell and is connected with a pipe collecting box arranged on the shell; the drop tube structure and the transmission structure are electrically connected with the controller through power lines.

Preferably, each of the drop tube structures comprises a mounting frame mounted in the housing, a tube delivery roller is movably mounted on the mounting frame, the outer side of the tube delivery roller abuts against the outlet end of the storage box, a plurality of tube placing cavities used for accommodating drop tubes in a matching manner with the outlet end of the storage box are formed in the tube delivery roller, each of the tube placing cavities can only accommodate one blood collection tube, and the drop tube structure further comprises a first motor mounted on one side of the mounting frame, and an output shaft of the first motor is fixedly connected with the tube delivery roller; the falling pipe structure is communicated with the guide pipe groove through the pipe conveying roller, and is electrically connected with the controller through the first motor.

Preferably, the number of the tube placing cavities is three, and the tube placing cavities are uniformly arranged on the tube conveying roller at intervals.

Preferably, the conveying structure comprises two limiting plates which are arranged in the shell at intervals, a driving wheel is arranged at one end of each limiting plate and is positioned between the two limiting plates, an auxiliary wheel is arranged at one end, far away from the driving wheel, of each limiting plate and is positioned between the two limiting plates, the conveying structure further comprises an annular conveying belt arranged on the driving wheel and the auxiliary wheel, an anti-skid layer is arranged on the annular conveying belt, a second motor is arranged on each limiting plate, and an output shaft of the second motor is fixedly connected with the driving wheel; the conveying structure is communicated with the drainage groove through the annular conveying belt, and the conveying structure is electrically connected with the controller through the second motor.

Preferably, a shock-absorbing protective layer is arranged on the inner surface of the conduit groove.

Preferably, the shock absorption protective layer is made of EPE pearl cotton material or sponge material.

Preferably, the controller is an FRDH-750-R controller.

Compared with the prior art, the utility model discloses the beneficial effect who has as follows:

when the utility model is used, one of the tube placing cavities on the tube conveying roller of each tube falling structure is communicated with the outlet end of the corresponding storage box, then the blood sampling tubes are separately placed in each storage box according to categories, one blood sampling tube in each storage box falls into the corresponding tube placing cavity under the action of gravity of the blood sampling tubes, when the blood sampling work is carried out, according to the blood sampling detection project, medical staff start the first motor of the corresponding tube falling structure to work through the controller, the tube conveying roller of the tube falling structure is driven to rotate through the first motor until the tube conveying roller rotates to the preset position, the first motor stops working, at the moment, the tube placing cavity containing the blood sampling tubes on the tube conveying roller inclines to enable the blood sampling tubes to fall into the conduit groove and be conveyed to the drainage groove, and then conveyed to the conveying structure through the drainage groove, and simultaneously, the other tube placing cavity on the tube conveying roller rotates to the lower part of the tube storage box and is communicated with the outlet end of the storage box, a blood sampling tube is stored in the tube placing cavity for the next tube placing operation, then a second motor of the conveying structure is started to work through the controller, the second motor drives the annular conveying belt to convey the blood sampling tube to the conveying groove, and the blood sampling tube is conveyed to the tube collecting box through the conveying groove and is used by medical staff; by adopting the structure, the utility model, the medical staff can realize the automatic tube selection and transportation of the blood sampling tube only by operating the controller according to the blood sampling detection project, thus solving the problems of large workload, lower working efficiency and easy error selection of the blood sampling tube caused by negligence in the traditional tube selection by the medical staff; therefore, the utility model has the advantages of can alleviate medical staff work load, improve work efficiency and be difficult for the wrong blood sampling tube of selecting.

Drawings

The present invention will be further explained with reference to the drawings and examples.

Fig. 1 is a schematic view of a conveying mechanism of a blood collection tube placement conveying device according to the present invention;

fig. 2 is a schematic structural view of a blood collection tube placement conveying device of the present invention.

Description of reference numerals: 1. the pipe conveying device comprises a shell, 2, a controller, 3, a storage box, 4, a pipe falling structure, 5, a pipe guiding groove, 6, a drainage groove, 7, a conveying structure, 8, a conveying groove, 9, a pipe receiving box, 41, a mounting frame, 42, a pipe conveying roller, 43, a pipe placing cavity, 44, a first motor, 71, a limiting plate, 72, a driving wheel, 73, an auxiliary wheel, 74, an annular conveying belt, 75, an anti-skid layer, 76, a second motor, 10 and a shock absorption protective layer.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1 to 2, a blood collection tube placement conveying device comprises a housing 1 and a controller 2, wherein a plurality of tube storage boxes 3 for storing blood collection tubes are arranged at the top of the housing 1 side by side, and the outlet ends of the tube storage boxes 3 extend into the housing 1; a drop tube structure 4 is arranged below the outlet end of each storage box 3, a guide tube groove 5 which is obliquely arranged with a high front part and a low back part is arranged below the drop tube structure 4, the guide tube groove 5 is communicated with the drop tube structure 4, and a drainage groove 6 is arranged below the rear end of the guide tube groove 5; the device is characterized by further comprising a conveying structure 7 which is arranged in the shell 1 and located below the drainage groove 6, one end of the conveying structure 7 is communicated with the drainage groove 6, the other end of the conveying structure 7 is communicated with a conveying groove 8 which is arranged below the conveying structure 7, the conveying groove 8 is obliquely arranged on the shell 1 in a manner that the front end is low and the rear end is high, and the front end of the conveying groove 8 extends out of the shell 1 and is connected with a pipe collecting box 9 arranged on the shell 1; wherein, the drop tube structure 4 and the transmission structure 7 are electrically connected with the controller 2 through power lines.

Each of the drop tube structures 4 comprises a mounting frame 41 mounted in the housing 1, a tube delivery roller 42 is movably mounted on the mounting frame 41, the outer side of the tube delivery roller 42 abuts against the outlet end of the storage box 3, a plurality of tube placing cavities 43 used for accommodating drop tubes in cooperation with the outlet end of the storage box 3 are formed in the tube delivery roller 42, each of the tube placing cavities 43 can only accommodate one blood collection tube, and the drop tube structure further comprises a first motor 44 mounted on one side of the mounting frame 41, and an output shaft of the first motor 44 is fixedly connected with the tube delivery roller 42; wherein, the drop tube structure 4 is communicated with the guide tube groove 5 through the tube conveying roller 42, and the drop tube structure 4 is electrically connected with the controller 2 through the first motor 44.

The number of the tube placing cavities 43 is three, and the tube placing cavities 43 are uniformly arranged on the tube conveying roller 42 at intervals.

The conveying structure 7 comprises two limiting plates 71 which are arranged in the housing 1 at intervals, a driving wheel 72 is arranged at one end of each limiting plate 71, the driving wheel 72 is positioned between the two limiting plates 71, an auxiliary wheel 73 is arranged at one end, far away from the driving wheel 72, of each limiting plate 71, the auxiliary wheel 73 is positioned between the two limiting plates 71, the conveying structure further comprises an annular conveying belt 74 arranged on the driving wheel 72 and the auxiliary wheel 73, an anti-skid layer 75 is arranged on the annular conveying belt 74, a second motor 76 is arranged on each limiting plate 71, and an output shaft of the second motor 76 is fixedly connected with the driving wheel 72; wherein the conveying structure 7 is communicated with the drainage groove 6 through the endless conveying belt 74, and the conveying structure 7 is electrically connected with the controller 2 through the second motor 76.

And a shock absorption protective layer 10 is arranged on the inner surface of the guide pipe groove 5.

The shock absorption protective layer 10 is made of EPE pearl cotton material or sponge material.

The controller 2 is an FRDH-750-R controller.

The first motor 44 and the second motor 76 are both 40SF100B servo motors.

When the blood collection tube falling device is used specifically, firstly, one of the tube placing cavities 43 on the tube sending drum 42 of each falling tube structure 4 is communicated with the outlet end of the corresponding tube storage box 3, then the blood collection tubes are separately placed in each tube storage box 3 according to the category, and at the moment, one blood collection tube in each tube storage box 3 falls into the corresponding tube placing cavity 43 under the action of the gravity of the blood collection tube; secondly, when the blood sampling operation is performed, the medical staff starts the corresponding first motor 44 to operate through the controller 2 according to the blood sampling detection items, the tube conveying roller 42 is driven to rotate through the first motor 44 until the tube conveying roller 42 rotates to the preset position, the first motor 44 stops operating, at this time, the tube placing cavity 43 containing the blood sampling tubes on the tube conveying roller 42 inclines to enable the blood sampling tubes to fall into the conduit groove 5, the blood sampling tubes are conveyed to the drainage groove 6 through the conduit groove 5, then the blood sampling tubes are conveyed to the anti-slip layer 75 above the annular conveying belt 74 through the drainage groove 6, meanwhile, the other tube placing cavity 43 on the tube conveying roller 42 rotates to the position below the tube storage box 3 to be communicated with the outlet end of the tube storage box 3, and then one blood sampling tube is contained in the tube placing cavity 43 to be subjected to the next tube conveying operation; then, the controller 2 starts the second motor 76 of the conveying structure 7 to operate, and the driving wheel 72 and the auxiliary wheel 73 are driven by the second motor 76 to rotate, so as to drive the endless conveyor belt 74 and the anti-slip layer 75 to move to convey the blood collection tubes to the conveying groove 8; finally, the blood collection tube is conveyed to a tube collection box 9 by the conveying groove 8 for medical staff to take.

In a word, the utility model adopts the above structure, have the advantage that can alleviate medical staff work load, improve work efficiency and be difficult for the wrong heparin tube of selecting.

Various other modifications and changes may be made by those skilled in the art based on the above teachings and concepts, and all such modifications and changes are intended to fall within the scope of the claims.

Claims (7)

1. A blood collection tube falling position conveying device comprises a shell (1) and a controller (2), wherein a plurality of storage boxes (3) for placing blood collection tubes are arranged on the top of the shell (1) side by side, and the outlet ends of the storage boxes (3) extend into the shell (1); the method is characterized in that: a pipe dropping structure (4) is arranged below the outlet end of each storage box (3), a guide pipe groove (5) which is obliquely arranged from high front to low back is arranged below the pipe dropping structure (4), the guide pipe groove (5) is communicated with the pipe dropping structure (4), and a drainage groove (6) is arranged below the rear end of the guide pipe groove (5); the drainage device is characterized by further comprising a conveying structure (7) which is arranged in the shell (1) and located below the drainage groove (6), one end of the conveying structure (7) is communicated with the drainage groove (6), the other end of the conveying structure (7) is communicated with a conveying groove (8) which is arranged below the conveying structure (7), the conveying groove (8) is obliquely arranged on the shell (1) in a manner that the front end is low and the rear end is high, and the front end of the conveying groove (8) extends out of the shell (1) and is connected with a pipe collecting box (9) which is arranged on the shell (1); the falling pipe structure (4) and the transmission structure (7) are electrically connected with the controller (2) through power lines.

2. A blood collection tube landing transfer device as in claim 1, wherein: each falling tube structure (4) comprises a mounting frame (41) mounted in the shell (1), a tube conveying roller (42) is movably mounted on the mounting frame (41), the outer side of the tube conveying roller (42) is abutted against the outlet end of the storage box (3), a plurality of tube placing cavities (43) used for accommodating falling tubes in a matching manner with the outlet end of the storage box (3) are formed in the tube conveying roller (42), a cavity of each tube placing cavity (43) can only accommodate one blood sampling tube, the falling tube structure further comprises a first motor (44) mounted on one side of the mounting frame (41), and an output shaft of the first motor (44) is fixedly connected with the tube conveying roller (42); wherein the falling pipe structure (4) is communicated with the guide pipe groove (5) through the pipe conveying roller (42), and the falling pipe structure (4) is electrically connected with the controller (2) through the first motor (44).

3. A blood collection tube landing transfer device as in claim 2, wherein: the number of the tube placing cavities (43) is three, and the tube placing cavities (43) are uniformly arranged on the tube conveying roller (42) at intervals.

4. A blood collection tube landing transfer device as in claim 1, wherein: the conveying structure (7) comprises two limiting plates (71) which are arranged in the shell (1) at intervals, one end of each limiting plate (71) is provided with a driving wheel (72), the driving wheel (72) is located between the two limiting plates (71), one end, far away from the driving wheel (72), of each limiting plate (71) is provided with an auxiliary wheel (73), the auxiliary wheel (73) is located between the two limiting plates (71), the conveying structure further comprises an annular conveying belt (74) arranged on the driving wheel (72) and the auxiliary wheel (73), an anti-skid layer (75) is arranged on the annular conveying belt (74), the limiting plates (71) are provided with a second motor (76), and an output shaft of the second motor (76) is fixedly connected with the driving wheel (72); wherein the conveying structure (7) is communicated with the drainage groove (6) through the annular conveying belt (74), and the conveying structure (7) is electrically connected with the controller (2) through the second motor (76).

5. A blood collection tube landing transfer device as in claim 4, wherein: and a shock absorption protective layer (10) is arranged on the inner surface of the guide pipe groove (5).

6. A blood collection tube landing transfer device as in claim 5, wherein: the shock absorption protective layer (10) is made of EPE pearl cotton material or sponge material.

7. A blood collection tube landing transfer device as in any one of claims 1 to 6, wherein: the controller (2) is an FRDH-750-R controller.

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