CN213445042U

CN213445042U - Batch pipe taking device

Info

Publication number: CN213445042U
Application number: CN202022177147.1U
Authority: CN
Inventors: 欧阳建华; 卢勇
Original assignee: Dongguan Xinbiao Automation Equipment Co ltd
Current assignee: Dongguan Chuangshida Automation Technology Co ltd
Priority date: 2020-09-28
Filing date: 2020-09-28
Publication date: 2021-06-15
Anticipated expiration: 2030-09-28

Abstract

The application provides a pipe device is got in batches includes: the suction nozzle comprises a base plate, a cover plate, a handle, a first positioning adsorption component, a second positioning adsorption component, a third positioning adsorption component, a fourth positioning adsorption component and a plurality of suction nozzles, wherein a groove is formed in the top of the base plate, the cover plate is hermetically fixed on the top of the base plate, a sealed cavity is formed between the cover plate and the groove, and a connecting hole communicated with the cavity is formed in the cover plate; the first positioning adsorption assembly, the second positioning adsorption assembly, the third positioning adsorption assembly and the fourth positioning adsorption assembly are fixedly distributed at four corners of the bottom of the substrate, and the first positioning adsorption assembly, the second positioning adsorption assembly, the third positioning adsorption assembly and the fourth positioning adsorption assembly are all communicated with the cavity; the suction nozzles are fixed at the bottom of the substrate in a matrix arrangement and are communicated with the cavity; the handle is fixed on the base plate. The batch taking and delivering device has the advantages of simple structure, capability of realizing batch taking and delivering, high taking and delivering efficiency, avoidance of artificial contact pollution and avoidance of falling, collision and damage.

Description

Batch pipe taking device

Technical Field

The application relates to the technical field of blood collection tube taking and delivering appliances, in particular to a batch taking and delivering tube device.

Background

The blood collection tube is a disposable negative pressure vacuum double-layer tube capable of realizing quantitative blood collection, and in the production and processing process of the blood collection tube, a plurality of different processing procedures are often required to be carried out on the blood collection tube, and the blood collection tube is required to be frequently transferred.

However, most of the blood collection tubes are transferred in the production and processing process manually, that is, the blood collection tubes are taken one by one manually and transferred to different processing stations, in the process, the taking and transferring efficiency is low, the phenomena of falling, collision and the like easily occur artificially, the risk of artificial contact pollution exists, and the blood collection tubes are damaged and polluted.

Therefore, there is a need for a batch pipe taking device to overcome the above problems.

SUMMERY OF THE UTILITY MODEL

An object of the embodiment of the application is to provide a get tub device in batches, this get tub device in batches have simple structure, can realize getting in batches and send, get and send efficient, avoid the artificial contact pollution and avoid the advantage of the collision damage that drops.

To achieve the above object, a first aspect of the embodiments of the present application provides a batch pipe taking device, including: the suction nozzle comprises a base plate, a cover plate, a handle, a first positioning adsorption component, a second positioning adsorption component, a third positioning adsorption component, a fourth positioning adsorption component and a plurality of suction nozzles, wherein a groove is formed in the top of the base plate, the cover plate is hermetically fixed on the top of the base plate, a sealed cavity is formed between the cover plate and the groove, and a connecting hole communicated with the cavity is formed in the cover plate; the first positioning adsorption assembly, the second positioning adsorption assembly, the third positioning adsorption assembly and the fourth positioning adsorption assembly are fixedly distributed at four corners of the bottom of the substrate, and the first positioning adsorption assembly, the second positioning adsorption assembly, the third positioning adsorption assembly and the fourth positioning adsorption assembly are all communicated with the cavity; the suction nozzles are fixed at the bottom of the substrate in a matrix arrangement and are communicated with the cavity; the handle is fixed on the base plate.

Optionally, the bottom of the substrate is provided with a first mounting hole, a second mounting hole, a third mounting hole and a fourth mounting hole which are all communicated with the cavity in a penetrating manner, and the first mounting hole, the second mounting hole, the third mounting hole and the fourth mounting hole are distributed on four corners of the bottom of the substrate.

Optionally, the first positioning adsorption assembly comprises: the upper end of the first installation pipe is hermetically fixed in the first installation hole, the upper end of the first positioning adsorption nozzle is fixedly connected to the lower end of the first installation pipe, the first silica gel sucker is hermetically fixedly sleeved at the lower end of the first installation pipe, and the first positioning adsorption nozzle is positioned in the first silica gel sucker;

the second positioning adsorption assembly comprises: the upper end of the second installation pipe is hermetically fixed in the second installation hole, the upper end of the second positioning adsorption nozzle is fixedly connected to the lower end of the second installation pipe, the second silica gel adsorption nozzle is hermetically and fixedly sleeved at the lower end of the second installation pipe, and the second positioning adsorption nozzle is positioned in the second silica gel adsorption disc;

the third positioning and adsorbing assembly comprises: the upper end of the third installation pipe is hermetically fixed in the third installation hole, the upper end of the third positioning adsorption nozzle is fixedly connected to the lower end of the third installation pipe, the third silica gel adsorption nozzle is hermetically fixed at the lower end of the third installation pipe, and the third positioning adsorption nozzle is positioned in the third silica gel adsorption disc;

the fourth positioning and adsorbing assembly comprises: fourth installation pipe, fourth location suction nozzle and fourth silica gel sucking disc, the inclosed upper end of fourth installation pipe is fixed in the fourth mounting hole, the inclosed upper end fixed connection of fourth location suction nozzle in the lower extreme of fourth installation pipe, the airtight fixed cover of all fixing of fourth silica gel sucking disc is located the lower extreme of fourth installation pipe, just the fourth location suction nozzle is located in the fourth silica gel sucking disc.

Optionally, the lower end of the first positioning adsorption nozzle is formed with a first conical surface structure, the lower end of the second positioning adsorption nozzle is formed with a second conical surface structure, the lower end of the third positioning adsorption nozzle is formed with a third conical surface structure, and the lower end of the fourth positioning adsorption nozzle is formed with a fourth conical surface structure.

Optionally, fifth mounting holes corresponding to the suction nozzles one to one are further formed in the bottom of the substrate, the fifth mounting holes penetrate through and are communicated with the cavity, the fifth mounting holes are distributed in the bottom of the substrate in a matrix arrangement, and the suction nozzles are hermetically fixed in the fifth mounting holes in one to one correspondence.

Optionally, a plurality of long ventilation grooves are further formed in the bottom of the groove, and the long ventilation grooves are distributed between two adjacent rows of the fifth mounting holes.

Optionally, the batch measuring and pipe taking device further comprises a fifth silica gel sucker in one-to-one correspondence with the suction nozzle, and the upper end of the fifth silica gel sucker is fixedly sleeved with the lower end of the suction nozzle in a sealing manner.

Optionally, two sides of the substrate are both protruded outwards to form symmetrical mounting bosses, and two ends of the handle are fixedly connected to the mounting bosses.

Optionally, the batch pipe taking device further comprises a sealing ring, and the sealing ring is clamped between the base plate and the cover plate.

Optionally, the top of the base plate is further provided with an annular mounting step, and the cover plate is embedded in the annular mounting step.

The top of the base plate of the batch pipe taking device is provided with the groove, the cover plate is hermetically fixed on the top of the base plate, a sealed cavity is formed between the cover plate and the groove, and the cover plate is provided with the connecting hole communicated with the cavity; the first positioning adsorption assembly, the second positioning adsorption assembly, the third positioning adsorption assembly and the fourth positioning adsorption assembly are fixedly distributed at four corners of the bottom of the substrate, and the first positioning adsorption assembly, the second positioning adsorption assembly, the third positioning adsorption assembly and the fourth positioning adsorption assembly are all communicated with the cavity; the suction nozzles are fixed at the bottom of the substrate in a matrix arrangement and are communicated with the cavity; the handle is fixed on the base plate. Then, when needing to adsorb to get and send the heparin tube, communicate on outside air exhaust device through the connecting hole, make and form the evacuation in the cavity, through the suction nozzle that is the matrix arrangement, first location adsorption component, second location adsorption component, third location adsorption component and fourth location adsorption component adsorb respectively and live just right heparin tube, and through first location adsorption component, second location adsorption component, third location adsorption component and fourth location adsorption component fix a position the heparin tube that is located four corners, can fix a position absorption batch heparin tube of absorption fast and transfer, the rethread grips the handle and transfers whole batch heparin tube that the device drove the absorption to appointed station on. Not only simple structure can realize getting in batches and send, replaces the manual work mode of taking the heparin tube one by the manual work and transfers, and not only efficiency improves greatly, can avoid taking place the phenomenon such as heparin tube drops, collision moreover, avoids artificial contact pollution risk, prevents heparin tube damage and pollution.

Drawings

Fig. 1 is an assembled perspective view of an embodiment of a batch pipe taking device in the embodiment of the present application.

Fig. 2 is a schematic view of fig. 1 from another view angle.

Fig. 3 is an exploded view of fig. 1.

Fig. 4 is an assembled perspective view of the first positioning absorption assembly of an embodiment of the batch pipe taking device in the embodiment of the present application.

Fig. 5 is an exploded view of fig. 4.

Fig. 6 is an assembled perspective view of a second positioning absorption assembly of an embodiment of a batch pipe taking device in an embodiment of the present application.

Fig. 7 is an exploded view of fig. 6.

Fig. 8 is an assembled perspective view of a third positioning absorption assembly of an embodiment of a batch pipe taking device in an embodiment of the present application.

Fig. 9 is an exploded view of fig. 8.

Fig. 10 is an assembled perspective view of a fourth positioning absorption assembly of an embodiment of a batch pipe taking device in an embodiment of the present application.

Fig. 11 is an exploded view of fig. 10.

Fig. 12 is a perspective view illustrating a combination of a suction nozzle and a fifth silicone suction cup of an embodiment of a batch pipe measuring device according to the present application.

Fig. 13 is an exploded view of fig. 12.

Detailed Description

The present application will be further described with reference to the accompanying drawings and preferred embodiments, but the embodiments of the present application are not limited thereto.

Referring to fig. 1 to 13, a batch pipe taking device 100 of the present application includes: the vacuum suction device comprises a substrate 10, a cover plate 20a, a handle 30, a first positioning adsorption component 40, a second positioning adsorption component 50, a third positioning adsorption component 60, a fourth positioning adsorption component 70 and a plurality of suction nozzles 80, wherein a groove 11 is formed in the top of the substrate 10, the cover plate 20a is hermetically fixed on the top of the substrate 10, a sealed cavity (not shown) is formed between the cover plate 20a and the groove 11, and a connecting hole 21 communicated with the cavity is formed in the cover plate 20a so as to be communicated with an external suction device through the connecting hole 21. First location adsorption component 40, second location adsorption component 50, third location adsorption component 60 and fourth location adsorption component 70 fixed distribution are in four corners of base plate 10 bottom, and first location adsorption component 40, second location adsorption component 50, third location adsorption component 60 and fourth location adsorption component 70 all communicate in the cavity. The suction nozzles 80 are fixed at the bottom of the substrate 10 in a matrix arrangement, and the suction nozzles 80 are communicated with the cavity; the handle 30 is fixed to the base plate 10. Then, when needing to adsorb to get and send the heparin tube, communicate on external air exhaust device through connecting hole 21 for form evacuation in the cavity, through being the suction nozzle 80 of matrix arrangement, first location adsorption component 40, second location adsorption component 50, third location adsorption component 60 and fourth location adsorption component 70 adsorb respectively and hold the just right heparin tube, and transfer the heparin tube that is located four corners through first location adsorption component 40, second location adsorption component 50, third location adsorption component 60 and fourth location adsorption component 70 and fix a position, can fix a position the absorption and adsorb batch heparin tube fast, the whole batch of heparin tube that drives of absorption is got tub device 100 and is transferred to appointed station through holding handle 30. Not only simple structure can realize getting in batches and send, replaces the manual work mode of taking the heparin tube one by the manual work and transfers, and not only efficiency improves greatly, can avoid taking place the phenomenon such as heparin tube drops, collision moreover, avoids artificial contact pollution risk, prevents heparin tube damage and pollution. Specifically, the following:

please refer to fig. 3, the bottom of the substrate 10 is provided with a first mounting hole 12, a second mounting hole 13, a third mounting hole 14 and a fourth mounting hole 15 all penetrating and communicating with the cavity, and the first mounting hole 12, the second mounting hole 13, the third mounting hole 14 and the fourth mounting hole 15 are distributed at four corners of the bottom of the substrate 10, so that the layout is simpler and more reasonable.

Referring to fig. 2 to 11, the first positioning absorption assembly 40 includes: first installation pipe 41, first location absorption mouth 42 and first silica gel sucking disc 43, the inclosed upper end of first installation pipe 41 be fixed in first mounting hole 12 in, the inclosed upper end fixed connection of first location absorption mouth 42 is in the lower extreme of first installation pipe 41, the inclosed fixed cover of first silica gel sucking disc 43 is all located the lower extreme of first installation pipe 41, and first location absorption mouth 42 is located first silica gel sucking disc 43. Then the positioning action through first location adsorption nozzle 42, the mouth of pipe that the guide location that can be better is located the heparin tube of corner position is adsorbed by first silica gel sucking disc 43 and first location adsorption nozzle 42 and is lived, adsorbs more stably firmly. Meanwhile, the second positioning adsorption assembly 50 includes: second installation pipe 51, second location adsorption nozzle 52 and second silica gel sucking disc 53, the inclosed second mounting hole 13 that is fixed in of upper end of second installation pipe 51, the inclosed upper end fixed connection of second location adsorption nozzle 52 in the lower extreme of second installation pipe 51, the airtight fixed cover of all locating of second silica gel sucking disc 53 is located the lower extreme of second installation pipe 51, and second location adsorption nozzle 52 is located second silica gel sucking disc 53. Then through the positioning action of second location adsorption nozzle 52, the mouth of pipe of the heparin tube that the guide location that can be better is located the second corner position is adsorbed by second silica gel sucking disc 53 and second location adsorption nozzle 52 and is lived, adsorbs more stably firmly. Further, the third positioning adsorption assembly 60 includes: third installation pipe 61, third location adsorption nozzle 62 and third silica gel sucking disc 63, the inclosed upper end that is fixed in third mounting hole 14 of third installation pipe 61 in the third installation pipe 61, the inclosed upper end fixed connection of third location adsorption nozzle 62 in the lower extreme of third installation pipe 61, the airtight fixed cover of all fixing of third silica gel sucking disc 63 locates the lower extreme of third installation pipe 61, and third location adsorption nozzle 62 is located third silica gel sucking disc 63. Then through the positioning action of third location adsorption nozzle 62, the mouth of pipe of the heparin tube that the guide location that can be better is located third edge position is adsorbed by third silica gel sucking disc 63 and third location adsorption nozzle 62 and is lived, adsorbs more stably firmly. The fourth positioning adsorption assembly 70 includes: fourth installation pipe 71, fourth location adsorption nozzle 72 and fourth silica gel sucking disc 73, the inclosed upper end of fourth installation pipe 71 is fixed in fourth mounting hole 15, the inclosed upper end fixed connection of fourth location adsorption nozzle 72 in the lower extreme of fourth installation pipe 71, the airtight lower extreme of locating fourth installation pipe 71 that all fixes the cover of fourth silica gel sucking disc 73, and fourth location adsorption nozzle 72 is located fourth silica gel sucking disc 73. Then through the positioning action of fourth location adsorption nozzle 72, the mouth of pipe that the guide location that can be better is located the heparin tube of fourth corner position is adsorbed by fourth silica gel sucking disc 73 and fourth location adsorption nozzle 72 and is lived, adsorbs more stably firmly.

Preferably, the lower end of the first positioning suction nozzle 42 is formed with a first tapered surface structure 421, the lower end of the second positioning suction nozzle 52 is formed with a second tapered surface structure 521, the lower end of the third positioning suction nozzle 62 is formed with a third tapered surface structure 621, and the lower end of the fourth positioning suction nozzle 72 is formed with a fourth tapered surface structure 721. The lower end of the first positioning adsorption nozzle 42, the lower end of the second positioning adsorption nozzle 52, the lower end of the third positioning adsorption nozzle 62 and the lower end of the fourth positioning adsorption nozzle 72 can be more smoothly guided to be inserted into the tube opening of the blood collection tube, and the structure is more reasonable.

Referring to fig. 2 and 3, the bottom of the substrate 10 is further provided with fifth mounting holes 16 corresponding to the suction nozzles 80 one to one, the fifth mounting holes 16 penetrate through and communicate with the cavity, the fifth mounting holes 16 are distributed at the bottom of the substrate 10 in a matrix arrangement, and the suction nozzles 80 are hermetically fixed in the fifth mounting holes 16 in a one to one correspondence manner, so that the mounting structure of the suction nozzles 80 is simpler and more reasonable.

Referring to fig. 2, a plurality of long ventilation grooves 17 are further formed at the bottom of the groove 11, and the long ventilation grooves 17 are distributed between two adjacent rows of the fifth mounting holes 16, so that the air in the cavity flows more smoothly, the weight of the substrate 10 is reduced, and the use is more labor-saving.

Referring to fig. 2, fig. 3, fig. 12 and fig. 13, the batch blood collection tube device 100 of the present application further includes fifth silica gel suckers 90 corresponding to the suction nozzles 80 one to one, and the upper ends of the fifth silica gel suckers 90 are fixedly sleeved at the lower ends of the suction nozzles 80 in a sealed manner, so as to more stably and firmly adsorb the tube openings of the blood collection tubes, and reduce the occurrence of air leakage.

Referring to fig. 1 to 3, the two sides of the base plate 10 are protruded outward to form the mounting bosses 18 that are symmetrical to each other, and the two ends of the handle 30 are fixedly connected to the mounting bosses 18, so that the mounting structure of the handle 30 is more firm and reasonable.

Referring to fig. 3, the batch tube taking device 100 of the present application further includes a sealing ring 20b, and the sealing ring 20b is clamped between the substrate 10 and the cover plate 20a to ensure that the connection between the cover plate 20a and the substrate 10 is airtight and has a more reasonable structure. Furthermore, the bottom of the substrate 10 is further provided with an annular mounting step 19, and the cover plate 20a is embedded in the annular mounting step 19, so that the cover plate 20a can be better limited in the annular mounting step 19 after being mounted, and the mounting structure of the cover plate 20a is firmer and more stable.

The number of the suction nozzles 80 can be flexibly selected according to the use requirement, which is not limited in this application and thus is not described herein again.

The working principle of the batch pipe taking device 100 of the present application will be described in detail with reference to the accompanying drawings:

when the blood sampling tubes are required to be adsorbed, taken and delivered, the connection holes 21 are communicated with an external air extractor, so that vacuum pumping is formed in the cavity, the suction nozzles 80, the first positioning adsorption component 40, the second positioning adsorption component 50, the third positioning adsorption component 60 and the fourth positioning adsorption component 70 which are arranged in a matrix form are used for respectively adsorbing the blood sampling tubes right opposite to each other, the blood sampling tubes positioned at four corners are positioned through the first positioning adsorption nozzle 42 of the first positioning adsorption component 40, the second positioning adsorption nozzle 52 of the second positioning adsorption component 50, the third positioning adsorption nozzle 62 of the third positioning adsorption component 60 and the fourth positioning adsorption nozzle 72 of the fourth positioning adsorption component 70, the adsorbed blood sampling tubes can be quickly positioned, and the whole batch taking and delivering device 100 is delivered through the holding handle 30 to drive the adsorbed batch of blood sampling tubes to be delivered to a designated station.

Because the groove 11 is formed in the top of the substrate 10 of the batch tube taking device 100, the cover plate 20a is hermetically fixed on the top of the substrate 10, a sealed cavity is formed between the cover plate 20a and the groove 11, and the cover plate 20a is provided with a connecting hole 21 communicated with the cavity; the first positioning adsorption component 40, the second positioning adsorption component 50, the third positioning adsorption component 60 and the fourth positioning adsorption component 70 are fixedly distributed at four corners of the bottom of the substrate 10, and the first positioning adsorption component 40, the second positioning adsorption component 50, the third positioning adsorption component 60 and the fourth positioning adsorption component 70 are all communicated with the cavity; the suction nozzles 80 are fixed at the bottom of the substrate 10 in a matrix arrangement, and the suction nozzles 80 are communicated with the cavity; the handle 30 is fixed to the base plate 10. Then, when needing to adsorb to get and send the heparin tube, communicate on external air exhaust device through connecting hole 21 for form evacuation in the cavity, through being the suction nozzle 80 of matrix arrangement, first location adsorption component 40, second location adsorption component 50, third location adsorption component 60 and fourth location adsorption component 70 adsorb respectively and hold the just right heparin tube, and transfer the heparin tube that is located four corners through first location adsorption component 40, second location adsorption component 50, third location adsorption component 60 and fourth location adsorption component 70 and fix a position, can fix a position the absorption and adsorb batch heparin tube fast, the whole batch of heparin tube that drives of absorption is got tub device 100 and is transferred to appointed station through holding handle 30. Not only simple structure can realize getting in batches and send, replaces the manual work mode of taking the heparin tube one by the manual work and transfers, and not only efficiency improves greatly, can avoid taking place the phenomenon such as heparin tube drops, collision moreover, avoids artificial contact pollution risk, prevents heparin tube damage and pollution.

The present application has been described in connection with the embodiments, but the present application is not limited to the embodiments disclosed above, and various modifications and equivalent combinations that are made according to the essence of the present application should be covered.

Claims

1. A batch pipe measuring device, comprising: the suction nozzle comprises a base plate, a cover plate, a handle, a first positioning adsorption component, a second positioning adsorption component, a third positioning adsorption component, a fourth positioning adsorption component and a plurality of suction nozzles, wherein a groove is formed in the top of the base plate, the cover plate is hermetically fixed on the top of the base plate, a sealed cavity is formed between the cover plate and the groove, and a connecting hole communicated with the cavity is formed in the cover plate; the first positioning adsorption assembly, the second positioning adsorption assembly, the third positioning adsorption assembly and the fourth positioning adsorption assembly are fixedly distributed at four corners of the bottom of the substrate, and the first positioning adsorption assembly, the second positioning adsorption assembly, the third positioning adsorption assembly and the fourth positioning adsorption assembly are all communicated with the cavity; the suction nozzles are fixed at the bottom of the substrate in a matrix arrangement and are communicated with the cavity; the handle is fixed on the base plate.

2. The batch pipe taking device according to claim 1, wherein the bottom of the base plate is provided with a first mounting hole, a second mounting hole, a third mounting hole and a fourth mounting hole which are all communicated with the cavity in a penetrating manner, and the first mounting hole, the second mounting hole, the third mounting hole and the fourth mounting hole are distributed at four corners of the bottom of the base plate.

3. The batch pick up tube apparatus of claim 2, wherein the first positioning and suction assembly comprises: the upper end of the first installation pipe is hermetically fixed in the first installation hole, the upper end of the first positioning adsorption nozzle is fixedly connected to the lower end of the first installation pipe, the first silica gel sucker is hermetically fixedly sleeved at the lower end of the first installation pipe, and the first positioning adsorption nozzle is positioned in the first silica gel sucker;

4. The batch pipe taking device according to claim 3, wherein the lower end of the first positioning adsorption nozzle is formed with a first conical surface structure, the lower end of the second positioning adsorption nozzle is formed with a second conical surface structure, the lower end of the third positioning adsorption nozzle is formed with a third conical surface structure, and the lower end of the fourth positioning adsorption nozzle is formed with a fourth conical surface structure.

5. The batch pipe taking device according to claim 1, wherein the bottom of the substrate is further provided with fifth mounting holes corresponding to the suction nozzles one to one, the fifth mounting holes penetrate through and are communicated with the cavity, the fifth mounting holes are distributed on the bottom of the substrate in a matrix arrangement, and the suction nozzles are hermetically fixed in the fifth mounting holes in one to one correspondence.

6. The batch pipe taking device according to claim 5, wherein a plurality of elongated ventilation grooves are further formed in the bottom of the groove, and the elongated ventilation grooves are distributed between two adjacent rows of the fifth mounting holes.

7. The batch pipe taking device according to claim 1, further comprising fifth silica gel suckers corresponding to the suction nozzles one by one, wherein the upper ends of the fifth silica gel suckers are fixedly sleeved at the lower ends of the suction nozzles in a sealing manner.

8. The batch tube taking device as claimed in claim 1, wherein the two sides of the base plate are protruded outwards to form symmetrical mounting bosses, and two ends of the handle are fixedly connected to the mounting bosses.

9. The batch pick up of claim 1, further comprising a gasket disposed between the base plate and the cover plate.

10. The batch pipe taking device according to claim 1, wherein the top of the base plate is further provided with an annular mounting step, and the cover plate is embedded in the annular mounting step.