CN217348419U - Automatic boxing machine for nucleic acid detection reagent tubes - Google Patents

Abstract

Automatic cartoning machine of nucleic acid detect reagent pipe, it has a board, the board mesa still including: the reagent tube storage box comprises a containing box, a plurality of reagent tubes and a plurality of positioning holes, wherein the containing box is provided with a plurality of positioning holes in an array arrangement on the top surface of the containing box; the conveying device is used for conveying the containing boxes; the feeding device is used for providing a reagent tube; and the feeding manipulator is fixedly arranged on the table board and positioned between the conveying device and the feeding device and is used for installing the reagent tube in the containing box. The embodiment of the utility model provides an automatic cartoning machine can be automatic carry after arranging in order the reagent pipe that piles, adorn it to the splendid attire incasement box within simultaneously to have continuous automatic dress box ability, have higher production efficiency.

Description

Automatic boxing machine for nucleic acid detection reagent tubes

Technical Field

The utility model relates to an automatic production equipment field, specificly relate to a be used for going on to the automatic cartoning machine in reagent tubulation to box that nucleic acid detects usefulness.

Background

The nucleic acid detection method is generally a nucleic acid detection method in which, after a sample is collected, whether or not the sample is infected with an invader virus is determined by the presence or absence of nucleic acid of the invader virus. Once a nucleic acid is detected as "positive", the presence of the virus in the patient is confirmed.

In the process of nucleic acid detection, instruments such as a reagent tube 600 and a collection swab are generally used, as shown in fig. 1, the current reagent tube 600 has a tube body 601 and a ring body 602 located at the upper end of the tube body 601, and the tube body 601 is conical, so that in the process of producing, assembling and packaging the whole reagent tube for nucleic acid detection, the reagent tube 600 needs to be installed in the box in advance, thereby facilitating the assembling production work of the reagent tube 600.

And because the shape of present reagent pipe is more unique, so carry and the in-process of dress box comparatively inconvenient, either pack the box through the manual work, or pack the box after adjusting the direction of reagent pipe in advance, no matter which kind of mode, can not realize automatic dress box and the efficient equipment work that carries on.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a neotype automatic cartoning machine of nucleic acid testing reagent pipe, reagent pipe carry through material loading vibration dish, snatch through the material loading manipulator and then adorn it to the box body within, realize the requirement of automatic dress box.

The utility model provides a technical scheme that technical problem adopted is:

automatic cartoning machine of nucleic acid testing reagent pipe, it has a board, the board mesa still including:

the reagent tube storage box comprises a containing box, a plurality of reagent tubes and a plurality of fixing holes, wherein the containing box is provided with a plurality of mounting holes in an array arrangement on the top surface of the containing box, and the mounting holes are used for loading the reagent tubes;

the conveying device is used for conveying the containing box and comprises a conveying channel and a driving device for driving the containing box to be driven in the conveying channel;

the feeding device is used for providing reagent tubes, is positioned beside the conveying device and is fixedly arranged on the table board, and comprises a feeding vibration disc for conveying the reagent tubes and a material receiving table communicated with a discharge port of the feeding vibration disc, wherein a material receiving groove is formed in the side surface of the material receiving table communicated with the discharge port of the feeding vibration disc, and the material receiving groove is formed in the side surface of the material receiving table in the vertical direction;

feeding manipulator, feeding manipulator is fixed to be installed on the board mesa, and is located between conveyor and the loading attachment, be used for installing the reagent pipe in the splendid attire case, feeding manipulator is including sharp module and will sharp module erects the frame of conveyor and loading attachment top, just install on the sharp module and follow sharp direction reciprocating motion's the material head of getting by its drive, get the material head including telescopic cylinder and with the piston rod that telescopic cylinder stretches out downwards is connected gets the material seat, get and install the material straw of getting that is used for absorbing the reagent pipe on the material seat.

Further, the containing box is including the box main part of seting up a cavity, install will on the box main part the upper cover that the cavity lid closed, just the mounting hole is seted up on the upper cover, the inner wall upper end of cavity is followed the inner wall surface has seted up a step, the step makes the cavity upper end constitutes a cross sectional area and is greater than the district of placing of cavity lower extreme cross sectional area, the upper cover have with place the length and the width size of district looks adaptation, make the upper cover embedding place within the district and by the step bearing.

Further, material loading vibration dish discharge gate department is connected with the material loading track, the material loading track is including a plurality of that set up side by side, and is a plurality of material loading track inlet end position in proper order with material loading vibration dish discharge gate is connected, and is a plurality of material loading track export with connect above the material platform connect the butt joint of material recess, it is corresponding, connect the material recess be with material loading track is corresponding a plurality of, and arrange each other side by side.

Furthermore, a plurality of the feeding tracks comprise two side walls which are mutually parallel, a channel for a reagent tube to pass through is formed between the two side walls, and the width of the channel is matched with that of the reagent tube.

Furthermore, connect the material platform including fixed install connect the material pole setting two each other side by side on the board mesa, two connect material pole setting top to be connected with and connect the flitch, connect the both ends of flitch respectively with two connect material pole setting fixed connection, make connect the flitch crossbearer in two connect on the material pole setting, connect the material recess to set up in connect the flitch with connect on the corresponding side of material track, just connect the material recess to run through connect the material thickness direction.

Furthermore, the feeding device is also provided with a material conveying mechanism, the material conveying mechanism is positioned between the feeding track and the material receiving platform and is used for communicating an outlet of the feeding track with a material receiving groove of the material receiving platform, and the material conveying mechanism comprises a material conveying mechanism

The conveying base is fixedly arranged on the table board and is positioned between the feeding track and the receiving table;

the material conveying platform is fixedly arranged on the top surface of the material conveying base, a plurality of material conveying channels corresponding to the material feeding rails are formed in the position, located on the top surface of the material conveying platform, the material conveying channels penetrate through the material conveying platform along the length direction of the material conveying platform, the material conveying channels are deep corresponding to the reagent tubes, one end of each material conveying channel is communicated with the material feeding rails, and the other end of each material conveying channel is communicated with the material receiving grooves.

Furthermore, the material conveying platform is also provided with a mounting column and a top cover used for covering the plurality of material conveying channels, the mounting column is provided with a mounting end protruding out of the top surface of the material conveying platform, and the top cover is fixedly mounted on the mounting end, so that a spacing interval is formed between the top cover and the top surface of the material conveying platform, and the area of the top cover corresponds to the area of the top surface of the material conveying platform.

Furthermore, get and offer on the material seat with connect a plurality of equidistant side by side linkage holes that the material recess is corresponding, it is corresponding get the material straw be with a plurality of that the linkage hole is corresponding, and install in within the linkage hole, get the material straw including:

the rod body penetrates through the linkage hole, an air suction hole is formed in the upper portion of the rod body along the axis of the rod body, and one end, located above the material taking seat, of the rod body is connected with an external air compressor;

the cap body is fixedly arranged on one end, positioned above the material taking seat, of the rod body, and the size of the cap body is larger than the diameter of the linkage hole;

the shaft shoulder is formed at one end of the rod body below the material taking seat, and the diameter of the shaft shoulder is larger than that of the rod body, so that the rod body is in a stepped shaft shape;

the compression spring is sleeved on the rod body and positioned between the shaft shoulder and the material taking seat, and the diameter of the compression spring is smaller than that of the shaft shoulder;

the material suction head is arranged at the end part of the rod body below the material taking seat, and the material suction head is convenient to extend into the reagent tube.

Further, the material suction head is conical with a wide upper part and a narrow lower part.

Compared with the prior art, the beneficial effects of the utility model reside in that:

an embodiment the automatic cartoning machine of nucleic acid detection reagent pipe that provides, loading attachment carries the reagent pipe through adopting material loading vibration dish to put in order the reagent pipe at the in-process of carrying, make its vertical direction be located the material loading track, convey within the defeated material passageway, and install and connect material platform connect the material recess within, thereby make installing side by side of a plurality of reagent pipes connect material platform on, thereby be convenient for the material loading machine hand snatch. This equipment can be with the containing box who is used for splendid attire reagent pipe at the in-process of conveyor's transport, absorbs reagent pipe on connecing the material platform through material loading manipulator to adorn it to within the mounting hole of containing box, thereby realize automatic dress box processing with reagent pipe after through the arrangement, and can swiftly carry rapidly after the dress box, thereby provide the holistic production efficiency of equipment.

And, at the in-process that material loading manipulator absorbs the reagent pipe, owing to installed a compression spring on it to make the body of rod have a buffering effect that has compression spring to provide, when carrying out the in-process that the reagent pipe absorbs, when getting the material straw and moving down and absorbing the reagent pipe, can prevent that the lift cylinder from moving down and forming too big to the reagent pipe or get the material straw and cause the damage under compression spring's effect, thereby increased the holistic production security performance of this equipment.

The invention is further described with reference to the drawings and embodiments.

Drawings

FIG. 1 is a schematic structural diagram of a reagent tube requiring boxing in the embodiment of the present invention.

Fig. 2 is a schematic structural diagram of the present invention.

Fig. 3 is a schematic structural view of the present invention with the outer shell removed.

Fig. 4 is a schematic structural view of the middle containing box of the present invention.

Fig. 5 is a schematic structural diagram of the feeding device in the present invention.

Fig. 6 is a schematic structural view of the middle feeding vibration plate of the present invention.

Fig. 7 is a partially enlarged structural view of a portion a in fig. 6.

Fig. 8 is a schematic structural view of the feeding mechanism of the present invention.

Fig. 9 is an exploded view of the feeding mechanism of the present invention.

Fig. 10 is a schematic structural view of the receiving platform of the present invention.

Fig. 11 is a schematic structural view of the loading robot according to the present invention.

Fig. 12 is a schematic structural view of the material taking head of the present invention.

Fig. 13 is an exploded view of the material suction pipe of the present invention.

Detailed Description

In order to make the technical problem, technical solution and advantageous effects solved by the present invention more clearly understood, the following description is given in conjunction with the accompanying drawings and embodiments to further explain the present invention in detail. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

It should be noted that all the directional indicators (such as up, down, left, right, front, and back) in the embodiments of the present invention are only used to explain the relative position relationship between the components, the motion situation, and the like in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indicator is changed accordingly.

In addition, the descriptions provided with "first", "second", and the like in the embodiments of the present invention are for descriptive purposes only and are not to be construed as indicating or implying relative importance or implying any number of indicated technical features.

Referring to fig. 1 to 13, the automatic box packing machine for nucleic acid detecting reagent tubes 600 according to the embodiment of the present invention is used for packing the reagent tubes 600 into the containing box 200, so as to facilitate the later processing and packing of the reagent tubes 600 in the containing box 200, and includes a conveying device 300 for conveying the containing box 200 and completing the packing of the reagent tubes 600 into the containing box 200 during the conveying process, a feeding device 400 for providing the reagent tubes 600, and a feeding manipulator 500 for taking down the reagent tubes 600 from the feeding device 400 to the containing box 200 on the conveying device 300.

As shown in fig. 2 to 3, the conveying device 300 has a conveying path 301 for conveying the containing box 200, and a driving device 302 for driving the containing box 200 within the conveying path 301 is further disposed on the conveying device 300, specifically, the driving device 302 is a motor, and the conveying device 300 is driven by the motor, so that the containing box 200 is driven within the conveying path 301, and further, the containing box 200 completes the loading operation of the reagent tube 600 during the conveying process. As shown in fig. 4, the containing box 200 has a box main body 210 with a chamber 211, and an upper cover 212 installed on the box main body 210 for covering the chamber 211, and a plurality of mounting holes 201 for installing the reagent tubes 600 therein are opened on the upper cover 212, and the mounting holes 201 are arranged in an array, so as to facilitate the installation of the reagent tubes 600. Meanwhile, a step 213 is formed at the upper end portion of the inner wall of the chamber 211 along the inner wall surface, the step 213 enables the upper end of the chamber 211 to form a placing region 214, wherein the cross-sectional area of the placing region 214 is larger than that of the lower end of the chamber 211, and the length and width of the upper cover 212 correspond to the relevant size of the placing region 214, so that the upper cover 212 can be placed in the placing region 214, and the upper cover 212 is supported by the step 213, thereby sealing the chamber 211. In the process of packing the reagent tube 600, the reagent tube 600 is inserted into the packing box 200 through the mounting hole 201, and at the same time, since the reagent tube 600 is provided with the ring body 602 at the upper end, the reagent tube 600 can be fixedly clamped into the mounting hole 201, and the tube body 601 of the reagent tube 600 is inserted into the chamber 211 through the mounting hole 201. Because the box main part 210 provides accommodation space for reagent pipe 600 through the cavity 211 that sets up to provide through upper cover 212 and install fixed mounting hole 201 with reagent pipe 600, thereby make containing box 200 produce more conveniently, compare thereby it is used for holding reagent pipe 600 to drill respectively on whole block, the embodiment of the utility model provides a containing box 200 production processes still less, and manufacturing cost is lower.

In the embodiment, as shown in fig. 2-3 and 5, the loading device 400 is fixedly installed beside the conveying device 300, and is used for conveying the disordered reagent tubes 600 and arranging them for loading onto the containing box 200, and includes a loading vibration tray 410 fixedly installed on the top of the machine 100, the loading vibration tray 410 is used for conveying the reagent tubes 600, and uniformly arranging the orientations of the reagent tubes 600 during the vibration conveying of the loading vibration tray 410, so that the reagent tubes 600 flow out through the outlet 411 of the loading vibration tray 410 in a uniform state, thereby facilitating the loading onto the containing box 200. Meanwhile, the feeding device 400 is further provided with a receiving platform 420, a receiving groove 421 for receiving the reagent tube 600 is formed in the side meter of the receiving platform 420 corresponding to the discharge hole 411, and the receiving groove 421 is communicated with the discharge hole 411 of the feeding vibration plate 410, so that the reagent tube 600 flowing out through the discharge hole 411 is received, and the reagent tube 600 is captured and then loaded into the containing box 200.

Specifically, as shown in fig. 5 to 10, the discharge hole 411 of the feeding vibration tray 410 is connected with a plurality of feeding rails 412, wherein the feeding rails 412 are arranged side by side, the inlet ends of the plurality of feeding rails 412 are sequentially connected with the discharge hole 411 of the feeding vibration tray 410, the outlet ends of the plurality of feeding rails are butted with the receiving grooves 421 on the receiving table 420, correspondingly, the receiving grooves 421 on the receiving table 420 are arranged in a plurality corresponding to the feeding rails 412, and meanwhile, the receiving grooves 421 are arranged side by side on the receiving table 420, so that the reagent tubes 600 can be conveyed into the receiving grooves 421 along the respective feeding rails 412 and are arranged side by side in the receiving grooves 421, and the reagent tubes 600 can be conveniently clamped and loaded into the containing box 200.

The feeding tracks 412 are configured as shown in fig. 6-7, each feeding track 412 includes two side walls 413 which are parallel to each other, and the two side walls 413 are opposite to each other, so that a channel 414 for the reagent tube 600 to pass through is formed between the two side walls 413, and the width of the channel 414 is adapted to the reagent tube 600, so that the reagent tube 600 can pass through the channel 414 without falling out. Specifically, as shown in fig. 7, the feeding rail 412 is formed by two side walls 413 which are opposite to each other, so that the channel 414 formed by the two side walls 413 is open in the vertical direction, so that the ring body 602 of the reagent tube 600 is located at the upper end of the channel 414, and the tube body 601 is located at the upper end of the channel 414 after passing through the channel 414, so as to be vertically arranged in the feeding rail 412 and vertically transferred to the receiving groove 421 of the receiving table 420 within the limitation of the ring body 602, so as to be sucked and loaded into the containing box 200 within the receiving groove 421.

Wherein, the structure of the material receiving platform 420 is as shown in fig. 10, the material receiving platform 420 has two material receiving vertical rods 423 that are arranged side by side and fixedly installed on the table top of the machine 100, the tops of the two material receiving vertical rods 423 are linked with a material receiving plate 422, the top end of the material receiving plate 422 is fixedly linked with the top ends of the two material receiving vertical rods 423 respectively, so that the material receiving plate 422 is transversely arranged on the two material receiving vertical rods 423, meanwhile, a material receiving groove 421 is arranged on a side surface of the material receiving plate 422 corresponding to the material receiving rail, and the material receiving groove 421 penetrates through the thickness direction of the material receiving plate 422, so that when the material receiving groove 421 receives the reagent tube 600 conveyed from the material receiving rail 412, the tube body 601 of the reagent tube 600 can be arranged in the material receiving groove 421 and is arranged along the vertical direction, and is limited in the material receiving groove 421 by the ring 602 of the reagent tube 600, so as to prevent the reagent tube 600 from falling down in the material receiving groove 421, meanwhile, the plurality of reagent tubes 600 are respectively arranged in the receiving groove 421 and arranged side by side, so that the plurality of reagent tubes 600 arranged side by side can be clamped conveniently.

In the embodiment, a material conveying mechanism 430 is further provided on the feeding device 400, as shown in fig. 5 and 8-9, the material conveying mechanism 430 is located between the feeding rail 412 and the material receiving platform 420, and is used for communicating the feeding rail 412 with the material receiving groove 421 on the material receiving platform 420, so as to conveniently convey the reagent tube 600 on the feeding rail 412 to the material receiving groove 421, which includes a material conveying base 431 fixed on the top of the machine platform 100, the material conveying base 431 is used for providing a top surface higher than the machine platform 100, and a material conveying platform 432 is fixedly installed on the top surface of the material conveying base, meanwhile, a plurality of material conveying channels 433 corresponding to the feeding rail 412 are opened on the top surface of the material conveying platform 432, and the material conveying channels 433 penetrate through the material conveying platform 432 along the length direction of the material conveying platform 432, and the material conveying channels 433 have a depth adapted to the reagent tube 600, thus in the process of conveying the reagent tube 600, the tube body 601 is vertically located in the material conveying channel 433 under the limitation of the ring body 602, one end of the material conveying channel 433 is communicated with the material feeding channel 412, and the other end of the material conveying channel is communicated with the material receiving groove 421.

Meanwhile, the feeding table 432 is further provided with a mounting column 434 and a top cover 435 for covering the feeding channel 433, the feeding channel 433 is covered by the top cover 435, thereby preventing the reagent tube 600 from jumping out of the feed path 433 due to the jumping during the feeding by the feed mechanism 430, specifically, as shown in FIG. 9, wherein the mounting post 434 has a mounting end 436 protruding from the top surface of the material table 432, and the top cover 435 is fixedly mounted on the mounting end 436, so that the top cover 435 is spaced apart from the top surface of the feeding platform 432, so that when the reagent tube 600 is transported in the feeding channel 433, the space facilitates the reagent tube 600 to pass through the ring 602, and the top cover 435 has an area corresponding to the top surface of the material delivery platform 432, thereby covering a plurality of feed delivery passages 433 opened above the top surface of the feed delivery table 432.

In an embodiment, the loading robot 500 is fixedly installed on the machine platform 100, as shown in fig. 3, between the conveying device 300 and the loading device 400, and is configured to suck the reagent tubes 600 on the receiving platform 420 and then load the reagent tubes into the mounting holes 201 of the containing boxes 200 located on the conveying path 301, so as to complete the boxing of the reagent tubes 600. As shown in fig. 11 to 13, the loading robot 500 has a rack 501 fixedly installed on the top surface of the machine 100 in a vertical direction, and a linear module 502 is fixedly installed on the top surface of the rack 501, so that the linear module 502 is supported by the rack 501 above the conveying device 300 and the loading device 400, thereby facilitating the loading of the reagent vessel 600 on the conveying device 300 after being removed from the receiving platform 420. Meanwhile, a material taking head 510 which is driven by the linear module 502 and moves along the linear direction of the linear module 502 for sucking the reagent tube 600 is arranged on the linear module 502, the material taking head 510 comprises a telescopic cylinder 511 with a piston rod extending downwards, a material taking seat 512 is connected to the piston rod, and a material taking suction pipe 513 for sucking the reagent tube 600 is arranged on the material taking seat 512. The mechanism of the material taking seat 512 and the material taking suction pipe 513 is as shown in fig. 12-13, the material taking seat 512 is provided with a plurality of linkage holes 514 which are arranged side by side at equal intervals and correspond to the number of the material taking grooves, wherein the material taking suction pipe 513 is arranged in the linkage holes 514, so that all the reagent tubes 600 positioned on the material receiving platform 420 can be sucked, and the reagent tubes 600 are arranged in the mounting holes 201 of the containing box 200 after being sucked by the material receiving platform 420 under the driving of the linear module 502. As shown in fig. 13, the material taking suction pipe 513 includes a rod body 5131, the rod body 5131 penetrates through the linkage hole 514, an air suction hole 5136 is formed in the rod body 5131 along the axis, and meanwhile, one end of the rod body 5131 above the material taking seat 512 is communicated with an external air compressor, so that the air compressor extracts air through the air suction hole 5136, and the reagent tube 600 can be sucked. Meanwhile, the material taking suction pipe 513 further comprises a cap body 5132 which is arranged at one end of the rod body 5131 above the material taking seat 512, so that the rod body 5131 is arranged above the material taking seat 512 to prevent the rod body from falling out of the material taking seat 512 along the linkage hole 514, a shaft shoulder 5133 with the diameter larger than that of the rod body 5131 is arranged above a section of the rod body 5131 below the material taking seat 512, so that the rod body 5131 is in a stepped shaft shape, a compression spring 5134 which is sleeved on the rod body 5131 is arranged between the shaft shoulder 5133 and the material taking seat 512, and the rod body 5131 is extended out below all the time under the action of the compression spring 5134. At the lower end of the rod body 5131, a suction head 5135 is formed, and the suction head 5135 is used for extending into the reagent tube 600, so that the reagent tube 600 is extracted under the suction action of the air compressor. In order to improve the suction effect on the reagent tube 600, the suction head 5135 is in a narrow conical shape, so that the suction head 5135 can more smoothly extend into the reagent tube 600, and the reagent tube 600 is connected onto the suction head 510 through the interference fit effect in the continuous extending process. When the linear module 502 moves the material taking head 510 to the upper side of the containing box 200 of the conveying device 300, the telescopic cylinder 511 moves the material taking seat 512 and the material taking suction pipe 513 downward, so as to load the sucked reagent tube 600 into the mounting hole 201 of the containing box 200, at the moment, the external air compressor blows air to the direction of the material taking head 5135 through the air suction hole 5136, and thus the reagent tube 600 is separated from the material taking head 5135 under the action of wind.

Various other modifications and alterations of the disclosed structure and principles may occur to those skilled in the art, and all such modifications and alterations are intended to be included within the scope of the present invention.

Claims (9)

1. Automatic cartoning machine of nucleic acid detect reagent pipe, it has a board, its characterized in that, the board mesa still including:

the reagent tube storage box comprises a containing box, a plurality of reagent tubes and a plurality of fixing holes, wherein the containing box is provided with a plurality of mounting holes in an array arrangement on the top surface of the containing box, and the mounting holes are used for loading the reagent tubes;

the conveying device is used for conveying the containing box and comprises a conveying channel and a driving device for driving the containing box to be driven in the conveying channel;

the feeding device is used for providing reagent tubes, is positioned beside the conveying device and is fixedly arranged on the table board, and comprises a feeding vibration disc for conveying the reagent tubes and a material receiving table communicated with a discharge port of the feeding vibration disc, wherein a material receiving groove is formed in the side surface of the material receiving table communicated with the discharge port of the feeding vibration disc, and the material receiving groove is formed in the side surface of the material receiving table in the vertical direction;

feeding manipulator, feeding manipulator is fixed to be installed on the board mesa, and is located between conveyor and the loading attachment, be used for installing the reagent pipe in the splendid attire case, feeding manipulator is including sharp module and will sharp module erects the frame of conveyor and loading attachment top, just install on the sharp module and follow sharp direction reciprocating motion's the material head of getting by its drive, get the material head including telescopic cylinder and with the piston rod that telescopic cylinder stretches out downwards is connected gets the material seat, get and install the material straw of getting that is used for absorbing the reagent pipe on the material seat.

2. The automatic nucleic acid detecting reagent tube packing machine according to claim 1, wherein the containing box includes a box main body having a chamber, an upper lid mounted on the box main body to cover the chamber, and the mounting hole is formed in the upper lid, a step is formed in an upper end of an inner wall of the chamber along a surface of the inner wall, the step enables the upper end of the chamber to form a placing area having a cross sectional area larger than a cross sectional area of a lower end of the chamber, and the upper lid has a length and a width that are adapted to the placing area, so that the upper lid is inserted into the placing area and supported by the step.

3. The automatic boxing machine for nucleic acid detecting reagent tubes according to claim 1, wherein a feeding track is connected to a discharge port of the feeding vibration tray, the feeding track comprises a plurality of feeding tracks arranged side by side, an inlet of each feeding track is sequentially connected to a discharge port of the feeding vibration tray, outlets of the feeding tracks are in butt joint with the receiving grooves on the receiving table, and the receiving grooves are correspondingly arranged side by side and correspond to the feeding tracks.

4. The automatic boxing machine for nucleic acid detection reagent tubes according to claim 3, wherein each of the plurality of feeding rails comprises two side walls which are arranged side by side, a channel for the reagent tube to pass through is formed between the two side walls, and the width of the channel is matched with that of the reagent tube.

5. The automatic boxing machine for nucleic acid detecting reagent tubes according to claim 4, wherein the material receiving platform comprises two material receiving vertical rods which are fixedly arranged on the table board side by side, a material receiving plate is connected to the tops of the two material receiving vertical rods, two ends of the material receiving plate are respectively and fixedly connected with the two material receiving vertical rods, so that the material receiving plate is cross-bridged above the two material receiving vertical rods, the material receiving groove is formed in the side face, corresponding to the material receiving rail, of the material receiving plate, and the material receiving groove penetrates through the thickness direction of the material receiving plate.

6. The automatic boxing machine for nucleic acid detecting reagent tubes as claimed in claim 3, wherein the loading device further comprises a feeding mechanism, the feeding mechanism is located between the loading track and the receiving platform for communicating the outlet of the loading track with the receiving groove of the receiving platform, and the feeding mechanism comprises a feeding mechanism

The conveying base is fixedly arranged on the table board and is positioned between the feeding track and the receiving table;

the material conveying platform is fixedly arranged on the top surface of the material conveying base, a plurality of material conveying channels corresponding to the material feeding rails are formed in the position, located on the top surface of the material conveying platform, the material conveying channels penetrate through the material conveying platform along the length direction of the material conveying platform, the material conveying channels are deep corresponding to the reagent tubes, one end of each material conveying channel is communicated with the material feeding rails, and the other end of each material conveying channel is communicated with the material receiving grooves.

7. The automatic nucleic acid detecting reagent tube packing machine as claimed in claim 6, wherein said feeder table further has a mounting post and a top cover for covering a plurality of said feeder passages, said mounting post having a mounting end protruding from a top surface of said feeder table, said top cover being fixedly mounted on said mounting end such that said top cover is spaced apart from said top surface of said feeder table by a distance corresponding to an area of said top surface of said feeder table.

8. The automatic nucleic acid detecting reagent tube boxing machine of claim 3, wherein a plurality of linkage holes are formed in the material taking seat in parallel and at equal intervals corresponding to the material receiving grooves, the corresponding material taking suction tubes are a plurality of linkage holes and are arranged in the linkage holes, and each material taking suction tube comprises:

the rod body penetrates through the linkage hole, an air suction hole is formed in the upper portion of the rod body along the axis of the rod body, and one end, located above the material taking seat, of the rod body is connected with an external air compressor;

the cap body is fixedly arranged on one end, positioned above the material taking seat, of the rod body, and the size of the cap body is larger than the diameter of the linkage hole;

the shaft shoulder is formed at one end of the rod body below the material taking seat, and the diameter of the shaft shoulder is larger than that of the rod body, so that the rod body is in a stepped shaft shape;

the compression spring is sleeved on the rod body and positioned between the shaft shoulder and the material taking seat, and the diameter of the compression spring is smaller than that of the shaft shoulder;

the material suction head is arranged at the end part of the rod body below the material taking seat, and the material suction head is convenient to extend into the reagent tube.

9. The automatic boxing machine for nucleic acid detecting reagent tubes of claim 8, wherein the suction head is conical with a wide top and a narrow bottom.

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