CN214933017U - Multi-sample container processing module and processing system - Google Patents

Abstract

The utility model provides a multi-sample container processing module and a processing system, which belong to the technical field of medical instruments, and a discharging mechanism comprises a storage box, and a storage space is arranged in the storage box, wherein, the storage space is divided into a first storage cavity and a second storage cavity by a clapboard in the storage space; the transition mechanism is provided with a material receiving end and a material discharging end at two ends respectively, wherein the material receiving end is provided with a material receiving frame, the material discharging end is provided with a rotating structure and a material discharging plate, and a driving structure is arranged between the material receiving frame and the rotating structure; and the printing mechanism is positioned above the transition mechanism, wherein the printing mechanism comprises a laser head, and an emission light source of the laser head corresponds to the position of the rotating structure. Cut apart into two storage chambers with it through the baffle, realize depositing of two kinds of different sample containers to improve the nimble utilization to storage tank inner space, and then reduce processing system's manufacturing cost.

Description

Multi-sample container processing module and processing system

Technical Field

The utility model belongs to the technical field of medical instrument, a processing module, especially a many sample container processing module and processing system are related to.

Background

The current hospital outpatient clinic fluid examination process is as follows: the patient arrives at the inspection window by the check sheet, the staff selects the container according to the medical advice and submits to the reservation requirement, the patient arrives at the window again after sampling, the staff receives the specimen and prints the bar code to be pasted on the container, and simultaneously prints the receipt sheet to the patient, and the time and the place of taking the sheet are informed. There are the following problems: 1. the waiting time is long due to long queuing at peak time; 2. various errors such as insufficient sample collection amount, wrong container taking and the like are caused by various reasons; 3. the workload is large, and the error of putting on the hat is easy to occur; 4. when a sample is received, a patient's visit card is required to be taken to print a bar code and be attached to a container, and a receipt is printed for the patient at the same time, so that the sample possibly has biohazard, hospital infection is possible, and patient complaints are often caused; 5. the manual bar code is not consistent in height, so that the detection speed is reduced, and the maximum efficiency cannot be exerted.

Chinese patent (CN207718498U) discloses an outpatient body fluid collecting self-service machine, which comprises: the laser printing machine comprises a rack, at least one transmission mechanism is arranged on the rack, at least one discharging mechanism and one laser printing mechanism are respectively arranged at two ends of the transmission mechanism, at least one rotating mechanism is arranged at the same end position of the laser printing mechanism, and the rotating mechanism and the laser printing mechanism are respectively positioned at the upper side and the lower side of the transmission mechanism.

However, the self-service machine described above can only store a single sample container in the discharge mechanism, and if two sample containers need to be stored, the number of discharge mechanisms needs to be increased, which results in the manufacturing cost of the processing system.

Disclosure of Invention

The utility model aims at having above-mentioned problem to current technique, provide one kind and can strengthen quality control before the analysis, improve work efficiency, reduce the mistake, stop the institute and feel probably, shorten check-out time, optimize the flow of seeing a doctor, promote the processing system that the patient experienced of seeing a doctor.

The purpose of the utility model can be realized by the following technical proposal: a multiple sample container processing module, comprising:

the discharging mechanism comprises a storage box, a feeding end and a discharging end are arranged at two ends of the storage space respectively, and a partition plate is arranged in the storage space and divides the storage space into a first storage cavity and a second storage cavity;

the transition mechanism is provided with a receiving end and a discharging end at two ends respectively, wherein the receiving end is provided with a receiving frame for receiving a sample container falling from the blanking end, the discharging end is provided with a rotating structure for completely exposing a blank area on the sample container and an obliquely arranged discharging plate, and a driving structure for transporting the sample container on the receiving frame to the rotating structure is arranged between the receiving frame and the rotating structure;

and the printing mechanism is positioned above the transition mechanism, wherein the printing mechanism comprises a laser head, and an emission light source of the laser head corresponds to the position of the rotating structure.

In the multi-sample container processing module, a single feed port or two feed ports are arranged at the feed end, wherein when the number of the feed ports is two, the two feed ports are respectively positioned at two sides of the storage box and are respectively and correspondingly communicated with the first storage cavity and the second storage cavity; the discharge end is provided with single discharge gate or sets up two discharge gates, and wherein, when the quantity of discharge gate is two, two discharge gates set up side by side to correspond the intercommunication with first storage chamber and second storage chamber respectively.

In the above-mentioned multi-sample container processing module, the discharge port is provided with a rotatable blanking wheel, wherein the surface of the blanking wheel is provided with a blanking slot, and the blanking slot is depressed towards the center of the blanking wheel along the surface of the blanking wheel.

In foretell many samples container processing module, the baffle is including dismantling the first baffle of connecting on the storage tank, and with the rotatory complex second baffle of first baffle, wherein, has the door plant at feed inlet department swing joint, and forms linkage structure through the connecting rod between door plant and the second baffle.

In the above multi-sample container processing module, the material receiving frame is provided with a fixed material receiving plate and a movable material receiving plate, and one side of the fixed material receiving plate opposite to the movable material receiving plate is respectively provided with a guide inclined plane, namely a first guide inclined plane and a second guide inclined plane, wherein a blanking channel and a material receiving groove are formed by opening and closing the first guide inclined plane and the second guide inclined plane.

In the multi-sample container processing module, the discharge end is provided with the baffle arm which is positioned on the moving track of the material receiving frame, wherein the first guide inclined plane and the second guide inclined plane are opened and closed through the abutting and separation between the baffle arm and the movable material receiving plate.

In the multi-sample container processing module, the fixed material receiving plate and the movable material receiving plate are matched through magnetic attraction, wherein the fixed material receiving plate is connected with the magnetic block, the movable material receiving plate is connected with the ejector rod, and the ejector rod penetrates through the fixed material receiving plate and the magnetic block and is in threaded connection with the movable material receiving plate.

In the above multi-sample container processing module, a pushing structure is connected to the material receiving frame and located between the material receiving groove and the blocking arm, wherein the pushing structure separates the relative distance between the two auxiliary rotating shafts.

In foretell many sample container processing module, push away the structure including push away the support, and push away be connected with on the support with one of them assist axis of rotation both ends correspond to lean on the complex kicking block, wherein, be provided with on the kicking block and push away from the first work inclined plane of this assistance axis of rotation and realize the second work inclined plane that this assistance axis of rotation resets, and first work inclined plane and second work inclined plane are two adjacent inclined planes on the kicking block.

The utility model also provides a many sample container processing system, it is including a plurality of many sample container processing module, and will be a plurality of many sample container processing module divide into two sets ofly, and is two sets of many sample container processing module between set up conveying mechanism.

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

(1) the utility model discloses a storage chamber, two storage chambers are cut apart into it through the baffle, realize depositing of two kinds of different sample container, thereby improve the nimble utilization to the storage tank inner space, and then reduce processing system's manufacturing cost, in addition, discharge mechanism, the automatic cooperation between transition mechanism and the printing mechanism, reduce the transmission number of times of sample container between inspection personnel and patient, avoid taking the phenomenon by mistake, and the regular placing in discharge mechanism of sample container, avoid contacting with the external world and taking place the pollution, the security and the reliability that the sample container was deposited are improved.

(2) The opening size of the door plate is matched with linkage between the door plate and the second baffle, so that material supplementing of the first storage cavity and the second storage cavity is realized, and the operation is flexible and reliable. In addition, the second baffle is around first baffle in rotatory process, and first storage chamber and second storage chamber are controlled strictly, avoid the sample container to take place alternately, improve the accuracy nature and the reliability of the ejection of compact.

(3) The discharge gate can be blocked through the blanking wheel to combine the blanking groove on the blanking wheel, realize the ejection of compact one by one of sample container, improve the reliability of the ejection of compact, in addition, the sample container is embedded in the blanking groove when the ejection of compact, guarantees that the blanking wheel is rotatory in-process, extrudees the sample container, guarantees the reliability of the ejection of compact of sample container.

(4) The cooperation is inhaled through magnetism between fixed flitch and the activity connects the flitch, conveniently changes the relative distance between fixed flitch and the activity connects the flitch for connect the sample container in the silo can fall into the revolution mechanic of below reliably on, in addition, through the convex part on the ejector pin, realize the ejector pin and the fixed joint cooperation that connects between the flitch, thereby control is fixed connects the flitch and the activity connects separation distance between the flitch, and then avoids the fixed flitch that connects of ejector pin roll-off, improves and connects the reliability that the material frame used.

(5) The distance of the movable material receiving plate when the fixed material receiving plate is far away from is adjusted by the aid of the screwing match and the rotating ejector rod, so that the movable material receiving plate is adaptive to discharging of sample containers of different sizes, and the sample containers in the material receiving groove can reliably fall into a rotating structure of the lower part when the movable material receiving plate is far away from the fixed material receiving plate.

(6) Through the top pushing structure, the ejection of compact of the sample container that the realization was located the revolution mechanic and has accomplished the printing, through connecing the silo and keeping off leaning on the cooperation between the arm, realize connecing on the silo not the sample container of printing fall into revolution mechanic, form continuous action, improve the work efficiency that the sample container printed.

Drawings

Fig. 1 is a schematic diagram of a multiple sample container processing system according to the present invention.

Fig. 2 is a schematic structural view of a multi-sample container processing module according to the present invention.

Fig. 3 is a schematic structural diagram of a discharging mechanism according to a preferred embodiment of the present invention.

Fig. 4 is a schematic view of a partial structure of a discharging mechanism according to a preferred embodiment of the present invention.

Fig. 5 is a schematic view of a partial structure of a discharging mechanism according to a preferred embodiment of the present invention.

Fig. 6 is a schematic structural diagram of a transition mechanism according to a preferred embodiment of the present invention.

Fig. 7 is a partial structural schematic diagram of a transition mechanism according to a preferred embodiment of the present invention.

Fig. 8 is a schematic structural view of a rotating structure according to a preferred embodiment of the present invention.

Fig. 9 is a schematic structural diagram of a top block according to a preferred embodiment of the present invention.

In the figure, 100, a discharging mechanism; 110. a storage box; 111. a first storage chamber; 112. a second storage chamber; 113. a feed inlet; 114. a first discharge port; 115. a second discharge port; 116. a first inclined guide plate; 117. a side plate; 120. a partition plate; 121. a first baffle plate; 122. a second baffle; 123. a second inclined guide plate; 130. a door panel; 140. a connecting rod; 150. a drive member; 160. closing the plate; 170. a blanking wheel; 171. a charging chute; 180. a first rotating electrical machine; 190. a second rotating electrical machine;

200. a transition mechanism; 210. a material receiving frame; 211. fixing a material receiving plate; 2111. a first guide slope; 212. a movable material receiving plate; 2121. a second guide slope; 213. a magnetic block; 214. a top rod; 2141. a convex portion; 220. a rotating structure; 221. rotating the bracket; 2211. a first guide groove; 222. a third rotating electrical machine; 223. a main rotating shaft; 224. an auxiliary rotating shaft; 225. a magnetic ring; 230. a discharge plate; 240. a drive structure; 241. a transmission motor; 242. a screw rod; 250. a catch arm; 260. a pushing structure; 261. pushing the bracket; 2611. a second guide groove; 262. a top block; 2621. a first working bevel; 2622. a second working bevel; 263. a rotating rod; 264. an elastic member; 265. fixing the rod;

300. a printing mechanism; 310. a laser head; 400. a conveying mechanism; 410. a conveyor belt; 420. a guide plate; 430. a barrier plate.

Detailed Description

The following are specific embodiments of the present invention and the accompanying drawings are used to further describe the technical solution of the present invention, but the present invention is not limited to these embodiments.

As shown in fig. 1 to 9, the present invention provides a multi-sample container processing module, comprising:

the discharging mechanism 100 comprises a storage box 110, wherein a storage space for storing sample containers is arranged in the storage box 110, a feeding end and a blanking end are respectively arranged at two ends of the storage space, a partition plate 120 is arranged in the storage space and divides the storage space into a first storage cavity 111 and a second storage cavity 112;

a transition mechanism 200, two ends of which are respectively a receiving end and a discharging end, wherein the receiving end is provided with a receiving rack 210 for receiving the sample container falling from the blanking end, the discharging end is provided with a rotating structure 220 for completely exposing the blank area on the sample container and a discharging plate 230 obliquely arranged, and a driving structure 240 for transporting the sample container on the receiving rack 210 to the rotating structure 220 is arranged between the receiving rack 210 and the rotating structure 220;

and a printing mechanism 300 located above the transition mechanism 200, wherein the printing mechanism 300 comprises a laser head 310, and an emission light source of the laser head 310 corresponds to the position of the rotating structure 220.

The utility model provides a pair of many sample container processing module, cut apart into two through baffle 120 and store the chamber with it, realize depositing of two kinds of different sample containers, thereby improve the nimble utilization to storage tank 110 inner space, and then reduce processing system's manufacturing cost, in addition, discharge mechanism 100, the automatic cooperation between transition mechanism 200 and the printing mechanism 300, reduce the transmission number of times of sample container between inspection personnel and patient, avoid taking place the phenomenon by mistake, and the regular placing in discharge mechanism 100 of sample container, avoid contacting with the external world and taking place the pollution, improve security and the reliability that the sample container deposited.

Preferably, as shown in fig. 1 to 9, in order to improve the working efficiency, a plurality of discharging mechanisms 100, a plurality of transition mechanisms 200, and a plurality of printing mechanisms 300 are provided, and the number of the discharging mechanisms 100, the number of the transition mechanisms 200, and the number of the printing mechanisms 300 are in one-to-one correspondence, a plurality of multi-sample container processing modules are formed, and are divided into two groups, and a conveying mechanism 400 is provided between the two groups of structures, so that the two groups of structures are discharged by the same conveying mechanism 400, and the connection between the two groups of structures is realized, wherein the conveying mechanism 400 includes a conveying belt 410, and guide plates 420 are provided on both sides of the conveying belt 410, and the guide plates 420 are butted with the discharging plates 230.

It is further preferred that a blocking plate 430 is disposed at one end of the conveyor 410 between the two guide plates 420 to ensure reliable output of the sample containers.

Preferably, as shown in fig. 1 to 9, when two feeding ports 113 are disposed at the feeding end and one discharging port is disposed at the blanking end, the two feeding ports 113 are a first feeding port 113 and a second feeding port 113, and the first feeding port 113 and the second feeding port 113 are located at two sides of the storage box 110, wherein the first storage cavity 111 is formed between the first feeding port 113 and the discharging port, and the second storage cavity 112 is formed between the second feeding port 113 and the discharging port. When the feeding end is provided with a feeding hole 113 and the blanking end is provided with two discharging holes, the two discharging holes are respectively a first discharging hole 114 and a second discharging hole 115, and the first discharging hole 114 and the second discharging hole 115 are arranged side by side, wherein the first storage cavity 111 is formed between the feeding hole 113 and the first discharging hole 114, and the second storage cavity 112 is formed between the feeding hole 113 and the second discharging hole 115. When the feeding end is provided with two feeding ports 113 and the blanking end is provided with two discharging ports, the two feeding ports 113 are respectively a first feeding port 113 and a second feeding port 113, and the two discharging ports are respectively a first discharging port 114 and a second discharging port 115, wherein the first storage cavity 111 is formed between the first feeding port 113 and the first discharging port 114, and the second storage cavity 112 is formed between the second feeding port 113 and the second discharging port 115.

Preferably, as shown in fig. 1 to 9, the partition 120 includes a first blocking plate 121 detachably connected to the storage box 110, and a second blocking plate 122 rotatably engaged with the first blocking plate 121, wherein a door panel 130 is movably connected to the feeding hole 113, and a linkage structure is formed between the door panel 130 and the second blocking plate 122 through a connecting rod 140.

In this embodiment, the first baffle 121 and the second baffle 122 are connected by a hinge to form a rotating structure 220 between the first baffle 121 and the second baffle 122, the second baffle 122 is connected with the door 130 by a connecting rod 140 to form linkage, the opening of the door 130 pulls the second baffle 122 to rotate, when the door 130 is in a half-open state, the opening of the first storage cavity 111 near one end of the feed port 113 is reduced, the opening of the second storage cavity 112 near one end of the feed port 113 is enlarged, and at this time, the second storage cavity 112 can be supplemented with corresponding sample containers; when the door 130 is in the fully opened state, the opening degree of the first storage cavity 111 near one end of the feeding hole 113 is maximized, and the second storage cavity 112 near one end of the feeding hole 113 is covered by the second baffle 122 and is closed, so that the corresponding sample container can be replenished into the first storage cavity 111.

In this embodiment, when the first storage chamber 111 and the second storage chamber 112 share one feed inlet 113, the feeding of the first storage chamber 111 and the second storage chamber 112 is realized through the opening of the door 130 and the linkage between the door 130 and the second baffle 122, and the operation is flexible and reliable. In addition, the second baffle 122 strictly controls the first storage cavity 111 and the second storage cavity 112 in the rotating process around the first baffle 121, so that the sample containers are prevented from being crossed, and the accuracy and the reliability of discharging are improved.

Further preferably, a first inclined guiding plate 116 is disposed on the wall of the storage cavity near one end of the inlet 113, and a second inclined guiding plate 123 is disposed on the first baffle 121 near one end of the outlet, so that the sample container can be smoothly discharged from the outlet.

Preferably, as shown in fig. 1 to 9, the door panel 130 is rotatably connected to the feeding hole 113, wherein a driving member 150 (e.g., an air cylinder) is mounted on the storage box 110, and the door panel 130 is driven to rotate by the driving member 150 to change the opening degree of the feeding hole 113.

In this embodiment, the door panel 130 is driven to rotate by the cylinder, so that the door panel 130 is automatically opened and closed, the door panel 130 is prevented from being pushed to rotate automatically due to the increase of the number of the sample containers in the second storage cavity 112, and the storage reliability of the sample containers is ensured.

It is further preferable that the number of the driving members 150 is two, and the two driving members 150 are respectively located at both sides of the door panel 130, wherein one end of the driving member 150 is mounted on the storage box 110, and the other end of the driving member 150 is connected to the door panel 130. By providing two driving members 150, the reliability of the door panel 130 when it is opened or closed is ensured.

Preferably, as shown in fig. 1 to 9, a sealing plate 160 is installed at each side of the door panel 130, wherein the sealing plate 160 is located in the storage space or embedded in the side plates 117 at both sides of the storage case 110.

In this embodiment, the sealing plates 160 are installed on both sides of the door 130, so that the sample container is prevented from falling from the opening and closing position of the door 130 when the material is supplemented into the storage chamber, thereby improving the reliability of the material supplement of the sample container.

Preferably, as shown in fig. 1 to 9, a rotatable drop wheel 170 is mounted at each of the first and second discharge ports 114 and 115, wherein a drop groove 171 is provided on a surface of the drop wheel 170.

In this embodiment, can the shutoff discharge gate through blanking wheel 170 to combine blanking groove 171 on the blanking wheel 170, realize the ejection of compact one by one of sample container, improve the reliability of the ejection of compact, in addition, sample container is embedded in blanking groove 171 when the ejection of compact, guarantees that blanking wheel 170 extrudes sample container in rotatory in-process, guarantees the reliability of sample container ejection of compact.

Preferably, as shown in fig. 1 to 9, the discharging wheel 170 mounted to the first discharging hole 114 is driven by a first rotating motor 180, and the discharging wheel 170 mounted to the second discharging hole 115 is driven by a second rotating motor 190.

Preferably, as shown in fig. 1 to 9, the material receiving frame 210 is provided with a fixed material receiving plate 211 and a movable material receiving plate 212, and guide inclined surfaces, namely a first guide inclined surface 2111 and a second guide inclined surface 2121, are respectively provided at opposite sides of the fixed material receiving plate 211 and the movable material receiving plate 212, wherein a material discharging channel and a material receiving groove are formed by opening and closing between the first guide inclined surface 2111 and the second guide inclined surface 2121.

In this embodiment, in an initial state, the fixed material receiving plate 211 and the movable material receiving plate 212 are in a combined state, at this time, the first guiding inclined surface 2111 and the second guiding inclined surface 2121 are spliced to form a material receiving slot, and the material receiving slot is located below the material receiving end, at this time, a sample container falling from the material receiving end can be received, then the sample container in the material receiving slot is conveyed to the upper side of the rotating structure 220 through the driving structure 240, then the movable material receiving plate 212 moves in a direction away from the fixed material receiving plate 211, so as to expand a relative distance between the movable material receiving plate 212 and the fixed material receiving plate 211, at this time, the first guiding inclined surface 2111 and the second guiding inclined surface 2121 are separated to form a material falling channel, so that the sample container falls onto the rotating structure 220, and finally the rotating structure 220 drives the sample container to rotate, so that a blank area on the sample container is in a completely exposed state, so that the printing mechanism 300 can completely print the patient information into the blank area of the sample container, the printing quality is improved, and the working efficiency of subsequent medical staff in scanning and registering the sample container is improved.

Further preferably, the discharge end is provided with a blocking arm 250, and the blocking arm 250 is located on the moving track of the material receiving frame 210, wherein the movable material receiving plate 212 and the fixed material receiving plate 211 are separated by the abutting fit between the blocking arm 250 and the movable material receiving plate 212.

Preferably, as shown in fig. 1 to 9, the fixed material receiving plate 211 and the movable material receiving plate 212 are magnetically engaged with each other.

Further preferably, the two ends of the fixed material receiving plate 211 are respectively connected with a magnetic block 213, the two ends of the movable material receiving plate 212 are respectively connected with a top rod 214, wherein one end of the top rod 214 penetrates through the fixed material receiving plate 211 and the magnetic block 213 and is connected to the movable material receiving plate 212, and the other end of the top rod 214 is provided with a convex portion 2141.

In this embodiment, the fixed flitch 211 that connects and the activity connect through magnetism between the flitch 212 to inhale the cooperation, conveniently change the fixed flitch 211 that connects and the activity connects the relative distance between the flitch 212, make connect the sample container in the silo can fall into on the revolution mechanic 220 of below reliably, in addition, through the convex part 2141 on the ejector pin 214, realize the cooperation of joint between ejector pin 214 and the fixed flitch 211 that connects, thereby control the fixed flitch 211 that connects and the activity connects the separation distance between the flitch 212, and then avoid the fixed flitch 211 that connects of ejector pin 214 roll-off, improve and connect the reliability that the work or material rest 210 used.

Further preferably, the ejector rod 214 is in threaded fit with the movable material receiving plate 212.

In this embodiment, the ejector rod 214 is rotated through the screw connection, and the distance of the movable material receiving plate 212 when being far away from the fixed material receiving plate 211 is adjusted, so as to adapt to the discharge of sample containers with different sizes, and ensure that the sample containers in the material receiving groove can reliably fall into the rotating structure 220 below when the movable material receiving plate 212 is far away from the fixed material receiving plate 211.

Preferably, as shown in fig. 1 to 9, the driving structure 240 includes a transmission motor 241, and an output end of the transmission motor 241 is connected with a screw 242, wherein the receiving rack 210 is screwed on the screw 242.

Preferably, as shown in fig. 1 to 9, the rotating structure 220 includes a rotating bracket 221, and a third rotating motor 222 is mounted on the rotating bracket 221, wherein an output end of the third rotating motor 222 is connected with a main rotating shaft 223, and two auxiliary rotating shafts 224 attached to the main rotating shaft 223 and connected to the rotating bracket 221, and a structure of a shape like a Chinese character 'pin' is formed between the main rotating shaft 223 and the two auxiliary rotating shafts 224, wherein the two auxiliary rotating shafts 224 are rotated by the rotation of the main rotating shaft 223, so that the sample container located between the two auxiliary rotating shafts 224 is rotated, a blank area on the sample container is completely exposed, and the printing mechanism 300 is convenient to print the patient information on the blank area.

Further preferably, an annular magnetic ring 225 is nested on the main rotating shaft 223, or an annular magnetic ring 225 is nested on the auxiliary rotating shaft 224, or an annular magnetic ring 225 is nested on both the main rotating shaft 223 and the auxiliary rotating shaft 224.

In this embodiment, the annular magnetic ring 225 is embedded in the main rotating shaft 223 or the auxiliary rotating shaft 224, so that the idle stroke generated when the main rotating shaft 223 drives the auxiliary rotating shaft 224 to rotate is avoided, and the reliability of the autorotation of the sample container is improved.

As shown in fig. 1 to 9, a pushing structure 260 is connected to the material receiving frame 210, and the pushing structure 260 is located between the material receiving slot and the blocking arm 250, wherein the pushing structure 260 separates a relative distance between the two auxiliary rotating shafts 224, so as to realize automatic discharging of the printed sample container.

In this embodiment, through pushing up structure 260, realize being located the ejection of compact of the sample container that has accomplished the printing on revolution mechanic 220, through connect the silo and keep off the cooperation of leaning on between the arm 250, realize connecing the sample container that the silo was gone up not to print and fall into revolution mechanic 220 on, form continuous action, improve the work efficiency that the sample container printed.

Further preferably, the pushing structure 260 includes a U-shaped pushing support 261, and two pushing blocks 262 are connected to two sides of an open end of the U-shaped pushing support 261, wherein the two pushing blocks 262 are respectively in abutting engagement with two ends of one of the auxiliary rotating shafts 224.

Further preferably, two sides of the rotating bracket 221 are respectively provided with a first guide slot 2211, and two ends of one of the auxiliary rotating shafts 224 are respectively clamped in the first guide slots 2211.

In this embodiment, by providing the first guide groove 2211 on the rotating bracket 221, when the top block 262 pushes the auxiliary rotating shaft 224, two ends of the auxiliary rotating shaft 224 can move along the first guide groove 2211, so as to ensure the straightness of the movement of the auxiliary rotating shaft 224, and further, the smooth discharging of the printed sample container is realized.

Preferably, as shown in fig. 1 to 9, two ends of the ejector block 262 are respectively connected to the U-shaped pushing support 261 through corresponding rotating rods 263, and the rotating rod 263 on the side of the U-shaped pushing support 261 far away from the material receiving slot is connected to the second guide slot 2611 on the U-shaped pushing support 261 in a clamping manner, wherein one end of the rotating rod 263 connected to the second guide slot 2611 in a clamping manner is connected to the fixing rod 265 on the U-shaped pushing support 261 through an elastic member 264, and the ejector block 262 is provided with a first working inclined surface 2621 and a second working inclined surface 2622, a slope of the first working inclined surface 2621 extends obliquely upward from one end far away from the material receiving slot to one end near the material receiving slot, a slope of the second working inclined surface 2622 extends obliquely upward from one end near the material receiving slot to one end far away from the material receiving slot, and a slope of the first working inclined surface 2621 is smaller than a slope of the second working inclined surface 2622.

In this embodiment, when the pushing structure 260 approaches the rotating structure 220, the first working inclined surface 2621 is in rolling fit with the end of the auxiliary rotating shaft 224, and as the slope on the first working inclined surface 2621 increases progressively, the auxiliary rotating shaft 224 is pushed to move along the first guide groove 2211, and the auxiliary rotating shaft 224 generates downward pressure on the top block 262, so as to drive the rotating rod 263 clamped on the second guide groove 2611 to move along the second guide groove 2611, so that the top block 262 deflects, when the auxiliary rotating shaft 224 crosses from the first working inclined surface 2621 to the second working inclined surface 2622, because the slope of the second working inclined surface 2622 is greater than the slope of the first working inclined surface 2621, the rolling connection between the auxiliary rotating shaft 224 and the first working inclined surface 2621 is released, and the auxiliary rotating shaft 224 falls back, and the discharge of the sample container is completed at this time.

The utility model provides a working principle of a multi-sample container processing module, under the initial condition, the unprinted sample container is installed in the storage cavity, when the user inputs the patient information such as medical insurance card or visit card, the blanking wheel 170 rotates under the effect of the rotating electrical machines, the unprinted sample container in the corresponding storage cavity falls into the blanking groove 171 of the blanking wheel 170, along with the rotation of the blanking wheel 170, the unprinted sample container breaks away from the blanking groove 171 and enters the receiving groove below, then the transmission electrical machines 241 drives the screw rod 242 to rotate, so that the receiving frame 210 moves towards the discharging end until the baffle arm 250 contacts with the ejector rod 214, along with the continuous movement of the receiving frame 210, the relative distance between the movable receiving plate 212 and the fixed receiving plate 211 is enlarged, when the distance between the movable receiving plate 212 and the fixed receiving plate 211 is greater than the size of the unprinted sample container, the unprinted sample container falls into between two auxiliary rotating shafts 224, then the third rotating electrical machines 222 drives the main rotating shaft 223 to rotate, thereby realizing the rotation of the two auxiliary rotating shafts 224, and further realizing the rotation of the unprinted sample containers, so that the blank areas on the unprinted sample containers are in a completely exposed state, finally, the patient information is printed on the blank areas through the printing mechanism 300, and the patient information is moved to the discharging end through the material receiving frame 210 again, when the top block 262 abuts against the auxiliary rotating shafts 224, the auxiliary rotating shafts 224 are pushed to move along the first guide grooves 2211, the relative distance between the two auxiliary rotating shafts 224 is pulled apart, and the sample containers which have finished printing are output from the discharging plate 230.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein may be made by those skilled in the art without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims (10)

1. A multiple sample container processing module, comprising:

the discharging mechanism comprises a storage box, a feeding end and a discharging end are arranged at two ends of the storage space respectively, and a partition plate is arranged in the storage space and divides the storage space into a first storage cavity and a second storage cavity;

the transition mechanism is provided with a receiving end and a discharging end at two ends respectively, wherein the receiving end is provided with a receiving frame for receiving a sample container falling from the blanking end, the discharging end is provided with a rotating structure for completely exposing a blank area on the sample container and an obliquely arranged discharging plate, and a driving structure for transporting the sample container on the receiving frame to the rotating structure is arranged between the receiving frame and the rotating structure;

and the printing mechanism is positioned above the transition mechanism, wherein the printing mechanism comprises a laser head, and an emission light source of the laser head corresponds to the position of the rotating structure.

2. The multiple-sample container processing module according to claim 1, wherein the feeding end is provided with a single feeding port or two feeding ports, wherein when the number of the feeding ports is two, the two feeding ports are respectively located at two sides of the storage box and respectively correspondingly communicated with the first storage chamber and the second storage chamber; the discharge end is provided with single discharge gate or sets up two discharge gates, and wherein, when the quantity of discharge gate is two, two discharge gates set up side by side to correspond the intercommunication with first storage chamber and second storage chamber respectively.

3. The multiple sample container processing module of claim 1, wherein the discharge port is provided with a rotatable drop wheel, wherein a surface of the drop wheel is provided with a chute that is recessed along the surface of the drop wheel toward a center of the drop wheel.

4. The multiple-sample container processing module according to claim 1, wherein the partition comprises a first baffle detachably connected to the storage box and a second baffle rotatably engaged with the first baffle, wherein a door is movably connected to the feeding port, and a linkage structure is formed between the door and the second baffle through a connecting rod.

5. The multi-sample container processing module according to claim 1, wherein the receiving frame is provided with a fixed receiving plate and a movable receiving plate, and guide slopes, which are a first guide slope and a second guide slope, are respectively provided at opposite sides of the fixed receiving plate and the movable receiving plate, wherein the blanking channel and the receiving groove are formed by opening and closing between the first guide slope and the second guide slope.

6. The multi-sample container processing module according to claim 5, wherein the discharge end is provided with a blocking arm, and the blocking arm is located on a moving track of the material receiving frame, wherein the first guide slope and the second guide slope are opened and closed by abutting and separating the blocking arm and the movable material receiving plate.

7. The multiple-specimen-container processing module of claim 5, wherein the fixed material-receiving plate and the movable material-receiving plate are magnetically coupled, wherein the fixed material-receiving plate is coupled with a magnetic block, and the movable material-receiving plate is coupled with a push rod, the push rod penetrating through the fixed material-receiving plate and the magnetic block and being screwed to the movable material-receiving plate.

8. The multiple sample container processing module of claim 6, wherein a pushing structure is connected to the receiving rack and located between the receiving trough and the stop arm, wherein the relative distance between the two auxiliary rotational axes is separated by the pushing structure.

9. The multiple-sample-container processing module of claim 8, wherein the pushing structure comprises a pushing support, and a top block is connected to the pushing support, wherein the top block is provided with a first working slope and a second working slope, and the first working slope and the second working slope are two adjacent slopes on the top block.

10. A multiple sample container processing system comprising a plurality of multiple sample container processing modules according to any one of claims 1 to 9, wherein said plurality of multiple sample container processing modules are divided into two groups, and wherein a transport mechanism is provided between said two groups of multiple sample container processing modules.

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