JP7181364B2 - Chemical sorting equipment - Google Patents

Description

The present invention relates to a medicine sorting device for sorting returned medicines, for example.

In order to improve the efficiency of hospital operations, a drug payment device that automatically pays drugs has been put into practical use and is attracting attention.
That is, dispensing medicines based on a prescription into a tray for each patient improves the efficiency of complicated medicine payment operations and reduces medicine payment errors (for example, Patent Document 1 below).

JP 2007-209599 A

As mentioned above, with the practical use of the drug payment system, the efficiency of drug payment operations has been greatly improved. may be returned without being used.
The return of such medicines is a daily occurrence in large hospitals, and the types and amounts of returned medicines are extremely large, and the sorting work after collection is an extremely difficult task.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a chemical sorting apparatus capable of efficiently sorting collected chemicals.

In order to achieve this object, the medicine sorting apparatus of the present invention includes a sorting tray in which a plurality of returned unused drugs are stored in a non-aligned state, and image data representing the states of the plurality of drugs in the sorting tray. an identification camera for acquisition, a first transport unit for taking out the medicine from the sorting tray based on the image data acquired by the identification camera, and a mount for laying the medicine taken out by the first transport unit on its side and rotating it. a detector that detects information about the medicine on the detector; a controller that determines a storage container for storing the medicine based on the information detected by the detector; and a second transport unit for transporting the medicine to the storage container. The control unit is connected via a network to an external database that stores information such as the type of medicine.

This achieves the intended purpose.

As described above, according to the present invention, collected chemicals can be efficiently sorted.
That is, in the present invention, it is possible to exchange various data such as information on types of drugs with the outside of the drug sorting apparatus. Collected chemicals can be efficiently sorted based on the detected information and external data.

BRIEF DESCRIPTION OF THE DRAWINGS The perspective view of the medicine sorting apparatus which concerns on Embodiment 1 of this invention A configuration block diagram of the entire medicine sorting device of the ii-ii cross section in FIG. 1 is a perspective view of a sorting tray according to Embodiment 1 of the present invention; FIG. FIG. 1 is a front view showing a drug (one example) according to Embodiment 1 of the present invention; FIG. 1 is a perspective view of a main part of a first conveying unit of a medicine sorting apparatus according to Embodiment 1 of the present invention; FIG. 1 is a perspective view of a main part of a first conveying unit of a medicine sorting apparatus according to Embodiment 1 of the present invention; FIG. 1 is a perspective view of a principal part of a vibrating section and a sorting tray of a medicine sorting apparatus according to Embodiment 1 of the present invention; A perspective view of a sorting tray and a frame of a medicine sorting apparatus according to Embodiment 1 of the present invention. The top view of the frame of the medicine sorting apparatus according to Embodiment 1 of the present invention A diagram showing an example of a cross-sectional view of the sorting tray on the XX plane of FIG. The perspective view of the discrimination|determination part of the medicine sorting apparatus which concerns on Embodiment 1 of this invention Main part top view of the discrimination part in FIG. FIG. 2 is a perspective view of a main part for explaining the relationship between the rotating part of the medicine sorting apparatus according to Embodiment 1 of the present invention and the configuration of the second conveying part; FIG. 13 is a cross-sectional view of essential parts for explaining the relationship between the configuration of the rotating part and the second conveying part in the XiV-XiV cross section of FIG. FIG. 2 is a perspective view of a main part of the second conveying unit of the medicine sorting apparatus according to Embodiment 1 of the present invention; FIG. 2 is a perspective view of a main part of the second conveying unit of the medicine sorting apparatus according to Embodiment 1 of the present invention; The front view of the storage box installation part of the medicine sorting apparatus according to Embodiment 1 of the present invention Cross-sectional view of essential parts of the take-out head and the storage box for explaining the operation of the conveying unit of the medicine sorting device of the XViii-XViii cross section of FIG. Cross-sectional view of essential parts of the take-out head and the storage box for explaining the operation of the conveying unit of the medicine sorting device of the XViii-XViii cross section of FIG. Cross-sectional view of essential parts of the take-out head and the storage box for explaining the operation of the conveying unit of the medicine sorting device of the XViii-XViii cross section of FIG. Cross-sectional view of essential parts of the take-out head and the storage box for explaining the operation of the conveying unit of the medicine sorting device of the XViii-XViii cross section of FIG. Cross-sectional view of essential parts of the take-out head and the storage box for explaining the operation of the conveying unit of the medicine sorting device of the XViii-XViii cross section of FIG. Cross-sectional view of essential parts of the take-out head and the storage box for explaining the operation of the conveying unit of the medicine sorting device of the XViii-XViii cross section of FIG. Cross-sectional view of essential parts of the take-out head and the storage box for explaining the operation of the conveying unit of the medicine sorting device of the XViii-XViii cross section of FIG. Cross-sectional view of essential parts of the take-out head and the storage box for explaining the operation of the conveying unit of the medicine sorting device of the XViii-XViii cross section of FIG. Cross-sectional view of essential parts of the take-out head and the storage box for explaining the operation of the conveying unit of the medicine sorting device of the XViii-XViii cross section of FIG. Cross-sectional view of essential parts of the take-out head and the storage box for explaining the operation of the conveying unit of the medicine sorting device of the XViii-XViii cross section of FIG. A perspective view of a display unit of a medicine sorting apparatus according to Embodiment 1 of the present invention. 1 shows a schematic diagram for explaining the operation of a display section in a storage box installation section of a medicine sorting apparatus according to Embodiment 1 of the present invention, FIG. 15 XViii-XViii cross section of the device, a cross-sectional view of the essential parts of the take-out head, the storage box, and the storage box installation part, (b) is an enlarged front view within the dotted line F in FIG. 1 shows a schematic diagram for explaining the operation of a display section in a storage box installation section of a medicine sorting apparatus according to Embodiment 1 of the present invention, FIG. 15 XViii-XViii cross section of the device, a cross-sectional view of the essential parts of the take-out head, the storage box, and the storage box installation part, (b) is an enlarged front view within the dotted line F in FIG. 1 shows a schematic diagram for explaining the operation of a display section in a storage box installation section of a medicine sorting apparatus according to Embodiment 1 of the present invention, FIG. 15 XViii-XViii cross section of the device, a cross-sectional view of the essential parts of the take-out head, the storage box, and the storage box installation part, (b) is an enlarged front view within the dotted line F in FIG. Flowchart of overall operation of the medicine sorting apparatus according to Embodiment 1 of the present invention Flowchart of detailed operation in the first movement step S200 shown in FIG. Flowchart of detailed operations in the drug identification step S300 shown in FIG.

(Embodiment 1)
Embodiment 1 of the present invention will be described in detail below with reference to the drawings.
[1] Configuration of the medicine sorting apparatus according to the present embodiment [1]-(1) Overall configuration of the medicine sorting apparatus 1 First, the overall configuration of the medicine sorting apparatus will be described.

FIG. 1 shows a perspective view of a medicine sorting apparatus according to Embodiment 1 of the present invention.
Also, FIG. 2 shows a block diagram of the entire configuration of the medicine sorting apparatus of the ii-ii cross section of FIG.
3 shows a perspective view of a sorting tray according to Embodiment 1 of the present invention, and FIG. 4 shows a front view showing drugs (one example) according to Embodiment 1 of the present invention.

As shown in FIG. 2, the medicine sorting apparatus 1 in this embodiment includes a sorting tray installation section 8 in which a plurality of sorting trays 7 (an example is shown in FIG. 3) are installed, and the sorting tray installation section 8. is provided with a transport section 12 (an example of a first transport section) for taking out the chemicals 9 to 11 (an example is shown in FIG. 4) from the sorting tray 7 installed in the sorting tray installation section 8 .
In addition, as shown in FIG. 2, the medicine sorting apparatus 1 according to the present embodiment is transported by the transport section 12 to the side of the sorting tray installation section 8 (the left side of the sorting tray installation section 8 in FIG. 2). A discriminating unit 13 is provided for discriminating the size, type, etc. of the chemicals 9 to 11 that have been used.

Furthermore, the medicine sorting apparatus 1 in this embodiment is provided with a storage box 62 for storing the drugs 9 to 11 and a storage box installation section 15 for installing a plurality of storage boxes 62 in the storage case 6 .
In addition, the medicine sorting apparatus 1 in the present embodiment has a conveying part 14 (second conveying part example) is provided.

Furthermore, the medicine sorting apparatus 1 in this embodiment is provided with a control section 16 that controls the conveying section 12, the determining section 13, the conveying section 14, and the like. The control unit 16 is connected to the database 4 outside the medicine sorting apparatus using a network.
As described above, the medicine sorting apparatus 1 according to the present embodiment can be roughly divided into the sorting tray setting unit 15, the transport unit 12 (first transport unit), the determination unit 13, and the transport unit 14 (second transport unit). (an example of a transport section), a storage box installation section 15, and a control section 16.

[1]-(2) Structure of chemicals 9 to 11 and sorting tray 7 Next, the chemicals 9 to 11 and sorting tray 7 in this embodiment will be described.
In the present embodiment, as shown in FIG. 3, unused medicines collected from hospital rooms are put in the sorting tray 7 in a state in which the orientations thereof are random (non-aligned state). That is, inside the sorting tray 7 in the present embodiment, various kinds of chemicals 9 to 11 of different types, sizes, container shapes, etc. are oriented in random directions (not aligned in one direction). stored in a neat shape.

As shown in FIGS. 4(a) to 4(c), the medicines 9 to 11 in this embodiment have an identification code 18 (an example of a first identification code) indicating their respective types and an identification code indicating their expiration date ( An example of a second identification code (not shown) is attached. Furthermore, in this embodiment, the external shapes of the chemicals 9 to 11 are greatly different from each other.
As described above, the medicine sorting apparatus 1 according to the present embodiment allows the medicines 9 to 11 of various types (types of medicines, sizes, shapes of containers, etc.) to be arranged in random directions (one direction). The chemicals 9 to 11 stored in a form facing the container) are taken out from the sorting tray 7, and the taken out chemicals 9 to 11 are sorted by their types (for example, the kind of medicine, the size, the shape of the container, etc.). ) is a separate sorting device.

[1]-(3) Configuration of Sorting Tray Setting Section 8 Next, the configuration of the sorting tray setting section 8 in this embodiment will be described with reference to FIG.
A plurality of sorting trays 7 are stacked vertically and stored in the sorting tray setting section 8 in this embodiment.

A lifting mechanism 17 is provided in the sorting tray installation section 8 in this embodiment. The lifting mechanism 17 is configured so that the control unit 16 can lift the uppermost sorting tray 7 of the vertically stacked sorting trays 7 above the sorting tray setting unit 8 .
Further, the sorting tray installation section 8 in this embodiment is provided with a vibrating section 21 . The vibrating section 21 is configured so that the control section 16 can vibrate the sorting tray 7 in the horizontal direction.

[1]-(4) Configuration of Transport Unit 12 Next, the configuration of the transport unit 12 in this embodiment will be described with reference to FIG.
An identification camera 19 is provided in the transport section 12 in this embodiment. This identification camera 19 can acquire the state of the medicines (for example, 9 to 11) in the sorting tray 7 located at the top of the sorting tray setting section 8 as image data by the control section 16. ing.

The conveying unit 12 in this embodiment includes a plurality of nozzles 20 (an example of a first holding unit) inside a picking head 64 (an example of a first picking head). The control unit 16 determines the drugs 9 to 11 to be taken out from the sorting tray 7 based on the image data acquired by the identification camera 19, and based on the shapes of the drugs 9 to 11 determined based on the image data, selects a plurality of drugs. The nozzles 20 holding the chemicals 9 to 11 can be determined from among the nozzles 20 of .

After that, the control unit 16 in this embodiment can adsorb the determined chemicals 9 to 11 with the nozzles 20 holding the determined chemicals 9 to 11, and convey them from inside the sorting tray 7 onto the determination unit 13. It is possible.

[1]-(5) Configuration of Determination Unit 13 Next, the configuration of the determination unit 13 in this embodiment will be described with reference to FIG.
The discriminating portion 13 in the present embodiment includes a rotary portion 25 having a valley portion 24 (a valley portion 24 inclined upward from the approximate center portion toward the outside) formed in a substantially central portion, and A detection unit 26 (for example, an optical sensor) that detects the sizes of the chemicals 9 to 11 transported onto the trough 24 of the rotation unit 25, and a detection unit 27 (second , such as a bar code reader), and a detection unit 28 (an example of a third detection unit, such as a camera) for detecting expiration dates of the chemicals 9-11.

The control unit 16 can control the rotation of the rotating unit 25 to rotate the chemicals 9 to 11 transported onto the valley portion 24 of the rotating unit 25 .
Further, the control unit 16 controls each of the detection unit 26, the detection unit 27, and the detection unit 28, and detects the sizes of the chemicals 9 to 11, the types of the chemicals 9 to 11, the expiration dates of the chemicals 9 to 11, and the like. configured to allow

[1]-(6) Configuration of Conveying Unit 14 Next, the configuration of the conveying unit 14 in this embodiment will be described with reference to FIG.
The conveying unit 14 in this embodiment includes a take-out head 55 including a holding portion 47 (an example of a second holding portion), a drawer portion 58 (an example of a suction nozzle), and expands and contracts the holding portion 47 toward the storage box 62 side. A drive unit 59 is provided. The holding portion 47 can hold the chemicals 9 to 11 on the discrimination portion 13 and take them out from the discrimination portion 13 by the control portion 16 .

The drawer 58 draws out the storage box 62 stored in the storage case 6 of the storage case installation section 15 to the rear of the storage box installation section 15 (in the direction of arrow A in FIG. 1) by the control section 16. is now possible.
Therefore, the control unit 16 in this embodiment pulls out the storage box 62 from the storage case 6 of the storage case installation unit 15 to the rear of the storage box installation unit 15 by the drawer unit 58 .

After that, the control unit 16 holds the drugs 9 to 11 on the discrimination unit 13 in the holding unit 47, takes them out from the discrimination unit 13, and then moves the take-out head 55 so that they are taken out by the holding unit 47. The chemicals 9 to 11 are conveyed (moved) into the storage box 62 . Furthermore, after that, the control section 16 controls the drawer section 58 to pull the storage box 62 back into the storage case 6 of the storage case installation section 15 .
As described above, the control unit 16 can transport the chemicals 9 to 11 on the discriminating unit 13 into the storage box 62 .

[1]-(7) Configuration of Storage Box Setting Unit 15 As already described, as shown in FIGS. 11 can be installed.

[1]-(8) Configuration of Control Unit 16 Next, the configuration of the control unit 16 in this embodiment will be described with reference to FIG.
The control unit 16 includes a memory storing a control program for performing each operation of the transport unit 12, the determination unit 13, and the transport unit 14. The control unit 16 controls each operation. By executing a program, the operation of the entire medicine sorting apparatus 1 can be controlled.

In addition, the control unit 16 is connected to the database 4 outside the drug sorting apparatus 1 using a network, and exchanges various data such as information on the types of drugs 9 to 11 with the outside of the drug sorting apparatus 1. configured to be able to
Furthermore, as shown in FIG. 2, the control unit 16 is connected to a display 63 so that the control state of the control unit 16, such as the operating state currently being executed, can be displayed on the display 63. It consists of
Now, the detailed configuration of the essential parts in this embodiment will be described below.

[1]-(9) Detailed Configurations of Transport Unit 12, Vibration Unit 21, and Frame 22 of Medicine Sorting Apparatus Next, details of the configuration of the transport unit 12, vibration unit 21, and frame 22 of the medicine sorting apparatus explain.
5 and 6 are perspective views of essential parts of the first conveying section of the medicine sorting apparatus according to Embodiment 1 of the present invention.

Moreover, FIG. 7 shows a perspective view of the essential parts of the vibrating section and the sorting tray of the medicine sorting apparatus according to Embodiment 1 of the present invention.
Moreover, FIG. 8 shows a perspective view of a sorting tray and a frame of the medicine sorting apparatus according to Embodiment 1 of the present invention.
Moreover, FIG. 9 shows the top view of the frame of the medicine sorting apparatus according to Embodiment 1 of the present invention.

10 is a diagram showing an example of a cross-sectional view of the sorting tray taken along the line XX in FIG. Here, in order to make the explanation easier to understand, the arrangement of chemicals 9 to 11 in FIG. 10 is different from the arrangement of chemicals 9 to 11 in FIG. 3, and only one medicine 9 to 11 is shown.
As shown in FIG. 3, the sorting tray 7 in the present embodiment contains the chemicals 9 to 11 in a state in which the directions thereof are random (non-aligned state). As shown in FIG. 2, the sorting trays 7 are stacked vertically in the sorting tray setting section 8 and held.

Then, as shown in FIG. 2 , the uppermost sorting tray 7 among the vertically stacked sorting trays 7 is lifted by the lifting mechanism 17 .
In that state, as shown in FIG. 2, the control unit 16 controls the identification camera 19 in the transport unit 12, and the state of the chemicals 9 to 11 in the sorting tray 7 lifted by the lifting mechanism 17 is Acquire as image data.

After that, as shown in FIGS. 2 and 6, the control unit 16 determines the nozzles 20 (an example of the first holding unit) in the take-out head 64 based on the image data that can be recognized. . Here, the nozzles 20 in this embodiment are prepared in three sizes of large, medium and small (see FIG. 2). For example, when the medicine 9 with a large diameter can be recognized, the nozzle 20 that adsorbs the medicine 9 with a large diameter is selected and determined. When the medium-diameter medicine 11 is recognized, the nozzle 20 for sucking the medium-diameter medicine 11 is selected and determined. When the medicine 10 with a small diameter can be recognized, the nozzle 20 for sucking the medicine 10 with a small diameter is selected and determined. That is, the control unit 16 acquires image data of the medicines placed in the sorting tray from the upper part of the sorting tray 7 by the identification camera 20, and then determines the medicines 9 to 11 to be taken out based on the image data. After that, the nozzle 20 is determined based on the sizes of the chemicals 9 to 11 determined based on the image data.

Furthermore, after that, the control unit 16 controls the determined nozzles 20 to adsorb the chemicals 9 to 11 with the nozzles 20, and moves the take-out head 64 in this state to determine the chemicals 9 to 11. 13 to the top.
Here, the identification camera 19 may not be able to identify the chemicals 9 to 11 in the sorting tray 7 as chemicals due to the plurality of chemicals 9 to 11 coming into contact with each other.

In such a case, as shown in FIGS. 2 and 7, the control unit 16 controls the vibrating unit 21 provided in the lifting mechanism 17 of the sorting tray installation unit 8 to move the vibrating unit 21 to the sorting tray 7. is fixed, and in that state, the sorting tray 7 is vibrated in the horizontal direction (the direction of C in FIG. 7), thereby relaxing the contact state of the chemicals 9 to 11, and then the control unit 16 controls the identification camera 19 again to perform the image recognition described above so that it can be recognized as a drug.

That is, the control unit 16 acquires image data of the chemicals 9 to 11 placed in the sorting tray 7 from the upper part of the sorting tray 7 by the identification camera 19, and then takes out the chemicals 9 to 11 based on this image data. 11 could not be determined, the control unit 16 causes the vibrating unit 21 to vibrate the sorting tray 7 in the horizontal direction. Therefore, by applying vibration in this way, the degree of overlapping of the chemicals 9 to 11 can be relaxed. 11) can be determined.

Further, when recognizing the chemicals 9 to 11 as described above, the control unit 16 uses the image data to determine the longitudinal direction of the chemicals 9 to 11 in the sorting tray 7 and the orientation of the chemicals 9 to 11 when unloaded onto the discrimination unit 13 . The amount of offset from the longitudinal direction of 9-11 is detected.
After that, after the chemicals 9 to 11 are adsorbed by the nozzle 20, the control unit 16 rotates (corrects) the nozzle 20 in the adsorption rotation direction by the detected offset amount. The adsorbed chemicals 9 to 11 are transported onto the discriminating section 13 shown in FIGS.

Moreover, in order to increase the recognition rate of the chemicals 9 to 11 by the identification camera 19, it is preferable that the chemicals 9 to 11 do not come into contact with the inner wall surface of the sorting tray 7. FIG.
For example, in this embodiment, the frame 22 shown in FIG. 9 is arranged inside the sorting tray 7 (see FIGS. 7 and 10).
That is, since the frame 22 has a sloped surface 23 that slopes from top to bottom from the outer periphery to the inner periphery, the chemicals 9 to 11 do not come into contact with the inner peripheral surface of the sorting tray 7. 19 can increase the recognition rate of drugs 9-11.

[1]-(10) Detailed Configuration of Discriminating Unit 13 of Medicine Sorting Apparatus Next, the configuration of the discriminating unit 13 of the drug sorting apparatus will be described in detail.
FIG. 11 shows a perspective view of the discrimination section of the medicine sorting apparatus according to Embodiment 1 of the present invention.
Moreover, FIG. 12 shows a top view of the principal part of the discriminating portion in FIG.

As shown in FIG. 11, the discriminating portion 13 in the present embodiment has a rotating portion in which a trough portion 24 (a state in which a trough portion 24 is inclined upward from the approximate center portion toward the outside) is formed in the approximate center portion. a detection unit 26 for detecting the size of the chemicals 9 to 11 transported to the valley 24 of the rotation unit 25; a detection unit 27 for detecting the types of the chemicals 9 to 11 to be rotated; and a detection unit 28 for detecting expiration dates of 1 to 11.

Here, as shown in FIG. 12, the rotating part 25 of the discriminating part 13 in this embodiment includes two rotating bodies 29 (an example of a first rotating body) and a rotating body 30 (an example of a second rotating body). is formed by
More specifically, as shown in FIG. 12, the rotating body 29 in this embodiment includes a roller 31 (an example of a first roller), a roller 32 (an example of a second roller), It is composed of a plurality of belts 33 (an example of a first belt) bridged by rollers 31 and 32 .

Furthermore, as shown in FIG. 12, the rotating body 30 in this embodiment is bridged by a roller 35 (an example of a third roller), a roller 36 (an example of a fourth roller), and rollers 35 and 36. It is composed of a plurality of belts 37 (an example of a second belt). In addition, the belt 33 of the rotating body 29 is provided with a chemical contact surface 38 (an example of a first chemical contact surface) that contacts the chemicals 9-11.

Furthermore, the belt 37 of the rotation 30 is provided with a drug contact surface 39 (an example of a second drug contact surface) that contacts the drugs 9-11.
Here, the valley portion 24 of the rotating portion 25 in this embodiment is formed from one end 40 of the chemical contact surface 38 and one end 41 of the chemical contact surface 39, and the one end 40 of the chemical contact surface 38 and the chemical contact surface 38 are formed. One end 41 of the surface 39 forms an obtuse angle (less than 180 degrees) on the side that contacts the chemicals 9 to 11 .

With this configuration, in the discriminating portion 13 of the present embodiment, the chemicals 9 to 11 transported to the vicinity of the valley portion 24 of the rotating portion 25 by the nozzle 20 of the transporting portion 12 are transferred to the chemical contact surface 38 or the chemical It can be moved to valley 24 via contact surface 39 .
Further, the discriminating section 13 of the present embodiment includes an arrangement section 42 for arranging the chemicals 9 to 11 moved to the trough 24 at the rotation starting position of the trough 24 . More specifically, the arrangement portion 42 includes a reference plate 44 (see FIGS. 11 and 12) having a reference surface 43 (see FIGS. 11 and 12) that serves as a reference for detecting the sizes of the chemicals 9-11. , a position regulating plate 45 (see FIG. 11) for arranging the chemicals 9 to 11 so that the reference parts of the chemicals 9 to 11 are in contact with the reference surface 43, and a position regulating plate driving section for driving the position regulating plate 45. 46 (see FIG. 11).

Here, an air cylinder using air as a driving source is used for the position regulating plate driving portion 46 .
Next, a method for detecting the sizes of chemicals 9 to 11 will be described.
After the chemicals 9 to 11 are moved to the trough portion 24 by the nozzle 20 of the conveying portion 12, the control portion 16 drives the position regulating plate driving portion 46 to move the position regulating plate 45 (in this embodiment, 11, in the direction of D in FIG. 12), the chemicals 9 to 11 are placed so that the portion serving as the reference for detecting the size of the chemicals 9 to 11 is in contact with the reference plane 43 .

In this state, the size of the chemicals 9 to 11 can be detected by detecting the portion (E in FIG. 12) opposite to the reference portion of the chemicals 9 to 11 by the detection unit 26. .
Next, the relationship between the configuration of the rotating section 25 and the conveying section 14 in this embodiment will be described.

In this embodiment, after the determination unit 13 detects the size, type, and expiration date of the drugs 9 to 11, the control unit 16 detects the storage box 62 in the storage box installation unit 15 that stores the drugs 9 to 11. to decide. Furthermore, after that, the control unit 16 controls the transport unit 14 to transport the chemicals 9 to 11 above the valley part 24 of the discrimination unit 13 to the storage box 62 in the storage box installation unit 15 by the transport unit 14. .

Here, as shown in FIG. 13, the holding portion 47 (an example of a second holding portion) of the conveying portion 14 includes a plurality of holding claws 48 and 49 (an example of a first holding claw and a second holding claw, respectively). ) by which the drugs 9-11 can be held in a pinched manner. Therefore, in the present embodiment, a space portion 50 (an example of a first space portion) is provided between each of the plurality of belts 33, and a width 51 of the space portion (a width of the first space portion) one example) is set to be smaller than the width 52 (not shown) of the holding claw 48 . Similarly, a space portion 52 (an example of a second space portion) is provided between each of the plurality of belts 37, and the width 53 of the space portion is greater than the width 54 of the holding claws 49 (see FIG. 14). set to be small.

Further, in this embodiment, in the valley portion 24 of the rotating portion 25, the space portion 50 and the space portion 52 are arranged to face each other, and the belts 33 and 37 are arranged to face each other. (see FIG. 12).
By arranging them in this manner, the holding claws 48 and 49 allow the holding portion 47 of the conveying portion 14 to hold the chemicals 9 to 11 more stably. As a result, the reliability of the transport operation of the chemicals 9 to 11 in the transport section 14 can be further enhanced.

[1]-(11) Detailed configurations of the transport unit 14, the storage box installation unit 15, and the storage box 62 of the medicine sorting device Next, the details of the transport unit 14, the storage box installation unit 15, and the storage box 62 of the medicine sorting device configuration.
The conveying unit 14 in the present embodiment includes a shaft 56 for moving a take-out head 55 (an example of a second take-out head) in the X direction (horizontal direction) and a shaft 57 for moving the take-out head 55 in the Y direction (vertical direction). and (see FIGS. 15 and 16).

18 to 27 are cross-sectional views of essential parts of the take-out head and the storage box for explaining the operation of the conveying unit of the medicine sorting apparatus in cross section XViii-XViii of FIG. The take-out head 55 in this embodiment includes a pull-out portion 58 (an example of a suction nozzle) that pulls out the storage box 62 from the rear of the storage case 6, a holding portion 47 that takes out the chemicals 9 to 11 from the determination portion 13, and the holding portion 47. toward the storage box 62 side in two steps, and a detection unit 60 (an example of a fourth detection unit) that detects the state of storage of the chemicals 9 to 11 in the storage box 62. there is

Here, FIG. 18 shows a state in which the drugs 9 to 11 are transported from the discrimination section 13 to the storage case 6 side by the holding section 47. As shown in FIG.
In this state, the control unit 16 drives the drawer unit 58, and the storage box 62 determined based on the result of discrimination of the size, type, and expiry date of the medicines 9 to 11 by the determination unit 13 is selected. , from the storage case 6. The operations at this time are operations shown in the order of FIGS. 19, 20 and 21. FIG.

Here, the control unit 16 drives the drawer unit 58 to extend it to the storage box 62 for storing the identified medicines 9 to 11, and sucks the storage box 62 with the drawer unit 58 by sucking air. (See FIG. 19). Next, the control section 16 pulls back the drawer section 58 and pulls out the storage box 62 to the rear of the storage case 6 (see FIGS. 20 and 21).
At this time, as shown in FIG. 21, the holding portion 47 is positioned above the rear opening of the storage box 62 that has been pulled out. Then, the chemicals 9 to 11 will drop into the storage box 62 .

In this state, the holding portion 47 from which the drugs 9 to 11 are separated is lifted as shown in FIG. is pushed into the storage case 6. After that, the controller 16 releases the attraction force of the drawer 58 and returns the drawer 58 rearward as shown in FIG. 25 .
As described above, in this embodiment, the sorted drugs 9 to 11 can be stored in the storage boxes 62 suitable for each.

Next, the medicine sorting apparatus of this embodiment detects whether or not the storage box 62 is full of the chemicals 9 to 11 stored as described above. explain.
In this embodiment, FIG. 26 shows a state in which the inside of the storage box 62 is not filled with the stored drugs 9 to 11 when the storage box 62 is pulled out by the drawer portion 58 .

On the other hand, in FIG. 27, when the storage box 62 is pulled out by the drawer 58, the storage box 62 is filled with a plurality of drugs 9 to 11 stored therein. This indicates that the
That is, as shown in FIG. 26, when the storage box 62 is not filled with the stored chemicals 9 to 11, when the storage box 62 is pulled out by the drawer 58, the detection unit 60 is substantially perpendicular to the bottom surface of storage box 62 .

On the other hand, as shown in FIG. 27, when the storage box 62 is filled with a plurality of medicines 9 to 11, the storage box 62 can be pulled out from the drawer 58. , the detection unit 60 is pushed by the chemicals 9 to 11 and is in an inclined state with respect to the bottom surface of the storage box 62 .
Therefore, by detecting the inclination of the detection unit 60 with respect to the bottom surface of the storage box 62 by the control unit 16, it is detected whether or not the storage box 62 is filled with the chemicals 9 to 11 stored therein. .

In addition, when the detection unit 60 detects that the storage box 62 is full of stored chemicals 9 to 11, the control unit 16 does not open the holding unit 47, and does not open the holding unit 47. A storage box 62 is selected, and the newly selected storage box 62 is pulled out. After that, the control unit 16 causes the newly selected storage box 62 to store the medicines 9 to 11 .

That is, when such a full state is detected, the holding part 47 is not opened, and another storage box 62 is newly pulled out to store the medicines 9 to 11 therein. In other words, the control unit 16 controls the above operations and also sets addresses for storing the specific chemicals 9 to 11 in the storage box 62 in the storage case 6 . In addition, the medicine sorting apparatus of the present embodiment checks whether or not at least one of the stored chemicals 9 to 11 is stored in the storage box 62 outside the storage box 62 (that is, the storage box installation section 15). The stored state is displayed for confirmation from the outside of the device), and the display will be described below.

The storage box installation section 15 has a display section 61 (see FIGS. 28 to 31) at a place where each storage box 62 of the storage case 6 is stored.
As shown in FIG. 28, the display unit 61 in this embodiment is formed of a plate-like elastic body, more specifically, a flat plastic plate, part of which is coated with red paint to display. It forms a region 61a.

FIG. 29(a) shows a cross-sectional view of the main part of the initial state of the display section 61 in the storage box installation section 15 in this embodiment, and FIG. 29(b) shows the initial state of the display section 61. The front view is shown.
In particular, as shown in FIG. 29(b), in the initial state, that is, when the drugs 9 to 11 are not stored in the storage box 62, the display area 61a of the display unit 61 is stored in the storage box 62. , the display area 61a is invisible from the outside. 29(b) to 31(b) indicate a state in which the storage box 62 is absent. becomes visible from

Next, the control unit 16 drives the drawer unit 58 to extend it to the storage box 62 for storing the identified medicines 9-11. In this state, the storage box 62 is sucked by the drawer portion 58 by air suction, and then the drawer portion 58 is driven to pull back the drawer portion 58, thereby storing the identified medicines 9 to 11. The storage box 62 is pulled out to the rear of the storage case 6 (that is, the direction opposite to the display section 61) (see FIG. 30(a)). Next, the control section 16 extends the drawer section 58 and pushes the storage box 62 into the storage case 6 (see FIG. 17). After that, the controller 16 releases the attraction force of the drawer 58 and returns the drawer 58 backward (see FIG. 31(a)).

In this state, the storage box 62 is pulled out to the rear of the display unit 61 at least once in order to store the drugs 9 to 11, that is, at least one of the drugs 9 to 11 is stored in each storage box 62. Then, the display area 61a of the display unit 61 is arranged outside the storage box 62, and the display area 61a becomes visible from the front of the storage box installation unit 15 (see FIG. 31(a)). .

Therefore, in the medicine sorting apparatus according to the present embodiment, the storage case 6 of the storage box setting part 15 is provided with the display unit 61 for displaying whether or not at least one of the chemicals 9 to 11 is stored. A worker (for example, a medical worker who uses a drug sorting device) can check whether or not at least one of the drugs 9 to 11 is stored according to the display state of the corresponding display unit 61 outside the storage box 62. Since it can be easily confirmed from (that is, the outside of the storage box installation part 15), as a result, the sorting of collected medicines can be performed more efficiently.

In this embodiment, the display portion 61 provided in the storage case 6 of the storage box installation portion 15 uses a plate-like elastic body, but is not limited to this. can be used to display whether or not at least one of the chemicals 9 to 11 is stored.

[2] Operation of the medicine sorting device in this embodiment Below, the operation of the medicine sorting device in this embodiment will be described in detail.
The operation of each part of the medicine sorting device in this embodiment is performed by the control unit 16 described above, but the operation of the medicine sorting device in this embodiment can be broadly divided into the following:
(1) Tray initial position movement step S100
(2) First movement step S200
(3) Chemical identification step S300
(4) Second movement step S400
The above operations (1) to (4) are performed (see FIG. 32).
Now, the details of (1) to (4) above will be described below.

[2]-(1) Tray initial position movement step S100
First, unused medicines 9 to 11 collected from hospital rooms are placed in sorting tray 7 .
Next, the sorting trays 7 are piled up and held in the sorting tray installation section 8 in the vertical direction. Then, the vertically stacked sorting trays 7 are lifted by the lifting mechanism 17 .

[2]-(2) First movement step S200
In the tray initial position moving step S100 of the preceding process, after the sorting tray 7 is raised to a predetermined position by the raising mechanism 17, the control unit 16 operates the identification camera 19 (see FIGS. 2, 5, etc.). ) is controlled, the inside of the raised sorting tray 7 is imaged from above the sorting tray 7, and the image data imaged from the top of the sorting tray 7 is acquired (chemical image reading step in FIG. 33). equivalent to S201).

After that, using the obtained image data, the control unit 16 performs image processing on the image data, and recognizes the shapes of the drugs 9 to 11 inside the sorting tray 7 (the drug shape recognition step in FIG. 33). corresponding to S202).
After that, the control unit 16 determines one drug from the drugs 9 to 11 whose shape has been recognized, and prepares a plurality of nozzles 20 (Fig. 2, an example of which is shown in FIG. 6), the nozzle 20 most suitable for the shape is determined (corresponding to the holding portion determination step S203 in FIG. 33).

After that, after the chemicals 9 to 11 are adsorbed by the nozzle 20, the control unit 16 rotates (corrects) the nozzle 20 in the adsorption rotation direction by the detected rotation offset amount, and in this state, The chemicals 9 to 11 adsorbed by the nozzle 20 are conveyed onto the discriminating section 13 shown in FIG. 16 described later (corresponding to the chemical conveying step S204 in FIG. 33).
In the drug shape recognition step S202 in this embodiment, the control unit 16 uses the image data projected from the upper part of the sorting tray 7 to determine the longitudinal direction of the drugs 9 to 11 adsorbed by the nozzle 20. and the orientation when it is lowered onto the discriminating section 13, the amount of rotation offset (the amount of deviation in the direction of attraction rotation) in the attraction rotation direction (F in FIG. 6) is detected.

In this way, the amount of offset in the adsorption direction (the amount of deviation during adsorption) between the longitudinal direction of the chemicals 9 to 11 adsorbed by the nozzle 20 and the direction when they are lowered onto the discrimination section 13 is detected, By rotating (correcting) by the offset amount (deviation amount), the nozzle 20 that has adsorbed the chemicals 9 to 11 is installed in the discriminating section 13 in a state in which the rotational deviation of these chemicals 9 to 11 is eliminated. can be done.

[2]-(3) Chemical identification step S300
Next, the chemical specifying step S300 will be described.
After the selected chemicals 9 to 11 have been transported to the discriminating section 13 in the first moving process S200 of the preceding process, more , the control unit 16 uses the detection unit 26 to detect the sizes of the chemicals 9 to 11 (corresponding to the first detection step S301 in FIG. 34).

Therefore, in the first detection step S301 in this embodiment, the control unit 16 uses the placement unit 42 to move the transported chemicals 9 to 11 to the rotation start position. More specifically, the control unit 16 drives the position restricting plate driving unit 46 in the direction of D in FIGS. 11 and 12 to move the position restricting plate 45 . By moving in this manner, the transported chemicals 9 to 11 are placed so that the portion serving as a reference for detecting the size of the chemicals 9 to 11 is in contact with the reference surface 43. (see FIGS. 11 and 12).

That is, the rotation start position is the position where the reference portion for detecting the sizes of the chemicals 9 to 11 contacts the reference plane 43 .
Next, in this state, the control unit 16 uses the detection unit 26 to detect the portion (E in FIG. 12) opposite to the reference portion of the chemicals 9 to 11, thereby detecting the chemicals 9 to 11. 11 size is detected. In addition, the detection part 26 of this embodiment uses an optical sensor. Further, in the first detection step S301 in the present embodiment, the rotating portion 25 in the discriminating portion 13 is in a non-rotating state (=non-rotating).

Next, the control section 16 drives the rotating section 25 , more specifically, drives the rotating bodies 29 and 30 of the rotating section 25 , and the medicine transported onto the valley portion 24 of the discriminating section 13 . 9 to 11 are rotated at a predetermined rotation speed (first rotation speed) (corresponding to the first rotation operation step S302 in FIG. 34).
Then, the control unit 16 uses the detection unit 27 to detect the identification code 18 (shown in FIG. 9) for detecting the type of medicine on the medicines 9 to 11 being rotated, and Based on the obtained identification code 18, data on the type of medicine is acquired (corresponding to the first identification code detection step S303 in FIG. 34).

Although the barcode (registered trademark) is used as the identification code 18 in this embodiment, the identification code 18 is not limited to this, and a QR code (registered trademark) may be used. Since a barcode is used for the identification code 18 in this embodiment, a barcode reader is used as the detector 27 .
Next, the control section 16 drives the rotating section 25 , more specifically, drives the rotating bodies 29 and 30 of the rotating section 25 , and the medicine transported onto the valley portion 24 of the discriminating section 13 . 9 to 11 are rotated at a predetermined rotation speed (second rotation speed) (corresponding to the second rotation operation step S304 in FIG. 34).

Then, using the detection unit 28, the control unit 16 uses characters indicating expiration dates (not shown) written on the rotated medicines 9 to 11, or identification codes (not shown) corresponding to expiration dates. , a character indicating the expiration date, or an identification code corresponding to the expiration date) is detected as an example of the second identification code, and the character indicating the detected expiration date (not shown) or the character corresponding to the expiration date Based on the identification code, data regarding the expiration date of the medicines 9 to 11 being rotated is acquired (corresponding to the second identification code detection step S305 in FIG. 34).

In this embodiment, the character indicating the expiration date or the identification code corresponding to the expiration date is a printed character using alphanumeric characters, but it is not limited to this. In addition, barcodes (registered trademark), QR codes (registered trademark), etc. may be used.
Furthermore, an OCR (Optical Character Recognition) system using a camera was used as the detection unit 27 in this embodiment.

Here, the first rotation speed in the first rotation operation step S302 and the second rotation speed in the second rotation operation step S304 of the rotating portion 25 in this embodiment are different rotation speeds. there is
More specifically, in the first identification code detection step S303, the control unit 16 uses the detection unit 27 to detect the identification code 18 (see FIG. 4), and then detects the type of the detected medicine. Get data about After that, the control unit 16, based on data related to the type of the detected drug (for example, data including characters indicating the detected use-by date, or information on the size and shape of an identification code corresponding to the use-by date, etc.) , the second rotation speed, and then the control unit 16 drives the rotation unit 25, more specifically, drives the rotation members 29 and 30 of the rotation unit 25, The chemicals 9 to 11 transported onto the troughs 24 are rotated at a predetermined rotation speed (second rotation speed). This makes it possible to more accurately detect the character indicating the expiration date or the identification code corresponding to the expiration date.

The rotating portion 25 in this embodiment is configured using a stepping motor, so that the control portion 16 can freely change the rotational speed of the rotating portion 25 .
Next, the control unit 16 stores the chemicals 9 to 11 based on the information on the size, type, and expiration date of the chemicals 9 to 11 detected by the detection unit 26, the detection unit 27, and the detection unit 28. A box 62 is determined (corresponding to the storage box determination step S306 in FIG. 34).

In particular, in the present embodiment, information on the sizes of the chemicals 9 to 11 detected by at least the detection unit 26, in other words, by the detection unit 26 that detects the sizes of the chemicals 9 to 11 at least by a mechanical detection method. , the storage box 62 for storing the drugs 9 to 11 is determined.
Here, the reason why the storage box 62 for storing the drugs 9 to 11 is determined based on at least the size information of the drugs 9 to 11 detected by the detection unit 26 will be described. Also in this embodiment, for example, the detection unit 27 is used to detect the identification code 18 (for example, shown in FIG. 4) for detecting the type of medicine, and the identification code 18 is detected by a non-mechanical detection method. reading.

Using such a non-mechanical detection technique (for example, an optical detection technique for the coded identification code 18 in this embodiment), it is also possible to determine the storage box 62 for storing the drugs 9 to 11. be.
However, using such a non-mechanical detection method, information on the types of chemicals 9 to 11 is read, and based on the information on the types of chemicals 9 to 11 detected by the non-mechanical detection method, When the storage box 62 for storing the chemicals 9 to 1 is determined, if the identification code 18 for detecting the type of the chemicals 9 to 11 cannot be read, the storage box 62 for storing the chemicals 9 to 11 is selected. It may cause the problem of not being able to decide.

In particular, in the case of the medicine payment apparatus of this embodiment, the medicines 9 to 11 once prepared (for patients, etc.) are handled in a hospital or the like. In the case of the chemicals 9 to 11 once prepared in this way, the types of the chemicals 9 to 11 are detected due to stains on the identification code 18 for detecting the types of the chemicals on the chemicals 9 to 11. It must be taken into account that the identification code 18 for the user may not be readable.

Therefore, as in the present embodiment, at least the size of the chemicals 9 to 11 detected by the detection unit 26, in other words, the size of the chemicals 9 to 11 detected by the detection unit 26 that detects the size of the chemicals 9 to 11 by at least a mechanical detection method. By determining the storage box 62 for storing the drugs 9 to 11 based on the information, the sizes of the drugs 9 to 11 can be reliably detected, and furthermore, the size of the drug 9 can be detected based on the information. 11 can be reliably determined.

The storage box 62 for storing the chemicals 9 to 11 is determined based on all of the information on the size, type, and expiration date of the chemicals 9 to 11 detected by the detection unit 26, the detection unit 27, and the detection unit 28. By doing so, the collected chemicals 9 to 11 can be sorted with higher accuracy.
Further, the discrimination unit 13 in the present embodiment uses the three detection units of the detection unit 26, the detection unit 27, and the detection unit 28 to determine the size, type, expiration date, etc. of the chemicals 9 to 11. The information is read and the storage box 62 for storing the drugs 9 to 11 is determined. At least one detection unit is provided, the information for the drugs 9 to 11 is read, and then the storage box 62 for storing the drugs 9 to 11 is determined. You can also

In addition, in the storage box determination step S306 in this embodiment, the storage box 62 for storing the drugs 9 to 11 is directly determined, but the present invention is not limited to this. It is also possible to set the address of the storage box 62 in the storage box setting section 15 that stores 1 to 11, and determine the address of the storage box 62 in the storage box setting section 15.
The above is the description of the drug specifying step S300.

[2]-(4) Second movement step S400
Next, the second moving step S400 will be described.
In the medicine specifying step S300 of the previous process, the storage box 62 to be stored is determined by the determination unit 13, and then the control unit 16 uses the transport unit 14 to place the drug into the storage box 62 in the storage box setting unit 15. and convey (second movement step S400).
The above is the description of the second movement step S400.
The above is the detailed description of the operation of the medicine sorting apparatus according to the present embodiment.

[3] Effect of the medicine sorting apparatus in this embodiment As described above, in this embodiment, the chemicals 9 to 11 are taken out from the sorting tray 7 installed in the sorting tray installation unit 8 by the transport unit 12, and then The type of the chemicals 9 to 11 conveyed by the conveying section 12 is discriminated by the discriminating section 13, then the chemicals 9 to 11 discriminated by the discriminating section 13 are taken out by the conveying section 14, and then the conveying section 14 Since the chemicals 9 to 11 are stored in the storage box 62, the collected chemicals 9 to 11 can be efficiently sorted.

In the present invention, the chemicals are taken out from the sorting trays installed in the sorting tray installation section by the first conveying section, then the type of the chemicals conveyed by the first conveying section is discriminated by the discriminating section, and then The medicines discriminated by the discriminating part are taken out by the second conveying part and then stored in the storage box by the second conveying part, so that the collected medicines can be efficiently sorted. can be done.

Therefore, it is particularly useful for a medicine sorting device for sorting returned medicines.

1 drug sorting device 4 database 5 door 6 storage case 7 sorting tray 8 sorting tray installation unit 9, 10, 11 chemicals 12 transport unit (an example of the first transport unit)
13 discrimination unit 14 transport unit (an example of a second transport unit)
15 storage box installation unit 16 control unit 17 lifting mechanism 18 identification code 19 identification camera 20 nozzle (an example of a first holding unit)
21 excitation part 22 frame body 23 inclined surface 24 trough part 25 rotation part 26 detection part (an example of the first detection part, for example, an optical sensor)
27 detection unit (an example of the second detection unit, for example, barcode reader)
28 detection unit (an example of a third detection unit, such as a camera)
29 rotating body (an example of the first rotating body)
30 rotating body (an example of a second rotating body)
31 roller (an example of the first roller)
32 roller (an example of the second roller)
33 belt (an example of the first belt)
35 roller (an example of the third roller)
36 roller (an example of the fourth roller)
37 belt (an example of the second belt)
38 chemical contact surface (an example of the first chemical contact surface)
39 chemical contact surface 40 one end 41 one end 42 placement portion 43 reference surface 44 reference plate 45 position control plate 46 position control plate driving portion 47 holding portion (an example of a second holding portion)
48 holding claw (an example of the first holding claw)
49 holding claw (an example of a second holding claw)
50 space (an example of the first space)
51 Width of the space (an example of the width of the first space)
52 space (an example of the second space)
53 Width of the space (an example of the width of the second space)
54 Width of holding claw (an example of width of second holding claw)
55 take-out head (an example of a second take-out head)
56 Shaft 57 Shaft 58 Drawer (an example of a suction nozzle)
59 drive unit 60 detection unit (an example of a fourth detection unit)
61 display unit 61a display area 62 storage box 63 display 64 take-out head (an example of a first take-out head)

Claims (3)

a sorting tray in which a plurality of unused and returned drugs are stored in a non-aligned state;
an identification camera for acquiring the states of the plurality of drugs in the sorting tray as image data;
a first transport unit that takes out medicine from the sorting tray based on the image data acquired by the identification camera;
a placement section on which the drug taken out by the first transport section is laid sideways and which rotates the drug at a first rotation speed ;
a detection unit that detects the type of the chemical while rotating the chemical on the mounting unit at the first rotation speed ;
a control unit that determines a storage location of the medicine based on information detected by the detection unit;
a second transport unit that transports the medicine from the placement unit to the storage destination;
with
The control unit determines a second rotation speed different from the first rotation speed as a rotation speed for rotating the drug on the placement unit according to the type of the drug detected by the detection unit. do,
Chemical sorting equipment. The control unit is connected via a network to an external database in which information such as the type of the drug is stored.
The chemical sorting apparatus according to claim 1. The control unit determines the storage location of the drug based on at least one of the type, size, and expiration date of the drug.
3. A drug sorting apparatus according to claim 1 or claim 2.

Images