JP7142344B2 - drug supply device - Google Patents

Description

The present disclosure relates to drug delivery devices.

A storage facility for storing a plurality of sheet-shaped drug sheets in which a plurality of drug sheets are enclosed in a divided state includes a storage unit for storing a plurality of cassettes containing a plurality of drug sheets, and a position and drug sheet corresponding to each of the plurality of cassettes. A configuration comprising: a movable base that is movable to and from an unloading position; a cassette moving device that is capable of moving the cassette between a storage position in the storage section and a take-out position on the movable base; and a sheet cutting device that cuts the drug sheet. is disclosed, for example, in Japanese Patent Application Laid-Open No. 2013-133220 (Patent Document 1).

JP 2013-133220 A

In the configuration described in the above document, the sheet cutting device is provided on the movable base. The size of the moving base becomes large, and consequently, the size of the entire apparatus becomes large.

In the present disclosure, a compact drug delivery device is provided.

In accordance with the present disclosure, a drug delivery device is provided that receives strip packages and dispenses strip packages according to a prescription. A strip package has a predetermined number of two or more packages in which drugs are individually packaged, and the predetermined number of packages are arranged in a line to form an integral structure. The medicine supply device includes a storage section for storing the strip package, a transport section for taking out the strip package from the storage section, a cutting section for cutting the strip package taken out from the storage section by the transport section, a storage section, and a transport section. and a housing that houses the section and the cutting section. The cutting section is provided separately from the conveying section and attached to the housing.

In the medicine supply device described above, the cutting section has a positioning section that determines the position of the strip package conveyed from the storage section to the cutting section by the conveying section.

The drug delivery device described above further comprises a memory for storing the dimensions of the package. The locator positions the strip package based on the dimensions.

The drug supply device described above further includes an imaging device for imaging the strip package. The positioning unit determines the position of the strip package based on image information of the strip package imaged by the imaging device.

The drug supply device described above further includes a second storage section that stores less than a predetermined number of packages.

In the medicine supply device described above, the cutting section divides the strip package into a first cut body to be dispensed and a second cut body not to be dispensed. The conveying section moves the second cut body from the cutting section to the second accommodating section.

The drug supply device described above further includes a detection device that detects the number of packages contained in the second container.

According to the present disclosure, a compact drug delivery device can be realized.

1 is a schematic front view showing a schematic configuration of a medicine supply device based on an embodiment; FIG. FIG. 4 is a schematic diagram of a strip package; It is a perspective view of a 1st accommodating part. It is a perspective view of a 2nd accommodating part. FIG. 4 is a schematic side view of the first housing and the second housing in the forward position; It is a typical side view of a 1st accommodation part and a 2nd accommodation part in a retracted position. It is a typical side view of a conveyance part. It is a typical front view of a cutting part. FIG. 4 is a schematic diagram of a cut strip package; It is a block diagram which shows the system configuration|structure of a chemical|medical agent supply apparatus. It is the 1st flowchart which shows the taking-out operation|movement of the package by a medicine supply apparatus. It is the 2nd flowchart which shows the taking-out operation|movement of the package by a medicine supply apparatus. It is the 3rd flowchart which shows the taking-out operation|movement of the package by a medicine supply apparatus. It is the 4th flowchart which shows the taking-out operation|movement of the package by a medicine supply apparatus. It is the 5th flowchart which shows the taking-out operation|movement of the package by a medicine supply apparatus.

Hereinafter, embodiments will be described based on the drawings. In the following description, the same parts are given the same reference numerals. Their names and functions are also the same. Therefore, detailed description thereof will not be repeated.

[Structure of medicine supply device 1]
FIG. 1 is a schematic front view showing a schematic configuration of a medicine supply device 1 based on an embodiment. As shown in FIG. 1 , the medicine supply device 1 has a housing 2 . A plurality of drug storage units 10 are arranged vertically (six in the embodiment) and horizontally (four in the embodiment) and housed in the housing 2 . The housing 2 also accommodates a conveying section 40 , a cutting section 60 and a relay container 70 . The conveying section 40 , the cutting section 60 and the relay container 70 are provided separately and attached to the housing 2 separately.

The conveying unit 40 is configured to be movable in the vertical direction and the horizontal direction at a front position with respect to the drug containing unit 10 . The cutting section 60 and the relay container 70 are positioned below the drug containing section 10 . The relay container 70 is arranged below the cutting section 60 . A payout tray 80 is arranged below the relay container 70 . The payout tray 80 is transported from the outside of the housing 2 to a predetermined position below the relay container 70 inside the housing 2 . Also, the dispensing tray 80 is conveyed to the outside of the housing 2 from a predetermined position below the relay container 70 inside the housing 2 .

FIG. 2 is a schematic diagram of the strip package 100. As shown in FIG. The strip package 100 shown in FIG. 2 is accommodated in the medicine supply device 1 and dispensed from the medicine supply device 1 according to the prescription. As shown in FIG. 2, the strip package 100 has a predetermined number of two or more (three in the embodiment) packages 110 in which drugs 200 are individually packaged, and the predetermined number of packages 110 are arranged in a line. It is constructed integrally. Each package 110 has a seal 112 at its peripheral portion. The seal portion 112 is formed by heat-sealing the packaging material forming the package 110 . Medicine 200 is accommodated in a space formed so as to be surrounded by seal portion 112 . The dosage form of drug 200 may be, for example, powder, tablet, or the like.

A perforation 114 is formed in the seal portion 112 that partitions the adjacent packages 110 . By separating the strip packages 100 along the perforations 114, adjacent packages 110 are easily separated.

FIG. 3 is a perspective view of the first housing portion 20. FIG. The drug container 10 shown in FIG. 1 includes a first container 20 and a second container 30, the details of which will be described later. The first accommodation portion 20 accommodates the strip package 100 . The second storage unit 30 stores packages 110 less than the number of packages 110 contained in the strip package 100 . In the case of the strip package 100 in which the three packages 110 shown in FIG. be accommodated.

The first accommodation section 20 has a cassette 21 . The cassette 21 is composed of a substantially flat bottom portion 22 and a pair of substantially flat side walls 23 . The pair of side walls 23 are provided substantially perpendicular to the bottom surface portion 22 and arranged parallel to each other. The pair of side walls 23 are configured to be movable relative to the bottom surface portion 22 in directions toward or away from each other. The cassette 21 accommodates one or more strip packages 100 in a space defined by the bottom portion 22 and the side walls 23 while arranging them in the front-rear direction in an upright state. The cassette 21 has an outlet 24 at its front end. The takeout port 24 is an opening for taking out the strip package 100 from the cassette 21 .

The first accommodation section 20 has a moving operation section 26 . The moving operation part 26 is attached to the bottom part 22 of the cassette 21 . The moving operation part 26 has a plate-like shape provided substantially perpendicularly to the bottom part 22 . The moving operation unit 26 is configured to be movable in the front-rear direction. The moving operation unit 26 moves the strip package 100 accommodated in the cassette 21 toward the outlet 24 by moving forward. An urging member such as a constant force spring may be attached to the moving operation part 26 for urging the moving operation part 26 forward. An actuator may be provided to move the moving motion part 26 in the front-rear direction.

The first container 20 has a stop 25 at the outlet 24 that rests against the edge of the strip package 100 . The stop portion 25 includes a lower stop portion 25A that contacts the lower edge of the strip package 100, a side stop portion 25B that contacts the side edge of the strip package 100, and a pressing portion 25C that contacts the upper edge of the strip package 100. have. The lower stop portion 25A protrudes upward from the bottom portion 22 . A side stop 25B is provided on each of the pair of side walls 23 . A side stop portion 25B provided on one of the pair of side walls 23 protrudes toward the other of the pair of side walls 23 . A side stop portion 25B provided on the other of the pair of side walls 23 protrudes toward one of the pair of side walls 23 . The side stop portion 25B extends vertically.

The pressing portion 25C extends in the front-rear direction. The pressing portion 25</b>C is provided on the movable member 27 . Each side wall 23 is formed with a window portion 23A obtained by cutting out a portion of the side wall 23 in a rectangular shape. The movable member 27 is attached to the window portion 23A. The movable member 27 has a vertical dimension smaller than that of the window portion 23A. Therefore, the movable member 27 can change its vertical position within the window portion 23A. A pressing portion 25C attached to the movable member 27 is also vertically adjustable. A pressing portion 25</b>C attached to the movable member 27 provided on one side wall 23 protrudes toward the other of the pair of side walls 23 . A pressing portion 25</b>C attached to a movable member 27 provided on the other side wall 23 protrudes toward one of the pair of side walls 23 .

The first housing portion 20 has a pair of link portions 29 . One end of the link portion 29 is rotatably attached to the first link shaft 28 . The first link shaft 28 is provided at the front end of the bottom portion 22 . The first link shaft 28 is arranged forward of the side wall 23 . The other end of the link portion 29 is rotatably attached to a second link shaft 38 of the second housing portion 30 shown in FIG. 4 to be described later. The first accommodation portion 20 and the second accommodation portion 30 are joined via a link portion 29 . As the link portion 29 rotates around the first link shaft 28 and the second link shaft 38 , the second housing portion 30 moves relative to the first housing portion 20 .

The pair of first link shafts 28 and the link portion 29 may be configured to be fixed to each of the pair of side walls 23 and movable relative to the bottom surface portion 22 together with the side walls 23 . In this case, since the first link shaft 28 and the link portion 29 can be moved integrally with the side wall 23, adjustment of the cassette 21 according to the dimensions of the strip package 100 is facilitated.

4 is a perspective view of the second housing portion 30. FIG. The second housing portion 30 has a thin plate-like bottom portion 32 and a pair of side walls 33 rising upward from the bottom portion 32 . The pair of side walls 33 are arranged parallel to each other. The second housing portion 30 further has an inclined wall 34A and an upright wall 34B connecting the pair of side walls 33 together. The side wall 33, the inclined wall 34A and the standing wall 34B all have a thin plate shape. The inclined wall 34A rises upward from the bottom portion 32 and extends while being inclined with respect to the bottom portion 32 . The standing wall 34B extends substantially perpendicularly to the bottom portion 32 . The inclined wall 34A and the standing wall 34B are provided substantially perpendicular to both of the pair of side walls 33 .

The second storage unit 30 stores upright packages 110 less than the number of packages 110 contained in the strip package 100 (one or two consecutive packages 110 in the embodiment). A lower edge portion of the package 110 accommodated in the second accommodation portion 30 is supported by the bottom portion 32 . Package 110 is arranged to lean against inclined wall 34A and standing wall 34B, and is supported by inclined wall 34A and standing wall 34B.

A second link shaft 38 is provided on the outer surface of the pair of side walls 33 on the opposite side of the opposing surfaces facing each other. As described above, the other end of the link portion 29 shown in FIG. 3 is rotatably attached to the second link shaft 38 . The second link shaft 38 is provided near the upper edge of the side wall 33 .

An engaging shaft portion 37 is also provided on the outer surface of the side wall 33 . The engaging shaft portion 37 extends substantially perpendicular to the outer surface of the side wall 33 and protrudes from the side wall 33 . The engaging shaft portion 37 is provided near the lower edge of the side wall 33 .

The detection device 54 shown in FIG. 4 is a sensor for detecting the number of packages 110 contained in the second container 30 . The sensing device 54 may be an optical sensor. The detection device 54 may be a reflective optical sensor that detects the reflection of the light that irradiates the second housing portion 30 . Based on the difference between the amount of light reflected by the package 110 and the amount of light reflected by the inclined wall 34A or the vertical wall 34B of the second storage section 30, the range in which the package 110 exists in the second storage section 30 is detected. Accordingly, the detection device 54 can detect the number of packages 110 accommodated in the second accommodation portion 30 . The sensing device 54 may be configured to include multiple optical sensors. A plurality of optical sensors may be arranged side by side in the horizontal direction.

FIG. 5 is a schematic side view of the first housing portion 20 and the second housing portion 30 in the forward position. FIG. 5 shows two vertically arranged first housing portions 20, with the upper first housing portion 20 indicated by a solid line and the lower first housing portion 20 indicated by a broken line. Four strip packages 100 are accommodated side by side in the front-rear direction (left-right direction in FIG. 5) in the first accommodation portion 20 shown in FIG. The strip package 100 is urged toward the ejection port 24 at the front end by the movement action part 26 . Stops 25 (lower stop 25A and one side stop 25B are shown in FIG. 5) engage the edges of the frontmost strip package 100 such that strip package 100 is is prevented from moving forward beyond the stop 25.

The second housing portion 30 shown in FIG. 5 is arranged at a position that covers the outlet 24 from the front (left side in FIG. 5). The position where the second accommodation portion 30 is arranged in FIG. 5 is referred to as the front position. Since the second container 30 is arranged so as to block the outlet 24, front access to the strip package 100 in the first container 20 is prevented.

FIG. 6 is a schematic side view of the first accommodation portion 20 and the second accommodation portion 30 at the retracted position. The second housing portion 30 shown in FIG. 6 is arranged at a position that is retracted from the front position and does not cover the outlet 24 . The position where the second accommodation portion 30 is arranged in FIG. 6 is referred to as a retracted position. The second housing portion 30 is configured to reciprocate between a front position shown in FIG. 5 and a retracted position shown in FIG. As shown in FIG. 6, the second accommodation portion 30 is arranged in a position away from the front of the outlet 24, and the outlet 24 is open so that the strip package 100 in the first accommodation portion 20 can be removed. It is possible to access from the front.

FIG. 7 is a schematic side view of the transport section 40. FIG. As shown in FIG. 7, the transport section 40 has a hollow box-shaped casing 41 . An intake port 42 is formed in a portion of the side surface of the casing 41 . The intake port 42 is an opening penetrating the side surface of the casing 41 in the thickness direction. The internal space and the outside of casing 41 communicate with each other via inlet 42 . The intake port 42 opens on the rearward outer surface of the casing 41 . The intake port 42 is open to the outer surface of the casing 41 facing the medicine containing portion 10 .

The detection device 54 described with reference to FIG. 4 is mounted on the top surface of the casing 41 . The detection device 54 is provided at the rear edge of the upper surface of the casing 41 . The detection device 54 is arranged above the intake 42 .

The transport section 40 has a suction device 44 . The suction device 44 can reciprocate in the front-rear direction (left-right direction in FIG. 7). The suction device 44 is configured to reciprocate between a position inside the casing 41 indicated by solid lines in FIG. 7 and a position outside the casing 41 indicated by dashed lines in FIG. 7 via the inlet 42 . .

The suction device 44 has a suction port 44A. The suction device 44 can suck the strip package 100 and the package 110 into the suction port 44A. The suction device 44 can suck and take out the strip package 100 at the forefront from the first storage section 20, and can also suck and take out the package 110 stored in the second storage section 30. can be done.

More specifically, the suction device 44 is moved to a position outside the casing 41, and with the suction port 44A in contact with the strip package 100 or the package 110, a vacuum such as a suction pump 40P (not shown in FIG. 7) is operated. By driving the pressure generating source, the strip package 100 or the package 110 can be sucked into the suction port 44A.

By moving the suction device 44 to a position inside the casing 41 while the strip package 100 is sucked into the suction port 44A, the strip package 100 can be taken out from the first container 20. FIG. By elastically deforming the edge portion of the foremost (leading) strip package 100 , the leading strip package 100 passes over the stop 25 and passes through the outlet 24 to be taken out of the first container 20 . At this time, the second and subsequent strip packages 100 are moved toward the outlet 24 by the moving action section 26, but are prevented from passing through the outlet 24 because the movement is restricted by the stop section 25. It stays in the first accommodation part 20 .

By moving the suction device 44 to a position inside the casing 41 while the package 110 is sucked into the suction port 44A, the package 110 can be taken out from the second container 30 . Since the package 110 is stored in the second storage section 30 in an upright state so as to lean against the inclined wall 34A and the vertical wall 34B, the suction port 44A can be easily brought into contact with the package 110. can be easily taken out from the second housing portion 30 .

When the suction device 44 that has sucked the strip package 100 or package 110 into the suction port 44A moves to a position inside the casing 41, the drive of the negative pressure generation source is stopped. As a result, the strip package 100 or the package 110 is no longer sucked by the suction device 44 , and the strip package 100 or the package 110 falls from the suction device 44 . Then, the strip package 100 or package 110 drops into the receiving portion 46 which is the hollow space inside the casing 41 . An inclined surface 45 is provided below the inlet 42, and the strip package 100 or the package 110 is slid along the inclined surface 45 and dropped into the receiving portion 46, whereby the strip packaging is accommodated in the receiving portion 46. The posture of the body 100 or the package 110 can be adjusted.

The transport section 40 has an opening/closing bottom plate 48 . The opening/closing bottom plate 48 constitutes the bottom of the casing 41 , that is, the bottom of the receiving portion 46 . As indicated by the solid line and broken line in FIG. 7, the opening/closing bottom plate 48 is configured to rotate around the rotation shaft. When the opening/closing bottom plate 48 is in the closed position indicated by the solid line in FIG. When the opening/closing bottom plate 48 is in the open position indicated by the dashed line in FIG. 7, the strip packages 100 and/or packages 110 accommodated in the receiving section 46 drop from the casing 41 and move downward on the conveying section 40. do.

The conveying section 40 further has a retracting operation section 47 . The retracting motion part 47 is configured to rotate around a rotation shaft as indicated by a double arrow in FIG. 7 . The retracting motion portion 47 can be engaged with the engaging shaft portion 37 shown in FIG. In a state in which the retracting motion part 47 is engaged with the upward facing surface of the engaging shaft part 37, the retracting motion part 47 receives the driving force of the retraction motor 40M2 (not shown in FIG. 7) and rotates downward. The second accommodation part 30 can be pushed down to move the second accommodation part 30 from the forward position shown in FIG. 5 to the retracted position shown in FIG.

A biasing spring is attached to the first link shaft 28 shown in FIG. 3 so that the second accommodation portion 30 can return from the retracted position to the front position when the pushing down of the second accommodation portion 30 by the retracting portion 47 is released. It may be configured such that the urging spring is provided and exerts an upward urging force on the link portion 29 .

FIG. 8 is a schematic front view of the cutting section 60. FIG. As shown in FIG. 8 , the cutting section 60 has a wall section 62 , a cutter 64 and a positioning section 66 . The conveying section 40 is configured to be able to move the strip package 100 from the first accommodating section 20 to the cutting section 60 . The wall portion 62 is inclined with respect to the vertical direction. The strip package 100 conveyed to the cutting section 60 is arranged to lean against the wall section 62 and is supported by the wall section 62 . The cutter 64 incorporates a cutting blade 64A for cutting the strip package 100. As shown in FIG.

The positioning portion 66 positions the strip package 100 with respect to the cutter 64 . The positioning portion 66 of the embodiment moves the strip wrapper 100 along the wall portion 62 to position the strip wrapper 100 with respect to the cutter 64 . Cutting is performed based on the dimensions of the packages 110 forming the strip package 100 and the number of packages 110 to be dispensed among the strip packages 100 conveyed from the first storage unit 20 to the cutting unit 60. A positioning portion 66 slides the strip package 100 along the wall portion 62 so that the blade 64A is positioned at an appropriate cutting position. Typically, cutting blade 64A is aligned with perforation 114 of strip package 100 (see FIG. 2).

The dimensions of the package 110 may be associated with the type of the strip package 100 and stored in advance in the memory 91, which will be described later. Alternatively, the drug supply device 1 may be provided with an imaging device 52, which will be described later, for imaging the strip packaging 100, and the dimensions of the packaging 110 can be determined based on the imaging information of the strip packaging 100 imaged by the imaging device 52. can be asked for.

The positioning section 66 may move the cutter 64 to position the strip package 100 with respect to the cutter 64 . The positioning unit 66 may move both the cutter 64 and the strip package 100 independently to position the strip package 100 with respect to the cutter 64 .

FIG. 9 is a schematic diagram of a cut strip package 100. FIG. A strip package 100 having three packages 110 shown in FIGS. 2 and 8 is cut by a cutting section 60 into a first cut 102A and a second cut 102B. In the example shown in FIG. 9, the first cut body 102A contains one package 110, and the second cut body 102B contains two packages 110. In the example shown in FIG.

In the example shown in FIG. 9, among the strip packages 100 conveyed to the cutting section 60, the number of packages 110 to be dispensed is one. The package 110 to be delivered constitutes the first cut body 102A. The package 110 that is not to be delivered constitutes the second cut body 102B. When the strip package 100 is divided into the first cut body 102A and the second cut body 102B, the first cut body 102A falls from the cutting section 60 to the relay container 70 below by its own weight. may be configured.

The cutting part 60 keeps the second cut body 102B supported even after the strip package 100 is cut. The second cut body 102B that is not to be dispensed moves from the cutting section 60 to the second storage section 30 . The transport section 40 moves the second cut body 102B from the cutting section 60 to the second storage section 30 by sucking and holding the second cut body 102B.

The relay container 70 shown in FIG. receive and temporarily contain Although one relay container 70 is illustrated in FIG. 1, the drug supply device 1 may be provided with a plurality of relay containers 70. In this case, separate relay containers are provided for each of the plurality of drugs 200 included in the prescription. The container 70 may contain the strip package 100, the package 110 and the first cut body 102A.

Dispensing tray 80 shown in FIG. 1 receives strip package 100, package 110 and first cut 102A contained in one or more relay containers 70. FIG. When all the medicines 200 to be dispensed according to the prescription are placed in the dispensing tray 80 , the medicines 200 are dispensed to the outside of the medicine supply device 1 together with the dispensing tray 80 .

FIG. 10 is a block diagram showing the system configuration of the medicine supply device 1. As shown in FIG. As shown in FIG. 10 , the medicine supply device 1 has a controller 90 and an operation section 92 .

The operation unit 92 is operated by an operator who operates the medicine supply device 1 . Information required for dispensing operation of the strip package 100 and/or package 110 using the medicine supply device 1 is input to the controller 90 by the operation of the operation unit 92 by the operator. The information required for the dispensing operation includes prescription data based on the prescription and various setting information. The setting information includes the type of drug 200 contained in each drug container 10, the number of packages 110 contained in the strip package 100 contained in the first container 20 of each drug container 10, and the packaging. The dimensions of the body 110 and the like can be mentioned. Information necessary for the payout operation may be input to the controller 90 from an external computer.

The controller 90 receives input of imaging information of the strip package 100 from the imaging device 52 . The imaging device 52 may image the strip package 100 supported by the cutting section 60 , or may image the strip package 100 supported by the first storage section 20 or the transport section 40 . The controller 90 receives input of information on the number of packages 110 contained in the second container 30 from the detection device 54 .

The controller 90 has a memory 91 . The memory 91 is provided as an area for storing programs for executing various operations of the medicine supply device 1 and for storing necessary data. The memory 91 stores information necessary for the dispensing operation, imaging information of the strip package 100, and the number of packages 110 accommodated in the second accommodation section 30 (accommodated number).

The controller 90 controls the overall operation of the medicine supply device 1 based on the programs stored in the memory 91 and the information required for the dispensing operation. The controller 90 performs various processes for controlling dispensing operations of the strip packages 100 and/or packages 110 . Specifically, the controller 90 controls the conveying section 40 and the cutting section 60 .

The transport unit 40 has a transport unit moving motor 40M1, a retraction motor 40M2, a suction device moving motor 40M3, an opening/closing motor 40M4, and a suction pump 40P. Controller 90 controls motors 40M1-40M4 and pump 40P by outputting control signals to these motors 40M1-40M4 and pump 40P. By properly driving and stopping motors 40M1 to 40M4 and pump 40P, transport of strip package 100 or package 110 by transport unit 40 is performed.

The transport section moving motor 40M1 generates driving force for moving the entire transport section 40 vertically and horizontally. Conveying section moving motor 40M1 receives a control signal from controller 90 and moves conveying section 40 to a position corresponding to drug containing section 10 from which strip package 100 and/or package 110 is to be taken out.

The retraction motor 40M2 generates a driving force for moving the second housing portion 30 from the front position shown in FIG. 5 to the retraction position shown in FIG. The retraction motor 40M2 receives a control signal from the controller 90, rotates the retraction movement portion 47 downward, and pushes down the engagement shaft portion 37 by the retraction movement portion 47, thereby moving the second housing portion 30 from the front position to the retracted position. move to

The suction device moving motor 40M3 generates driving force for moving the suction device 44 in the front-rear direction. The suction device moving motor 40M3 receives a control signal from the controller 90 to move the suction device 44 forward from the inside to the outside of the casing 41, and moves the suction device 44 to a position where the strip package 100 or the package 110 can be sucked. position. The suction device moving motor 40M3 receives a control signal from the controller 90 to move the suction device 44 backward into the casing 41 to take the sucked strip package 100 or package 110 into the casing 41.

The opening/closing motor 40M4 generates driving force for rotating the opening/closing bottom plate 48. As shown in FIG. The opening/closing motor 40M4 receives a control signal from the controller 90 to move the opening/closing bottom plate 48 to the closed position so that the strip package 100 and/or the package 110 can be received by the receiving portion 46 and stored in the receiving portion 46. do. The opening/closing motor 40M4 receives a control signal from the controller 90, moves the opening/closing bottom plate 48 to the open position, and drops the strip package 100 and/or the package 110 accommodated in the receiving section 46 to the conveying section 40. Eject from

The suction pump 40P is driven by receiving a control signal from the controller 90 to generate negative pressure. The negative pressure generated by the suction pump 40P is transmitted to the suction port 44A of the suction device 44, and the strip package 100 or the package 110 is sucked into the suction port 44A.

The cutting section 60 has a positioning section moving motor 60M1 and a cutting blade moving motor 60M2. Controller 90 controls motors 60M1-60M2 by outputting control signals to these motors 60M1-60M2. Cutting unit 60 cuts strip package 100 by appropriately driving and stopping motors 60M1 and 60M2.

The positioning portion moving motor 60M1 generates driving force for moving the positioning portion 66. As shown in FIG. The positioning section moving motor 60M1 receives a control signal from the controller 90 and moves the positioning section 66 relative to the wall section 62 to move the strip package 100 conveyed to the cutting section 60 and supported by the wall section 62 to the wall. It is moved along the portion 62 . The positioning unit moving motor 60M1 moves the strip package 100 to a cutting position corresponding to the size of the strip package 100 and positions the strip package 100 with respect to the cutter 64. FIG.

The cutting blade moving motor 60M2 generates driving force for moving the cutting blade 64A. The cutting blade moving motor 60M2 receives a control signal from the controller 90 and cuts the strip package 100 supported by the wall portion 62. As shown in FIG. When the strip package 100 is not cut, the cutting blade movement motor 60M2 positions the cutting blade 64A at a standby position spaced apart from the wall portion 62 by a certain distance.

The positioning section moving motor 60M3 generates driving force for moving the positioning section 66. As shown in FIG. The positioning portion moving motor 60M3 receives a control signal from the controller 90 to move the positioning portion 66 relative to the wall portion 62 to move the strip package 100 to the position for cutting, thereby moving the strip package to the cutter 64. The body 100 is positioned.

[Operation of medicine supply device 1]
The operation of taking out the strip package 100 and/or the package 110 from the drug container 10 and supplying it to the relay container 70 by the drug supply device 1 having the above configuration will be described below. FIG. 11 is a first flow chart showing the operation of taking out the package 110 by the medicine supply device 1. As shown in FIG.

First, in step S<b>11 , the conveying section 40 is moved to the corresponding medicine containing section 10 . The controller 90 outputs a control signal to the conveying portion moving motor 40M1 to move the conveying portion 40 to a position corresponding to the drug containing portion 10 from which the strip package 100 and/or the package 110 is to be taken out.

Next, in step S12, the controller 90 divides the required number of packages 110 dispensed from the medicine supply device 1 according to the prescription by a predetermined number (3 in the embodiment) of packages 110 contained in the strip package 100. to determine whether the required number is divisible by the predetermined number.

If it is determined that the required number of packages 110 is divisible (YES in step S12), the process proceeds to step S13, and the second container 30 is lowered. The controller 90 outputs a control signal to the retraction motor 40M2 to rotate the retraction movement portion 47 downward, thereby lowering the second housing portion 30 from the front position to the retraction position.

Next, in step S14, the strip package 100 in the first container 20 is picked up and taken out. Since the second accommodation portion 30 has been moved to the retracted position in the previous step S13, the second accommodation portion 30 is not in the front position, and the outlet 24 of the first accommodation portion 20 is accessible. The controller 90 outputs a control signal to the suction device moving motor 40M3 to move the suction device 44 forward and bring the suction port 44A into contact with the strip package 100. FIG. The controller 90 outputs a control signal to the suction pump 40P to generate a negative pressure to suck the strip package 100 to the suction port 44A. Further, the controller 90 outputs a control signal to the suction device moving motor 40M3 to move the suction device 44 rearward and take out the strip package 100 from the first container 20. FIG.

Next, in step S15, the removed strip package 100 is put into the receiving section 46. As shown in FIG. The controller 90 outputs a control signal to the suction device moving motor 40M3 to continue the rearward movement of the suction device 44 to move the suction device 44 to a position inside the casing 41 . Further, the controller 90 outputs a control signal to the suction pump 40P to stop the suction pump 40P. As a result, the strip package 100 is no longer attracted to the suction port 44A, and the strip package 100 falls under its own weight and is accommodated in the receiving portion 46. As shown in FIG.

Next, in step S16, the controller 90 determines whether or not the number of strip packages 100 taken out from the first container 20 has reached the quotient number calculated in step S12. If it is determined that the number of quotients has not yet been reached (NO in step S16), the process of taking out strip package 100 from first accommodating section 20 and putting it into receiving section 46 is repeated according to steps S14 and S15. be

If it is determined that the number of quotients has been reached (YES in step S16), all of the necessary number of packages 110 have been taken out and put into the receiving section 46, so the process proceeds to step S17, and the second accommodation is performed. Return the section 30 to its original forward position. The controller 90 outputs a control signal to the retraction motor 40M2 to rotate the retraction operation section 47 upward. The force pushing down the second accommodation portion 30 transmitted from the retracting motion portion 47 to the second accommodation portion 30 via the engagement shaft portion 37 is released, and the force of the biasing spring provided on the first link shaft 28 , the second housing portion 30 moves from the retracted position to the forward position.

Next, in step S<b>18 , the conveying section 40 is moved to the relay container 70 . The controller 90 outputs a control signal to the transport section moving motor 40M1 to move the transport section 40 downward and move the transport section 40 to a position above the relay container 70 .

Next, in step S19, the strip package 100 in the receiving portion 46 is supplied to the relay container 70. As shown in FIG. The controller 90 outputs a control signal to the open/close motor 40M4 to move the open/close bottom plate 48 from the closed position to the open position, drop the strip package 100 accommodated in the receiving portion 46 from the receiving portion 46, and It is supplied to the relay container 70 .

If it is determined in step S12 that the required number of packages 110 is not divisible by the predetermined number of packages 110 included in the strip package 100 (NO in step S12), the process proceeds to step S20, where the second storage unit A determination is made whether there is a package 110 in 30 . Based on the information about the number of packages 110 in the second container 30 input from the detection device 54, the controller 90 determines whether there are any packages 110 in the second container 30 (the number of packages 110 contained is 1 or more). or not).

FIG. 12 is a second flow chart showing the operation of taking out the package 110 by the medicine supply device 1. As shown in FIG. If it is determined in step S20 that there is a package 110 in the second accommodation unit 30 (the number of accommodation is 1 or more) (YES in step S20), the process proceeds to step S21 via the connector 1, and the second accommodation unit 30 It is determined whether the number of packages 110 in portion 30 is greater than the fraction. The controller 90 compares the remainder (also referred to as a fraction) calculated in step S12 with the number of packages 110 stored in the second storage section 30 to determine the number of packages 110 stored. Determine whether or not it is greater than the number of remainders.

If it is determined that the number of packages 110 contained is greater than the remainder (YES in step S21), the process proceeds to step S22, and controller 90 determines that the number of quotients calculated in step S12 is 1 or more. or not.

If it is determined that the number of quotients is 1 or more (YES in step S22), then in step S23, second accommodation section 30 is lowered. At step S24, the strip package 100 in the first container 20 is picked up and taken out. In step S25, the removed strip package 100 is put into the receiving section 46. As shown in FIG. In step S26, it is determined whether or not the number of strip packages 100 taken out from the first container 20 has reached the quotient number calculated in step S12. In step S27, the second housing portion 30 is put back. The processing in steps S23 to S27 is the same as the processing described in steps S13 to S17.

If it is determined in step S22 that the number of quotients is less than 1, that is, the number of quotients is zero (NO in step S22), the processing of steps S23 to S27 is not performed, and the process proceeds to the next step S28.

Next, in step S28, the package 110 in the second container 30 is picked up and taken out. Since the second accommodation portion 30 has been moved to the front position in the previous step S27, the second accommodation portion 30 is in an accessible state. The controller 90 outputs a control signal to the suction device moving motor 40M3 to move the suction device 44 forward and bring the suction port 44A into contact with the package 110. As shown in FIG. The controller 90 outputs a control signal to the suction pump 40P to generate a negative pressure to suck the package 110 to the suction port 44A. Further, the controller 90 outputs a control signal to the suction device moving motor 40M3 to move the suction device 44 backward and take out the package 110 from the second container 30. FIG.

Next, at step S29, the controller 90 determines whether or not there is a strip package 100 in the receiver 46. FIG. If the processing of the previous step S25 has been performed, it means that the strip package 100 is present in the receiving portion 46. FIG. In other words, if the determination at step S22 determines that the quotient number is greater than or equal to 1, then there is a strip package 100 in the receptacle 46, and if the determination at step S22 determines that the quotient number is zero, the receptacle There will be no strip package 100 in 46 .

If it is determined that there is a strip package 100 in the receiving section 46 (YES in step S29), then in step S30, the conveying section 40 is moved to the relay container . At step S31, the strip package 100 in the receiving portion 46 is supplied to the relay container 70. As shown in FIG. The processing in steps S30-S31 is the same as the processing described in steps S18-S19.

If it is determined in step S29 that there is no strip package 100 in the receiving section 46 (NO in step S29), the processing of steps S30 to S31 is not performed, and the process proceeds to the next step S32. During the processing of steps S29 to S31, the package 110 taken out from the second container 30 in step S28 is sucked by the suction device 44 and held.

Next, in step S<b>32 , the conveying section 40 is moved to the cutting section 60 . The controller 90 outputs a control signal to the transport section moving motor 40M1 to move the transport section 40 to the cutting section 60. FIG.

Next, in step S33, the adsorbed package 110 is transferred to the cutting section 60. As shown in FIG. The controller 90 outputs a control signal to the suction device moving motor 40M3 to move the suction device 44 forward and cause the cutting section 60 to support the package 110 sucked by the suction port 44A. The controller 90 outputs a control signal to the suction pump 40P to stop the suction pump 40P. As a result, the package 110 is no longer attracted to the suction port 44</b>A, and the package 110 is handed over to the cutting section 60 . Further, the controller 90 outputs a control signal to the suction device moving motor 40M3 to move the suction device 44 rearward to a position where the operation of the cutting section 60 is not hindered.

Next, in step S34, it is determined whether or not the cutting of the package 110 has been completed. The controller 90 outputs an appropriate control signal to the positioning portion moving motor 60M1 to move the positioning portion 66 along the wall portion 62 and move the package 110 relative to the cutter 64. Align the cutting blade 64A to the appropriate cutting position in .

The controller 90 outputs a control signal to the cutting blade moving motor 60M2 to move the cutting blade 64A. The cutting blade 64A reciprocates so as to move toward the wall portion 62 and then move away from the wall portion 62 . Thereby, the cutting unit 60 divides the package 110 into a first cut body 102A to be delivered and a second cut body 102B not to be delivered. The medicine supply device 1 may be configured such that the first cut body 102A falls from the cutting section 60 to the relay container 70 by its own weight. Alternatively, the medicine supply device 1 may be configured such that the conveying section 40 sucks the first cut body 102A and conveys it from the cutting section 60 to the relay container 70 .

When the first cut body 102A cut by the cutting section 60 moves into the relay container 70, it is determined that the cutting of the package 110 is completed (YES in step S34).

When the cutting of the package 110 is completed, the conveying section 40 receives the package 110 remaining in the cutting section 60, that is, the second cut body 102B, from the cutting section 60 in step S35. The controller 90 outputs a control signal to the suction device moving motor 40M3 to move the suction device 44 forward and bring the suction port 44A into contact with the second cut body 102B. The controller 90 outputs a control signal to the suction pump 40P to generate a negative pressure to suck the second cut body 102B to the suction port 44A. Further, the controller 90 outputs a control signal to the suction device moving motor 40M3 to move the suction device 44 backward to receive the second cut body 102B from the cutting section 60. As shown in FIG.

Next, in step S36, the conveying section 40 is moved to the corresponding drug containing section 10. As shown in FIG. The controller 90 outputs a control signal to the conveying portion moving motor 40M1 to return the conveying portion 40 to the position corresponding to the drug containing portion 10 from which the package 110 was taken out.

Next, in step S<b>37 , the adsorbed package 110 (second cut body 102</b>B) is returned to the second storage section 30 . The controller 90 outputs a control signal to the suction device moving motor 40M3 to move the suction device 44 forward and cause the second container 30 to support the package 110 sucked by the suction port 44A. The controller 90 outputs a control signal to the suction pump 40P to stop the suction pump 40P. As a result, the package 110 is no longer attracted to the suction port 44</b>A, and the package 110 is returned to the second container 30 . Further, the controller 90 outputs a control signal to the suction device moving motor 40M3 to move the suction device 44 rearward to a position inside the casing 41 .

FIG. 13 is a third flow chart showing the operation of taking out the package 110 by the medicine supply device 1. As shown in FIG. If it is determined in step S21 that the number of packages 110 in second container 30 is equal to or less than the fraction (NO in step S21), the process proceeds to step S38 via connector 4, and second container 30 It is determined whether the number of packages 110 inside is the same as the fraction. The controller 90 compares the remainder (fraction) calculated in step S12 with the number of packages 110 accommodated in the second container 30, and determines that the number of packages 110 accommodated is the remainder. Determine if they are the same.

If it is determined that the number of packages 110 contained is the same as the remainder (YES in step S38), then in step S39 is the number of quotients calculated in step S12 equal to or greater than 1? determine whether or not In step S40, the second housing portion 30 is lowered. In step S41, the strip package 100 in the first container 20 is picked up and taken out. In step S42, the removed strip package 100 is put into the receiving section 46. As shown in FIG. In step S43, it is determined whether or not the number of strip packages 100 taken out from the first container 20 has reached the quotient number calculated in step S12. In step S44, the second housing portion 30 is put back. The processing in steps S39 to S44 is the same as the processing described in steps S22 to S27.

Next, in step S45, the package 110 in the second container 30 is picked up and taken out. Since the second housing portion 30 has been moved to the front position in the previous step S44, the second housing portion 30 is accessible. The controller 90 outputs a control signal to the suction device moving motor 40M3 to move the suction device 44 forward and bring the suction port 44A into contact with the package 110. As shown in FIG. The controller 90 outputs a control signal to the suction pump 40P to generate a negative pressure to suck the package 110 to the suction port 44A. Further, the controller 90 outputs a control signal to the suction device moving motor 40M3 to move the suction device 44 backward and take out the package 110 from the second container 30. FIG.

Next, in step S46, the package 110 taken out is thrown into the receiving section 46. As shown in FIG. The controller 90 outputs a control signal to the suction device moving motor 40M3 to continue the rearward movement of the suction device 44 to move the suction device 44 to a position inside the casing 41 . Further, the controller 90 outputs a control signal to the suction pump 40P to stop the suction pump 40P. As a result, the package 110 is no longer attracted to the suction port 44A, and the package 110 falls under its own weight and is accommodated in the receiving portion 46. As shown in FIG.

Next, in step S47, the conveying section 40 is moved to the relay container 70. As shown in FIG. The controller 90 outputs a control signal to the transport section moving motor 40M1 to move the transport section 40 to a position above the relay container 70 .

Next, in step S48, the package 110 in the receiving portion 46 is supplied to the relay container 70. As shown in FIG. The controller 90 outputs a control signal to the open/close motor 40M4 to move the open/close bottom plate 48 from the closed position to the open position, drop the package 110 accommodated in the receiving portion 46 from the receiving portion 46, and Feed into container 70 .

FIG. 14 is a fourth flow chart showing the operation of taking out the package 110 by the medicine supply device 1. As shown in FIG. If it is determined in step S38 that the number of packages 110 in the second storage unit 30 is not the same as the fraction (NO in step S38), the second storage unit It is determined that the number of packages 110 contained in 30 is smaller than the fraction (number of remainders).

In this case, the process proceeds to step S49 via the connector 5, and the package 110 in the second container 30 is sucked and taken out. At this time, the process of lowering the second housing portion 30 is not performed, the second housing portion 30 remains in the front position, and the second housing portion 30 is accessible. Next, in step S50, the package 110 taken out is thrown into the receiving section 46. As shown in FIG. The processing in steps S49 to S50 is the same as the processing described in steps S45 to S46.

Next, in step S51, the second housing portion 30 is lowered. The processing in step S51 is the same as the processing described in step S13 above.

Next, in step S52, it is determined whether or not the number of quotients calculated in step S12 is 1 or more. The processing in step S52 is the same as the processing described in step S22 above.

Next, in step S53, the strip package 100 in the first container 20 is picked up and taken out. In step S54, the removed strip package 100 is put into the receiving section 46. As shown in FIG. In step S55, it is determined whether or not the number of strip packages 100 taken out from the first container 20 has reached the quotient number calculated in step S12. The processing in steps S53 to S55 is the same as the processing described in steps S14 to S16 above.

Next, in step S56, the strip package 100 in the first container 20 is picked up and taken out. The processing in step S56 is the same as the processing described in step S14 above. By taking out the strip packages 100 in step S53 and taking out the strip packages 100 in step S56, the number of strip packages 100 obtained by adding 1 to the quotient calculated in step S12 is will be taken out from

Next, in step S57, the second housing portion 30 is returned to the original front position. In step S<b>58 , the transport section 40 is moved to the relay container 70 . In step S<b>59 , the package 110 in the receiving portion 46 is supplied to the relay container 70 . The processing in steps S57 to S59 is the same as the processing described in steps S17 to S19 above. In this case, since both the package 110 put into the receiving portion 46 in step S50 and the strip package 100 put into the receiving portion 46 in step S54 are accommodated in the receiving portion 46, step At S59, both the package 110 and the strip package 100 are supplied from the receiver 46 to the relay container 70. As shown in FIG.

Next, in step S<b>60 , the conveying section 40 is moved to the cutting section 60 . The processing in step S60 is the same as the processing described in step S32 above.

Next, in step S61, the sucked strip package 100 is transferred to the cutting section 60. As shown in FIG. At step S62, it is determined whether or not the strip package 100 has been cut. In step S<b>63 , the package 110 remaining on the cutting section 60 is sucked and received from the cutting section 60 . In step S64, the conveying section 40 is moved to the corresponding drug containing section 10. As shown in FIG. In step S<b>65 , the sucked package 110 is returned to the second container 30 . The processing in steps S61 to S65 is the same as the processing described in steps S33 to S37 above, except that the object to be cut is changed from the package 110 to the strip package 100. FIG.

FIG. 15 is a fifth flow chart showing the operation of taking out the package 110 by the medicine supply device 1. As shown in FIG. If it is determined in step S20 that there is no package 110 in the second housing portion 30 (the number of housing units is zero) (NO in step S20), the process proceeds to step S66 via the connector 2, and the second housing portion 30 is lowered. In step S67, it is determined whether or not the number of quotients calculated in step S12 is one or more. At step S68, the strip package 100 in the first container 20 is picked up and taken out.

In step S69, the removed strip package 100 is put into the receiving section 46. As shown in FIG. In step S70, it is determined whether or not the number of strip packages 100 taken out from the first container 20 has reached the quotient number calculated in step S12. At step S71, the strip package 100 in the first container 20 is picked up and taken out. In step S72, the second housing portion 30 is returned to its original forward position. The processing in steps S66 to S72 is the same as the processing described in steps S51 to S57.

Next, in step S73, it is determined whether or not there is a strip package 100 in the receiving portion 46. As shown in FIG. In step S<b>74 , the transport section 40 is moved to the relay container 70 . At step S 75 , the strip package 100 in the receiving portion 46 is supplied to the relay container 70 . The processing in steps S73 to S75 is the same as the processing described in steps S29 to S31.

Next, in step S76, the conveying section 40 is moved to the cutting section 60. As shown in FIG. At step S 77 , the sucked strip package 100 is passed to the cutting section 60 . At step S78, it is determined whether or not the strip package 100 has been cut. In step S<b>79 , the package 110 remaining on the cutting section 60 is sucked and received from the cutting section 60 . In step S<b>80 , the conveying section 40 is moved to the corresponding drug containing section 10 . In step S<b>81 , the adsorbed package 110 is returned to the second container 30 . The processing in steps S76 to S81 is the same as the processing described in steps S60 to S65.

Thus, upon completion of the processing in steps S19, S37, S48, S65, or S81, the strip package 100 and/or package 110 is taken out from the drug container 10 and supplied to the relay container 70. is terminated (“End” in FIG. 11).

[Action and effect]
Next, the operation and effects of this embodiment will be described.

As shown in FIG. 8, the medicine supply device 1 of this embodiment includes a cutting section 60 that cuts the strip package 100 taken out from the first storage section 20 by the conveying section 40 . As shown in FIG. 1 , the cutting section 60 is provided separately from the conveying section 40 and attached to the housing 2 .

If the cutting section 60 is integrated with the transporting section 40, the cutting section 60 will also move when the transporting section 40 moves, so it is necessary to secure a space for the movement of the cutting section 60. . By providing the cutting section 60 separately from the conveying section 40 instead of forming it integrally with the conveying section 40 as in the embodiment, a space for moving the cutting section 60 can be made unnecessary. Therefore, the conveying part 40 can be formed in a small size, and thus the whole medicine supply device 1 can be made small.

As shown in FIG. 8 , the cutting section 60 has a positioning section 66 for positioning the strip package 100 conveyed from the first storage section 20 to the cutting section 60 by the conveying section 40 . Since the positioning portion 66 for positioning the strip package 100 is provided in the cutting portion 60 instead of the conveying portion 40, the conveying portion 40 can be formed in a small size. be able to.

As shown in FIG. 9, the drug supply device 1 has a memory 91 that stores the dimensions of the package 110. As shown in FIG. The positioning unit 66 positions the strip package 100 based on the dimensions of the package 110 stored in the memory 91 . In this way, it is possible to cut at an appropriate position for each type of package 110 .

As shown in FIG. 9 , the drug supply device 1 includes an imaging device 52 for imaging the strip package 100 . The positioning unit 66 determines the position of the strip package 100 based on the imaging information of the strip package 100 captured by the imaging device 52 . In this way, it is possible to cut at an appropriate position for each type of package 110 .

As shown in FIG. 2, the strip package 100 is integrally constructed by arranging a predetermined number of packages 110 . As shown in FIG. 5, the drug supply device 1 further includes a second storage section 30 that stores less than the predetermined number of packages 110 described above. According to such a configuration, the strip package 100 composed of the predetermined number of packages 110 can be accommodated in the first storage section 20, and the fractional number of packages 110 less than the predetermined number can be accommodated in the second storage section 30. can do.

As shown in FIG. 9, the cutting section 60 divides the strip package 100 into a first cut body 102A to be dispensed and a second cut body 102B not to be dispensed. The transport section 40 moves the second cut body 102B from the cutting section 60 to the second storage section 30 . Since the second cut body 102B remaining after cutting can be effectively used and the waste of the packaging body 110 can be reduced, the medicine supply device 1 with low running cost can be realized.

As shown in FIGS. 4 and 10 , the medicine supply device 1 further includes a detection device 54 that detects the number of packages 110 contained in the second container 30 . According to such a configuration, based on the number of packages 110 contained in the second container 30 and the required number of packages 110 to be dispensed from the medicine supply device 1 according to the prescription, the strip packaging in the first container 20 is determined. It can be determined whether to take out the body 100 first or to take out the package 110 in the second container 30 first. In this way, wasteful operations of the medicine supply device 1 can be reduced, so that the efficiency of the take-out work can be improved.

Although the embodiments have been described above, it should be considered that the embodiments disclosed this time are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the scope of the claims rather than the above description, and is intended to include all changes within the meaning and scope equivalent to the scope of the claims.

Reference Signs List 1 medicine supply device 2 housing 10 medicine container 20 first container 21 cassette 22 bottom surface 23, 33 side wall 23A window 24 outlet 25 stop 25A lower stop 25B side stopping portion 25C holding portion 26 moving operation portion 27 movable member 28 first link shaft 29 link portion 30 second housing portion 32 bottom portion 34A inclined wall 34B standing wall 37 engaging shaft portion 38 second link shaft, 40 conveying unit, 40M1 to 40M4, 60M1 to 60M2 motor, 40P pump, 41 casing, 42 intake port, 44 suction device, 44A suction port, 45 slope, 46 receiving portion, 47 evacuation operation portion, 48 Opening/Closing Bottom Plate 52 Imaging Device 54 Detecting Device 60 Cutting Part 62 Wall Part 64 Cutter 64A Cutting Blade 66 Positioning Part 70 Relay Container 80 Dispensing Tray 90 Controller 91 Memory 92 Operation Part 100 Strip Package 102A First cut 102B Second cut 110 Package 112 Sealing portion 114 Perforation 200 Medicine.

Claims (5)

In a drug supply device that accommodates a strip package and dispenses the strip package according to a prescription,
The strip package has a predetermined number of two or more packages in which a drug is individually packaged, and the predetermined number of packages are arranged in a line and integrally constructed,
The drug supply device is
a first container for containing the strip package;
a second storage unit that stores less than the predetermined number of packages;
a cutting unit that divides the strip package into a first cut to be dispensed and a second cut not to be dispensed by cutting the strip package;
a conveying unit that moves the strip package from the first storage unit to the cutting unit and moves the second cut body from the cutting unit to the second storage unit ;
A housing that houses the first storage unit, the second storage unit, the transport unit, and the cutting unit,
The medicine supply device, wherein the cutting section is provided separately from the conveying section and attached to the housing. 2. The medicine supply device according to claim 1, wherein said cutting section has a positioning section that determines the position of said strip package conveyed from said first storage section to said cutting section by said conveying section. Further comprising a memory for storing the dimensions of the package,
3. The drug supply device according to claim 2, wherein the positioning part positions the strip package based on the dimensions. Further comprising an imaging device for imaging the strip package,
3. The drug supply device according to claim 2, wherein the positioning unit positions the strip package based on imaging information of the strip package imaged by the imaging device. The medicine supply device according to any one of claims 1 to 4 , further comprising a detection device that detects the number of the packages contained in the second container.

Images