JP2021019938A - Medication support device - Google Patents

Abstract

To provide one medication pack by surely detecting a boundary of medication packs from pack continuums in which a plurality of medication packs are in a row like a belt.SOLUTION: The medication support device includes: a first transportation part 10 that transports, in a transporting direction A, pack continuums 1 in which a plurality of medication packs 2, having respectively bag parts for covering medicines and crimp parts 4 for preventing medicines from leaking out of the bag parts, are in a row like a belt; a detection part 27 for detecting boundary part which are formed by the crimp parts 4, 4 of the medication parts 2, 2 that are adjacent in the transportation direction A in the pack continuums 1; a cut part 30 which, in the prescribed position of the boundary parts, cuts the pack continuums 1 to separate into single medication packs 2; and a CPU of a control part which, based on a signal from the detection part 27, controls the cut part 30 to cut the boundary part at the prescribed position of the pack continuums 1. The detection part 27 discriminates the bag part and the crimp part 4 of the pack continuums 1, which are transported by the first transportation part 10, as well as detecting the boundaries.SELECTED DRAWING: Figure 1

Description

The present invention relates to a medication support device.

A device is known that detects and cuts the boundary position of a pouch continuum in which a plurality of pouches are connected in a strip shape (see, for example, Patent Document 1). In Patent Document 1, as a detection means for detecting the cut position, a means for detecting the thickness of the pouch continuum is adopted.

A drug-packed pack in which a drug is packaged is composed of a bag portion for containing the drug and a boundary portion between the packs. The boundary portion is formed by crimping the films together.
However, the films forming the bag portion are easily charged with static electricity, and in most cases, the bag portions are in close contact with each other due to static electricity. Therefore, there is a problem that the difference in thickness between the bag portion and the boundary portion cannot be detected.

The present invention has been made in view of the above circumstances, and one can reliably detect the boundary portion of a drug-packed pack from a pack continuum in which a plurality of drug-packed packs are connected in a band shape. It is intended to provide a one-pack drug pack for the minute.

In order to achieve the above object, in the present invention, a plurality of drug packaging packs each having a bag portion for covering the drug and a leak prevention portion for preventing the drug from leaking from the bag portion are connected in a band shape. A transporting means for transporting the pack continuum in the transport direction, a detection means for detecting a boundary portion formed by the leakage prevention portion of the drug-packed pack adjacent to the pack continuum in the transport direction, and the pack. The cutting means for cutting the continuum at a predetermined position of the boundary portion and separating the continuum into one drug-packed pack, and the boundary portion so as to cut the boundary portion at the predetermined position based on the signal from the detection means. The detection means includes a control means for controlling the cutting means, and the detection means identifies the bag portion and the leakage prevention portion of the pack continuum transported by the transport means, and detects the boundary portion. It is in the support device.

According to the present invention, the boundary portion of a drug-packed pack is reliably detected from a pack continuum in which a plurality of drug-packed packs are connected in a band shape, and one drug-packed pack is provided. be able to.

It is sectional drawing which shows typically the whole structure including the transport path of the pack continuum of the medication support device which concerns on Embodiment 1 of this invention. It is a figure which shows the drug package pack and the pack continuum used for the medication support device which concerns on Embodiment 1. FIG. It is a control block diagram which shows the main control composition of the medication support device which concerns on Embodiment 1. FIG. (A) is a diagram for explaining Example 1, a schematic diagram for explaining the stop position of the drug-packed pack of the pack continuum before cutting, and (b) is a diagram for explaining Example 1. It is a schematic diagram explaining the positional relationship of the 1st transport part, the detection part, and the cut part when the drug package pack of a pack continuum is cut by a cut part. It is a figure explaining Example 1, and is the timing chart at the time of cutting at the substantially central part of the boundary part of the drug-packed pack of a pack continuum. (A) is a schematic diagram of a pack continuum after cutting one drug-packed pack, and (b) is a diagram for explaining Example 2, in which the drug-packed pack of the pack continuum is cut. It is a schematic diagram which transports a pack continuum to a home position after that. (A) is a diagram for explaining Example 3, and is a schematic diagram showing a cut position of the pack continuum and an appropriate arrangement configuration of a detection unit (tip detection sensor, boundary sensor). (B) and (c) are schematic views showing the cut position of the pack continuum and the improper arrangement configuration of the detection unit (tip detection sensor, boundary sensor). It is a flowchart of the initial operation explaining Example 4. It is sectional drawing which shows typically the whole structure including the transport path of the pack continuum of the medication support device which concerns on Embodiment 2 of this invention. It is a top view of the main part of the medication support device which concerns on Embodiment 2. It is a perspective view of the main part of the medication support device which concerns on Embodiment 2. FIG. (A) is a perspective view of a main part of the medication support device according to the second embodiment, and (b) is a plan view of the entire (a). It is a control block diagram which shows the main control composition of the medication support device which concerns on Embodiment 2. It is a flowchart of the operation which provides the drug package pack for one time by the medication support device which concerns on Embodiment 2. It is a perspective view of the main part of the medication support device to which this invention is applied. It is a perspective view of the whole medication support device to which this invention is applied. It is sectional drawing of the main part which shows the structure of the 1st transport part used for the medication support device to which this invention is applied.

(Embodiment 1)
Hereinafter, embodiments of the present invention including examples will be described in detail with reference to the drawings. In each embodiment, each embodiment, etc., components (members, components), etc. having the same function and shape, etc. will be described by giving the same reference numerals after being described once unless there is a risk of confusion. Is omitted.
The basic configuration and operation of the medication support device according to the first embodiment of the present invention will be described with reference to FIGS. 1 to 3. FIG. 1 is a cross-sectional view schematically showing an overall configuration including a transport path of a pack continuum of the medication support device according to the first embodiment of the present invention. FIG. 2 is a diagram showing a drug-packed pack and a pack continuum used in the medication support device according to the first embodiment. FIG. 3 is a control block diagram showing a main control configuration of the medication support device according to the first embodiment.

As shown in FIG. 1, the medication support device 100 includes a storage unit 6 for storing the pack continuum 1, a first transport unit 10, a cut portion 30, a second transport unit 20, and a discharge unit 35. ing. The storage unit 6 may be configured to be detachable from the main body of the medication support device 100, and in this case, it is also called a cartridge.
Further, in the medication support device 100, each part / device is covered with an exterior (not shown), but in each figure, the exterior is shown in a removed state.

As shown in FIGS. 1 and 2, the pack continuum 1 used in the first embodiment refers to a state in which a plurality of drug-packed packs 2 (for four doses in FIG. 2) are connected in a band shape. The pack continuum 1 is usually provided and sold to a drug recipient at a pharmacy or the like, and the required number of doses to the drug recipient is cut into a continuous sheet shape. In one drug package pack 2, the drug 3 such as capsules and tablets is divided into small pieces and packed in a bag, and the bag portion 2a covering the drug 3 and the drug 3 are prevented from leaking from the bag portion 2a. Each has a three-sided crimping portion 4 forming a leak prevention portion. One drug package pack 2 is usually a single dose unit for the person taking the drug.

The drug package pack 2 is formed of, for example, a resin film, has a rectangular shape in a plan view in the example shown in FIG. 2, and has three sides crimped or crimped or as shown by hatching (diagonal lines) in FIG. It is a welded crimping portion 4, and is packed in a bag so that the drug 3 does not leak. The crimping portion 4 has a band-shaped width of about 10 to 15 mm, and has higher rigidity than the transparent or translucent film-shaped bag portion 2a in which the drug 3 can be visually recognized. A perforation 5 is provided at the center of the crimping portions 4 and 4 of the drug packaging pack 2 adjacent to the pack continuum transport direction A, and one drug can be torn by hand by a person who takes the drug freely. It is possible to separate and separate into one package pack 2.

As shown in FIG. 2, the boundary portion 2b is formed by the crimping portions 4 and 4 of the drug-packed pack 2 adjacent to each other in the pack continuum transport direction A. As will be described later, when the pack continuum 1 is transported to the downstream side of the pack continuum transport direction A by the first transport unit 10, the drug-packed pack located at the rightmost end of FIG. 2 in the pack continuum 1 It is shown that the end portion of the crimping portion 4 of 2 is the tip portion 2c of the pack continuum 1. That is, as will be described later, the crimping portion 4 at the most downstream end of the drug-packed pack 2 located at the most downstream of the pack continuum transport direction A of the pack continuum 1 is the tip portion 2c.
Unless otherwise specified, the plurality of drug-packed packs 2 constituting the pack continuum 1 shown in the following figures are assumed to have the same size in the pack continuum transport direction A.

As shown in FIG. 1, the storage portion 6 is formed with an opening 7 through which the pack continuum 1 is passed. The storage unit 6 has a substantially rectangular parallelepiped shape. In the storage unit 6, the thickness of the storage unit wall (storage wall) is omitted for the sake of simplification of the drawing. In the example of FIG. 1, a single storage unit 6 is illustrated for the sake of simplicity of description, but a plurality of storage units 6 may be arranged.

In the storage unit 6, for example, a pack continuum 1 corresponding to four types of medicines to be taken in the morning, noon, night, and before going to bed is stored.
The method of storing the pack continuum 1 in the storage unit 6 is that the pack continuum 1 is folded in a zigzag shape in the vertical direction in FIG. 1, but it may be stored in a roll shape in the left-right direction due to reasons such as a margin of storage space. You may.

As shown in FIG. 1, the first transport unit 10 includes a drive-side transport roller 11a and a driven-side transport roller 11b, which are a pair of rotary transport members. The first transport unit 10 functions as a first transport means provided in the storage unit 6. The first transport unit 10 conveys the tip end portion of the pack continuum 1 through the opening 7 of the storage unit 6 from the inside to the outside of the storage unit 6 or from the outside to the inside. Functions as a means of transporting.

The transport rollers 11a and 11b are rotatably supported by the wall portion of the storage portion 6 via a rotation shaft, respectively. The driving force transmission mechanism for transmitting the driving force to the first transport unit 10 is composed of a storage unit side driving force transmission mechanism provided on the storage unit 6 side and a device main body side driving force transmission mechanism provided on the device main body side. Become. The storage unit-side driving force transmission mechanism provided on the storage unit 6 side includes a rotating shaft 12 fixed to the transport roller 11a and a bevel gear which is a driven bevel gear fixed to one end of the rotating shaft 12. A bevel gear 14 on the drive side that meshes with the bevel gear 13, a rotatable shaft 15 whose one end is fixed to the bevel gear 14, and a driven gear 16 fixed to the other end of the shaft 15. ..

As the device body side driving force transmission mechanism provided on the device body side, a drive gear 17 provided on the device body side that meshes with the driven gear 16 and a single drive gear 17 as a drive source fixed to the output shaft. It has the first transfer motor 18 of the above. The first transfer motor 18 is composed of, for example, a stepping motor that can be rotationally driven in both forward and reverse directions by inputting a drive pulse, and is fixed to the apparatus main body side.

The pair of bevel gears 13 and 14, the shaft 15, the driven gear 16, and the drive gear 17 are drive transmission means / drive transmission members that transmit a driving force to the transfer roller 11a via the rotating shaft 12. The shaft 15 is rotatably supported by bearings. The rotating shaft 12 and the bevel gear 13 are fixed to the storage portion 6, and the bevel gear 14, the shaft 15, and the driven gear 16 are supported by the outer wall portion of the storage portion 6.

The pair of transport rollers 11a and 11b are also holding members that hold the tip end portions of the pack continuum 1. That is, with respect to the tip of the pack continuum 1 stored in advance in the storage portion 6, the crimping portion of the pack continuum 1 is usually formed by the transfer roller 11a and the transfer roller 11b at a pharmacy or by a medication person or a medication supporter. A set holding operation is performed in which the tip portion of 4 is sandwiched and held.
The transport rollers 11a and 11b have both a function of contacting and transporting the crimping portion 4 which is one end portion in a direction orthogonal to the transport direction of the pack continuum 1 and a role as the holding member.

As described above, the first transport unit 10 can transport the tip end portion of the pack continuum 1 stored inside the storage unit 6 to the outside of the storage unit 6 and discharge the pack continuum 1. Then, when the medication user gives an instruction to discharge the drug package pack 2, for example, when the first transfer motor 18 rotates in the normal direction, the transfer rollers 11a and 11b rotate in the normal direction via the above-mentioned drive transmission members and are stored. The pack continuum 1 stored inside the unit 6 is sent out and transported from the opening 7 to the outside of the storage unit 6.
By switching the rotation direction of the first transfer motor 18 to, for example, the reverse direction, the extra pack continuum 1 can be returned to the inside of the storage unit 6 and stored without any problem until the next transfer.

The cut portion 30 functions as a cutting means for cutting the pack continuum 1 at a predetermined position on the boundary portion 2b and separating the pack continuum 1 into one drug-packed pack 2. That is, the cut portion 30 is a cutting means for cutting and separating the pack continuum 1 transported by the first transport unit 10 into one drug-packed pack 2. The cut portion 30 is installed at a predetermined position on the device main body side so that the pack continuum 1 transported by the first transport unit 10 of the storage unit 6 can be cut.

The cutting portion 30 is composed of a cutter module having a pair of sharp blades and having at least one of the blades movable up and down. Cutter modules are commercially available and inexpensive.
The cut portion 30 is not limited to the cutter module, and may be of a type in which the rotary blade is raised and lowered by a cutter motor. Further, a method of separating at the perforation 5 of the drug packaging pack 2 by changing the transport speed between the transport rollers of the first transport unit 10 and the second transport unit 20 or by gripping in the opposite direction, or other methods. A cutting method may also be used as needed, and any means may be used as long as the drug-packed pack 2 can be separated by the crimping portions 4 existing in the entire direction orthogonal to the transport direction of the pack continuum 1.

The second transport unit 20 functions as a transport means for transporting the tip end portion of the pack continuum 1 to the outside of the storage portion 6 through the opening 7 of the storage unit 6, and the pack continuum body is more than the first transport unit 10. It also functions as a second transport means arranged downstream of the transport direction A. The second transport unit 20 includes a drive-side transport roller 21a and a driven-side transport roller 21b, which are a pair of rotary transport members. The second transport unit 20 is provided at a predetermined position on the device main body side outside the storage unit 6.

The transport rollers 21a and 21b are rotatably supported by an immovable member on the device main body side via a rotation shaft, respectively. The mechanisms for transmitting the driving force to the second transport unit 20 are a driven pulley 21c fixed to the transport roller 21a, a second transport motor 25 as a drive source in which the drive pulley 25a is fixed to the output shaft, and a drive pulley 25a. And a belt 26 bridged to the driven pulley 21c. The second transfer motor 25 is composed of, for example, a stepping motor that can be rotationally driven in both forward and reverse directions by inputting a drive pulse, and is fixed to the device main body side.
The transfer roller 21a forms a nip with the transfer roller 21b. The second transfer motor 25 is fixed to an immovable member on the device main body side.

The discharge unit 35 functions as a discharge means for receiving one drug package pack 2 cut and separated by the cut unit 30. The discharge section 35 is formed with a concave pack receiving section 36 capable of keeping one drug package pack 2 cut / separated and discharged at a position where it can be provided to the recipient. There is. The pack receiving unit 36 communicates with a pack taking-out port provided on the exterior (not shown) for the taking person to take out one discharged drug-packed pack 2.

The transport path from the storage portion to the discharge portion of the pack continuum will be described with reference to FIGS. 1 and 2. A detection unit 27 is arranged in the transport path 19 between the storage unit 6 and the cut unit 30. The detection unit 27 is arranged on the upstream side of the pack continuum transport direction A with respect to the cut unit 30. The transport path 19 is shown only in FIG. 1 for the sake of brevity, and is omitted in other drawings.
As shown in FIGS. 1 and 2, the detection unit 27 serves as a detection means for detecting the boundary portion 2b of FIG. 2 of the drug-packed packs 2 and 2 adjacent to the pack continuum transport direction A in the pack continuum 1. Has the function of.

The detection unit 27 distinguishes between the bag portion 2a of the pack continuum 1 transported by the first transport unit 10 and the crimping portions 4 and 4 of the drug-packed packs 2 and 2 adjacent to the pack continuum transport direction A. At the same time, it also has a function of detecting the boundary portion 2b of the drug-packed packs 2 and 2 adjacent to the pack continuum transport direction A in the pack continuum 1. Further, it also has a function of identifying the tip portion 2c of the pack continuum 1 and the boundary portion 2b of the drug-packed packs 2 and 2 adjacent to each other in the pack continuum transport direction A in the pack continuum 1.

The detection unit 27 includes a tip detection sensor 28 that detects the tip 2c, which is the end of the drug-packed pack 2 at the most downstream side of the pack continuum transport direction A in the pack continuum 1, and the pack continuum 1 in the pack continuum 1. It has a boundary sensor 29 that detects the boundary 2b of the adjacent drug packaging packs 2 and 2 in the body transport direction A.
The detection unit 27 has a tip detection sensor 28 and a boundary sensor 29 for the drug-packed pack 2 at the most downstream end of the pack continuum transport direction A of the pack continuum 1 conveyed by the first transport unit 10. And are installed in a unique arrangement. That is, the boundary sensor 29 and the tip detection sensor 28 are the bag portion 2a of the drug packaging pack 2 located at the most downstream of the pack continuum transport direction A of the pack continuum 1, and the most downstream end of the bag portion 2a. It is arranged so that the crimping portion 4 (tip portion 2c of the pack continuum 1) formed in the portion can be detected alternately.

The detection unit 27 is non-contact with the drug-packed pack 2 of the pack continuum 1 and is adjacent to the bag portion 2a of the pack continuum 1 transported by the first transport unit 10 in the pack continuum transport direction A. A person who identifies the crimping portions 4 and 4 of the drug packaging packs 2 and 2 and detects the boundary portion 2b of the drug packaging packs 2 and 2 adjacent to the pack continuum transport direction A in the pack continuum 1. However, it is preferable because it does not give a load to the drug 3.

The tip detection sensor 28 includes a light-reflecting photo sensor that optically detects the tip 2c of the pack continuum 1 without contacting the drug-packed pack 2 of the pack continuum 1, and a light-transmitting type. Photosensor is used.

An ultrasonic sensor is used as the boundary sensor 29. The ultrasonic sensor is a sensor that measures the distance from the detection target using ultrasonic waves, and is configured to read the attenuation rate of the ultrasonic waves with respect to the detection target. Since the bag portion 2a of the drug packaging pack 2 is sealed between the films via an air layer, the ultrasonic wave attenuation rate differs between the bag portion 2a of the drug packaging pack 2 and the crimping portion 4. The ultrasonic sensor reliably detects and distinguishes between the bag portion 2a and the crimping portion 4 by utilizing the difference in the attenuation rate of ultrasonic waves between the bag portion 2a and the crimping portion 4 of the drug packaging pack 2. Can be done.

However, the ultrasonic sensor detects the tip portion 2c of the continuous drug-packed pack 2 of the pack continuum 1 and the boundary portion 2b of the adjacent drug-packed packs 2 and 2 of the pack continuum 1. Cannot be identified. Therefore, the detection unit 27 requires the tip detection sensor 28 in addition to the boundary sensor 29 as described above.

On the other hand, if an area sensor such as a CCD, which is also an image sensor, is used as the detection unit 27, the tip portion of the drug-packed pack 2 located at the most downstream of the continuous pack continuum 1 can be used by using the image processing determination. The detection of 2c and the boundary portion 2b of the adjacent drug-packed packs 2 and 2 of the pack continuum 1 can be detected and identified. As a result, when the area sensor is used as the detection unit 27, the tip detection sensor 28 becomes unnecessary.

As a common advantage of the ultrasonic sensor and the area sensor, in the thickness detection sensor and the like disclosed in Patent Document 1, the films of the bag portion 2a may be stuck to each other by static electricity, and the pack continuum 1 Although it is difficult to detect and identify the boundary portion 2b of the adjacent drug packaging packs 2 and 2, both sensors can detect the boundary portion 2b.
Further, with both sensors, even if the drug packaging pack 2 is a transparent pack, the boundary portion 2b of the adjacent drug packaging packs 2 and 2 of the pack continuum 1 can be detected.
Further, since both sensors can detect without contact, there is an advantage that the drug 3 is not damaged.

The main control configuration of the medication support device 100 according to the first embodiment will be described with reference to FIG.
As shown in FIG. 3, the medication support device 100 has a control unit 50 incorporating a CPU (central processing unit), a storage unit 52, and a timer unit 56 that control the operation of each unit of the medication support device 100. The CPU may have a timer (timekeeping) function in addition to having a calculation and control function. The storage unit 52 includes a ROM (read-only memory), a RAM (memory that can be read and written at any time), an external memory, and the like. A program (for example, a timing chart and a control flowchart described later) that can be read by the CPU, data, and the like are stored in the ROM in advance. Examples of the above data include the medication time set in the storage unit.

A touch panel 51 is electrically connected to the input / output port of the control unit 50 as a user interface. On the touch panel 51, the medication person or the medication supporter can input the medication time, the storage unit selection, and the like, and the current time and the next medication timing are displayed. The touch panel 51 is not limited to this, and for example, the input unit and the display unit may be separate and a combination such as a keyboard and an LED display unit may be used.

The discharge switch 54, the tip detection sensor 28 provided as the detection unit 27 described above, the boundary sensor 29, and the discharge sensor 37 are electrically connected to the input port of the control unit 50. The discharge switch 54 is a so-called start switch for activating the medication support device 100 to activate the operation of discharging the target drug package pack 2 to the discharge unit 35, and is mainly performed by the medication person or the medication supporter. It is a switch to push. The discharge switch 54 is arranged on the front surface of the exterior (not shown) near the discharge portion 35 of the medication support device 100 so that the medication user or the like can easily press the discharge switch 54.
The discharge sensor 37 functions as a discharge pack detecting means for detecting that the cut drug package pack 2 has been transported / discharged to the discharge unit 35. The emission sensor 37 may be, for example, a reflection type sensor or various transmission type sensors having a receiving unit (not shown) installed at a position facing the reflection type sensor, or may be performed by image processing using a CCD sensor.

The notification unit 55, the first transfer motor 18 of the first transfer unit 10, the second transfer motor 25 of the second transfer unit 20, and the cutter motor 31 of the cut unit 30 are electrically connected to the output port of the control unit 50. ing.
The notification unit 55 notifies the medication time by sound or vibration including light and voice of an LED or the like, warns of forgetting to take the medication, or notifies the state of each of the above units. is there.

The first transfer motor 18 and the second transfer motor 25 are connected to the output port of the control unit 50 via their respective stepping motor drivers (described as STM drivers in the block diagram). The cutter motor 31 is connected to the output port of the control unit 50 via a DC motor driver (described as a DCM driver in the block diagram).

When various signals from the touch panel 51, the discharge switch 54, the tip detection sensor 28 of the detection unit 27, the boundary sensor 29, and the discharge sensor 37 are input to the CPU of the control unit 50, the CPU of the control unit 50 sends the input information. , The next command signal is output. That is, the CPU of the control unit 50 controls the display device of the touch panel 51, the audio device and the optical device of the notification unit 55, the STM drivers of the first transfer motor 18 and the second transfer motor 25, and the DCM driver of the cutter motor 31. A command signal is output, which is an instruction to do so.

The CPU of the control unit 50 cuts the boundary portion 2b of the adjacent drug packaging packs 2 and 2 of the pack continuum 1 at a predetermined position based on the signals from the tip detection sensor 28 and the boundary sensor 29. It has a function as a control means for controlling the motor 31.

Further, in the CPU of the control unit 50, based on the signals from the tip detection sensor 28 and the boundary sensor 29, the boundary portion 2b of the drug packaging packs 2 and 2 of the pack continuum 1 is set at the boundary portion 2b as a predetermined position. It has a function as a control means for controlling the cutter motor 31 so as to cut in the vicinity of the perforation 5 which is substantially the center of the above.

Further, when the CPU of the control unit 50 cuts the nth drug-packed pack 2 located at the most downstream of the pack continuum transport direction A from the pack continuum 1 by the cut unit 30, the pack continuation after being cut. The first transport motor 18 of the first transport unit 10 is controlled so as to transport the n + 1th drug-packed pack 2 located at the most downstream side of the body 1 to the upstream side in the transport direction of the pack continuum 1, and the pack It has a function as a control means for positioning the n + 1th drug package pack 2 located at the most downstream of the continuum 1 at a predetermined position.
In addition, the CPU of the control unit 50 has a function of executing the control operation shown in the description, the timing chart, or the control flowchart described later.

In the transport path of the pack continuum shown in FIG. 1, the arrangement position of each portion is predetermined up to the nip of the first transport portion 10, the cut portion 30, the nip of the second transport portion 20, and the discharge portion 35. .. Further, since the first transfer motor 18 and the second transfer motor 25 are stepping motors that are driven by the input of drive pulses, respectively, high-precision transfer operation is possible.
The first transfer motor 18 and the second transfer motor 25 are not limited to these, and may be ordinary DC motors.

First, the overall operation of the medication support device 100 will be briefly described. First, the user, the medication user or the medication supporter (hereinafter, represented by the “medicine recipient”) inputs the medication time and the like. Since one storage unit 6 used in the medication support device 100 is set as described above, for example, the medication time in the morning according to the order of the drug package pack 2 of the pack continuum 1 to be dosed in the morning ( Set the medication time (time) for day, night, and before going to bed. The medication time is set by inputting and setting the medication time using the input unit of the touch panel 51 of FIG. 3 and confirming whether the medication time is correct on the display unit.

When the input of the medication time and the like is completed, the medication support device 100 waits until the medication time arrives, and when the predetermined time is reached, the notification unit 55 operates to notify the medication person of the medication time by voice or light. Then, when the medication user presses the discharge switch 54, the operation of the notification unit 55 is stopped. If the discharge switch 54 is not pressed and a predetermined time has passed from the notification of the medication time, the control unit 50 in FIG. 3 determines that the medication was not taken, and the memory of FIG. 3 indicates that the medication was not taken. It is recorded in the unit 52, and the notification unit 55 is activated again.

In FIG. 1, the drug-packed pack 2 of the pack continuum 1 set by being sandwiched between the nip of the transport rollers 11a and 11b of the first transport unit 10 is detected from the inside of the storage unit 6 by the initial operation. It is conveyed to the detection position of the tip detection sensor 28 of 27, and is positioned and held at a standby position where the tip of the pack continuum 1 protrudes from the nip by a predetermined amount from the detected information, for example, a home position described later.
At this time, the detection method of the tip portion of the pack continuum 1 is not limited to the tip detection sensor 28 such as a light reflection type or light transmission type photo sensor, and an area sensor such as a CCD may be used alone.

When instructed to provide one dose of the drug-packed pack, the transport rollers 11a and 11b of the first transport unit 10 rotate to rotate the pack continuum 1 supplied from the storage unit 6. Only the length is transported. When the tip of the pack continuum 1 passes through the cut portion 30, the second transport portion 20 is driven to transport the pack while being niped by the transport rollers 21a and 21b. At this time, the timing at which the first transport unit 10 is driven may be matched with the drive timing of the second transport unit 20.

Next, the boundary sensor 29 detects the cut portion to be cut (for example, the perforation 5 of the crimping portion 4 of the drug packaging pack 2 shown in FIG. 2). At this time, since the distance between the rotation axes of the transfer rollers 11a and 11b of the first transfer unit 10 and the transfer rollers 21a and 21b of the second transfer unit 20 is constant and the rotation is performed at a constant transfer speed, the boundary sensor 29 Can be detected accurately.
When the boundary sensor 29 detects the cut portion to be cut and transports a predetermined amount, the first transport unit 10 is stopped and the second transport unit 20 is stopped at the same time, so that the pack continuum 1 is also stopped.

Next, the cutter module of the cutting portion 30 operates in a state of being nipated by the rollers of both the first conveying portion 10 and the second conveying portion 20, and the vicinity of the perforation 5 in FIG. 2 is cut. The cut single-drug packaged pack 2 is continuously transported by the transport rollers 21a and 21b of the second transport unit 20, and then the rear end of the drug-packed pack 2 is discharged away from the transport rollers 21a and 21b. It is discharged to the part 35. As a result, the user, the medication user or the medication supporter, can take out one dose of the drug package pack 2 from the discharge unit 35.
On the other hand, the drug packaging pack 2 on the side of the cut storage unit 6 is retracted by a predetermined amount by the transfer rollers 11a and 11b of the first transfer unit 10, and the new tip after cutting is held in the above-mentioned standby position. To.
When one cut drug package pack 2 is taken out from the discharge unit 35, the discharge sensor 37 is turned on. At this time, when the drug recipient takes out the drug package pack 2, the discharge sensor 37 is turned off again, and the process of providing the drug package pack 2 for one dose is completed based on the determination result. When this process is completed, the input value can be automatically changed and the next process can be repeated if there is a next reservation.

As described above, in the first embodiment, the first transport unit 10 and the second transport unit 20 that transport the pack continuum 1 in the pack continuum transport direction A, and the pack continuum transport direction A in the pack continuum 1 The detection unit 27 that detects the boundary 2b of the adjacent drug packaging packs 2 and 2 and the pack continuum 1 are cut at a predetermined position on the boundary 2b of the drug packaging pack 2 to package one drug. A cut unit 30 that separates the packs 2 from each other and a control unit 50 that controls the cut unit 30 so as to cut the boundary portion 2b at a predetermined position based on a signal from the detection unit 27 are provided.
Further, the detection unit 27 includes the bag portion 2a of the drug packaging pack 2 of the pack continuum 1 transported by the first transport unit 10, and the crimping portions 4 and 4 of the adjacent drug packaging packs 2 and 2. It was a medication support device 100 that identifies and detects the boundary portion 2b of the adjacent drug packaging packs 2 and 2.

With this configuration, according to the first embodiment, in the medication support device that provides the drug packaged pack, the boundary portion of the drug packaged pack from the pack continuum in which a plurality of drug packaged packs are connected in a band shape. Can be reliably detected and a single drug package pack can be provided.
Further, according to the first embodiment, the unique configuration described at any time in the first embodiment, for example, the ultrasonic sensor is used as the boundary sensor 29 of the detection unit 27 as the detection means, and the area as the detection unit 27. By using the sensor, the above-mentioned peculiar effect is also obtained.

(Example 1)
The medication support device according to the first embodiment will be described with reference to FIGS. 4 and 5. FIG. 4A is a diagram for explaining Example 1, and is a schematic diagram for explaining the stop position of the drug-packed pack of the pack continuum before cutting. FIG. 4B is a diagram for explaining Example 1, and describes the positional relationship between the first transport portion, the detection portion, and the cut portion when the drug-packed pack of the pack continuum is cut by the cut portion. It is a schematic diagram. FIG. 5 is a diagram illustrating Example 1, and is a timing chart when cutting is aimed at a substantially central portion of a boundary portion of adjacent drug-packed packs of a pack continuum.
As shown in FIG. 4A, the tip of the crimping portion 4 of the drug-packed pack 2 located at the most downstream side of the pack continuum transport direction A of the pack continuum 1 during normal transport before cutting. The portion 2c is stopped at a predetermined position upstream of the pack continuous body transport direction A from the arrangement position of the tip detection sensor 28.

When the drug packaging pack 2 located at the most downstream side is cut at a predetermined time, the first transport motor 18 of the first transport unit 10 of FIG. 1 is turned on as shown in FIGS. 4 (b) and 5. Then, the pack continuum is transported downstream in the transport direction A at a transport speed V via the transport rollers 11a and 11b. A case where both the tip detection sensor 28 and the boundary sensor 29 are used as the detection unit 27 will be described.
As shown by the reference numerals (a) in FIGS. 4 (a) and 5 (a), the boundary sensor 29 first detects the crimping portion 4 of the drug packaging pack 2 located at the most downstream, and this is the case. Since it is the tip portion 2c of the drug package pack 2, it is not a boundary portion to be cut. That is, since the tip detection sensor 28 is OFF at the site where the boundary sensor 29 first detects the crimping portion 4 of the drug packaging pack 2 located at the most downstream, the drug packaging pack located at the most downstream The crimping portion 4 at the most downstream end of 2, that is, the tip end 2c of the pack continuum 1.

After the tip detection sensor 28 is turned on, the boundary sensor 29 detects the boundary portion 2b formed by the crimping portions 4 and 4 of the adjacent drug packaging packs 2 and 2 (indicated by the reference numeral (b) in FIG. 5). The part) is the boundary that should be cut first.
Triggered by the detection of the boundary sensor 29 described above, the substantially central portion of the boundary portion 2b in FIG. 4, that is, the vicinity portion where the perforation 5 is provided stops the transport of the pack continuum 1 at the timing when the cut position is reached. Then, the cutter motor 31 of the cutting portion 30 is turned on to cut.

The stop timing of the pack continuum 1 is controlled by the control unit 50 by calculating the transport distance of the drug-packed pack 2 of the pack continuum 1 for each pack.
In FIGS. 4 and 5, the reference numeral “W” represents the width of the pack continuum transport direction A of the boundary portion 2b of the adjacent drug packaging packs 2 and 2, and the boundary sensor 29 indicates the width of the pack continuum 1. Measure each pack of the drug package pack 2.
The symbol "L" represents the distance in the pack continuum transport direction A from the boundary sensor 29 to the cut portion 30, and is determined by the layout.
The symbol "P" represents the width of the bag portion 2a of the drug-packed pack 2 in the pack continuum transport direction A.

Assuming that the transport speed of the drug-packed pack 2 of the pack continuum 1 is "V", the transport time (for example, sec: sec) from the boundary sensor 29 to the cut position of the cut portion 30 is expressed by the following mathematical formula 1. Can be done.

The drive pulse count of the first transfer motor 18 may be used to grasp that the cut position has been reached in terms of distance.

As described above, in the first embodiment, on the premise of the basic configuration of the first embodiment, the CPU of the control unit 50 is a pack continuum based on the signals from the tip detection sensor 28 and the boundary sensor 29. The cutter motor 31 is controlled so that the boundary portion 2b of the drug packaging packs 2 and 2 of 1 is cut near the perforation 5 which is substantially the center of the boundary portion 2b as a predetermined position.
With such a configuration, according to the first embodiment, it is possible to reliably cut one drug-packed pack in the vicinity of the perforation 5, which is a position substantially at the center of the boundary portion 2b.

(Example 2)
The medication support device according to the second embodiment will be described with reference to FIG. FIG. 6 (a) is a schematic view of a pack continuum after cutting one drug-packed pack, and FIG. 6 (b) is a diagram for explaining Example 2, in which one pack of drug is packaged. It is a schematic diagram which transports a pack continuum to a home position after cutting a chemical pack.
In FIGS. 6A and 6B, the arrangement order of the drug-packed packs 2 extending from the most downstream to the upstream of the pack continuum transport direction A in the pack continuum 1 is set to n as a natural number. , The most downstream drug-packed pack 2 is named as the youngest n-pack, then the youngest n + 1, and so on (the same applies to FIG. 7 and the like described later).

As shown in FIG. 6A, after the n-th pack packaged pack 2 of the pack continuum 1 is cut by the cut portion 30, the tip detection sensor 28 and the boundary sensor 29 package the drug at what number. It is unknown whether it is in the position where pack 2 is detected. Therefore, in order to reliably cut the n + 1th drug-packed pack 2 next time, the tip portion 2c of the drug-packed pack 2 located at the most downstream of the pack continuum transport direction A in the pack continuum 1 is inserted. You need to figure it out.

Therefore, as shown in FIG. 6B, the CPU of the control unit 50 controls to reversely drive the first transfer motor 18 (see FIG. 1) of the first transfer unit 10. As a result, the transfer rollers 11a and 11b are rotated in the reverse direction, and the pack continuum 1 is conveyed in the switchback transfer direction B opposite to the pack continuum transfer direction A and returned to the home position which is a predetermined position ( Hereinafter, it is also referred to as switchback transport after cutting).
At the home position of the tip 2c of the drug packaging pack 2 located at the most downstream of the pack continuum 1, the detection signal of the tip detection sensor 28 changes from ON to OFF, and the drug packaging pack located at the most downstream 2 is a position where a predetermined amount is conveyed. In the first embodiment, as described in the overall operation, the home position of the tip portion 2c of the drug-packed pack 2 located at the most downstream of the pack continuum 1 is set, and the tip portion 2c of the pack continuum 1 is a transport roller. It was set to a standby position protruding from the nips of 11a and 11b by a predetermined amount in the pack continuum transport direction A.

As described above, in the second embodiment, the CPU of the control unit 50 cuts the nth drug-packed pack 2 located at the most downstream of the pack continuum transport direction A from the pack continuum 1 by the cut unit 30. Then, the first n + 1th drug-packed pack 2 located at the most downstream side of the packed continuum 1 after being cut is transported to the upstream side in the transport direction of the pack continuum 1. The transfer motor 18 was controlled to position the n + 1th drug-packed pack 2 located at the most downstream of the pack continuum 1 at a predetermined position.

With this configuration, according to the second embodiment, at the end of the job or the like, the tip portion located at the most downstream side of the drug-packed pack on the side of the cut pack continuum is returned to a predetermined position and positioned. , The position of the tip of the pack continuum can be grasped. As a result, in the next job, the boundary portion of the drug-packed pack of the pack continuum to be cut can be surely grasped.

(Example 3)
The medication support device according to the third embodiment will be described with reference to FIG. 7. FIG. 7A is a diagram illustrating the third embodiment, and is a schematic diagram showing a cut position of the pack continuum and an appropriate arrangement configuration of a detection unit (tip detection sensor, boundary sensor). 7 (b) and 7 (c) are schematic views showing the cut position of the pack continuum and the improper arrangement configuration of the detection unit (tip detection sensor, boundary sensor).
The reference numeral “L” represented by FIGS. 7 (a) and 7 (c) represents the distance in the pack continuum transport direction A from the boundary sensor 29 to the cut portion 30, and is determined by the layout.
The symbol "W" represents the width of the pack continuum transport direction A of the boundary portion 2b of the adjacent drug packaging packs 2 and 2.
The symbol "P" represents the width of the bag portion 2a of the drug-packed pack 2 in the pack continuum transport direction A. Here, W and P are set to the minimum size values of the standard specifications of the drug-packed pack 2 of the pack continuum 1.

As shown in FIG. 7A, when the n-th pack packaged pack 2 of the pack continuum 1 is cut by the cut portion 30, the boundary sensor 29 is the bag portion of the n + 1th drug packaged pack 2. It depends on 2a, and the bag portion 2a of the n + 1th drug packaging pack 2 is in a detectable arrangement state. In such an arrangement configuration in which the bag portion 2a of the n + 1th drug packaging pack 2 can be detected, an appropriate arrangement configuration in which L <P + W / 2 is established is OK.

As described above, in the arrangement configuration shown in FIG. 7A, the boundary sensor 29 always rests on the bag portion 2a of the next n + 1th drug package pack 2 after cutting. That is, since the boundary sensor 29 can detect the bag portion 2a of the n + 1th drug packaging pack 2, the detection portion of the boundary portion 2b of the next n + 1th drug packaging pack 2 becomes the boundary portion to be cut. Is guaranteed.

On the other hand, in the arrangement configuration shown in FIGS. 7 (b) and 7 (c), when the n-th pack-packed drug pack 2 of the pack continuum 1 is cut, the boundary sensor 29 packs the n + 1-th drug package. It is in an arrangement state where it passes through the bag portion 2a of the pack 2. It can be seen that in such an arrangement configuration in which the bag portion 2a of the n + 1th drug package pack 2 cannot be detected, the arrangement configuration is improper (NG) in which L <P + W / 2 is not established.

In the third embodiment, the boundary sensor 29 of the detection unit 27 is cut when the nth drug-packed pack 2 located at the most downstream side of the pack continuum 1 is cut from the pack continuum 1 in the cut unit 30. It can be expressed that the bag portion 2a of the n + 1th drug-packed pack 2 located at the most downstream of the pack continuum 1 is arranged at a detectable position. That is, it is an appropriate (OK) arrangement configuration that satisfies the arrangement configuration condition of L <P + W / 2.

With such a configuration, according to the third embodiment, the switchback transfer after the cut as described in the second embodiment becomes unnecessary, and it is necessary to manage the number of the drug-packed pack in which the detected boundary portion is detected. Since there is no such thing, it has the effect of making control easier.

(Example 4)
The medication support device according to the fourth embodiment will be described with reference to FIG. FIG. 8 is a flowchart of the initial operation for explaining the fourth embodiment.
The purpose of the initial operation is whether or not the pack continuum 1 is set, and when the pack continuum 1 is set, the drug package located at the most downstream of the pack continuum transport direction A of the pack continuum 1 is packaged. This is an operation for grasping the position of the tip portion 2c of the pack 2.
Initial operation is performed to set the tip 2c (see FIG. 2) of the drug-packed pack 2 of the pack continuum 1 to the home position, such as when the power is turned on or when the power of the device body recovered from the error is turned on. ..

First, in step S1 of FIG. 8, the state of the tip detection sensor 28 is confirmed. If the tip detection sensor 28 is ON, the pack continuum 1 is present. Therefore, in FIG. 1, the first transfer motor 18 and the second transfer motor 25 are reversely driven to retract the pack continuum 1 until the tip detection sensor 28 is turned off. Since the position where the tip detection sensor 28 is turned off is the position of the tip 2c of the drug packaging pack 2 of the pack continuum 1, a predetermined amount is conveyed and the first transfer motor 18 and the second transfer motor 25 are stopped to end. (Step S2 to Step S5).

On the other hand, in step S1, when the tip detection sensor 28 is turned off, the count of the timer unit 56 is cleared, the second transfer motor 25 is driven in the forward rotation, and the drug-packed pack 2 of the pack continuum 1 is used. It is driven until the tip portion 2c of the above is detected (step S6 to step S7). However, if the tip detection sensor 28 does not turn on even after carrying for a predetermined time due to the timer count of the timer unit 56, an error is transmitted to the CPU (see FIG. 3) of the control unit 50 if the pack continuum 1 is not set. To do. As a result, the CPU of the control unit 50 determines that an error occurs, and stops the first transfer motor 18 and the second transfer motor 25 to end the process (steps S9 to S10).

In the fourth embodiment, when the power of the apparatus main body is turned on, the CPU of the control unit 50 is located at the most downstream of the pack continuum 1 based on the signal from the tip detection sensor 28 or the area sensor of the detection unit 27. The configuration was such that initial control was performed to grasp the tip 2c, which is the most downstream end of the drug package pack 2.
With such a configuration, according to the fourth embodiment, even if the power of the apparatus main body is turned off in the middle of a job or the like, the most downstream end of the drug-packed pack located at the most downstream of the pack continuum (pack continuum). Since the cutting operation is performed after grasping the position (the tip of the drug-packed pack), it is possible to reliably cut one drug-packed pack at a time.

In the above-described fourth embodiment, the tip detection sensor 28 is used to detect the position of the tip portion 2c of the drug packaging pack 2 located at the most downstream side of the pack continuum 1. However, the area sensor is used. May be detected.
When the area sensor is used, if the tip portion 2c of the drug packaging pack 2 is located within the detection range of the area sensor, the initial operation itself described in the fourth embodiment becomes unnecessary.

(Embodiment 2)
The basic configuration and operation of the medication support device according to the second embodiment of the present invention will be described with reference to FIGS. 9 to 13. FIG. 9 is a cross-sectional view schematically showing an overall configuration including a transport path of a pack continuum of the medication support device according to the second embodiment of the present invention. FIG. 10 is a plan view of a main part of the medication support device according to the second embodiment, and FIG. 11 is a perspective view of the main part of the medication support device according to the second embodiment. 12 (a) is a perspective view of a main part of the medication support device according to the second embodiment, and FIG. 12 (b) is a plan view of the entire FIG. 12 (a). FIG. 13 is a control block diagram showing a main control configuration of the medication support device according to the second embodiment. In FIG. 10, the first transport unit 10 (see FIGS. 9 and 12) is not shown in order to simplify the diagram.

As shown in FIGS. 9 to 12, the medication support device 100A according to the second embodiment is replaced with the single storage unit 6 as compared with the medication support device 100 according to the first embodiment shown in FIG. The difference is that it has a plurality of storage units 6 (four in FIG. 9) for storing the pack continuum 1. Further, the medication support device 100A is different in that it is newly provided with a storage unit switching unit 40. Hereinafter, the medication support device 100A will be described with a focus on the differences from the medication support device 100.
Each storage unit 6 may be configured to be detachably attached to the main body of the medication support device 100A, and in this case, it is also called a cartridge. Further, in the medication support device 100A, each part / device is covered with an exterior (not shown), but in each figure, the exterior is shown in a removed state.

As shown in FIGS. 9 and 10, the storage portion 6 is formed with an opening 7 through which the pack continuum 1 passes. The storage unit 6 includes four storage units 6-1, 6-2, 6-3, and 6-4 in the examples shown in FIGS. 9 to 12. When it is necessary to explain the arrangement number of the storage unit, the storage unit 6-1, 6-2, 6-3, 6-4 is used as a code, and when it is generically used, the storage unit 6 is used as a code.

The four storage units 6-1, 6-2, 6-3, and 6-4 store, for example, a pack continuum 1 corresponding to four types of drugs to be taken in the morning, noon, night, and before going to bed. .. The four storage units 6-1, 6-2, 6-3, and 6-4 are installed at predetermined intervals on the turntable 41 of the storage unit switching unit 40.
As shown in FIG. 2, the pack continuum 1 used in the second embodiment has basically the same configuration as that used in the medication support device 100 according to the first embodiment. For example, a pack continuum 1 corresponding to four kinds of medicines to be taken in the morning, noon, night, and before going to bed is stored corresponding to four storage units 6-1, 6-2, 6-3, and 6-4. From this point of view, the pack continuum 1 is composed of a drug-packed pack 2 packed in a bag so that the same type of drug does not leak.

As shown in FIGS. 10 and 11, the storage unit switching unit 40 is fixed to a turntable 41 that can hold and rotate a plurality of (four) storage units 6 and a central portion on the back side of the turntable 41. A turntable pulley 42, a turntable motor 45 as a drive source that is arranged near the turntable 41 and can rotate in both forward and reverse directions to rotate the turntable 41, and a motor pulley 44 fixed to the output shaft of the turntable motor 45. It has a belt 43 hung between the rotary table pulley 42 and the turntable pulley 42. The turntable motor 45 constitutes a rotary drive unit that rotationally drives the turntable 41.
The turntable motor 45 is composed of, for example, a stepping motor that can be rotationally driven by inputting a drive pulse, and is fixed to an immovable member on the device main body side.

The storage unit switching unit 40 serves as a switching means for switching which of the pack continuums 1 stored in the plurality of storage units 6 is cut by relatively moving the plurality of storage units 6 and the cutting unit 30. And functions as a storage unit holding means or a holding unit for holding a plurality of storage units 6. In the second embodiment, the storage unit switching unit 40 functions as a first moving means for moving the plurality of storage units 6, and more specifically, the storage unit switching unit 40 is characterized in that the plurality of storage units 6 are integrally rotated.

The turntable 41 rotates by transmitting the driving force from the turntable motor 45 by the motor pulley 44, the belt 43, and the turntable pulley 42 as drive transmission members. Then, the rotation direction of the turntable 41 can be changed by the forward / reverse drive operation of the turntable motor 45.
By having the plurality of storage units 6, it is possible to store the pack continuum 1 having different types of drug-packed packs 2. For example, as described above, it can be provided in a daily cycle corresponding to different drug package packs 2 provided in a day such as morning, noon, night, and before going to bed.

Each storage unit 6 is not limited to being held and fixed to the turntable 41, and can be detachably configured with respect to the turntable 41. In this case, each storage unit 6 should be called a cartridge as described above. The details of the attachment / detachment will be omitted because they are beyond the scope of the present invention, but each storage unit 6 can be removed from the turntable 41 to easily replenish or replace the pack continuum 1.

The turntable 41 uses a turntable home position sensor (hereinafter, abbreviated as “turntable HP sensor”) that detects its own home position, and the target storage unit 6 is in the pack continuum 1. It is controlled so that it can be stopped at a predetermined position where the drug package pack 2 can be provided. Since each of the four types of pack continuums 1 is stored in each storage unit 6, the turntable 41 rotates so that the drug package pack 2 can be provided to the drug recipient at each medication timing. The target storage unit 6 of the four types of pack continuum 1 can be moved to a predetermined position.

In FIG. 11, the turntable HP sensor may be provided at four locations corresponding to each storage unit 6, or may be provided with another control method, for example, only one location, and is stopped at each stop position by a stepping motor. You may use a method of controlling the rotation. Further, unlike FIG. 11, it is not always a combination of 90 degrees and four storage units, but a form corresponding to another number may be used.

In FIG. 10, of the four types of pack continuum 1, for example, the storage unit 6-1 storing the pack continuum 1 to be taken in the morning is rotated and moved to a position facing the cut position of the cut unit 30. Is shown.

A pair of bevel gears 13, 14, a shaft 15, and a driven gear 16 which are a part of the drive transmission means for transmitting the drive to the first transport unit 10 are provided in each storage unit 6, respectively. The driven gear 16 which is at least a part of the drive transmission means for transmitting the drive to the first transfer unit 10 is a gear 17 which is a drive transmission member on the device body side including a drive source (convey motor 18) provided on the device body side. It is configured so that it can be attached to and detached from.

When the pack continuum 1 is discharged from the storage unit 6-1 provided on the turntable 41, the turntable 41 is rotated to rotate the gear 17 of the transport motor 18 on the apparatus main body side and the storage unit 6-1 side. Is connected to the driven gear 16. After that, at the next medication timing, the turntable 41 is rotated to connect the driven gear 16 on the storage unit 6-2 side and the gear 17 of the transport motor 18 on the apparatus main body side. Similarly, at the next medication timing, the turntable 41 is rotated to connect the driven gear 16 on the storage unit 6-3 side and the gear 17 of the transport motor 18 on the device main body side, and further at the next medication timing. The turntable 41 is rotated to connect the driven gear 16 on the storage unit 6-4 side and the gear 17 on the transport motor 18 on the apparatus main body side. The circumferential portion shown by the alternate long and short dash line in FIG. 12B represents the outermost circular GL in which the driven gear 16 and the gear 17 of the first transport portion 10 of each storage portion 6 are engaged with each other.

In the storage unit switching unit 40, the driving force from the turntable motor 45 is transmitted by the motor pulley 44, the belt 43, and the turntable pulley 42, but the present invention is not limited to this. That is, the transmission may be performed by gears, or the turntable pulley 42 may be removed and the motor may be directly connected to the rotating shaft of the turntable 41 to directly transmit the driving force of the motor.

As shown in FIGS. 9 and 12, the first transport unit 10 is provided in each of the four storage units 6-1, 6-2, 6-3, and 6-4.

The second transport unit 20 differs from the second transport unit 20 shown in FIG. 1 in a mechanism for transmitting a driving force to the second transport unit 20. That is, as shown in FIG. 10, the mechanism for transmitting the driving force to the second transport unit 20 includes the rotary shaft 22 fixed to the transport roller 21a and the driven gear 23 for transmitting the rotary drive force to the rotary shaft 22. It has a drive gear 24 that meshes with the driven gear 23, and a second conveyor 25 as a drive source in which the drive gear 24 is fixed to an output shaft.

The transfer roller 21a forming the nip with the transfer roller 21a is hidden behind the upper transfer roller 21a and cannot be seen, as shown in parentheses in FIG. The driven gear 23 and the drive gear 24 are drive transmission members that transmit a driving force to the transport roller 21a via the rotating shaft 22.

The transport path and operation from the storage portion to the discharge portion of the pack continuum will be described with reference to FIG. A detection unit 27 similar to that shown in FIG. 1 is arranged in the transport path 19 between the storage unit 6 and the cut unit 30.
The drug-packed pack 2 of the pack continuum 1 set between the nip of the transport rollers 11a and 11b of the first transport unit 10 detects the tip of the detection unit 27 from the inside of the storage unit 6 by the initial operation. It is conveyed to the detection position of the sensor 28, and is positioned and held at the home position, which is the standby position where the tip of the pack continuum 1 protrudes from the nip by a predetermined amount from the detected information. The detection method of the pack continuum 1 by the tip detection sensor 28 of the detection unit 27 may be performed by image processing using, for example, an area sensor such as a CCD sensor, or a reflection type sensor or a receiving unit (shown) at an opposite position. Various transmissive sensors equipped with (1) may be used.

When instructed to provide one dose of the drug-packed pack, the transport rollers 11a and 11b of the first transport unit 10 rotate to rotate the pack continuum 1 supplied from the storage unit 6. Only the length is transported. After the tip of the pack continuum 1 has passed through the cut portion 30, it has entered the transport rollers 21a and 21b of the second transport unit 20 and is nipped into the rollers of both the first transport unit 10 and the second transport unit 20. The cutter module is activated at. As a result, the vicinity of the perforation 5 which is substantially the center of the boundary portion 2b formed by the crimping portions 4 of the adjacent drug packaging packs 2 and 2 shown in FIG. 2 is cut. The cut single-drug packaged pack 2 is continuously transported by the transport rollers 21a and 21b of the second transport unit 20, and then the rear end of the drug-packed pack 2 is discharged away from the transport rollers 21a and 21b. It is discharged to the part 35. As a result, the user, the medication user or the medication supporter, can take out one dose of the drug package pack 2 from the discharge unit 35.
On the other hand, the drug packaging pack 2 on the side of the cut storage unit 6 is retracted by a predetermined amount by the transfer rollers 11a and 11b of the first transfer unit 10, and the new tip after cutting is set to the above-mentioned standby position, that is, the home. Positioned and held in position.
The basic operations are the transport and discharge operations of the above-mentioned pack continuum / drug packaged pack.

In the transport path 19 of the pack continuum 1 shown in FIG. 9, the arrangement position of each portion is predetermined until it reaches the nip of the first transport portion 10, the cut portion 30, the nip of the second transport portion 20, and the discharge portion 35. ing. Further, since the first transfer motor 18, the second transfer motor 25, and the turntable motor 45 of the holding unit 40 are stepping motors driven by input of drive pulses, respectively, high-precision transfer operation and rotation operation are possible. There is.

FIG. 13 is a control block diagram showing a main control configuration of the medication support device 100A according to the second embodiment. As shown in FIG. 13, the medication support device 100A has a control unit 50A incorporating a CPU (central processing unit), a storage unit 52, and a timer unit 56 that control the operation of each unit of the medication support device 100A. The CPU may have a timer (timekeeping) function in addition to having a calculation and control function. The storage unit 52 includes a ROM (read-only memory), a RAM (memory that can be read and written at any time), an external memory, and the like. A program (for example, a control flowchart and a timing chart described later) that can be read by the CPU, data, and the like are stored in advance in the ROM. The above data includes the storage unit No. The medication time set for each may be mentioned.

A touch panel 51 is electrically connected to the input / output port of the control unit 50A as a user interface. On the touch panel 51, the medication person or the medication supporter can input the medication time, the storage unit selection, and the like, and the current time and the next medication timing are displayed. The touch panel 51 is not limited to this, and for example, the input unit and the display unit may be separate and a combination such as a keyboard and an LED display unit may be used.

The discharge switch 54, the turntable HP sensor 46, the tip detection sensor 28 provided as the detection unit 27 described above, the boundary sensor 29, and the discharge sensor 37 are electrically connected to the input port of the control unit 50A. The tip detection sensor 28, the boundary sensor 29, and the discharge switch 54 of the detection unit 27 are the same as those in the first embodiment shown in FIG.

As described above, the turntable HP sensor 46 has a cut in which the storage portion 6 storing the target pack continuum 1 of the four types of pack continuum 1 faces the cut position of the cut portion 30. It detects that it is in a possible position. The discharge sensor 37 is the same as that of the first embodiment shown in FIG.

The output port of the control unit 50A has a notification unit 55, a first transfer motor 18 of the first transfer unit 10, a second transfer motor 25 of the second transfer unit 20, a turntable motor 45 of the storage unit switching unit and the holding unit 40. , The cutter motor 31 of the cut portion 30 is electrically connected.
The notification unit 55 is the same as the first embodiment shown in FIG.

The first transfer motor 18, the second transfer motor 25, and the turntable motor 45 are connected to the output port of the control unit 50A via their respective stepping motor drivers. The cutter motor 31 is connected to the output port of the control unit 50A via a DC motor driver.

When various signals from the input information from the touch panel 51, the discharge switch 54, the turntable HP sensor 46, the tip detection sensor 28 of the detection unit 27, the boundary sensor 29, and the discharge sensor 37 are input to the CPU of the control unit 50A, control is performed. The following command signal is output from the CPU of unit 50A. That is, from the CPU of the control unit 50A, the display device of the touch panel 51, the voice device and the optical device of the notification unit 55, the STM drivers of the first transfer motor 18, the second transfer motor 25, and the turntable motor 45, and the cutter motor 31. A command signal is output, which is an instruction for controlling the DCM driver of.

The CPU of the control unit 50A cuts the boundary portion 2b of the adjacent drug packaging packs 2 and 2 of the pack continuum 1 at a predetermined position based on the signals from the tip detection sensor 28 and the boundary sensor 29. It has a function as a control means for controlling the motor 31.

Further, in the CPU of the control unit 50A, the boundary portion 2b of the drug packaging packs 2 and 2 of the pack continuum 1 is positioned at the boundary portion 2b based on the signals from the tip detection sensor 28 and the boundary sensor 29. It has a function as a control means for controlling the cutter motor 31 so as to cut in the vicinity of the perforation 5 which is substantially the center of the above.

Further, when the CPU of the control unit 50A cuts the nth drug-packed pack 2 located at the most downstream side of the pack continuum transport direction A from the pack continuum 1 by the cut unit 30, the pack continuation after being cut. The first transport motor 18 of the first transport unit 10 is controlled so as to transport the n + 1th drug-packed pack 2 located at the most downstream side of the body 1 to the upstream side in the transport direction of the pack continuum 1, and the pack It has a function as a control means for positioning the n + 1th drug package pack 2 located at the most downstream of the continuum 1 at a predetermined position.

As described above, in the second embodiment, on the premise of the basic configuration of the second embodiment, the packs are continuously controlled by the CPU of the control unit 50A based on the signals from the tip detection sensor 28 and the boundary sensor 29. The cutter motor 31 was configured to cut the boundary portion 2b of the adjacent drug packaging packs 2 and 2 of the body 1 at a predetermined position.

With this configuration, according to the second embodiment, in the medication support device that provides the drug packaging pack, the boundary portion of the drug packaging pack from the pack continuum in which a plurality of drug packaging packs are connected in a band shape. Can be reliably detected and a single drug package pack can be provided.
Further, according to the second embodiment, the same peculiar configuration as described at any time in the first embodiment, for example, the ultrasonic sensor is used as the boundary sensor 29 of the detection unit 27 as the detection means, and the detection unit. By using the area sensor as 27, the above-mentioned peculiar effect is also obtained.

Further, in the second embodiment, on the premise of the basic device configuration of the second embodiment, the same configuration as that of the first embodiment of the first embodiment shown in FIGS. 4 and 5 can be adopted. That is, in the second embodiment, the CPU of the control unit 50 further has the boundary portion 2b of the drug packaging packs 2 and 2 of the pack continuum 1 based on the signals from the tip detection sensor 28 and the boundary sensor 29. The cutter motor 31 is controlled so as to be cut near the perforation 5 which is substantially the center of the boundary portion 2b as a predetermined position.
With this configuration, according to the second embodiment, it is possible to reliably cut one drug-packed pack in the vicinity of the perforation 5, which is a position substantially at the center of the boundary portion 2b.

Next, an operation flow for providing a single drug package pack with the medication support device 100A according to the second embodiment will be described with reference to the flowchart of FIG. FIG. 14 (a) is a flowchart of an operation in which the medication support device according to the second embodiment provides a single drug package pack, and FIG. 14 (b) is a storage unit movement process which is a subprocess of FIG. 14 (a). 14 (c) is a flowchart of the operation of the movement process of the pack continuum, which is a subprocess of FIG. 14 (a), to the standby position.
As described in the second embodiment of the first embodiment with reference to FIG. 6A, after cutting the n-th pack of the drug package 2 of the pack continuum 1 with the cut portion 30, the tip detection sensor It is unknown at which number 28 and the boundary sensor 29 are detecting the drug package pack 2. Therefore, in order to reliably cut the n + 1th drug-packed pack 2 next time, the tip portion 2c of the drug-packed pack 2 located at the most downstream of the pack continuum transport direction A in the pack continuum 1 is inserted. You need to figure it out.
In other words, in the second embodiment, the drug packaging pack is displaced from the predetermined position due to, for example, vibration of the transfer rollers 11a and 11b of the turntable 41 and the first transfer unit 10 during rotational drive or rotation stop. Even in this case, it is necessary to detect and grasp the amount of deviation by the tip detection sensor 28 of the detection unit 27 by performing the initial operation after that.

In step S11 of FIG. 14A, the user, the medication user or the medication supporter (hereinafter, represented by the “drug recipient”) inputs the medication time, the storage unit selection, and the like. Since four storage units 6 used in the medication support device 100A are set as described above, for example, the pack continuum 1 to be administered in the morning is stored in the storage unit 6-1 (storage unit No.). In that case, the medication time (time) in the morning is set, and the medication time (time) is set during the day, night, and even before going to bed. Set according to. The medication time is set by using the input unit of the touch panel 51 of FIG. In addition to inputting and setting the medication time corresponding to, the storage unit No. Make sure that the medication time corresponding to is correct.

After inputting the medication time, the storage unit selection, etc., the medication support device 100A waits until the medication time arrives, and when the prescribed time is reached, the notification unit 55 in FIG. 13 is activated to take the medication by voice or light. Notify the time (step S12 to step S13). Then, when the medication user presses the discharge switch 54, the operation of the notification unit 55 is stopped, and then the storage unit 6 containing the pack continuum 1 which is the drug package pack 2 to be administered is subjected to the “storage unit movement process”. The turntable 41 rotates and moves to a predetermined position as provided by (steps S14 to S15).
In step S14, if the discharge switch 54 was not pressed and a predetermined time had passed from the notification of the medication time, it was determined by the control unit 50A in FIG. 13 that the medication was not taken, and the medication was not taken. It is recorded in the storage unit 52 of FIG. 13, and the notification unit 55 is activated again.
As an example, as shown in the flowchart of FIG. 14B, the sub-process of the "retractor movement process" drives the turntable motor 45 until the turntable HP sensor 46 that detects the reference position of the turntable 41 is turned on. This is done (step S25 to step S26). In other words, based on the signal from the turntable HP sensor 46, until the target storage portion in which the pack continuum 1 corresponding to the medication time is stored occupies a position facing the cut position of the cut portion 30. It is rotationally moved by driving the turntable motor 45 of the holding portion 40.

After the "storage unit movement process", the process proceeds to step S16, and the process of moving the pack continuum 1 to the standby position is performed. This subprocess is shown in FIG. 14 (c). In this flowchart, the first transport unit 10 provided in each storage unit 6 is driven so that the pack continuum 1 is transported to the home position, which is also a predetermined standby position, by the feedback from the tip detection sensor 28 of the detection unit 27. It is performed by being performed (step S28 to step S29). The process of moving the pack continuum 1 to the standby position includes switchback transfer after cutting. At the home position, which is also the standby position of the tip 2c of the drug packaging pack 2 located at the most downstream of the pack continuum 1, the detection signal of the tip detection sensor 28 changes from ON to OFF and the drug is located at the most downstream. It is set at a position where a predetermined amount of the packaged pack 2 is conveyed. Specifically, the home position (standby position) of the pack continuum 1 is a standby position in which the tip portion 2c of the pack continuum 1 protrudes from the nips of the transfer rollers 11a and 11b in the pack continuum transfer direction A by a predetermined amount. Is set to.
After the operation of FIG. 14C, the pre-cut transfer process (transport operation of the pack continuum 1) → the cut process (cut operation of the pack continuum 1) → cut by the same operation as described with reference to FIG. The operation of providing the drug package pack 2 is performed in the flow of the post-transport process (transport operation of one cut drug package pack 2) (steps S17 to S19).

The detailed operations of steps S17 to S19 will be described below. In FIG. 9, when the first transport unit 10 holding the tip of the pack continuum 1 stored in the target storage unit by the nip of the transfer rollers 11a and 11b is driven, the pack is packed from the target storage unit. When the continuum 1 is sent out and the tip of the pack continuum 1 passes through the cut portion 30, the second transport portion 20 is driven to transport the pack continuum 1 while being nipated by the transport rollers 21a and 21b (step S17). At this time, the timing at which the first transport unit 10 is driven may be matched with the drive timing of the second transport unit 20.
Next, the boundary sensor 29 composed of an ultrasonic sensor detects a cut portion to be cut (for example, the vicinity of the perforation 5 of the crimping portions 4 and 4 of the adjacent drug packaging packs 2 and 2 shown in FIG. 2). At this time, the distance between the rotation axes of the transfer rollers 11a and 11b of the first transfer unit 10 and the transfer rollers 21a and 21b of the second transfer unit 20 is constant and the rotation is performed at a constant transfer speed, and the ultrasonic sensor is used to pack the drug. The portion of the bag portion 2a of the chemical pack 2 can be accurately detected. When the boundary sensor 29 composed of the ultrasonic sensor detects the cut portion to be cut and transports a predetermined amount, the first transport unit 10 is stopped and the second transport unit 20 is stopped at the same time, so that the pack continuum 1 also stops.

Next, by operating the cutting portion 30, the adjacent drug packaging packs 2 and 2 are cut at the vicinity of the perforations 5 of the crimping portions 4 and 4 (see FIG. 4), and one drug packaging pack is used. 2 is separated from the pack continuum 1 (step S18). The remaining pack continuum 1 is transported in the direction of returning to the storage unit 6 side by rotating the first transport unit 10 in the opposite direction by a predetermined amount, and the tip portion 2c of the remaining pack continuum 1 is conveyed by the tip detection sensor 28. When it is detected, the first transport unit 10 is stopped. One of the cut drug-packed packs 2 is discharged to the pack receiving section 36 of the discharging section 35 by the transporting of the second transporting section 20, and when sent to the pack taking-out port, the second transporting section 20 stops ( Step S19).
When one cut drug package pack 2 is taken out from the discharge unit 35, the discharge sensor 37 is turned on. At this time, when the drug recipient takes out the drug package pack 2, the discharge sensor 37 is turned off again, and the process of providing the drug package pack 2 for one dose is completed based on the determination result (step S20). .. When this process is completed, the input value can be automatically changed and the next process can be repeated if there is a next reservation.

As described above, in the second embodiment, the same control configuration as in the second embodiment of the first embodiment described with reference to FIG. 6 can be adopted on the premise of the basic device configuration of the second embodiment. That is, when the CPU of the control unit 50A of the second embodiment cuts the nth drug-packed pack 2 located at the most downstream side of the pack continuum transport direction A from the pack continuum 1 by the cut unit 30, it is cut. The first transport motor 18 of the first transport unit 10 is controlled so as to transport the n + 1th drug-packed pack 2 located at the most downstream side of the subsequent pack continuum 1 to the upstream side in the transport direction of the pack continuum 1. Then, the n + 1th drug-packed pack 2 located at the most downstream of the pack continuum 1 is positioned at a predetermined position.

With this configuration, according to the second embodiment, at the end of the job or the like, the tip portion located at the most downstream side of the drug-packed pack on the side of the cut pack continuum is returned to a predetermined position and positioned. , The position of the tip of the pack continuum can be grasped. As a result, in the next job, the boundary portion of the drug-packed pack of the pack continuum to be cut can be surely grasped.

Further, in the second embodiment, on the premise of the basic device configuration of the second embodiment, the same configuration as that of the third embodiment of the first embodiment described with reference to FIG. 7 can be adopted. That is, in the second embodiment, when the boundary sensor 29 of the detection unit 27 is cut from the pack continuum 1 by the cut unit 30 when the nth drug-packed pack 2 located at the most downstream of the pack continuum 1 is cut. The structure is such that the bag portion 2a of the n + 1th drug-packed pack 2 located at the most downstream of the pack continuum 1 after being cut is arranged at a detectable position. That is, as shown in FIG. 7A, the arrangement configuration is appropriate (OK) that satisfies the arrangement configuration condition of L <P + W / 2.

With such a configuration, according to the second embodiment, it is not necessary to carry out the switchback after cutting as described above, and it is not necessary to control the number of the drug-packed pack in which the detected boundary portion is detected. Has the effect of making it easier.

Further, in the second embodiment, on the premise of the basic device configuration of the second embodiment, the same configuration as that of the fourth embodiment of the first embodiment described with reference to FIG. 8 can be adopted. That is, in the second embodiment, when the power of the apparatus main body is turned on, the CPU of the control unit 50A moves to the most downstream of the pack continuum 1 based on the signal from the tip detection sensor 28 or the area sensor of the detection unit 27. It is configured to perform initial control for grasping the tip 2c of the crimping portion 4, which is the most downstream end of the located drug packaging pack 2.
With this configuration, according to the second embodiment, even if the power of the apparatus main body is turned off in the middle of a job or the like, the most downstream end of the drug-packed pack located at the most downstream of the pack continuum (pack continuum). Since the cutting operation is performed after grasping the position (the tip of the drug-packed pack), it is possible to reliably cut one drug-packed pack at a time.

According to the second embodiment, in the medication support device for providing the drug package pack, in addition to the above-mentioned basic effects, the following effects are also exhibited.

That is, the gear 16 of the first transport unit 10 of each storage unit 6 and the gear 17 on the device main body side can be brought into contact with each other in accordance with the medication timing, so that the first transport which is the drive source of the second embodiment With a simple configuration in which the number of motors 18 and gears 17 installed is single, the drive source of the first transport unit 10 can be shared. Even in a state in which the structure is significantly simplified in this way, the pack continuum 1 can be sent out and conveyed from each storage unit 6.

The drug package pack can be obtained without any difficulty for the drug recipient when taking the drug. In addition, the pack continuum received from the pharmacy can be easily set in the device. In addition, since there are a plurality of storage units, it is possible to set a drug package pack for each time zone. Further, since the storage portion switching portion is provided, it is possible to provide the medication package pack for each medication time to the recipient without enlarging the device structure.

More specifically, by providing the holding unit 40 which is also a storage unit switching unit, a plurality of storage units 6 are arranged in a circle on the turntable 41 and rotated to reduce the overall size. The size is reduced, and each storage unit 6 can be switched. When a plurality of storage units 6 are arranged in a row, a save space must be provided for switching, so that the size cannot be reduced.
Further, since the plurality of storage units 6 can be switched to the cut position of the cut unit 30, the cut unit 30 and the second transport unit 20 can be used in common, so that each storage unit 6 can be used even in a simplified structure. The pack continuum 1 can be sent out and reliably transported.

A medication support device to which the present invention can be applied will be described with reference to FIGS. 15 to 17. FIG. 15 is a perspective view of a main part of the medication support device to which the present invention is applicable, and FIG. 16 is a perspective view of the entire medication support device to which the present invention is applicable. FIG. 17 is a cross-sectional view of a main part showing the configuration of the first transport part used in the medication support device to which the present invention is applied.
As shown in FIGS. 15 and 16, the medication support device 100B to which the present invention is applicable differs from the medication support device 100A according to the second embodiment shown in FIGS. 9 to 12 in the following points. .. That is, the medication support device 100B has a larger number of storage units 6-1 to 6-8 than the medication support device 100A arranged on the device main body side in a matrix in the upper and lower stages as compared with the medication support device 100A. The main difference is that instead of the holding unit 40, which is also a unit switching unit, the moving unit 80 shown by the broken line (dotted line) and the X slider unit 81 and the Y slider unit 91 as the second moving means are newly provided. ..

The X slider unit 81 and the Y slider unit 91 relatively move the plurality of storage units 6 and the cut unit 30 to switch which of the pack continuums 1 stored in the plurality of storage units 6 is to be cut. It has a function as a switching means. The X slider portion 81 and the Y slider portion 91 function as a second moving means for moving at least the cut portion 30.

The medication support device 100B includes a moving unit 80 that integrally supports the cut portion 30 and the second transport portion 20, and a plurality of storage units 6-1 to 1 to which the moving unit 80 is arranged in a matrix on the device main body side. It has an X slider portion 81 and a Y slider portion 91 to be moved to any one of 6-8.
The moving unit 80 is integrally attached to the unit frame 89 shown by the broken line. The transport rollers 21a and 21b of the second transport unit 20 are rotatably supported by the unit frame 89 via a rotation shaft, respectively.

As shown in FIG. 16, the medication support device 100B includes a plurality of storage units 6-1 to 6-8, a first transport unit 10A provided in each storage unit 6-1 to 6-8, a mobile unit 80, and X. It has an exterior 97 that covers substantially the entire slider portion 81 and the Y slider portion 91. The exterior 97 has a predetermined discharge port 98 for discharging one drug-packed pack 2 which is cut and separated by a cut portion 30 provided in the moving unit 80 and transported by the second transport unit 20. It is exposed and placed in the position. The discharge port 98 is provided with a pack take-out port 99 for taking out the discharged drug-packed pack 2.
In FIGS. 15 and 16, the configurations of the storage units 6-1 to 6-8 are the same, and the reference numerals of the first transport units 10A provided in the storage units 6-1 to 6-8 are shown in the drawings. For the sake of simplicity, it is attached only to the storage unit 6-1. Although the internal components covered with the exterior 97 cannot be seen, they are intentionally shown in a translucent state in FIG.

The X slider unit 81 has a slide mechanism for moving the moving unit 80 in the X direction, which is the left-right direction (arrangement direction of the storage units 6 adjacent to each other in the lateral direction) in the drawing. The X slider portion 81 serves as a drive source in which a belt 85 spanned between a pair of rollers 83 and 84, a slide shaft 82 fixed to the belt 85, and a roller 84 on the drive side are attached to an output shaft. It has a motor 86. The motor 86 is a motor that can rotate in both forward and reverse directions.
A pair of rollers 83, 84 are rotatably supported on the device main body side. The slide shaft 82 extends in the Y direction, one end thereof is fixed to the belt 85, and the other end side is slidably attached to the unit frame 89 in the Y direction.
Since the slide shaft 82 moves in the X direction (or the direction opposite to the X direction) via the belt 85 by the rotation of the motor 86, the moving unit 80 attached to the unit frame 89 moves in the X direction (or the direction opposite to the X direction). ).

The Y slider unit 91 has a slide mechanism for moving the moving unit 80 in the Y direction, which is the vertical direction (arrangement direction of the storage units 6 adjacent to each other in the vertical direction) in the drawing. The Y slider portion 91 serves as a drive source in which a belt 95 spanned between a pair of rollers 93 and 94, a slide shaft 92 fixed to the belt 95, and a roller 94 on the drive side are attached to an output shaft. It has a motor 96. The motor 96 is a motor that can rotate in both forward and reverse directions.
A pair of rollers 93 and 94 are rotatably supported on the device main body side. The slide shaft 92 extends in the X direction in the drawing, one end thereof is fixed to the belt 95, and the other end side is slidably attached to the unit frame 89 in the X direction.
Since the slide shaft 92 moves in the Y direction (or the direction opposite to the Y direction) via the belt 95 due to the rotation of the motor 96, the moving unit 80 attached to the unit frame 89 moves in the Y direction (or the direction opposite to the Y direction). ).

Each of the storage units 6-1 to 6-8 is shown in FIGS. 15 and 16 as compared with the storage units 6-1 to 6-4 held on the turntable 41 shown in FIG. 9 and the like of the second embodiment. The difference is that it is installed and fixed on the device body side so as to function as a holding means. Further, as shown in FIG. 17, the first transport unit 10A is provided corresponding to each storage unit 6-1 to 6-8 as compared with the first transport unit 10 of the second embodiment. , And a first transport motor 58 having a drive gear 57 on the output shaft that always meshes with the driven gear 16 is used. The first transfer motor 58 is provided corresponding to each of the storage portions 6-1 to 6-8, and is installed and fixed on the apparatus main body side.

Next, the schematic operation of the medication support device 100B will be described. When a discharge switch (start switch) (not shown) provided in the medication support device 100B is pressed, the X slider portion 81 and the Y slider portion 91 are driven, for example, as shown in FIGS. 15 and 16. The moving unit 80 moves to the target storage unit 6-1 in which the target pack continuum 1 is stored.
Next, as shown in FIG. 17, the first transport unit 10A holding the tip of the pack continuum 1 stored in the target storage unit 6-1 by the nip of the transport rollers 11a and 11b is driven. Then, the pack continuum 1 is sent out from the target storage unit 6-1. When the tip end portion of the pack continuum 1 passes through the cut portion 30 in the moving unit 80, the second transport unit 20 is driven to transport the pack continuum 1. It is conveyed while being nipated by the rollers 21a and 21b. At this time, the timing at which the first transport unit 10A is driven may be matched with the drive timing of the second transport unit 20.

Next, a pack detection sensor (not shown) detects a cut portion to be cut (for example, the vicinity of the perforation 5 of the crimping portions 4 and 4 of the adjacent drug packaging packs 2 and 2 shown in FIG. 3). At this time, the distance between the rotation axes of the transfer rollers 11a and 11b of the first transfer unit 10A and the transfer rollers 21a and 21b of the second transfer unit 20 is constant, and the rotation is performed at a constant transfer speed. It can be detected accurately by the sensor.
When the cut portion to be cut is detected by the pack detection sensor, the first transport unit 10A is stopped and the second transport unit 20 is stopped at the same time, so that the pack continuum 1 is also stopped.

Next, by operating the cutting portion 30, the adjacent drug packaging packs 2 and 2 are cut at the portion near the perforation 5 (see, for example, FIG. 4), and one drug packaging pack 2 is combined with the pack continuum 1. Is separated from. The remaining pack continuum 1 is transported in the direction of returning to the storage unit 6 side by rotating the first transport unit 10A in the opposite direction by a predetermined amount, and the tip portion of the remaining pack continuum 1 is detected by the tip detection sensor. When this is done, the first transport unit 10A is stopped.

Next, the moving unit 80 is driven by driving the X slider portion 81 and the Y slider portion 91 while holding one drug packaging pack 2 cut by the nip of the transport rollers 21a and 21b of the second transport unit 20. Moves to the pack outlet 99. When one of the cut drug-packed packs 2 is sent to the pack take-out port 99 by the transportation of the second transportation unit 20, the second transportation unit 20 is stopped.

When the present invention is applied to the medication support device 100B, the tip detection sensor 28 and the boundary sensor 29 of the detection unit 27 shown in FIG. 9 used in the second embodiment may be adopted instead of the pack detection sensor. Alternatively, the area sensor may be used alone, not limited to this.
Then, the tip detection sensor 28 and the boundary sensor 29 or the area sensor of the detection unit 27 are transferred to the pack continuum 1 formed on the upstream side in the transport direction of the pack continuum 1 of the cut portion 30 constituting the moving unit 80. Place on the route. That is, the tip detection sensor 28 and the boundary sensor 29 of the detection unit 27 occupy the positions where the first transport unit 10A and the cut unit 30 which are arranged in the target storage unit 6 when the moving unit 80 moves are opposed to each other. At that time, it is arranged on the transport path of the pack continuum 1 formed between the first transport portion 10A and the cut portion 30.
The tip detection sensor 28 and the boundary sensor 29 of the detection unit 27 are not limited to the above arrangement, and may be arranged for each of the first transport units 10A arranged in the storage unit 6.

In the medication support device 100B to which the present invention can be applied, the cut portion 30 and the second transport portion 20 constitute the moving unit 80, but the present invention is not limited to this.
That is, only the cut portion 30 which is the cutting means constitutes the moving unit, and only the cutting portion 30 which has a holding function for holding the cut drug package pack 2 is the X slider portion which is the second moving means. It is moved by the 81 and the Y slider unit 91, and the cut unit 30 is moved to a position corresponding to the second transport unit 20 provided in the pack take-out port 99 in a state where the drug packaging pack 2 is cut and held, and cut. The drug packaged pack 2 may be transported by the second transport unit 20.
Even with such a configuration, it is possible to cut any one of the pack continuums 1 stored in the plurality of target storage units 6 and cut them into one drug-packed pack 2.

The medication support device 100B is not limited to this, and the plurality of storage units 6 themselves may move in a matrix in the X direction and / or the Y direction.
Alternatively, a method in which the moving unit 80 (cut portion 30, second transport portion 20) is attached to the robot arm and is freely moved in the X direction and / or the Y direction may be used.

Further, the medication support device 100B is not limited to this, and a first transport motor 58 having a drive gear 57 on the output shaft is provided on the moving unit 80 side, and the moving unit 80 is moved by the X slider portion 81 and the Y slider portion 91. The drive gear 57 may be configured to mesh with the driven gear 16 of the first transport unit 10A provided in the target storage unit 6 when stopped at a position facing the target storage unit 6. With this configuration, the drive gear 57 and the first transport motor 58 provided on the moving unit 80 side need be single, so that the drive source of the first transport unit 10A is common as in the second embodiment described above. Can be achieved. Even in a state in which the structure is significantly simplified in this way, the pack continuum 1 can be sent out and conveyed from each storage unit 6.

Next, medication support devices other than those described in the background technology and related technologies will be described. As a medication support device, a technique is known in which a drug package pack is stored in the device and the drug package pack is provided every time the drug is taken.

In the conventional medication support devices, for example, in Japanese Patent Application Laid-Open No. 2012-165800 and Japanese Patent No. 5996114, a continuous drug package pack is stored in the device, and when it is time to take the drug, the drug is taken by the person taking the drug. It can be prompted to remove the drug package pack. However, since it comes out of the device in a continuous state, it is necessary for the taking person to separate it, and the handicapped person has the problem that the medicine inside will pop out or in the worst case it cannot be separated. was there.

Japanese Patent No. 6060148 has a mechanism for cutting a series of drug-packed packs at a specific boundary in a packaging machine. As for the method of detecting the boundary portion, the width size information per pack is input in advance and the boundary portion is determined from the conveyed amount. When this is carried out by the medication support device, when the drug packaging pack slips during transportation, the slip amount is accumulated each time the drug is transported, so that there is a problem that the drug is spilled due to erroneous cutting at a place other than the boundary portion. Further, if the width size information per pack is erroneously input, or if the drug packaging packs having different width sizes are included, there is a problem that the information is cut at a place other than the boundary portion.

Japanese Patent Application Laid-Open No. 2-175171 uses an ultrasonic sensor as a method for detecting a perforated portion of paper in a printer device. In the case of an ultrasonic sensor, since the perforation width is too narrow, it is easy to make an erroneous detection. In particular, if a hole other than the perforation hole is detected, it cannot be recognized as a perforation.

In Japanese Patent Application Laid-Open No. 10-101034 and Japanese Patent No. 6462947, it is a device that detects and cuts the boundary position of a pouch continuum.
In JP-A-10-10134, as a means for detecting the boundary portion, the detection portion is conveyed while being in contact with the pouch continuum, and the boundary portion is detected by a mechanical change of the detection portion. However, in the present invention, since the drug is contained in the drug package pack, the contact transport method has a problem that the drug in the drug package pack is damaged.

In Japanese Patent No. 6462947, it is premised that the pouch itself has a marking for detecting the cut position as a means for detecting the cut position. This limits the pouch making device, and further, when manufacturing the pouch, there is a problem that the cost increases due to marking and the productivity decreases.

Although embodiments including preferred embodiments of the present invention have been described above, the present invention is not limited to such specific embodiments and is described in the scope of claims unless otherwise specified in the above description. Various modifications and changes are possible within the scope of the invention. For example, the technical items described in the above-described embodiments and examples may be appropriately combined.

The effects appropriately described in the embodiments of the present invention merely list the most preferable effects arising from the present invention, and the effects according to the present invention are limited to those described in the embodiments of the present invention. It's not a thing.

1 Pack continuum 2 Drug package pack 2a Bag part 2b Boundary part 2c Tip part 3 Drug 4 Crimping part (example of leak prevention part)
5 Perforations 6 Storage section 7 Opening section 10 First transport section (example of transport means)
11a, 11b Conveying rollers (conveying means, holding member)
16 Driven gear (an example of drive transmission member)
17 Drive gear (an example of drive transmission member)
18 Conveyor motor (driving source of transport means, example of transport drive unit)
19 Transport route 20 Second transport section (transport means, second transport means)
21a, 21b Conveying roller (second transport means)
27 Detection unit (example of detection means)
28 Tip detection sensor (component of detection means)
29 Boundary sensor (component of detection means)
30 Cut part (example of cutting means)
35 Discharge unit 36 Pack receiving unit 37 Discharge sensor (an example of discharge pack detection means)
40 Holding unit (holding means, an example of the first moving means)
41 Turntable 45 Turntable motor (drive source for holding means, example of rotary drive unit)
46 Turntable HP sensor 50, 50A Control unit (example of control means)
100, 100A medication support device A pack continuous transport direction

Japanese Unexamined Patent Publication No. 07-052930

Claims (10)

A transporting means for transporting a pack continuum in which a plurality of drug-packed packs each having a bag portion for covering the drug and a leak prevention portion for preventing the drug from leaking from the bag portion are transported in a band shape. ,
A detection means for detecting a boundary portion formed by the leakage prevention portion of the drug-packed pack adjacent to the pack continuum in the transport direction, and a detection means.
A cutting means for cutting the pack continuum at a predetermined position on the boundary portion and separating the pack continuum into one drug-packed pack.
A control means that controls the cutting means so as to cut the boundary portion at the predetermined position based on the signal from the detecting means.
With
The detection means is a medication support device that identifies the bag portion and the leakage prevention portion of the pack continuum transported by the transport means, and detects the boundary portion. The claim is characterized in that the control means controls the cutting means so that substantially the center of the boundary portion of the leakage prevention portion of the drug packaging pack adjacent to the transport direction is cut as the predetermined position. Item 1. The medication support device according to item 1. When the drug-packed pack located at the most downstream in the transport direction is cut from the pack continuum by the cutting means, the control means is located at the most downstream of the pack continuum after being cut. The claim is characterized in that the transport means is controlled so as to transport the drug package pack to the upstream side in the transport direction, and the drug package pack located at the most downstream position is positioned at a predetermined position. The medication support device according to 1 or 2. The detection means is located at the most downstream of the pack continuum after being cut when the drug-packed pack located at the most downstream in the transport direction is cut from the pack continuum by the cutting means. The medication support device according to any one of claims 1 to 3, wherein the bag portion of the drug package pack is arranged at a detectable position. When the power of the device main body is turned on, the control means performs initial control for grasping the most downstream end of the drug packaging pack located at the most downstream in the transport direction. Item 4. The medication support device according to any one of Items 1 to 4. The claim is characterized in that the detection means discriminates between the bag portion and the leakage prevention portion of the drug package pack and detects the boundary portion without contacting the drug package pack. The medication support device according to any one of 1 to 5. The medication support device according to any one of claims 1 to 6, wherein the detection means uses an ultrasonic sensor. The medication support device according to any one of claims 1 to 6, wherein the detection means uses an area sensor. It has a storage unit for storing the pack continuum, and has a storage unit.
The cutting means is arranged on the downstream side in the transport direction from the storage portion.
The transport means is configured to transport the pack continuum on a transport path from the storage unit to the cut means.
The medication support device according to any one of claims 1 to 8, wherein the detection means is arranged on the transport path between the storage unit and the cut means. It has a plurality of storage units for storing the pack continuum, and has a plurality of storage units.
A first moving means for moving the plurality of the storage portions with respect to the cutting means is provided.
The transport means is provided in each of the plurality of storage portions.
A drive source for driving the plurality of the transport means and the cut means are provided on the device main body side.
The drive source is connected to the transport means of the storage unit for storing the pack continuum to be cut to drive the transport means.
The transport means is configured to transport the pack continuum of the storage portion moved by the first moving means on a transport path from the storage portion to the cutting means.
The cutting means is arranged on the downstream side in the transport direction from the plurality of storage portions.
Any one of claims 1 to 8, wherein the detection means is arranged on the transport path between the storage portion moved by the first moving means and the cutting means. The medication support device described in.

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