JP2022040353A - Powdered medicine weighing device and medicine dividing and packing system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To develop a medicine delivery device capable of automatically cleaning the inside thereof.

SOLUTION: A medicine delivery device for extracting a predetermined amount of powdered medicine from a medicine container, dividing it into the predetermined number of amounts, and individually packing and discharging the amounts comprises container moving means 28. By the container moving means 28, a predetermined medicine container is extracted from a container storage device and is placed on a container placement device. Medicine is discharged from the medicine container and is input into a medicine input groove of a distribution dish. By a scraping-out device, powdered medicine input in the distribution dish is scraped out from the medicine input groove and is made to fall on a medicine packing region side. A cleaning instrument 61 is provided on the container moving means 28.

SELECTED DRAWING: Figure 8

COPYRIGHT: (C)2022,JPO&INPIT

Description

The present invention relates to a drug dispensing device, and more particularly to a drug dispensing device provided with a distribution dish for distributing powder.

The present invention also relates to a powder weighing device capable of weighing a predetermined amount of powder. The present invention also relates to a drug packaging system that packages powders in doses.

Large hospitals and large pharmacies have introduced drug dispensing devices with powdered packaging functions. The conventional drug dispensing device has a structure as disclosed in Patent Document 1, and is a combination of a distribution pan and a powder feeder.
The work of packaging the powder using the conventional drug dispensing device is performed by the pharmacist operating the device according to the doctor's prescription. That is, the pharmacist confirms the doctor's prescription and takes out the medicine bottle containing the prescribed powder from the medicine rack. Then, a scale such as a balance is used to weigh the total weight of the prescribed specific powder.

Then, the weighed powder is charged into the charging hopper of the powder feeder, and the trough of the powder feeder is vibrated. Also, the distribution dish is rotated at a constant rotation speed.
The powder charged into the charging hopper falls into the trough of the powder feeder, and the trough vibrates, so that the powder slowly moves to the tip side and falls into the groove of the distribution pan.

On the other hand, since the distribution dish is rotating at a predetermined speed, the powder falling from the trough is evenly distributed in the groove of the distribution dish.
Once the powder has fallen onto the distribution dish, the rotation of the distribution dish is temporarily stopped. After that, the disc of the scraping device is dropped into the groove of the distribution pan. After that, the distribution pan is rotated by an angle according to the number of distributions, and the powder is collected on the front side of the disc by a predetermined angle. Then, the disc is rotated, and the powder for a predetermined angle is scraped out of the distribution dish by the scraping plate and put into the packaging hopper. The powder dropped from the packaging hopper is packaged in the packaging device.

Here, the applicant has developed a drug dispensing device that automates the work of taking out a medicine bottle containing a desired powder from the medicine rack and the work of weighing a predetermined amount of powder from the medicine bottle, and disclosed it in Patent Document 2. ..
The drug dispensing device disclosed in Patent Document 2 includes a container storage unit for accommodating a plurality of drug containers and a robot (container moving means). In addition, there is a container mounting device around the distribution plate. The container mounting device has a function of vibrating the drug container to discharge powder from the drug container and a function of monitoring the weight of the drug container.
In the drug dispensing device disclosed in Patent Document 2, a drug container filled with powder that matches the doctor's prescription is selected from the drug containers housed in the container storage unit, and the drug container is taken out by a robot and placed on the container mounting device. Place.
Then, the container mounting device is vibrated to discharge the powder from the drug container, the weight of the drug container is monitored, and the weight of the powder discharged from the drug container is indirectly monitored.
When a predetermined amount of powder is discharged from the drug container, the scraping device is driven to scrape the powder out of the distribution dish and package it in the packaging device.

Patent Documents 3 and 4 disclose a V-mass type drug packaging device.

Japanese Unexamined Patent Publication No. 2000-8573 WO2015 / 07626 A1 Gazette Japanese Unexamined Patent Publication No. 9-10402 Japanese Unexamined Patent Publication No. 10-258111

Since the drug dispensing device is a device that handles the drug taken by the patient, it is not allowed to have dust or the like inside. In addition, it is not permissible for other drugs to be mixed with the drug that should be taken. Specifically, the drug of the packaging work performed earlier remains in the distribution dish, and it is not allowed that the previous drug is mixed with the drug to be packaged this time.
Here, the drug dispensing device disclosed in Patent Document 2 has a built-in robot, and the drug container is taken out by the robot and placed on the container mounting device.
Since the robot moves automatically, it is dangerous when a worker approaches. Therefore, the drug dispensing device disclosed in Patent Document 2 is entirely covered with a housing, and machinery including a robot is built in the housing. Therefore, it is difficult for workers to reach the distribution plate and its surroundings. Therefore, it is difficult to clean the drug dispensing device disclosed in Patent Document 2.

The present invention is an improvement of a conventional drug dispensing device, and an object of the present invention is to develop a drug dispensing device capable of automatically cleaning the inside.

A desirable embodiment of the powder weighing device is a powder weighing device that takes out a predetermined amount of powder from the drug container, and comprises a drug discharging means that acts on the drug container to discharge the powder from the drug container and a powder discharged from the drug container. It has a temporary container to receive and a fixed measuring means, the temporary container is placed on the measuring means, the amount of powder discharged from the drug container is monitored by the measuring means, and the desired amount of powder is dispensed by the drug discharging means. It is a powder weighing device characterized by discharging from a container and charging powder into a temporary container.

A desirable embodiment of the powder weighing device is to transport a drug discharging means that acts on the drug container to discharge the powder from the drug container, a temporary container that receives the powder discharged from the drug container, a fixed weighing means, and a temporary container. The temporary container is provided with a means for transporting the temporary container, the temporary container is placed on the measuring means, the amount of powder discharged from the drug container is monitored by the measuring means, and the desired amount of powder is discharged from the drug container by the drug discharging means. It is a powder weighing device characterized in that powder is charged into a temporary container and the temporary container is moved by a temporary container transport means.

In each aspect of the powder weighing device described above, the drug container has a powder storage unit for storing powder and a powder discharge unit for discharging powder, and a part or all of the drug discharge means is provided in the drug container. It is desirable to remove the powder from the powder discharge section by driving the drug discharge means in the drug container.

In each aspect of the powder weighing device described above, the drug container has a powder storage section for storing the powder and a powder discharging section for discharging the powder, and the drug discharging means is a vibrating means for vibrating the drug container installation section. It is desirable that the weight measuring means indirectly monitors the weight of the powder transferred to the temporary container from the change in the weight of the drug container.

The preferred embodiments of the powder weighing device are an array shelf, a drug container, a container mounting device that acts on the drug container to discharge the powder from the drug container, a temporary container that receives the powder discharged from the drug container, and a weighing means. It is a powder weighing device equipped with It is a powder weighing device characterized in that powder is discharged from the drug container of the unit to a temporary container and the amount of powder discharged into the temporary container is monitored by a measuring means.
It is desirable that the above aspect includes an operation in which the amount of powder discharged into the temporary container is monitored by the measuring means, and the container mounting device is stopped when a predetermined amount of powder falls into the temporary container.

Another embodiment has the above-mentioned powder weighing device and a drug packaging device that divides the drug into a desired number and individually packages the drug, and manually or automatically packages the powder in the temporary container. It is a drug packaging system characterized by being able to be put into.

According to the drug dispensing device of the present invention, the inside can be automatically cleaned. Therefore, it is possible to prevent foreign matter from being mixed in the drug package.

It is a perspective view of the drug dispensing apparatus which concerns on embodiment of this invention. It is a perspective view which shows through the housing of the main body apparatus of FIG. It is a perspective view which shows the container moving apparatus shown in FIG. FIG. 3 is an enlarged perspective view showing a drug division region of FIG. 2. It is a perspective view of the drug container and the container mounting device adopted in the drug dispensing device of FIG. 1, and shows the state in which the drug container is mounted on the container mounting device. It is sectional drawing of the drug container shown in FIG. 5, (a) shows the state which a lid member is open, and (b) shows the state which a lid member is closed. It is a perspective view which shows an example of a container moving device. It is a perspective view which shows another example of a container moving device. It is sectional drawing of an example of a drug container. The right figure of (a) is a schematic representation of the AA cross section of the drug container of FIG. 6 (a), the left figure is an arrow view thereof, and the right of (b) and (c). The figure is a schematic view corresponding to the AA cross section of the medicine container of another embodiment, and the left figure is an arrow view thereof. Yet another embodiment of the drug container, (a) indicates a state in which the lid member is open, (b) indicates a state in which the lid member is closed, and (c) conceptually indicates a drug discharge portion on the left side thereof. It is a side view displayed in the above, and (d) is a side view conceptually displaying the drug discharging portion on the right side thereof. It is explanatory drawing which showed the medicine payout apparatus of another Embodiment of this invention in a schematic plan view. It is a perspective view of the solid medicine feeder which discharges a solid medicine. It is an exploded perspective view of the solid medicine feeder of FIG. It is a perspective view of a hand-sowing device. It is a perspective view which shows typically the drug dispensing apparatus of another embodiment. It is sectional drawing of the powder feeder. It is a perspective view schematically showing the medicine dispensing apparatus of another embodiment. It is a perspective view schematically showing the medicine dispensing apparatus of another embodiment. It is a perspective view of the drug packaging system of the embodiment of this invention. It is a perspective view of the drug packaging system of another embodiment of this invention. It is a perspective view of the drug packaging system of still another embodiment of this invention. It is a perspective view of the drug packaging system of still another embodiment of this invention.

Hereinafter, embodiments of the present invention will be further described.
The drug dispensing device 1 of the present embodiment has a basic configuration of a drug dispensing device for which the applicant has applied for a patent in the past, and various improvements have been made thereto.
Prior to the explanation of the added improvement points, the basic configuration of the drug dispensing device 1 will be described.
As shown in FIG. 1, the drug dispensing device 1 of the present embodiment includes a housing 10 constituting the main body and an operation display unit 3.
A large number of drug containers 4 are housed in the drug dispensing device 1. Each drug container 4 is filled with powder. The drug dispensing device 1 selects a desired drug container 4 by operating the operation display unit 3, automatically takes out the powder contained in the drug container 4, weighs it, divides it into a predetermined number, and packages the powder. It is a device.

The drug dispensing device 1 has various devices built in the housing 10. Specifically, as shown in FIG. 2, the inside of the housing 10 is divided into a container arrangement area 12, a drug division area 13, and a drug packaging area 14.

As shown in FIG. 1, a door portion 16 is provided on a portion of the housing 10 that forms the outer wall surface of the container arrangement region 12.
The door portion 16 is a container loading / unloading port for loading / unloading the drug container 4 into / from the housing 10.

As shown in FIG. 2, the container arrangement area 12 of the housing 10 is provided with a container storage unit 23 for holding the drug container 4.
The container storage unit 23 includes a drum member 25 installed in an upright posture. The drum member 25 can rotate about a rotation axis extending in the vertical direction.

A plurality of container installation portions are provided on the outer peripheral surface of the drum member 25, and the drug container 4 is held in the container installation portions.

A container moving means 28 is provided in a region extending from the container arrangement region 12 to the drug division region 13. The container moving means 28 is a kind of robot, and has a structure including an arm portion 30 and an elevating mechanism 31, and the elevating mechanism 31 allows the arm portion 30 to move in the vertical direction. That is, the container moving means 28 is a kind of robot, and includes an arm portion 30 which is a robot arm.

As shown in FIG. 3, the arm portion 30 includes a trunk arm member 45 attached to the lifting platform 43 of the lifting mechanism 31, an intermediate arm member 46 attached to the tip end side of the trunk arm member 45, and an intermediate arm member. The structure is provided with a hand portion 47 attached to the tip side of the 46.

The trunk arm member 45 is attached to the elevating table 43 via a vertical axis (not shown), and is rotatable in the horizontal direction about the elevating table 43.
The intermediate arm member 46 is also attached to the tip of the trunk arm member 45 via a vertical axis (not shown), and is rotatable in the horizontal direction about the tip of the trunk arm member 45.

The hand portion 47 is roughly divided into a trunk portion 48 and a container holding portion 55, and these are integrally attached via a mounting bracket 56.
The trunk portion 48 is attached to the tip of the intermediate arm member 46 via a vertical axis (not shown), and is rotatable in the horizontal direction about the tip of the intermediate arm member 46.

The container holding portion 55 includes an electromagnet (not shown) for adsorbing the drug container 4.

In the drug dividing region 13, in the space located on the rear side of the front door 34 (see FIG. 1), as shown in FIG. 4, the distribution dish 35, the container mounting device (drug discharging means) 36, and the scratching are performed. A discharge device 37, a cleaning device 38, a drug inlet 39, and a camera member (photographing device) 40 are provided.
In the drug dividing region 13, a device for dividing the drug into a desired number by a distribution dish method is arranged.
In the present embodiment, two distribution dishes 35 are installed in parallel in the drug division region 13.
The number of distribution plates 35 is not limited and may be one, but it is desirable to have a plurality of distribution plates 35.

A container mounting device 36, a scraping device 37, and a cleaning device 38 are provided around each distribution dish 35. Specifically, one distribution dish 35 is associated with three container mounting devices 36, one scraping device 37, and one cleaning device 38.

The scraping device 37 is composed of a scraping mechanism 27 provided at the tip of the scraping arm 26 and the scraping arm 26. The scraping mechanism 27 has a disk-shaped scraping plate 57 that is rotated by power and a scraping plate 58.

Around the distribution plate 35, a drug inlet 39 for supplying powder to the drug packaging area 14 one by one is provided between the two distribution plates 35. In FIGS. 2 and 3, a lid 17 is provided on the drug inlet 39. A lid 17 is provided. The lid 17 automatically opens when the drug is charged into the drug inlet 39.

The distribution dish 35 is provided with a drug charging groove 32 that is continuous in an annular shape. The distribution dish 35 can be rotated by a rotation mechanism (not shown).

As shown in FIG. 5, the container mounting device 36 includes a shaking table 50 and a weight measuring means (measuring means) 52. The vibrating table 50 is provided with a vibrating means 51, and the vibrating table 50 vibrates when the vibrating means 51 is energized.

The shaking table 50 is provided with a container holding means for holding the drug container 4. In this embodiment, a magnet (not shown by an electromagnet) is used as a container holding means.

The weight measuring means (emission amount detecting means) 52 directly or indirectly measures the weight of the drug container 4.

In the present embodiment, the drug container 4 can be placed on the container mounting device 36, the drug container 4 can be vibrated, and the powder contained in the drug container 4 can be discharged to the distribution dish 35. Then, the weight change of the drug container 4 due to the discharge of the powder can be detected by the weight measuring means 52. In the present embodiment, the weight measuring means 52 functions as a discharge amount detecting means, and the discharge amount of the powder is detected by the weight change of the drug container 4.

The drug packaging area 14 is provided with a known drug packaging device 53 and printing means.
The drug packaging device 53 is a machine for packaging drugs one by one, and is formed by a sheet supply device and a sealing device. That is, the sheet supplied from the sheet supply device is formed in the shape of a bag to create a sachet, and the powder supplied from the drug division region 13 is sealed with the created sachet by the sealing device for each dose. , Package.
The printing means is a machine for printing predetermined information on the sachet.

The drug container 4 is a container having a substantially rectangular parallelepiped outer shape, and can accommodate powdered medicine inside. The drug container 4 is composed of a container body 6 and a lid 190 as shown in FIGS. 5 and 6. The lid 190 can be removed from the container body 6. In the present embodiment, the lid 190 is removed from the container body 6 to widen one end side of the container body 6 and filled with powder.
Further, as shown in FIG. 6A, the lid 190 can be opened to partially open the lid 190. Internal powder can be drained from the opening 188 formed by opening the lid 190.
Further, iron plates 182 and 183 are attached to two different surfaces of the drug container 4, respectively. The iron plate 183 provided on one surface is a portion for being attracted to the magnet of the arm portion 30 when the drug container 4 is held by the arm portion 30. Further, the iron plate 182 provided on the other surface is a portion for being attracted to the electromagnet 41 of the container mounting device 36 when it is installed in the container mounting device 36 described later.

Next, the basic operation of the drug dispensing device 1 of the present embodiment will be described.
The drug dispensing device 1 of the present embodiment can input information about a prescription, and based on the information, can perform a packaging operation of packaging powders for each dose.

That is, the drug dispensing device 1 has an operation of accommodating the drug container 4 in the container storage unit 23, an operation of taking out the drug container 4 from the container storage unit 23, an operation of moving the taken out drug container 4 to the vicinity of the distribution dish 35, and an operation of the drug container. The operation of placing 4 on the container mounting device 36, the operation of charging a predetermined amount of the drug into the distribution dish 35, the operation of supplying the drug from the distribution dish 35 to the drug packaging device 53 one by one, the operation of supplying the drug container 4 to the container. The operation of returning to the storage unit 23 is automatically performed. It should be noted that each of these operations is an operation controlled by a control unit (not shown).

As a preparatory step, the drug container 4 is filled with powder, and some of them are attached to the container storage unit 23 of the container arrangement area 12.

In the drug dispensing device 1 of the present embodiment, information regarding the prescription is input, and the packaging operation is automatically executed based on the information.

That is, in the drug dispensing device 1 of the present embodiment, the drug container 4 filled with the required powder is selected based on the information regarding the prescription, and the required drug container 4 is placed on the container from the container storage unit 23 by the container moving means 28. It is transported to the placement device 36.
The drug container 4 is held by the electromagnet 41 built in the shaking table 50.
Subsequently, a current of a constant frequency is applied to the vibrating means 51 to generate vibration, and the vibration table 50 is vibrated by this vibration.
Further, the distribution plate 35 is rotated before and after the start of vibration.

Before and after the start of vibration, the weight of the drug container 4 is measured by the weight measuring means 52. The weight of the drug container 4 is obtained by subtracting a constant value from the detected weight of the weight measuring means 52. More specifically, the weight of the drug container 4 is obtained by subtracting the weight of the member above the weight measuring means 52 of the container mounting device 36 from the detected weight of the weight measuring means 52.
The weight of the drug container 4 immediately after being installed on the shaking table 50 is stored as the original weight G. Further, the weight of the drug container 4 is constantly monitored. That is, the current weight of the drug container 4 is monitored as the current weight g.

When the shaking table 50 starts to vibrate, the medicine container 4 vibrates. Here, in the present embodiment, since the drug container 4 is firmly joined to the shaking table 50 by the electromagnet 41 and the degree of adhesion to the shaking table 50 is high, the drug container 4 has the same frequency as the shaking table 50. Vibrate. As a result, the powdered drug stored in the drug container 4 slowly moves toward the opening 188 side, is discharged from the opening 188, and falls.

The fact that the powder is falling is confirmed by the weight reduction of the drug container 4. Further, the amount of powdered medicine discharged is detected by the weight measuring means 52. That is, in the present embodiment, the current weight (current weight g) of the drug container 4 is continuously monitored by the weight measuring means 52 even while the powder is falling from the opening 188 of the drug container 4. Then, the original weight G of the drug container 4 immediately after installation on the shaking table 50 and the current weight g are compared, and the drop amount H (G minus g) of the powder is constantly calculated.
Then, when the total drop amount H of the powder reaches a desired weight, the vibration of the shaking table 50 is stopped.
That is, when the current weight g of the drug container 4 measured by the weight measuring means 52 is less than the original weight G before the start of vibration measured by the weight measuring means 52 by a desired weight, the vibration of the shaking table 50 is stopped. ..

After that, the rotation of the distribution plate 35 is stopped. Then, the scraping arm 26 of the scraping device 37 is swung, the tip side is lowered to lower the scraping mechanism 27, and the disc-shaped scraping plate 57 of the scraping mechanism 27 is placed in the drug charging groove of the distribution dish 35. Put it in 32.
Further, the distribution plate 35 is rotated by an angle corresponding to the number of distribution plates, and is scraped to the scraping plate 57. Subsequently, the scraping plate 57 is rotated, the medicine is scooped up by the scraping plate 58, discharged from the distribution plate 35, and the medicine is charged into the medicine charging port 39.
The drug charged into the drug charging port 39 drops a powder charging hopper (not shown), is carried to the drug packaging device 53, and is packaged in the drug packaging device 53.
This operation is sequentially repeated, all the medicines in the distribution dish 35 are discharged, and each medicine is packed in the medicine packaging device 53.
In parallel with this, the container moving means 28 is activated, and the drug container 4 is returned to the drum member 25 of the container storage unit 23.

Next, the improvements added to the basic configuration will be described.
The object of the drug dispensing device 1 of the present embodiment is to develop a drug dispensing device capable of automatically cleaning the inside.
The container moving means 28 of the drug dispensing device 1 of the present embodiment is a kind of robot, and includes an arm portion 30 and an elevating mechanism 31.
In the present embodiment, as shown in FIG. 7, the nozzle portion 60 of the dust collector is attached to the arm portion 30. The dust collector is a known vacuum cleaner, and the main body is not shown.
In this embodiment, the dust collector is operating while the arm portion 30 is operating. The arm portion 30 moves in the space inside the housing 10 when the drug container 4 is moved. Therefore, the nozzle portion 60 moves inside the housing 10 and sucks dust floating in the air and fine powder of the drug.
Therefore, dust and other chemicals are prevented from falling on the distribution dish 35.

Further, in the present embodiment, the cleaning tool 61 can be held by the hand portion 47 of the container moving means 28 as shown in FIG. The cleaning tool 61 is not limited, but for example, a brush, a wiping cloth, or the like can be considered. A blower can also be used for the cleaning tool 61.
In FIG. 8, a brush is used as the cleaning tool 61. Further, a small vacuum cleaner or only the nozzle portion of the vacuum cleaner may be held by the hand portion 47.
These cleaning tools 61 are stored in a predetermined position in the housing 10. Then, if necessary, the container moving means 28 moves to pick up the cleaning tool 61, for example, holding the cleaning tool 61 by a magnet or the like (not shown).

Then, for example, the cleaning tool 61 is pressed against the distribution plate 35 and rubbed to clean the distribution plate 35.
It is also possible to replace the cleaning tool 61 and perform cleaning in order.
For example, first, the brush is held as a cleaning tool 61, the distribution plate 35 is rubbed, and the chemicals and the like stuck to the distribution plate 35 are scraped off. Subsequently, the cleaning tool 61 is replaced with a vacuum cleaner, and dust and chemicals remaining on the surface of the distribution dish 35 are sucked up. Finally, the cleaning tool 61 is replaced with a wiping cloth, and the distribution dish 35 is patted to be adsorbed on the dust and the wiping cloth remaining on the surface.
Of course, at the same time as rubbing the distribution dish 35 with a brush, the scraped dust or the like may be sucked. For example, the nozzle portion 60 may be attached in the vicinity of the holding portion of the cleaning tool 61, and the shavings may be sucked by the nozzle portion 60 while rubbing the distribution dish 35 with a brush.

As one of the cleaning tools 61, the nozzle portion of the vacuum cleaner is exemplified, but the shape of the nozzle is arbitrary, and an elongated one or one that follows the cross-sectional shape of the distribution dish 35 can be considered. Further, a plurality of nozzles having different shapes may be built in the housing 10, and a necessary nozzle may be selected and held by the hand portion 47.
Further, the nozzle or brush of the vacuum cleaner may be inserted into the gap between the container mounting devices 36 for cleaning.

In the drug dispensing device 1 of the present embodiment, the container moving means 28 has a dust collecting means, and the inside of the drug dispensing device 1 can be cleaned by the dust collecting means.

Further, in the drug dispensing device 1 of the present embodiment, the container moving means 28 can hold the cleaning device 61, and the container moving means 28 is operated to bring the cleaning device 61 into contact with the internal device to dispense the drug. It is possible to clean the inside of 1.

In the above-described embodiment, the nozzle unit 60 is provided on the arm unit 30 and the external dust collector and the nozzle unit 60 are connected. However, the nozzle unit 60 is connected to the blower and blown from the nozzle unit 60 to discharge the drug. The inside of 1 may be cleaned. In this configuration, the nozzle portion 60 functions as a cleaning tool (a part of the blower).
A nozzle for collecting dust and a nozzle for connecting a blower may be provided separately, and the dust blown off by the nozzle for blower and the dust soared by the nozzle for collecting dust may be collected.
Further, a blower may be provided outside and the nozzle portion 60 may be connected to both the suction side and the discharge side of the blower so as to be switchable.
According to this configuration, the nozzle unit 60 is first connected to the discharge side of the blower to blow air from the nozzle unit 60 to scatter dust and the like in the drug dispensing device 1, and then the nozzle unit 60 is connected to the suction side of the blower to form a nozzle. Air is sucked from the unit 60, and the dust flying in the drug dispensing device 1 is collected.

Further, in the present embodiment, a device has been devised to prevent the drug from sticking or forming a lump in the drug container 4.
That is, in the present embodiment, the vibration generator 62 is attached to the mounting bracket 56 that connects the hand portion 47 and the arm portion 30 of the container moving means 28. It is desirable that the vibration generator 62 generates ultrasonic vibration.
The vibration generator 62 functions while the drug container 4 moves the drug container 4 from the container storage unit 23 to the vicinity of the distribution dish 35 by the container moving means 28.
While the drug container 4 is moving, the drug container 4 is vibrated by ultrasonic vibration, and the drug in the drug container 4 is loosened.

In the drug dispensing device 1 of the present embodiment, the container moving means 28 is provided, and the predetermined drug container 4 is taken out from the container storage unit 23 of the container arranging area 12 by the container moving means 28, and the container placing device 36 in the drug dividing region is provided. The drug is discharged from the drug container 4 and charged into the drug charging groove 32 of the distribution dish 35, and the powder charged into the distribution dish 35 by the scraping device 37 is scraped out from the drug charging groove 32 to the drug packaging area. The drug container 4 which has been dropped to the 14 side and has been discharged can be returned to the container storage unit 23 of the container arrangement area 12 by the container moving means 28, and the container moving means 28 has a vibration generator 62 and the drug. The drug in the drug container 4 can be loosened by vibrating the container 4.

Further, the conventional drug dispensing device does not have a means for confirming whether or not the drug is evenly dispersed in the drug charging groove 32 of the distribution dish 35. Therefore, even if there is a lump of medicine in the medicine container 4 or the medicine distribution in the medicine charging groove 32 becomes imbalanced due to the cause of the vibration of the container placing device 36 being unbalanced, this may occur. Could not be detected.
In the present embodiment, a device has been devised for the purpose of confirming whether or not the drug is evenly dispersed in the drug charging groove 32 of the distribution dish 35.

As shown in FIG. 4, in the drug dispensing device 1 of the present embodiment, the distance measuring sensor 65 is provided on the drug charging groove 32 of the distribution dish 35.
Here, the distance measuring sensor 65 measures the position of the object to be measured, for example, measuring the distance between the distance measuring sensor 65 and the object to be measured.
In the present embodiment, the distance measuring sensor 65 is located on the medicine charging groove 32 of the distribution dish 35, and measures the distance between the distance measuring sensor 65 and the surface of the medicine charging groove 32.
Therefore, if the drug is charged into the drug charging groove 32, the position of the drug and the distance between the distance measuring sensor 65 will be measured.

In the present embodiment, the distribution plate 35 is rotated and the distance measuring sensor 65 monitors the filling condition of the medicine. And if there is a variation in the height of the drug, some kind of alarm is issued.

The drug dispensing device 1 of the present embodiment has a distance measuring sensor 65 that detects the position of the surface of the distribution plate 35, and detects the height of the powder charged into the distribution plate 35 by the distance measuring sensor 65. ..

Further, the conventional drug dispensing device does not have a means for confirming whether or not the drug charged in the distribution dish 35 is a truly desired drug. Therefore, if the drug container 4 is filled with the wrong drug by some mistake, there is a concern that the wrong drug will be provided to the patient.
In the present embodiment, a device has been devised for the purpose of confirming whether or not the drug charged in the distribution dish 35 is a truly desired drug.

In the drug dispensing device 1 of the present embodiment, as shown in FIG. 4, the spectroscope 66 is provided in the vicinity of the distribution dish 35, and the electromagnetic wave emitted by the powder charged in the distribution dish 35 is detected by the spectroscope 66 and the distribution dish 35 is detected. You can check the type of powder that was put into the.
If the electromagnetic wave emitted by the drug is spectroscopically analyzed by the spectroscope 66, the drug can be roughly identified. In the present embodiment, the drug is identified from the electromagnetic wave emitted by the drug charged in the distribution dish 35 and compared with the prescribed drug. If they are different, some kind of alarm is issued.

Further, in the present embodiment, the camera member (photographing device) 40 is provided as shown in FIG.
In the present embodiment, the image pickup device for photographing the inside of the drug dispensing device 1 is provided, and the inside of the drug dispensing device 1 is photographed and recorded automatically and periodically by the photographing device.

Next, a modified example of the drug container will be described.
As shown in FIGS. 5 and 6, the above-mentioned drug container 4 is composed of a container body 6 and a lid 190, and the lid 190 is removed to widen one end side of the container body 6 to fill powder.
Further, as shown in FIG. 6A, the lid 190 is opened to partially open the lid 190, and the powder inside is discharged.
The drug container 4 described above is filled with the drug by removing the lid 190 on the left side of FIG. 6, and the drug is discharged from the same left lid 190 and put into the distribution dish 35.
In the above-mentioned drug container 4, the drug is charged from one side and the drug is discharged from the same side, so that the old drug may remain in the back of the container body 6.
That is, since the drug container 4 has the same filling route and dispensing route for the drug, the drug cannot be first-in, first-out unless the drug is completely discharged.

In the present embodiment, the drug can be first-in first-out by separating the drug filling route and the drug dispensing route, and a device has been devised to prevent the old drug from remaining.
Further, in the present embodiment, a device has been devised to shake off the adhered drug.

FIG. 9 is a cross-sectional view of the drug container 70 of the modified example.
The same members as those of the drug container 4 of the previous embodiment are designated by the same number.
Also about the drug container 70 of this embodiment. It is composed of a container body 71 and a lid 190. The shape and structure of the lid 190 are the same as those in the above-described embodiment.
The container body 71 of the drug container 70 of the present embodiment has a drug discharge opening 73 to which a lid 190 is attached, and a drug filling port 72 used for filling the drug.

The drug container 70 is installed in the container mounting device 36 described above in a vertical posture.
The drug discharge opening 73 is located at the lower part in the height direction with respect to the posture attached to the container mounting device 36, and is open to one side surface side.
On the other hand, the drug filling port 72 is located at the upper part in the height direction with respect to the posture attached to the container mounting device 36, and is open to the top surface. A lid member 75 is attached to the drug filling port 72.

A sieve portion 76 is provided inside the container body 71. In the present embodiment, the position of the sieve portion 76 in the height direction is between the drug discharge opening 73 and the drug filling port 72.
The phloem 76 is a plate or wall provided with a large number of small openings such as meshes and grids.

In the present embodiment, the medicine is filled from the medicine filling port 72 provided at the upper part. Then, the container body 71 is shaken as needed. Alternatively, vibration is mechanically applied. As a result, the filled drug passes through the phloem 76, and the lump is eliminated.
When the drug that has fallen to the lower part is attached to the container mounting device 36 and receives vibration, it advances horizontally toward the drug discharge opening 73 side of the lid 190 and is discharged from the drug discharge opening 73.

The container body 71 of the present embodiment is a vertical container and is discharged from the previously charged powder.
Further, since the sieve portion 76 is provided inside the container main body 71, the adhered chemical can be crushed and discharged by the mesh and the impact and vibration dropped.

Further, since the container body 71 is a vertical type, the outer shape of the container moving means 28 and the drug dispensing device 1 can be reduced.

Next, another modification of the drug container will be described.
By opening the lid 190 of the above-mentioned drug container 4, an opening 188 is formed in the container body, and the drug is discharged from the opening 188.
In the above-mentioned drug container 4, the size and shape of the opening for discharging the drug are fixed and cannot be changed.
Further, the route to the opening 188 in the drug container 4 is also fixed and cannot be changed.

However, the optimum opening diameter and opening shape differ depending on the amount of the drug discharged and the properties of the drug. Similarly, the optimum shape of the cross-sectional shape and the planar shape of the path leading to the opening 188 differs depending on the properties of the drug.
In the present embodiment, a device has been devised to change the shape of the drug discharging portion (opening 188) for discharging the drug.

The external shape of the drug container 80 of the present embodiment is the same as that of the drug container 4 of FIG. 6 described above.
In the drug container 80 of the present embodiment, the shape changing members 81 and 82 can be inserted into the drug discharging portion (opening 188), and the shape of the opening 188 can be changed.

The right figure of FIG. 10A is a schematic representation of the AA cross section of the drug container 4 of FIG. 6, and the left figure is an arrow view thereof.
In the drug container 4, the shape of the drug discharge portion (opening 188) is a rectangle with a low height. Further, the cross-sectional shape of the path leading to the opening 188 is not much different from the shape of the drug discharging portion (opening 188). The planar shape of the path leading to the opening 188 is a rectangle over the entire width of the inside of the drug container 4.

The drug container 80 of the present embodiment has the shape changing members 81 and 82 inserted in the opening 188.
Here, in the drug container 80a shown in FIG. 10B, a rectangular parallelepiped shape-changing member 81 is attached to both inner walls of the drug container 4.
In the drug container 80a, the opening 188 is small. The shape of the opening 188 is a rectangle close to a square.

The drug container 80b shown in FIG. 10 (c) has a right-angled trapezoidal shape-changing member 82 mounted on both inner walls of the drug container 4.
In the drug container 80b, the opening 188 is small. The shape of the opening 188 is an inverted, isosceles trapezoidal shape, and has an inclined surface on the side surface.
Further, the cross-sectional shape of the path leading to the opening 188 is not much different from the shape of the drug discharging portion (opening 188).

The drug container 80 has a drug discharge section (opening 188) for discharging the drug inside, and the container mounting device 36 vibrates the drug container 80 to move the drug in the drug container 80, and the drug discharge section The size of the drug discharging section and / or the width of the route to the drug discharging section in the drug container 80 can be changed.

Further, the drug container 80 has a drug discharge section (opening 188) for discharging the drug inside, and the container mounting device 36 vibrates the drug container 80 to move the drug in the drug container 80 and discharge the drug. The drug is discharged from the section, and the shape of the drug discharging section and / or the cross-sectional shape of the path leading to the drug discharging section in the drug container 80 can be changed.

The drug containers 4, 70, 80 described above all have only one drug discharging section (opening 188), but may have a plurality of drug discharging sections.
The drug container 140 shown in FIG. 11 has lids 190 at both ends of the container body 6, and drug discharge portions (openings 188a and 188b) on both sides of the container body 6.
The two drug discharging portions (openings 188a and 188b) have different openings, and the amount of drug that can pass through in a certain period of time is different.
That is, the drug discharging section (opening 188b) on the right side of the drawing has a smaller opening area than the drug discharging section (opening 188a) on the left side of the drawing.
Therefore, the amount of drug that can pass through the drug discharging portion (opening 188b) on the right side of the drawing in a certain time is smaller than that of the other.
Not only the area of the opening but also the shape of the opening may be changed.

Further, the route to the drug discharge portion (opening 188b) on the right side of the drawing is inclined upward toward the opening 188b.
Therefore, when the drug moves in the drug container 140 toward the opening 188b, the resistance applied to the drug is large.
The drug discharging section (opening 188b) on the right side of the drawing is used when a small amount of the drug is discharged.

The drug container 140 of the present embodiment has a plurality of drug discharging portions (openings 188a, 188b) for discharging the internal drug.
In addition, there are drug discharge sections having different opening areas and / or opening shapes. The drug moves in the drug container 140 and reaches the drug discharging section, and there is a drug discharging section having a different resistance to the drug before reaching the drug discharging section.

In the embodiment described above, only the powder is sent to the drug packaging area 14 and only the powder is packaged one by one, but a solid drug such as a tablet or a capsule may be packaged together with the powder.
Hereinafter, this configuration will be described. The drug dispensing device 1 described above is provided with a drug charging port 39 for charging the powdered drug scraped from the distribution dish 35 into the drug packaging area 14.
In the drug dispensing device 85 of the present embodiment, a solid drug feeder 86 for discharging a solid drug is arranged around a drug inlet 39.
FIG. 12 is a plan view showing the layout of the drug division region of the drug dispensing device 85 of the present embodiment.
The drug dispensing device 85 also has two distribution dishes 35, and a drug input port 39 is provided between them.

And three solid drug feeders 86 are provided in the vicinity of the drug inlet 39.
Here, the solid drug feeder 86 is disclosed in, for example, Japanese Patent Application Laid-Open No. 2014-144207, and is a device for dispensing solid drugs such as tablets and capsules one by one.
The solid drug feeder 86 used in the present embodiment is a known one, and its external shape is as shown in FIG.
As shown in FIG. 14, the solid drug feeder 86 is composed of a drug cassette 87 for accommodating a large number of tablets and a support 88 on which the drug cassette is mounted. The medicine cassette 87 is removable from the support base 88.
The drug cassette 87 has a storage section 90 provided with a drug storage space for storing a large number of tablets, and the rotor 91 is housed inside the storage section 90. A drug accommodating groove is provided on the outer peripheral surface of the rotor 91, and a plurality of pocket portions are formed in the space between the accommodating portion 90 and the inner wall. The plurality of pocket portions have a function of inflowing and holding the tablets contained in the accommodating portion 90. The drug storage groove is a groove whose upper and lower sides are open. Further, the pocket portion is a space in which the opening portion of the drug accommodating groove is closed by the inner wall of the accommodating portion, and the upper and lower portions are open.
A rotor gear is mounted on the rotating shaft of the rotor 91. Further, the accommodating portion 90 is formed with a drug discharging port at a position capable of communicating with the drug accommodating groove provided on the outer peripheral surface of the rotor 91.

On the other hand, a motor 93 such as a geared motor is housed in the support base 88, and a drive gear 92 is mounted on the rotating shaft of the motor. The support table 88 has a drive unit for driving the rotor 91 in the drug cassette 87.
When the motor 93 housed in the support base 88 is driven, the rotational force is transmitted from the drive gear 92 to the rotor gear, and the rotor 91 rotates. Then, the rotation of the rotor 91 stirs the tablet in the accommodating portion, and the tablet enters the pocket portion.

Then, the rotor 91 further rotates, the pocket portion sequentially reaches the drug discharge port, and the tablets held in the pocket portion are sequentially discharged from the drug discharge port.

In this embodiment, three solid drug feeders 86 are provided in the vicinity of the drug inlet 39. More precisely, three support bases 88 of the solid medicine feeder 86 are fixed in the vicinity of the medicine inlet 39.
As described above, the solid drug feeder 86 is composed of a drug cassette 87 and a support table 88, and the drug cassette 87 is removable from the support table 88. In the present embodiment, only the support table 88 is fixed in the vicinity of the drug input port 39, and the necessary drug cassette 87 is mounted on the support table 88.
Like the drug container 4, the drug cassette 87 is housed in the container arrangement area 12 in the housing 10, is held by the container moving means 28 as needed, is transported to the vicinity of the drug inlet 39, and is supported. It is mounted on the table 88.

Further, the medicine cassette 87 may be attached to the support base 88 by the user's hand.
For example, the drug dispensing device 1 has a front door 34 as shown in FIG. The user may manually open the front door 34, insert the drug cassette 87 into the drug dispensing device 1 from the outside, and attach it to the support base 88.
Further, as shown in FIG. 1, since the front door 34 has a small door 33, the medicine cassette 87 may be inserted from the small door 33 and mounted on the support base 88.

It is desirable that the drug cassette 87 is provided with an information storage member such as RFID, and the information of the drug contained in the drug cassette 87 is stored in the information storage member.
Further, a reading means for reading information from the information storage member is provided in or near the support base 88, and the prescription information and the information of the attached drug cassette 87 are collated. If they are different, it is desirable to give some kind of notification.

Further, in order to improve workability and safety, it is also recommended to use an automatic door that opens and closes the front door 34 and the small door 33 by power.
For example, when the prescription information input to the drug dispensing device 1 contains a drug to be supplied from the drug cassette 87, the front door 34 or any of the small doors 33 automatically opens. Then, an indicator lamp (not shown) of any of the support bases 88 lights up, indicating the support base 88 on which the medicine cassette 87 should be placed.
The pharmacist or the like inserts the necessary drug cassette 87 into the device through the front door 34 or the small door 33, and installs it on the designated support base 88.
The drug dispensing device 1 automatically reads information from the information storage member of the installed drug cassette 87, and collates the prescription information with the information of the mounted drug cassette 87.
If the attached drug cassette 87 matches the prescription information, for example, a character or symbol meaning "set completed" is displayed on the operation display unit 3.
Then, the front door 34 and the small door 33 that have been opened are automatically closed.

Also in the drug dispensing device 85 of the present embodiment, after the powder is charged into the distribution plate 35, the powder is ejected from the distribution plate 35 one by one by the scraping device 37, and the drug is charged into the drug inlet 39. At this time, the solid drug feeder 86 is activated, and at the same time as the powdered drug, the solid drug to be taken by the patient is discharged one by one, and the drug is charged into the drug inlet 39.
Then, one dose of powdered medicine and solid medicine are packaged in the same bag.

The drug dispensing device 85 of the present embodiment has a solid drug feeder 86 containing a solid drug and discharging a desired number of solid drugs, and has a drug inlet 39 for charging the drug on the drug packaging region 14 side. It is possible to charge the solid drug into the drug inlet 39 from the solid drug feeder 86.

Further, a large number of solid drug feeders 86 in which the drug cassette 87 and the support base 88 are combined are arranged at positions away from the distribution plate 35, and the gutter, slope, conveyor, robot, etc. are transported between the drug cassette 87 and the drug inlet 39. The solid drug discharged from the solid drug feeder 86 may be connected by means and charged into the drug inlet 39 by using the transport means. In this case, the drug inlet 39 may be different from the drug inlet 39 into which the powder is charged.

The drug dispensing device of the present embodiment has a plurality of solid drug feeders 86 containing a solid drug and discharging a desired number of solid drugs, and the solid drug feeder 86 is arranged at a predetermined position and has a drug packaging area. There is a drug inlet 39 for charging the drug on the 14 side, there is a solid drug moving means for moving the solid drug discharged from the solid drug feeder 86, and the solid drug discharged from the solid drug feeder 86 is used as the solid drug moving means. It is possible to move it with and charge it into the drug inlet 39.

The above-mentioned drug dispensing device 85 automatically counts solid drugs and charges them into the drug charging port 39. For example, a distribution device called a hand-sowing device 130 as shown in FIG. 15 is used. May be good.
The hand-sowing device 130 has a hand-sowing basin member 131, and a divider 132 is provided below the basin member 131. The hand-spreading basin member 131 has a large number of divided basins 133 having a square-shaped front view and opening to the top surface side, and by opening a shutter (not shown) provided at the bottom of the divided basin members 131, each divided small basin member 131 is opened. The medicine contained in the box 133 can be discharged to the lower divider 132 side.

The divider 132 has a large number of dividing basins 135, which are divided into squares like the dividing basin 133. A shutter is also provided for the dividing basin 135 of the dividing device 132.

The user sows the solid medicine into the hand-sowing box member 131 one by one. Then, the shutter provided at the lower part of the hand-spraying box member 131 is opened, and all the solid chemicals are transferred to the divider 132 side.
Then, the shutters of the divider 132 are opened one by one, and the solid drug is charged into the drug charging port 39 via a hopper and a transport mechanism (not shown).

Further, a tablet dispensing device independent from the above-mentioned drug dispensing devices 1,85 may be used in combination. For example, a drug packaging device (hereinafter referred to as another drug packaging device) as disclosed in Japanese Patent Application Laid-Open No. 2007-246114 is used in combination with the drug dispensing devices 1,85. The other drug packaging device disclosed in Japanese Patent Application Laid-Open No. 2007-246114 has a function of automatically counting and packaging solid drugs. This drug packaging device can also package powder.

For example, when the control device of the drug dispensing devices 1,85 receives the prescription and it is determined that the prescription cannot be satisfied by the drug dispensing device 1,85 alone because the prescription contains tablets, the portion dedicated to the solid drug. The contents of the prescription are automatically transmitted to the packaging device, and tablets and the like are packaged by the solid drug packaging device.
In addition, when the usage status of the drug dispensing device 1,85 is crowded and the patient is in a hurry due to a long waiting time, or when the drug dispensing device 1,85 is out of order, the drug dispensing device is used. It is also conceivable to enable the user to manually cancel the unprocessed prescription waiting from the unprocessed list of prescriptions stored in the control devices 1,85.
When the execution of the prescription is canceled by the manual operation, the drug dispensing devices 1 and 85 are changed to a state in which the user can select another drug dispensing device or a packaging machine. The user decides on a drug dispenser and a packing machine and runs the untreated prescription on the selected packing machine.

In principle, the drug dispensing devices 1 and 85 described above process the prescriptions received by the device in the order in which they are received and package the drugs one by one. If they have sex, the drugs may be packaged in order of priority.
Further, in the drug dispensing devices 1 and 85 described above, for example, 18 doses are continuously packaged, and if prescribed, the 18 doses are continuously packaged, except for a few doses in the drug container 4,80. It may be directly injected into the drug input port 39 from.

That is, if there is a problem in a part of the packaging result (foreign matter contamination, printing defect, etc.), or if the bag is torn, it may be desired to repack only a few packages.
Here, when packaging powders, as a general rule, it is necessary to distribute the drug to the distribution plate 35 and then package it, so even if you want to repackage by interruption, you must wait until the distribution plate 35 becomes empty. rice field.
Therefore, if the structure is such that the drug can be directly charged from the drug containers 4 and 80 into the drug inlet 39, the drug can be packaged even while the distribution dish 35 is in use.
In this case, the drug containers 4, 80 are installed in the container mounting device 36 and vibrated, and the drugs are discharged from the drug containers 4, 80 separately for each dose, and then charged into the drug inlet 39.
It is desirable to install the container mounting device 36 at a position where only one container can be dispensed directly from the drug containers 4 and 80 to the drug inlet 39 for interrupting a small number of packages.

In the drug dispensing device of the present embodiment, only one drug dispensing device 36 is mounted at a position where the drug container 4, 80 can be directly dispensed from the drug container 4, 80 to the drug packaging area 14.
If it is a small number of packages in a hurry, it can be packaged while being directly weighed from the container mounting device 36 even when it is being used in the distribution dish 35.

The drug dispensing device of the present embodiment acts on the drug containers 4, 80 to discharge the drug from the drug containers 4, 80, and puts the drug into the drug charging groove 32 of the distribution dish 35. The container mounting device 36 for loading the distribution dish is used, or the container mounting device 36 dedicated to the minority distribution is separately provided and the container mounting device 36 dedicated to the minority distribution is used, and the drug container 4 is used. , 80 can be discharged one dose at a time.

It is desirable that the inside of the housing 10 of the drug dispensing device is adjusted so that the temperature and humidity are within a certain range.
Specifically, it is desirable to have a heater, a cooler, a humidifier, and a dehumidifier, and adjust the temperature and humidity so as to be within a certain range.
That is, it is recommended to have a humidity adjusting means and to keep the internal humidity within a certain range.

As described above, the conventional drug dispensing device is a combination of a distribution dish and a powder feeder as disclosed in Patent Document 1, or a V-mass as disclosed in Patent Documents 3 and 4. The method is adopted. When using a traditional drug dispensing device, the pharmacist checks the doctor's prescription, removes the medicine bottle containing the prescribed powder from the medicine rack, and uses a scale such as a balance to remove the prescribed powder. It was necessary to weigh the total weight of the. In this way, the conventional drug dispensing device has to manually weigh the powder, which is troublesome.

The embodiments relating to the powder weighing device described below address this problem, and an object thereof is to propose a new powder weighing device and to simplify the packaging work.
Further, the aspect regarding the drug packaging system is to propose a drug packaging system in which a new powder weighing device and a conventional drug packaging device are combined.

In all of the drug dispensing devices of the above-described embodiment, the drug container 4 (or other form of the drug container and the same applies hereinafter) is held and moved by the container moving means 28, but instead of this, the drug container is moved. The drug discharged from 4 may be discharged by means of transportation.
FIG. 16 is a conceptual diagram of a drug dispensing device 100 that realizes this configuration.
The drug dispensing device 100 has an array shelf 101, and a plurality of pairs of powder discharge units 105 in which a drug container 4 and a container mounting device 36 are paired are installed on the array shelf 101.
Further, a measuring instrument (measuring means) 102 is installed in the vicinity of the array shelf 101. A temporary container 107 is placed on the measuring instrument 102. The temporary container 107 is, for example, a dish-shaped one.

The drug dispensing device 100 also has a distribution plate 35 and a drug charging port 39, as in the previous embodiment.
The drug dispensing device 100 also has a robot 106.
In the drug dispensing device 100, a powder feeder 201 is installed in the vicinity of the distribution dish 35. As shown in FIG. 17, the powder feeder 201 is composed of a charging hopper 205 and a powder feeder 206.
The powder feeder 206 is provided with two piezoelectric elements 207 and 208 under the trough 210 to vibrate the trough 210.

In the drug dispensing device 100 of the present embodiment, the container placing device 36 in the array shelf 101 is activated according to the prescription, and the drug is discharged from the drug container 4. The discharged drug is dropped into the temporary container 107 by a gutter (not shown).
The amount of the drug discharged from the drug container 4 is monitored by both the container placing device 36 and the measuring instrument 102. Then, when a predetermined amount of powder drops into the temporary container 107, the container mounting device 36 is stopped.
Then, the temporary container 107 is carried by the robot 106 to the vicinity of the charging hopper 205 of the powder feeder 201, and the powder in the temporary container 107 is charged into the charging hopper 205.
After that, the piezoelectric elements 207 and 208 of the powder feeder 206 are activated to vibrate the trough 210. As a result, the powder slowly moves toward the tip of the trough 210 and is rectified. Finally, the powder that moves at the head reaches the tip of the trough 210, and the powder that moves at the head falls from the tip of the trough 210 onto the distribution dish 35.
Subsequent operations are the same as in the previous embodiment.
A conveyor or the like can also be used in place of the robot 106.

In the drug dispensing device 100 of the present embodiment, there is a powder feeder 201 that gradually drops powder in the vicinity of the distribution dish 35, and the drug discharging device (container mounting) that acts on the drug container 4 to discharge the drug from the drug container 4. A device 36), a temporary container 107 for receiving the drug discharged from the drug container 4, and a temporary container transport means (robot 106) for transporting the temporary container 107 to the powder feeder 201. Is discharged from the drug container and the powder is charged into the temporary container 107, the temporary container 107 is moved to the powder feeder 201 by the temporary container transport means, and the powder is charged from the powder feeder 201 into the distribution dish 35.

Further, as in the drug dispensing device 120 shown in FIG. 18, a plurality of powder discharging units 105 in which a drug container 4 and a container mounting device 36 are paired are arranged radially and in a plurality of stages on a distribution dish 35. Things are also possible.
In the drug dispensing device 120, the container placing device 36 in the array shelf 101 is activated according to the prescription, and the drug is discharged from the drug container 4. The discharged drug is dropped onto the distribution dish 35 by a gutter (not shown).
Subsequent operations are the same as in the previous embodiment.

Further, these modifications will be described. The drug dispensing device 121 shown in FIG. 19 has a container mounting device (drug discharging means) 36 installed in the vicinity of the measuring instrument (measuring means) 102. The container mounting device 36 adopted in this embodiment is basically the same as that of FIG. 5 described above, but the weight measuring means (measuring means) 52 is not essential.

In the present embodiment, the drug container 4 is arranged in the array shelf 101. Further, in the present embodiment, the robot 106 functions as a drug container transporting means for transporting the drug container 4 from the array shelf 101 to the container mounting device 36.
In the present embodiment, the necessary drug container 4 is taken out from the array shelf 101 by the robot 106 and installed in the container mounting device (drug discharge means) 36.
Then, the container placing device 36 is activated, and the medicine is discharged from the medicine container 4. The discharged drug directly falls into the temporary container 107.
The amount of the drug discharged from the drug container 4 is monitored by the measuring instrument 102. Then, when a predetermined amount of powder drops into the temporary container 107, the container mounting device 36 is stopped.

The drug dispensing device 100 shown in FIG. 16 and the drug dispensing device 121 shown in FIG. 19 have a function of weighing the drug, a function of dividing the drug, and a function of individually packaging the drug.
Of the drug dispensing device 100 shown in FIG. 16 and the drug dispensing device 121 shown in FIG. 19, it is also possible to commercialize only the portion having the function of weighing the drug independently.
That is, in the drug dispensing device 100 shown in FIG. 16, the powder weighing device 500 is configured by the array shelf 101, the measuring instrument (measuring means) 102, and the powder discharging unit 105 in the array shelf 101.
Further, in the drug dispensing device 121 shown in FIG. 19, the array shelf 101, the measuring instrument (measuring means) 102, the robot (drug container transporting means) 106, and the container mounting device (drug) arranged in the vicinity of the measuring instrument 102. The powder weighing device 501 is configured by the discharging means) 36.

FIG. 20 is a conceptual diagram showing an example of a drug packaging system 122 using powder weighing devices 500 and 501. Although the powder weighing device 500 shown in FIG. 16 is shown as a representative in FIG. 20, the powder weighing device 501 shown in FIG. 19 may be adopted instead of the powder weighing device 500 shown in FIG. 21 and the following embodiments illustrate any of the powder weighing devices 500 and 501, but it is arbitrary which one is adopted.

The drug packaging system 122 includes a powder weighing device 500, a weighing pan moving conveyor (temporary container transporting means) 103, and a drug packaging device 125. The drug packaging device 125 adopts a distribution dish system.
The weighing dish moving conveyor 103 is a transfer device provided between the powder weighing device 500 and the drug packing device 125, and a weighing dish reversing device (not shown) is provided in the vicinity of the drug packing device 125.
The drug packaging device 125 includes a powder dispensing device (drug dividing means) 902 and a drug packaging device (drug packaging means) 903.
The powder distribution device 902 has a hopper (drug charging unit) 905 for charging powder, and divides the powder charged into the hopper 905 into a predetermined number.
The drug packaging device 903 individually packages the divided powders.
As described above, the powder weighing device 500 takes out the powder from the drug container 4 by the drug discharging means, transfers the powder to the temporary container 107, and directly measures the weight of the powder transferred to the temporary container 107 by the measuring instrument 102 as the weight measuring means. It has a drug discharge control means for performing an operation of transferring a predetermined amount of powder to the temporary container 107.
The temporary container 107 to which a predetermined amount of powder is transferred is conveyed to the vicinity of the drug packaging device 125 by the weighing dish moving conveyor 103, and the temporary container 107 is tilted by the weighing dish reversing device (not shown) to form a hopper (drug). The powder is charged into the charging unit) 905. Then, the drug is divided into a predetermined number by the drug packaging device 125 and individually packaged.

FIG. 21 is a conceptual diagram showing another example of a drug packaging system using powder weighing devices 500 and 501.
The drug packaging system 123 shown in FIG. 21 includes a powder weighing device (drug weighing means) 501, a weighing pan moving conveyor (temporary container transporting means) 103, and a drug packaging device 126. The drug packaging device 126 employs a V-mass system.
The V-mass type drug packaging device has a horizontally elongated V-mass (powder charging section) 930. A plurality of divided containers 931 are arranged at the bottom of the V box.
In the V-Masu type drug packaging device, the powders for a plurality of doses are weighed, and the powders for a plurality of doses are charged into the V-Masu 930. After that, use a spatula to evenly spread the powder. Then, the shutter provided in the lower part of the V-basin 930 is opened, and the powder in the V-basin 930 is charged into the lower split container 931. Then, the powder in each divided container 931 is individually packaged.

FIG. 22 is a perspective view showing an example of another drug packaging system 301 using the powder weighing device 500 or the powder weighing device 501.
The drug packaging system 301 of the present embodiment includes a powder weighing device 500, a drug packaging device 305, and a weighing dish moving device (temporary container transporting means) 306.
The drug packaging device 305 is a known distribution dish type drug packaging device.

The weighing pan moving device 306 is a known robot. The weighing pan moving device 306 has a function as a temporary container moving means for taking out the temporary container 107 from the temporary container accommodating shelf (not shown) and placing it on the measuring instrument 102, and transports the temporary container 107 from the measuring instrument 102 to the drug packaging device 305. It has a function as a temporary container transporting means.

In the embodiment described above, the distribution dish type drug packaging device is adopted as the drug packaging device 305, but the type of the drug packaging device is arbitrary. FIG. 23 is a perspective view when a V-mass type drug packaging device 307 is adopted as the drug packaging device.
It is also possible to move the temporary container 107 taken out from the weight measuring means 22 by the weighing pan moving device 306 to the V-mass type drug packaging device 307, and tilt the temporary container 107 to the V-mass portion 308 to charge powder. be. After that, the powder in the V-basin may be leveled manually, or a method of automatically leveling the powder may be adopted.

In the embodiment described above, the container mounting device 36 is adopted as the drug discharging means, and the drug container 4 is vibrated to take out the powder. In the present embodiment, the container mounting device 36, which is a drug discharging means, is an external force applying means for applying an external force to the drug container 4 to vibrate, and the external force applying means applies a vibration to the drug container 4 to cause powdering from the drug container 4. Is to discharge.
As another drug discharging means, a method of putting an instrument in the drug container 4 and scraping out the powder, or a method of incorporating a spiral conveyor or the like in the drug container and driving the spiral conveyor or the like from the outside can be considered.
For example, there is a scraping member or a spiral conveyor as a part of the drug discharging means, and the scraping member or the spiral conveyor is in the drug container. Then, the powder is discharged from the powder discharge unit by driving the scraping member or the spiral conveyor in the medicine container by an external force applying means such as a motor provided outside.
A motor may be built in the drug container. Further, the motor may be externally attached to the drug container. The drug may be discharged from the drug container using air pressure or wind.

It is also conceivable to provide a spiral groove as a part of the drug discharging means on the inner surface of the drug container and rotate the drug container by the external force applying means to discharge the powder.

1,85 Drug dispensing device 4,70,80,140 Drug container 10 Housing 12 Container placement area 13 Drug division area 14 Drug packaging area 28 Container moving means 30 Arm portion 32 Drug loading groove 35 Distribution dish 36 Container mounting device ( Drug discharge means)
39 Drug inlet 40 Camera member (photographing device)
47 Hand part 50 Shaking table 52 Weight measuring means (measuring means)
53 Drug packaging device 60 Nozzle section 61 Cleaning device 62 Vibration generator 65 Distance measuring sensor 66 Spectrometer 81, 82 Shape changing member 86 Solid drug feeder 102 Measuring instrument (measuring means)
103 Weighing dish moving conveyor (temporary container transport means)
107 Temporary container 122,123,301 Drug packaging system 500,501 Powder weighing device

Claims (7)

A powder weighing device that takes out a predetermined amount of powder from a drug container.
It has a drug discharge means that acts on the drug container to discharge the powder from the drug container, a temporary container that receives the powder discharged from the drug container, and a fixed measuring means.
Place the temporary container on the weighing means and place it on the measuring means.
Monitor the amount of powder discharged from the drug container with a fixed weighing means,
A powder weighing device characterized in that a desired amount of powder is discharged from a drug container by a drug discharging means and the powder is charged into a temporary container. It has a drug discharge means that acts on the drug container to discharge the powder from the drug container, a temporary container that receives the powder discharged from the drug container, a measuring means, and a temporary container transport means that transports the temporary container.
Place the temporary container on the weighing means and place it on the measuring means.
Monitor the amount of powder discharged from the drug container with a weighing means,
A powder weighing device characterized in that a desired amount of powder is discharged from a drug container by a drug discharging means, the powder is charged into the temporary container, and the temporary container is moved by the temporary container transporting means. The drug container has a powder storage unit for storing powder and a powder discharge unit for discharging powder.
The powder weighing according to claim 1 or 2, wherein the drug container has a part or all of the drug discharging means, and the powder is taken out from the powder discharging section by driving the drug discharging means in the drug container. Device. The drug container has a powder storage unit for storing powder and a powder discharge unit for discharging powder.
The drug discharging means is a vibrating means for vibrating the drug container installation portion, and the weight measuring means is characterized in that it indirectly monitors the weight of the powder transferred to the temporary container from the weight change of the drug container. The powder weighing device according to any one of claims 1 to 3. A powder weighing device equipped with an array shelf, a drug container, a container mounting device that acts on the drug container to discharge the powder from the drug container, a temporary container that receives the powder discharged from the drug container, and a weighing means. There,
The array shelf has a plurality of powder discharge units in which a drug container and a container mounting device are paired.
When the container mounting device is activated according to the prescription, the powder is discharged from the drug container of the powder discharge unit into the temporary container, and the amount of the powder discharged into the temporary container is monitored by the measuring means. Weighing device. The powder weighing device according to claim 5, wherein the amount of powder discharged into the temporary container is monitored by a measuring means, and the container mounting device is stopped when a predetermined amount of powder falls into the temporary container. .. The powder weighing device according to any one of claims 1 to 6 and a drug packaging device that divides the drug into a desired number and individually packages the drug, and manually or automatically dispenses the powder in the temporary container. A drug packaging system characterized by being able to be loaded into a packaging device.

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