The following description relates to a module for adjusting the quantity of various-shaped tablets in an automatic tablet dispenser which is installed in a medicine packing machine, and a tablet dispensing method thereof, and more particularly, to a module for adjusting the quantity of various-shaped tablets in an automatic tablet dispenser and a tablet dispensing method thereof, which can accurately and rapidly control supplying of tablets without missing any.
In general, a medicine packing machine is used to automatically pack tablets when a doctor or pharmacist prepares a medicine based on a prescription at hospital or drugstore.
Conventional medicine packing machines can be classified into manual packing machines and automatic packing machines. The manual packing machine and the automatic packing machine are different in view of distributing tablets manually or automatically, but the same in view of automatically packing tablets and discharging medicine packages to the outside.
That is, the manual packing machine includes a circular or quadrilateral distribution tray with a plurality of holes. A doctor or pharmacist puts tablets into the holes manually, generally, puts tablets corresponding to a dose of medicine into each hole. The tablets put into the holes are packed by a packing unit provided in the lower portion of the manual packing machine, and then discharged to the outside.
Also, the automatic packing machine includes a plurality of cassettes which are arranged in the form of a plurality of drawers or in the form of a plurality of drums, in the upper portion. Tablets are classified depending on their kinds and stored in the cassettes. The tablets stored in the cassettes are discharged from the cassettes based on data received from a computer interfacing the automatic packing machine. The discharged tablets are collected in a hopper provided below the cassettes, and packed in the packing unit provided below the hopper.
The manual packing machine can be manufactured as a small-sized machine, and suitable to be used at a small drugstore or hospital, and the automatic packing machine is suitable to be used at a large drugstore or hospital where a large amount of medicines is prepared. Also, a combination of a manual packing machine and automatic packing machine is being used at some drugstores or hospitals.
However, cassettes installed in a conventional automatic packing machine cannot automatically discharge pieces of tablets such as half tablets or various-shaped tablets. Accordingly, pieces of tablets or various-shaped tablets should be supplied manually using a manual packing machine. Accordingly, the conventional medicine packing machine has a problem that a time consumed to prepare a medicine is long and reliability of medication is low due to mistakes, such as over-dosage or under-dosage of medication.
Meanwhile, since in the conventional medicine packing machine a doctor or pharmacist picks up and distributes tablets with his or her hand, there is a risk of bacterial infection due to the direct contact of the hand or other mediums. If tablets infected with even a bit of bacteria due to the direct contact of a human's hand, etc. are absorbed in the body, this may cause fatal diseases to serious cases with low immunity.
According to an aspect, there is provided a quantity regulating module of an automatic tablet dispenser, and a tablet dispensing method thereof, which are capable of automatically packing various-shaped tablets, and accurately, rapidly and cleanly controlling supplying of tablets without missing any.
Therefore, according to the quantity regulating module of the automatic tablet dispenser and the tablet dispensing method thereof, it is possible to automatically pack various-shaped tablets, and accurately, rapidly and cleanly control supplying of tablets without missing any.
The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the principles of the invention.
The invention is described more fully hereinafter with reference to the accompanying drawings, in which exemplary embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the exemplary embodiments set forth herein. Rather, these exemplary embodiments are provided so that this disclosure is thorough, and will fully convey the scope of the invention to those skilled in the art. In the drawings, the size and relative sizes of layers and regions may be exaggerated for clarity. Like reference numbers in the drawings denote like elements.
Referring to
The automatic tablet dispenser 100 supplies tablets by a predetermined number to the hopper 120, and the tablets are packed together with tablets supplied from the cassettes 110 in the packing unit 130. The automatic tablet dispenser 100 can supply tablets to the hopper 120 in various ways. For example, the automatic tablet dispenser 100 supplies tablets to the hopper 120 through a conveyer, or using one of other various ways.
According to an embodiment, the automatic tablet dispenser 100 transfers tablets by vibration. That is, the automatic tablet dispenser 100 causes tablets to move in a line along a track by vibration after pouring the tablets into a predetermined space.
A quantity regulating module 50, which is installed in the automatic tablet dispenser 100, supplies the tablets transferred in a line along the track one by one or by a predetermined number to the hopper 120.
Referring to
The module body 10 includes an inlet 11, a hopper-side supply part 12, and a recollecting part 13. The inlet 11 is a passage through which tablets transferred along a track, etc. are put, and is seen by opening the upper part of the module body 10. The hopper-side supply part 12 transfers tablets put through the inlet 11 to the hopper 120 of the medicine packing machine 200 (see
The hopper-side supply part 12 and the recollecting part 13 each is assembled in such a manner as to rotate by a hinge 16 connected to its one end. The hopper-side supply part 12 and the recollecting part 13 each discharges tablets contained in the module body 10 to the outside, or prevents the tablets from being discharged to the outside. Accordingly, two different paths may be provided in which tablets discharged from the hopper-side supply part 12 are supplied to the hopper 120, and tablets discharged from the recollecting part 13 are recollected and redistributed or discharged out of the medicine packing machine. A partition may be provided between the hopper-side supply part 12 and the recollecting part 13.
Also, a solenoid valve 15 is connected to each of the hopper-side supply part 12 and the recollecting part 13 so that the hopper-side supply part 12 and the recollecting part 13 are rotatively driven to be opened or closed. Also, a spring 14 is connected to each of the hopper-side supply part 12 and recollecting part 13, so that the hopper-side supply part 12 and the recollecting part 13 are closed automatically by restoring force of the spring 14, not by separate driving force.
The detecting sensor 20 is disposed at a proper location in the module body 10, and counts the number of tablets put through the inlet 11.
The controller compares the number of tablets counted by the detecting sensor to a predetermined quantity, and opens the hopper-side supply part 12 if the counted value is equal to the predetermined quantity, and opens the recollecting part 13 if the counted value exceeds the predetermined quantity.
That is, the controller interfaces the detecting sensor 20, and compares the number of tablets counted by the detecting sensor 20 to a predetermined quantity set by key manipulation, etc. Then, if the counted value is equal to the predetermined quantity, the tablets are discharged to the hopper 120 and packed in a packing unit 130. However, if the counted value exceeds the predetermined quantity, the tablets are fed back to a location from which the tablets start to be transferred.
As illustrated in
That is, when no tablet passes through the detecting sensor 20, light emitted from the light-emitting part 21 is all received by the light-receiving part 22, so that an “On” signal is generated, and when a tablet passes through the detecting sensor 20, light emitted from the light-emitting part 21 is intercepted by the tablet and accordingly the light-receiving part 22 does not receive the light, so that an “Off” signal is generated. In this manner, the detecting sensor 20 counts the number of tablets passing through the light-emitting part 21 and light-receiving part 22 on the basis of the “On” and “Off” signals.
Basically, when the number of tablets fallen down through the inlet 11 reaches one or a desired number, the automatic tablet dispenser 100 stops vibration temporarily and prevents the following tablet from being fallen down. However, the case where the following tablet falls down due to inertial force of tablets moving along the track may occur. When such an unwanted successive dropping of two tablets occurs, by accurately detecting “On” and “Off” signals with a time difference between times at which the two tablets fall down, the detecting sensor 20 can accurately detect the number of tablets put into the module body 10 without any error.
Also, when half tablets or tablet pieces are supplied, two tablets positioned very closely to each other can be recognized as a single tablet. However, in this case, since the tablets fall down while being separated apart by free-falling, the detecting sensor 20 senses whether light passes though a gap between the two tablets separated apart, thus accurately counting the number of tablets.
The light-emitting part 21 may be positioned in correspondence to the light-receiving part 22. Accordingly, it is possible to more accurately count the number of tablets passing between the light-emitting part 21 and light-receiving part 22, and reduce possible errors of recognizing two tablets as a single object. That is, a pair of detecting sensors include a plurality of light-emitting parts 21 and a plurality of light-receiving parts 22, which are densely arranged, in such a manner that the light-emitting parts 21 can be positioned in correspondence to the light-receiving parts 22. Accordingly, a tablet passing between the pair of detecting sensors can be detected over a wide range.
Referring to
Also, as illustrated in
Meanwhile, the module body 10 can further include a stopper. The stopper drops a tablet rapidly into the inlet 11 or prevents the following tablet from being dropped down unwantedly, when the detecting sensor 20 senses the presence of the tablet.
As illustrated in
The quantity regulating module 50 includes a rotating member 60 and a motor 70.
The rotating member 60, which is disposed below the inlet 11, includes a plurality of wings 61, 62 and 63 positioned in the radial direction and receives tablets 30 falling down through the inlet 11. The rotating member 60 discharges a tablet 30 selectively to the hopper-side supply part 12 or to the recollecting part 13 according to the rotation direction.
The motor 70 receives a signal from the controller, and rotates the rotating member 60 forward or backward, that is, in the clockwise direction or in the counterclockwise direction.
The rotating member 60 is connected to the motor 70, and rotated in the clockwise direction or in the counterclockwise direction in the module body 10. The rotating member 60 includes the plurality of wings 61, 62 and 63 positioned in the radial direction, for example, in the shape of a wind sail or water-wheel. For example, the motor 70 is installed on the rear of a back module body 10′ the rotating member 60 is linked to the axis of the motor 70 and then a front module body 10″ is coupled with the back module body 10, thereby completing an assembly. The hopper-side supply part 12 and the recollecting part 13 are disposed below the rotating member 60, so that tablets fallen on the rotating member 60 are discharged to the hopper 120 or to the location from which the tablets start to be transferred.
In this case, the wings 61, 62 and 63 may be positioned at angles of 120°. As such, if the wings 61, 62 and 63 are positioned at the same angle of 120°, the wings 61, 62 and 63 can efficiently receive and discharge tablets. However, it will be understood by one of those skilled in the art that a plurality of wings can be positioned at predetermined angles, for example, at angles of 90°.
Meanwhile, the module body 10 can further include a discharge unit 19 for discharging tablets transferred to the recollecting part 13 to the outside. The discharge unit 19 includes a door 19a for discharging tablets to the outside and a solenoid 19b for driving the door 19a.
The operation of the quantity regulating module 50 will be described in detail with reference to
As such, the tablet 30 is discharged to the hopper-side supply part 12 or to the recollecting part 13 in a rotating manner, and accordingly, smooth driving is possible and no noise is generated. Also, it is prevented a phenomenon where a tablet is adhered to the inner wall of the module body 10 when the tablet is discharged. Also, when the first, second and third wings 61, 62 and 63 of the rotating member 60 are rotated, a tablet dropped between the first and second wings 61 and 62 is discharged by a single rotation to the hopper-side supply part 12 or recollecting part 13, and simultaneously the third wind 63 is ready to receive the following tablet that is to fall via the inlet 11, so that the entire structure becomes stable and energy efficiency is enhanced.
Meanwhile, as illustrated in
As illustrated in
The supply unit is used to supply tablets to the hopper 120 of the medicine packing machine 200 (see
That is, the supply unit can be comprised of a body 210 and a vibrating unit 220.
The body 210 is in a cylindrical shape whose upper part is opened and whose lower part is closed. The body 210 includes a guide track 211 therein. The guide track 211 has a spiral shape extending from the bottom to the upper part of the body 210. The guide track 211 is a passage through which tablets contained in the body 210 are transferred.
The vibrating unit 220 causes tablets contained in the body 210 to be transferred along the guide track 211. The vibrating unit 220 is installed below the body 210, and provides a soft vibration to the body 210 in the clockwise direction or in the counter-clockwise direction. Accordingly, tablets contained in the body 210 are transferred upward along the guide track 211.
The transfer passage 262, as illustrated in
The first door 280 is opened when the number of tablets supplied from the supply unit is equal to a predetermined quantity. The first door 280 may be opened to the transfer passage 262. The first door 280 may be constructed by connecting at least one door plate (in the current embodiment, three door plates 281, 281 and 283 positioned in the radial direction) to a motor. The number of the door plates 281, 282 and 293 may be three, two or four. Meanwhile, the first door 280 may be in the shape of a single plate connected to a solenoid.
The second door 290 is disposed between the first door 280 and the hopper 120, and opens or closes the transfer passage 262. The second door 290 may be disposed near the center of the first door 280 and the hopper 120. The second door 290 is opened in response to a signal of a main controller of the medicine packing machine 200. Since the second door 290 is disposed on the transfer passage 262, a time consumed to transfer tablets supplied from the supply unit to the hopper 120 can be reduced.
The main controller performs the entire control related to causing cassettes 110 to discharge tablets so that the tablets are collected in the hopper 120 of the medicine packing machine 200.
If the second door 290 is not provided, tablets supplied from the supply unit are discharged from the first door 280 to the hopper 120. The transfer distance of tablets becomes the length of the transfer passage 262 connecting the supply unit to the hopper 120. A time consumed to transfer tablets is proportional to the length of the transfer passage 262, and reducing the length of the transfer passage is impossible in view of the construction of the medicine packing machine 200.
However, in the medicine packing machine 200, tablets are supplied from a plurality of cassettes 110, as well as from the supply unit, and also a powdered medicine can be supplied separately, and the tablets and powdered medicine are all collected in the hopper 120 and then packed for each dose of medicine. Accordingly, the tablets discharged through the cassettes 110 disposed above the hopper 120 reach the hopper 120 rapidly by free-falling, and the powered medicine can also reach the hopper 120 in a short time because the powered medicine is supplied adjacent to the hopper 120.
That is, in the quantity regulating module 250 according to the current embodiment, the second door 290 is disposed at a proper location of the transfer passage 262 so that tablets supplied from the supply unit do not start from the first door 280 but start from a location adjacent to the hopper 120. According to a test result, the transfer time of tablets when the second door 290 is provided is much shorter than the transfer time of tablets when the second door 290 is not provided.
When the second door 290 is opened to discharge tablets to the hopper 120, the controller causes the supply unit to supply another tablet. Also, simultaneously, the controller maintains the first door 280 closed when a tablet exists between the first door 280 and the second door 290. That is, the first door 280 is opened when it is determined that no tablet exists between the first door 280 and the second door 290. Accordingly, the first door 280 is opened only when the number of tablets discharged from the supply unit is equal to the predetermined quantity and no tablet exists between the first door 280 and the second door 290.
Meanwhile, the quantity regulating module 250 can further include a recollecting passage 263. The recollecting passage 263 is used to return tablets supplied from the supply unit to the supply unit when the number of the tablets exceeds the predetermined quantity. That is, the first door 280 rotates in the counterclockwise direction when the number of tablets supplied from the supply unit exceeds the predetermined quantity, and discharges the tablets to the recollecting passage 263. The recollected tablets are returned to the body 210 via a recollecting barrel 215.
Also, the second door 290 may be implemented in such a manner that a plurality of door plates 291, 292, 293 and 294 for opening or closing the transfer passage 262 are positioned in the radial direction. The motor may be a step motor which is rotated by 90 upon each operation. The door plates 291, 292, 293 and 294 form a tolerance of an acute angle downward toward the bottom of the transfer passage 262, thereby preventing tablets from being caught by the door plates 291, 292, 293 and 294.
Also, concave curved parts 299 are formed at intersections of the door plates 291, 292, 293 and 294, in order to prevent tablets from being caught by the door plates 291, 292, 293 and 294. Specifically, the concave curved parts 299 can prevent small-sized tablets or tablets having sharp ends from being caught at the intersections of the door plates 291, 292, 293 and 294.
As shown in
In operation S1, tablets are supplied from the supply unit. The supply unit can be implemented in such a manner as to vibrate a body containing tablets therein using a vibrating unit. The tablets contained in the body 210 are transferred upward along a guide track formed on the inner wall of the body by vibration of the vibrating unit, and then discharged through an outlet.
In operation S2, it is determined whether the number of tablets discharged from the supply unit is equal to a predetermined quantity. In operation S2, the determination can be performed by a sensor for counting the number of tablets. For example, as described above, when it is assumed that tablets are transferred by vibration of the vibrating unit and the predetermined quantity is one tablet, if a single tablet falls down from the outlet of the guide track, the above condition is satisfied. However, if another tablet unwantedly falls down after a single tablet falls down through the outlet 213, the above condition is not satisfied.
In operation S4, it is determined whether a tablet exists between the first door and the second door. When the second door remains closed after the first door is opened and a tablet is discharged to the second door, it can be determined that a tablet exists between the first door and the second door. Meanwhile, when the first door is not opened after the second door is opened and a tablet is discharged, it can be determined that no tablet exists between the first door and the second door.
In operation S5, the first door is maintained closed if a tablet exists between the first door and the second door.
In operation S6, the first door is opened and the tablet is transferred to the second door if no tablet exists between the first door and the second door.
In operation S7, the second door is opened in response to a signal of a controller and the tablet is discharged to the hopper. The operation S7 may be controlled by a main controller of a medicine packing machine.
Meanwhile, after the first door is opened and a tablet is discharged toward the second door, operation of supplying another tablet from the supply unit to the second door may be performed.
Accordingly, when the second door is opened and the tablet is discharged to the hopper, simultaneously, other tablets are transferred from the first door to the second door and from the supply unit to the first door. Also, the tablet dispensing method can further include operation S3 of recollecting tablets in the supply unit when the number of the tablets exceeds a predetermined quantity.
In operation S3, the tablets can be returned to the supply unit through a recollecting passage by rotating the first door in the counterclockwise direction.
It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Thus, it is intended that the present invention covers the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.
The automatic tablet dispenser according to the present invention can be applied to various automatic packing machines.
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WO2009/038380 | 3/26/2009 | WO | A |
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